Pharmaceutical combinations for cancer treatment

ABTL0812, a polyunsaturated fatty acid derivative, is used in combination with chemotherapeutic, targeted, and immunotherapy agents to address the limitations of existing treatments, enhancing cancer therapy efficacy across multiple treatment modalities.

JP2026098001APending Publication Date: 2026-06-16ABILITI FARMASYUTIKALS SL

Patent Information

Authority / Receiving Office
JP · JP
Patent Type
Applications
Current Assignee / Owner
ABILITI FARMASYUTIKALS SL
Filing Date
2026-03-10
Publication Date
2026-06-16

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Abstract

This invention provides a novel combination therapy for second-line cancer treatment in human patients. [Solution] A pharmaceutical combination comprising a polyunsaturated fatty acid compound (A) represented by the following formula and a checkpoint inhibitor (B3) represented by an anti-PD1 antibody such as pembrolizumab. The combination may further include chemotherapeutic agents such as temozolomide, bortezomib, fluorouracil, leucovorin, irinotecan, oxaliplatin, paclitaxel, and carboplatin. Formula: COOR1-CHR2-(CH2)a-(CH=CHCH2)b-(CH2)c-CH3 [a is an integer between 0 and 7; b is an integer between 2 and 7; c is an integer between 0 and 7; R1 is H, Na, K, etc.; R2 is OH, etc.]
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Description

[Technical Field]

[0001] This invention relates to the use of ABTL0812 in the treatment of cancer in human patients, wherein the cancer treatment relates to chemotherapy, targeted therapy, immunotherapy, or radiotherapy. [Background technology]

[0002] EP2409963B1 (Lipopharma - filed in 2010) describes the use of 1,2-derivatives of polyunsaturated fatty acid (called D-PUFA) compounds for the treatment of cancer. The fatty acid derivative compounds described have the following formula: COOR1-CHR2-(CH2)a-(CH=CH-CH2)b-(CH2)c-CH3 Examples of preferred compounds are as follows: COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(182A1)

[0003] The paper “Erazo, et al.; Clinical Cancer Research; 22(10) May 15, 2016” provides a more detailed description of the above compound (182A1), which is referred to as “ABTL0812” in this paper, and this term is used herein.

[0004] As is well known in the art, pharmacological treatment of cancer is generally based on four major drug groups, including chemotherapy, targeted therapy, hormone therapy, and immunotherapy. Furthermore, radiation therapy is also a fundamental part of cancer treatment, often administered multiple times in conjunction with drug therapy.

[0005] WO2018 / 210830A1 (Ability Pharmaceuticals) describes the use of ABTL0812 compounds in combination with other chemotherapeutic agents in the treatment of cancer, for example, in relation to first-line therapy, such as the pharmaceutical combination of ABTL0812 with the chemotherapeutic agents docetaxel, paclitaxel, carboplatin, or cisplatin. [Overview of the project]

[0006] Starting with WO2018 / 210830A1 (Ability Pharmaceuticals) as the most relevant prior art document (the so-called closest prior art document), the problem solved by the present invention can be considered as providing an alternative use of ABTL0812 that may result in improved treatment of cancer.

[0007] As discussed above, the compound COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3 is referred to herein as ABTL0812.

[0008] As discussed above, WO2018 / 210830A1 (Ability Pharmaceuticals) describes the use of ABTL0812 compounds in combination with other chemotherapeutic agents in the treatment of cancer, for example, in relation to first-line therapy, such as the pharmaceutical combination of ABTL0812 with the chemotherapeutic agents docetaxel, paclitaxel, carboplatin, or cisplatin.

[0009] WO2018 / 210830A1 (Ability Pharmaceuticals) does not directly and clearly describe the use of ABTL0812 in second-line therapy for cancer treatment, and for example, the terms “second-line” or “second-choice” in relation to second-line therapy are not even mentioned in WO2018 / 210830A1.

[0010] The examples herein provide reasonable and detailed experimental data demonstrating significant synergistic effects, for example, with regard to the use of the ABTL0812 compound discussed in combination with other chemotherapeutic agents for second-line treatment of cancer in human patients.

[0011] Compound ABTL0812 is structurally and functionally similar to other 1,2-derivatives of polyunsaturated fatty acid (D-PUFA) compounds, as described in EP2409963B1 discussed above. Therefore, it is reasonable to assume that, at first glance, substantially all fatty acid derivative compounds of EP2409963B1 would have synergistic effects relevant to this specification when combined with chemotherapeutic agents and / or other preferred cancer treatments discussed herein.

[0012] Therefore, a first aspect of the present invention is (A): Compounds that are polyunsaturated fatty acids of the formula COOR1-CHR2-(CH2)a-(CH=CHCH2)b-(CH2)c-CH3, pharmaceutically acceptable salts thereof, or combinations thereof (i) a can be any integer value from 0 to 7, (ii)b can be any integer value between 2 and 7, (iii) c can be any integer value from 0 to 7, (iv) R1 is H, Na, K, CH3, CH3-CH2, or PO(O-CH2-CH3)2, (v) R2 is OH, OCH3, O-CH2COOH, CH3, Cl, CH2OH, OPO(O-CH2-CH3)2, N(OH)2, F, HCOO, or N(OCH2CH3)2. Compounds, their pharmaceutically acceptable salts, or combinations thereof, (B1): A chemotherapeutic agent compound, This relates to a pharmaceutical combination comprising a chemotherapeutic compound and a treatment for simultaneous, separate, or sequential use in the treatment of cancer in human patients, wherein the treatment is a second-line therapy for cancer.

[0013] As is known in the art, the first-line therapy is the treatment regimen(s) generally accepted by medical institutions for the initial treatment of a given type and stage of cancer. It is also referred to as primary treatment or therapy. The purpose of the first-line therapy is, if possible, to cure the cancer. This primary therapy, also called induction therapy, is the first attack of chemotherapeutic drugs against a malignancy.

[0014] In line with the common and general knowledge of those skilled in the art, the term "second-line therapy" of the first aspect relates to second-line treatment attempts when the first-line therapy does not function properly. The management of cancer cases requires regular evaluation of the treatment and adjustment as needed. Interruption of the primary therapy treatment and adoption of a new regimen are signs of "second-line therapy" treatment.

[0015] As understood by those skilled in the art in the current situation, the term "second-line therapy" requires that patients on first-line therapy be treated with a profile / mixture of cancer agents that is different from the profile / mixture of cancer agent(s) of the "second-line therapy".

[0016] It can be said that if the profile / mixture of cancer agent(s) of the second-line therapy functions satisfactorily (i.e., cures the patient's cancer), perhaps there will be no need to use the "second-line therapy".

[0017] As a mere example, in the current situation, the first-line therapy can involve, for example, the use of docetaxel, paclitaxel, and perhaps also ABTL0812, and then the second-line therapy can be, for example, ABTL0812 in combination with temozolomide, as discussed in Example 1.1 herein, and can be a cancer agent(s) of a different profile / mixture.

[0018] According to the technical field, chemotherapy is a type of cancer treatment that uses one or more anticancer drugs (chemotherapeutic agents) as part of a standardized chemotherapy regimen. The term chemotherapy has come to imply the non-specific use of intracellular toxic compounds to inhibit mitosis, or cell division; that is, chemotherapeutic agents are understood to be compounds that interfere with cell replication. Because DNA / cell replication is a common process that all cells use when they want to make more copies of themselves, chemotherapy cannot distinguish between cancer cells and normal cells. Therefore, classical chemotherapy can have serious side effects.

[0019] As discussed above, WO2018 / 210830A1 (Ability Pharmaceuticals) describes the use of ABTL0812 compounds in combination with other chemotherapeutic agents in the treatment of cancer, and therefore this document does not directly and explicitly describe the use of ABTL0812 in targeted therapies, immunotherapies, and / or radiotherapy for the treatment of cancer.

[0020] The examples herein provide reasonable and detailed experimental data demonstrating significant positive effects with regard to the use of the ABTL0812 compounds discussed above in targeted therapy, immunotherapy, or radiotherapy for the treatment of cancer in human patients.

[0021] Therefore, a second aspect of the present invention is, (A): Compounds that are polyunsaturated fatty acids of the formula COOR1-CHR2-(CH2)a-(CH=CHCH2)b-(CH2)c-CH3, pharmaceutically acceptable salts thereof, or combinations thereof (i) a can be any integer value from 0 to 7, (ii)b can be any integer value between 2 and 7, (iii) c can be any integer value from 0 to 7, (iv) R1 is H, Na, K, CH3, CH3-CH2, or PO(O-CH2-CH3)2, (v) R2 is OH, OCH3, O-CH2COOH, CH3, Cl, CH2OH, OPO(O-CH2-CH3)2, N(OH)2, F, HCOO, or N(OCH2CH3)2. Compounds, their pharmaceutically acceptable salts, or combinations thereof, (B2): A targeted therapy compound, This relates to pharmaceutical combinations comprising targeted therapy compounds and a treatment for simultaneous, separate, or sequential use in the treatment of cancer in human patients, wherein the treatment is a targeted therapy for cancer.

[0022] The term “targeted therapy” in the second aspect should be understood in accordance with the art. As is well known in the art, targeted therapy, or molecular targeted therapy, is one of the main forms of medical treatment (drug therapy) for cancer, the other being, for example, cytotoxic chemotherapy. As a form of molecular medicine, targeted therapy blocks the growth of cancer cells by interfering with specific target molecules necessary for carcinogenesis and tumor growth, rather than simply interfering with all dividing cells (for example, by conventional chemotherapy).

[0023] A third aspect of the present invention is: (A): Compounds that are polyunsaturated fatty acids of the formula COOR1-CHR2-(CH2)a-(CH=CHCH2)b-(CH2)c-CH3, pharmaceutically acceptable salts thereof, or combinations thereof (i) a can be any integer value from 0 to 7, (ii)b can be any integer value between 2 and 7, (iii) c can be any integer value from 0 to 7, (iv) R1 is H, Na, K, CH3, CH3-CH2, or PO(O-CH2-CH3)2, (v) R2 is OH, OCH3, O-CH2COOH, CH3, Cl, CH2OH, OPO(O-CH2-CH3)2, N(OH)2, F, HCOO, or N(OCH2CH3)2. Compounds, their pharmaceutically acceptable salts, or combinations thereof, (B3): An immunotherapy compound, This relates to a pharmaceutical combination comprising immunotherapy compounds for simultaneous, separate, or sequential use in the treatment of cancer in human patients, wherein the treatment is an immunotherapy for cancer.

[0024] The term “immunotherapy” in the third aspect should be understood in accordance with the relevant technical field.

[0025] As is well known in the field, immunotherapy is the treatment of disease by activating or suppressing the immune system. Immunotherapy designed to induce or amplify the immune response is classified as activating immunotherapy, while immunotherapy that reduces or suppresses it is classified as suppressive immunotherapy. In recent years, immunotherapy has attracted considerable interest from researchers, clinicians, and pharmaceutical companies, particularly due to its potential to treat various forms of cancer.

[0026] A fourth aspect of the present invention is: (A): Compounds that are polyunsaturated fatty acids of the formula COOR1-CHR2-(CH2)a-(CH=CHCH2)b-(CH2)c-CH3, pharmaceutically acceptable salts thereof, or combinations thereof (i) a can be any integer value from 0 to 7, (ii)b can be any integer value between 2 and 7, (iii) c can be any integer value from 0 to 7, (iv) R1 is H, Na, K, CH3, CH3-CH2, or PO(O-CH2-CH3)2, (v) R2 is OH, OCH3, O-CH2COOH, CH3, Cl, CH2OH, OPO(O-CH2-CH3)2, N(OH)2, F, HCOO, or N(OCH2CH3)2, The present invention relates to a pharmaceutical composition comprising a compound, a pharmaceutically acceptable salt thereof, or a combination thereof, for use in the treatment of cancer in human patients, wherein the treatment is radiotherapy for cancer.

[0027] The term “radiotherapy” in the fourth aspect should be understood in accordance with the art. As is well known in the field, radiotherapy (also called radiation therapy) is a cancer treatment that uses high doses of radiation to kill cancer cells and shrink tumors.

[0028] A fifth aspect of the present invention is: (A): Compounds that are polyunsaturated fatty acids of the formula COOR1-CHR2-(CH2)a-(CH=CHCH2)b-(CH2)c-CH3, pharmaceutically acceptable salts thereof, or combinations thereof (i) a can be any integer value from 0 to 7, (ii)b can be any integer value between 2 and 7, (iii) c can be any integer value from 0 to 7, (iv) R1 is H, Na, K, CH3, CH3-CH2, or PO(O-CH2-CH3)2, (v) R2 is OH, OCH3, O-CH2COOH, CH3, Cl, CH2OH, OPO(O-CH2-CH3)2, N(OH)2, F, HCOO, or N(OCH2CH3)2. Compounds, their pharmaceutically acceptable salts, or combinations thereof, (B1): A chemotherapeutic agent compound, For simultaneous, separate, or sequential use in the treatment of cancer in human patients, compound (B1) is Temozolomide, Topotecan, Irinotecan, Cyclophosphamide, Fluorouracil, Oxaliplatin, Leucovorin, and This relates to a pharmaceutical combination comprising a chemotherapeutic compound, which is at least one chemotherapeutic compound selected from the group consisting of doxorubicin.

[0029] In this specification, when compound (B) is used in general, it is understood to refer to any of compound (B1), compound (B2), and / or compound (B3).

[0030] As can be understood by those skilled in the art in the current circumstances, the agent of compound (B) in the above-mentioned related embodiment is, of course, not a compound within the scope of compound (A) in the above-mentioned related embodiment.

[0031] As will be understood by those skilled in the art in the current circumstances, with respect to the combination therapy discussed herein, it is not important whether the two compounds (A) and (B) are administered simultaneously, for example, as a single composition, or sequentially, for example, as two separate compositions. The important issue is that an effective amount of the first administered compound / drug is present in the patient's body and / or that the second compound / drug exerts its effect in the patient's body when administered.

[0032] As will be understood by those skilled in the art in the present circumstances, aspects of the present invention relate to combinations of compound (A) and at least one compound (B), for example, compound (A) + compound (B1), compound (A) + compound (B2), compound (A) + compound (B3), or compound (A) + compound (B1) + compound (B3). Since compound (A) may be administered in combination with radiotherapy according to a fourth aspect of the present invention, it will also be understood that radiotherapy may be administered in combination with any of the above combinations with compound (B).

[0033] Accordingly, the term “combination” in the relevant embodiments described above refers, in this specification, to various combinations of compounds (A) and (B), for example, in a single pharmaceutical composition, in a combined mixture consisting of separate pharmaceutical formulations / compositions of a single active compound such as a “tank mix,” and in the combined use of a single active ingredient in a sequential manner, i.e., sequentially over a moderately short period such as a few hours or a few days, or in simultaneous administration. The order in which compounds (A) and (B) are applied is not important. The combination of compounds (A) and (B) can be formulated for simultaneous, separate, or sequential administration. In particular, if administration is not simultaneous, the compounds are administered at relatively close intervals. Furthermore, the compounds may be administered in the same or different dosage forms, or by the same or different routes of administration; for example, one compound may be administered intravenously and the other orally. The combination of the two compounds may be administered, for example, as follows: -As a combination of two compounds that are always administered simultaneously and are part of the same pharmaceutical formulation; -As a combination of two units / compositions, each containing one of the substances that give rise to the possibility of simultaneous, sequential, or separate administration. For example, compound (A) is administered independently of compound (B) (i.e., in two separate units), but simultaneously.

[0034] In another preferred example, compound (A) is administered first, followed by compound (B) being administered separately or sequentially, or compound (B) is administered first, followed by compound (A) being administered separately or sequentially.

[0035] In another preferred example where two compounds (B) are administered, compound (A) is administered first, the first compound (B) is administered second separately or sequentially, and then the second compound (B) is administered third separately or sequentially. Alternatively, the first compound (B) is administered first, the second compound (B) is administered second separately or sequentially, and then compound (A) is administered third separately or sequentially. Alternatively, the first compound (B) is administered first, compound (A) is administered second separately or sequentially, and then the second compound (B) is administered third separately or sequentially.

[0036] For example, the term "pharmaceutical" in relation to "pharmaceutical composition" should be understood in accordance with the art in question, that is, it refers to a preparation / composition that is in a form that allows the biological activity of the active ingredient to be effective and physiologically acceptable, i.e., free from additional components that are unacceptably toxic to the subject to which it is administered. In particular, the term "pharmaceutically acceptable" means that it is approved by a state or federal regulatory authority or is included in the United States Pharmacopeia or other generally accepted pharmacopoeias for use in animals, and more specifically in humans.

[0037] Embodiments of the present invention are described below only as examples.

[0038] A combination of the preferred embodiments described herein and other preferred embodiments described herein constitutes a more preferred embodiment. [Brief explanation of the drawing]

[0039] In this explanation, ABTL0812 and ABTL are used interchangeably.

[0040] [Figure 1] Cytotoxicity of ABTL0812 (ABTL) and temozolomide (TMZ) in LA1-5S and SK-N-BE(2) cells. For further details, see the examples herein. [Figure 2] Cytotoxicity of ABTL0812 and topotecan in LA1-5S. For further details, see the examples herein. [Figure 3] Cytotoxicity of ABTL0812 and irinotecan in LA1-5S. For further details, please refer to the examples herein. [Figure 4] Cytotoxicity of ABTL0812 and cyclophosphamide in LA1-5S. For further details, please refer to the examples herein. [Figure 5]ABTL0812 and bortezomib exhibit potent synergistic effects in vitro in the multiple myeloma cell lines JJN-3 and OPM2. For further details, please refer to the examples herein. [Figure 6] ABTL0812 significantly enhances the anticancer effect of FOLFIRINOX without increasing toxicity in a human pancreatic cancer xenograft model using MiaPaca2 cells transplanted into nude mice. The results suggest that combination therapy may have clinical interest in the treatment of pancreatic cancer. For further details, please refer to the examples described herein. [Figure 7] ABTL0812 significantly enhances the anticancer effect of doxorubicin without increasing toxicity in a human endometrial cancer xenograft model using Ishikawa cells transplanted into nude mice. The results suggest that combination therapy with ABTL0812 plus doxorubicin may have clinical interest in the treatment of endometrial cancer. For further details, please refer to the examples described herein. [Figure 8] ABTL0812 increases disease-free survival in mice with glioblastoma tumors and enhances the antitumor activity of temozolomide. For further details, please refer to the examples herein. [Figure 9-1] ABTL0812 reduces the proliferation of glioblastoma tumors (U87MG, T98G cells) and enhances the antitumor activity of radiotherapy. For further details, please refer to the examples herein. [Figure 9-2] Same as above. [Figure 10] ABTL0812 increases disease-free survival in mice with glioblastoma tumors and enhances the antitumor activity of radiotherapy. For further details, please refer to the examples herein. [Figure 11]ABTL0812 significantly enhances the anticancer effect of olaparib without increasing toxicity in a human endometrial cancer xenograft model using Ishikawa cells transplanted into nude mice. The results suggest that combination therapy with ABTL0812 plus olaparib may have clinical interest in the treatment of endometrial cancer. For further details, please refer to the examples described herein. [Figure 12] ABTL0812 significantly enhances the anticancer effect of bevacizumab without increasing toxicity in a human endometrial cancer xenograft model using Ishikawa cells transplanted into nude mice. The results suggest that combination therapy with ABTL0812 plus bevacizumab may have clinical interest in the treatment of endometrial cancer. For further details, please refer to the examples described herein. [Figure 13] ABTL0812 enhances macrophage polarization against the M1 pro-inflammatory antitumor phenotype by significantly increasing IL-1B and TNF-α gene expression. Importantly, ABTL0812 suppresses M2 polarization against the anti-inflammatory pro-tumor phenotype by dramatically inhibiting IL10 gene expression, one of the major regulators of immunosuppression. TBP is TATA box-binding protein. NT stands for non-polarized macrophage. ABTL50uM stands for non-polarized macrophage treated with 50 μM ABTL0812. M1 stands for macrophage polarized to the M1 phenotype. M1+ABTL50 stands for macrophage polarized to the M1 phenotype treated with 50 μM ABTL0812. ABTL100uM stands for non-polarized macrophage treated with 100 μM ABTL0812. M1+ABTL100 refers to macrophages polarized to the M1 phenotype after treatment with 100 μM ABTL0812. M2 refers to macrophages polarized to the M2 phenotype. M2+ABTL50 refers to macrophages polarized to the M2 phenotype after treatment with 50 μM ABTL0812. For further details, please refer to the examples in this specification. [Figure 14]ABTL0812 induces PDL1 expression in endometrial and pancreatic cancer cell lines, and ABTL0812-mediated PDL1 expression is significantly inferior to PDL1 expression levels induced by IFNγ, a master regulator of PDL1 expression. These results highlight the potential combination of ABTL0812 with immune checkpoint inhibitors, as the induction of mediated PDL1 levels makes cancer cells targetable for immune checkpoint inhibitors. For further details, please refer to the examples herein. [Figure 15] ABTL0812 promotes immunogenic cancer cell death in human pancreatic MiaPaca2 cancer cells, which induces the release of immunogenic factors that promote sustained macrophage activation, along with polarization to the M1 pro-inflammatory and antitumor phenotype, by significantly inducing sustained IL-1β and TNF-α gene expression. These data, along with Figure 13, suggest that ABTL0812 can immunomodulate the tumor microenvironment through its anticancer effects on cancer cells, in addition to its direct effects on human macrophages, thus highlighting its potential combination with immune checkpoint inhibitors to enhance anticancer efficacy. RPMI or NT refers to the initial conditioned medium (control). MiaPACA-2 NT or MiaPACA-2 CM NT refers to the conditioned medium from untreated MiaPaca2 cells. MiaPACA-2 40UM ABTL refers to the conditioned medium from MiaPaca2 cells treated with ABTL0812 (40 μM ABTL0812). MiaPACA-2 CM 70uM relates to a conditioned medium from MiaPaca2 cells treated with ABTL0812 (70 μM ABTL0812). TBP is a TATA box-binding protein. For further details, please refer to the examples herein. [Figure 16]Administration of ABTL0812 alone increased the survival rate of a syngeneic mouse model of lung cancer using LLC1 cells subcutaneously transplanted into C57BL6 mice. ABTL0812 combined with anti-PD1 showed a greater increase in survival rate compared to anti-PD1, ABTL0812, and vehicle therapy. The data suggest enhancement of anti-PD1 treatment by ABTL0812, leading to increased mouse survival. These results demonstrate the potential benefits of combining anti-PD1 and ABT0812 in human patients. For further details, please refer to the examples described herein. [Figure 17] ABTL0812 administered alone showed a similar reduction in tumor volume to anti-PD1 + carboplatin / paclitaxel therapy, and both treatments significantly reduced tumor volume compared to a vehicle-group syngeneic mouse model of lung cancer using LLC1 cells subcutaneously transplanted into C57BL6 mice. The three-combination of ABTL0812 + anti-PD1 + carboplatin / paclitaxel therapy induced the highest tumor volume reduction and significantly improved upon the remaining treatments. This higher anticancer efficacy correlated with increased CD8 / CD4 gene expression levels within the tumor, validated in vivo and previous in vitro observations (Figures 15 and 13). The CD8 / CD4 ratio is commonly assessed to analyze cytotoxic antitumor T lymphocytes during drug therapy. The results suggest that the combination therapy of ABTL0812 + anti-PD1 + paclitaxel / carboplatin, which is the standard treatment for lung cancer patients, may have clinical interest in the treatment of lung cancer. For further details, please refer to the examples herein. [Figure 18] ABTL0812, combined with anti-PD1 + carboplatin / paclitaxel therapy, induced the highest tumor volume reduction in a syngeneic mouse model of lung cancer using LLC1 cells intraperitoneally transplanted into C57BL6 mice. The results suggest that the combination therapy of ABTL0812 + anti-PD1 + paclitaxel / carboplatin, a standard treatment for lung cancer patients, may have clinical interest in treating lung cancer. For further details, please refer to the examples described herein. [Figure 19-1]ABTL0812 induces PDL1 expression in endometrial and pancreatic cancer cell lines in vitro. These results highlight the potential combination of ABTL0812 with immune checkpoint inhibitors, as induction of PDL1 levels makes cancer cells targetable for immune checkpoint inhibitors. For further details, please refer to the examples herein. [Figure 19-2] Same as above. [Figure 20] ABTL0812 inhibits PD1 expression in activated and deactivated human primary T cells. Since PD1 mediates a repressive signal for T cell activity, its reduction by ABTL0812 may promote T cell activation and induce its anti-cancer activity. RFU stands for relative fluorescence unit. WB stands for Western blot. See the examples in this specification for further details. [Figure 21] ABTL0812 promotes the inhibition of immunosuppressive chemokine release in human cancer cells, leading to the promotion of a pro-inflammatory environment. For further details, please refer to the examples herein. [Figure 22-1] ABTL0812 induces immunogenic cell death (ICD) in human pancreatic cancer cells by inducing dose-dependent increases in the ICD markers extracellular Hmgb1 and ATP, surface calreticulin, and activated caspases 3 and 8. For further details, please refer to the examples herein. [Figure 22-2] Same as above. [Figure 23] ABTL0812 promotes CD3 T cell infiltration within tumor lesions in PTEN-KO mice with endometrial carcinogenesis, in addition to inhibiting oncogenic progression and reducing neoplastic lesions (EIN, endometrial intraepithelial neoplasia). UN was untreated. [Figure 24-1]ABTL0812 enhances immortalized THP-1 and human primary macrophage polarization against the M1 pro-inflammatory antitumor phenotype by significantly increasing IL-1β and TNF-α gene expression. Importantly, ABTL0812 suppresses M2 polarization against the anti-inflammatory pro-tumor phenotype by dramatically inhibiting IL10 gene expression, one of the key regulators of immunosuppression. These data suggest an immunomodulatory effect of ABTL0812 on macrophages against the antitumor phenotype, potentially synergistic with immunotherapy. [Figure 24-2] Same as above.

number

[0041] Related compound (A) In a preferred embodiment, (i) a can be any integer value between 5 and 7, (ii)b can be any integer value between 2 and 4, (iii) c can be any integer value between 1 and 5.

[0042] Preferably, R1 may be H, Na, K, CH3, CH3-CH2, or PO(O-CH2-CH3)2. Preferably, R2 may be OH, OCH3, O-CH2COOH, CH3, Cl, CH2OH, OPO(O-CH2-CH3)2, N(OH)2, F, HCOO, or N(OCH2CH3)2.

[0043] In a preferred embodiment, R1 is H and R2 is OH.

[0044] In another preferred embodiment, R1 is Na and R2 is OH.

[0045] Preferably, compound (A) is at least one compound selected from the group consisting of: COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812), COOH-CHOH-(CH2)6-(CH=CH-CH2)3-CH3(183A1), COOH-CHOH-(CH2)3-(CH=CH-CH2)3-(CH2)3-CH3(183A2), COOH-CHOH-(CH2)2-(CH=CH-CH2)4-(CH2)3-CH3(204A1), COOH-CHOH-(CH2)2-(CH=CH-CH2)5-CH3(205A1), and COOH-CHOH-CH2-(CH=CH-CH2)6-CH3(226A1).

[0046] Most preferably, compound (A) is COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812).

[0047] A pharmaceutically acceptable salt of compound (A) refers to any pharmaceutically acceptable salt of compound (A). As is known in the art, there are many known pharmaceutically acceptable salts. Examples of pharmaceutically acceptable salts include, but are not limited to, sodium (Na), potassium, acetate, sulfate, pyrosulfate, bisulfate, sulfite, bisulfites, phosphate, monophosphate, dihydrogen phosphate, metaphosphate, pyrophosphate, chloride, bromide, iodide, acetate, propionate, decanoate, caprylate, acrylate, formales, isobutyrate, caproate, heptanoate, propiolate, oxalate, malonate, succinate, suberate, sebacinate, fumarate, maleic acid, butin-1, Examples include 4-dioetes, hexyn-1,6-dioetes, benzoates, chlorobenzoates, methylbenzoates, dinitrobenzoates, hydroxybenzoates, methoxybenzoates, phthalates, sulfonates, xylene sulfonates, phenylacetates (phylacetates), phenylpropionates, phenylbutyrates, citrates, lactates, gamma-hydroxybutyrates, glycolates, tartrates, alkanesulfonates (e.g., methanesulfonates or mesylates), propanesulfonates, naphthalene-1-sulfonates, naphthalene-2-sulfonates, and mandelates. In certain embodiments, the salt of compound (A) is a sodium salt.

[0048] As will be understood by those skilled in the art in the present circumstances, where a preferred formula for compound (A), such as ABTL0812, is mentioned herein, it will be understood herein that it also includes, for example, compound (A) being COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812), and where a salt of ABTL0812 is mentioned, the salt thereof.

[0049] Preferably, compound (A) is the sodium salt of COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812).

[0050] Chemotherapy agent - Compound of the first embodiment (B1) In some embodiments, compound (B1) is at least one chemotherapeutic compound selected from the group consisting of: Temozolomide, Topotecan, Irinotecan, Cyclophosphamide, Fluorouracil (5-fluorouracil, 5-FU), Cisplatin, Carboplatin, Oxaliplatin, Leucovorin, Doxorubicin, Bleomycin, Capecitabine, Mitomycin B, Paclitaxel, Nab-paclitaxel, Docetaxel, Gemcitabine, Methotrexate, Pemetrexed, Cytarabine, Mercaptopurine, Gluphosphamide, Ixabepylon, Nimstine, Carmustine, Romustine, Mitoxantrone, Etoposide, Vincristine, Vinblastine, and Tamoxifen.

[0051] As understood in the current context, in relation to any of the preferred enumerated examples of compound (B1), it is most preferable that compound (A) is COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812).

[0052] In other embodiments, compound (B1) is at least one chemotherapeutic compound selected from the group consisting of: Temozolomide, Topotecan, Irinotecan, Cyclophosphamide, Fluorouracil, Oxaliplatin, Leucovorin, and Doxorubicin.

[0053] In other embodiments, compound (B1) is at least one chemotherapeutic compound selected from the group consisting of: Temozolomide, Topotecan, Fluorouracil, Oxaliplatin, and Leucovorin.

[0054] In other embodiments, compound (B1) is at least one chemotherapeutic compound selected from the group consisting of: Irinotecan, Fluorouracil, Oxaliplatin, and Leucovorin.

[0055] In other embodiments, compound (B1) is at least one chemotherapeutic compound selected from the group consisting of: Carboplatin, and Paclitaxel.

[0056] It is preferable that compound (B1) of the first embodiment contains two or more different chemotherapeutic agents (especially when compound (A) is COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812)) - for example, preferably compound (B1) of the first embodiment contains: Irinotecan, leucovorin, oxaliplatin, and fluorouracil, or Irinotecan, topotecan, and cyclophosphamide.

[0057] As can be understood by those skilled in the art in the current circumstances, the use of compound (B1) may be combined with other cancer treatment-related drugs / compounds, such as one or more targeted therapy agents (B2).

[0058] In particular, when the cancer is neuroblastoma, it is especially preferable that compound (A) is ABTL0812 and compound (B1) is temozolomide (see Example 1.1 for an example of this preferred embodiment).

[0059] In particular, when the cancer is neuroblastoma, it is especially preferable that compound (A) is ABTL0812 and compound (B1) is topotecan. (See Example 1.2 of this specification for an example of this preferred embodiment). In other embodiments, particularly when the cancer is pancreatic cancer or glioblastoma, compound (A) is ABTL0812 and compound (B1) is topotecan.

[0060] In particular, when the cancer is neuroblastoma, it is especially preferable that compound (A) is ABTL0812 and compound (B1) is irinotecan. (See Example 1.3 of this specification for an example of this preferred embodiment). In other embodiments, particularly when the cancer is pancreatic cancer or glioblastoma, compound (A) is ABTL0812 and compound (B1) is irinotecan.

[0061] In particular, when the cancer is neuroblastoma, it is especially preferable that compound (A) is ABTL0812 and compound (B1) is cyclophosphamide. (For an example of this preferred embodiment, see Example 1.4 of this specification.)

[0062] In particular, when the cancer is pancreatic cancer, it is especially preferable that compound (A) is ABTL0812 and compound (B1) is irinotecan, leucovorin, oxaliplatin, and fluorouracil. (For example, see Example 3.1 of this preferred embodiment.)

[0063] In particular, when the cancer is endometrial cell carcinoma, it is especially preferable that compound (A) is ABTL0812 and compound (B1) is doxorubicin. (For an example of this preferred embodiment, see Example 3.2 of this specification.)

[0064] In particular, when the cancer is glioblastoma, it is especially preferable that compound (A) is ABTL0812 and compound (B1) is temozolomide. (For an example of this preferred embodiment, see Example 3.3 of this specification.)

[0065] In particular, when the cancer is lung cancer, it is especially preferable that compound (A) is ABTL0812 and compound (B1) is pemetrexed.

[0066] In particular, when the cancer is lung cancer, it is especially preferable that compound (A) is ABTL0812 and compound (B1) is methotrexate.

[0067] Preferably, the pharmaceutically acceptable combinations discussed herein are such that compound (A) is ABTL0812, - Compound (B1) is temozolomide, and the cancer is neuroblastoma. - Compound (B1) is topotecan, and the cancer is neuroblastoma. - Compound (B1) is irinotecan, and the cancer is neuroblastoma. - Compound (B1) is cyclophosphamide, and the cancer is neuroblastoma. - Compound (B1) is irinotecan, leucovorin, oxaliplatin, and fluorouracil, and the cancer is pancreatic cancer. - Compound (B1) is doxorubicin, and the cancer is endometrial cancer, or - Compound (B1) is temozolomide, and the cancer is glioblastoma.

[0068] Compound (A) (particularly ABTL0812) is preferably administered orally.

[0069] The dose administered of compound (A) (particularly ABTL0812) is preferably 200 mg to 7000 mg per day, more preferably 1500 mg to 5000 mg per day, even more preferably 3000 mg to 4700 mg per day, and most preferably 3500 mg to 4300 mg per day.

[0070] Preferably, the daily dose of compound (A) (especially ABTL0812) is administered three times a day, most preferably 1200-1400 mg in three doses.

[0071] Targeted therapy agent - Compound of the second embodiment (B2) Preferably, compound (B2) is at least one targeted therapeutic agent compound selected from the group consisting of: Imatinib, Gefitinib, Erlotinib, Sorafenib, Sunitinib, Dasatinib, Lapatinib, Nilotinib, Proteasome inhibitors (preferably carfilzomib, ixazomib, or bortezomib), Tamoxifen, Janus kinase inhibitors (preferably tofacitinib), ALK inhibitors (preferably crizotinib), Bcl-2 inhibitors (preferably ovatocrax, navitocrax, or gossypol), PARP inhibitors (preferably iniparib or olaparib), PI3K inhibitor (preferably perifosine), Apatinib, Braf inhibitors (preferably vemurafenib or dabrafenib), MEK inhibitors (preferably trametinib), CDK inhibitors, Hsp90 inhibitors, Salinomycin, VAL-083 (Dianhydrogalactitol), Vintafolide, Serine / threonine kinase inhibitors (preferably temsirolimus, everolimus, vemurafenib, trametinib, or dabrafenib), and Monoclonal antibodies (preferably anti-VEGF mAb, rituximab, trastuzumab, alemtuzumab, cetuximab, panitumumab, or bevacizumab).

[0072] As understood in the current context, in relation to any of the preferred enumerated examples of compound (B2), it is most preferable that compound (A) is COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812).

[0073] In other embodiments, compound (B2) is at least one targeted therapeutic agent compound selected from the group consisting of: Proteasome inhibitors (preferably carfilzomib, ixazomib, or bortezomib), PARP inhibitors (preferably iniparib or olaparib), and Monoclonal antibodies (preferably anti-VEGF mAb, rituximab, trastuzumab, alemtuzumab, cetuximab, panitumumab, or bevacizumab).

[0074] In other embodiments, compound (B2) is at least one targeted therapeutic agent compound selected from the group consisting of: Bortezomib, Olaparib, and Bevacizumab.

[0075] The compound (B2) of the second embodiment may preferably contain two or more different targeted therapeutic agents (especially when compound (A) is COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812)).

[0076] As can be understood by those skilled in the art in the current circumstances, the use of compound (B2) may be combined with other cancer treatment-related drugs / compounds, such as one or more chemotherapeutic compounds.

[0077] In particular, when the cancer is multiple myeloma, it is especially preferable that compound (A) is ABTL0812 and compound (B2) is bortezomib (see Example 2.1 for an example of this preferred embodiment).

[0078] Bortezomib is a proteasome inhibitor, and it can be said that different proteasome inhibitors treat cancer based on similar mechanisms. Therefore, the positive experimental data for bortezomib discussed herein are considered reasonable to suggest that similar positive results can also be obtained with the use of other proteasome inhibitors, such as carfilzomib or ixazomib, rather than bortezomib.

[0079] In particular, when the cancer is endometrial cancer, it is especially preferable that compound (A) is ABTL0812 and compound (B2) is olaparib (see Example 5.1 for an example of this preferred embodiment).

[0080] Olaparib is a PARP inhibitor, and it can be said that different PARP inhibitors treat cancer based on similar mechanisms. Therefore, the positive experimental data for olaparib discussed herein are considered reasonable to suggest that similar positive results can also be obtained with the use of other PARP inhibitors, such as iniparib, rather than olaparib.

[0081] In particular, when the cancer is endometrial cancer, it is especially preferable that compound (A) is ABTL0812 and compound (B2) is bevacizumab (see Example 5.2 for an example of this preferred embodiment).

[0082] Bevacizumab works by inhibiting vascular endothelial growth factor (VEGF), thereby slowing the growth of new blood vessels, and can therefore be seen as an example of an anti-VEGF mAb.

[0083] Therefore, bevacizumab can be seen as an example of an anti-VEGF mAb, and it can be said that different anti-VEGF mAbs treat cancer based on similar mechanisms. Thus, the positive experimental data for bevacizumab discussed herein are considered reasonable to suggest that similar positive results can also be obtained with the use of anti-VEGF mAbs rather than bevacizumab.

[0084] Preferably, the pharmaceutically acceptable combinations discussed herein are such that compound (A) is ABTL0812, - Compound (B2) is bortezomib, and the cancer is multiple myeloma. - Compound (B2) is olaparib, and the cancer is endometrial cancer, or - Compound (B2) is bevacizumab, and the cancer is endometrial cancer.

[0085] Compound (A) (particularly ABTL0812) is preferably administered orally.

[0086] The dose administered of compound (A) (particularly ABTL0812) is preferably 200 mg to 7000 mg per day, more preferably 1500 mg to 5000 mg per day, even more preferably 3000 mg to 4700 mg per day, and most preferably 3500 mg to 4300 mg per day.

[0087] Preferably, the daily dose of compound (A) (especially ABTL0812) is administered three times a day, most preferably 1200-1400 mg in three doses.

[0088] Immunotherapy agent - Compound of the third embodiment (B3) As is known in the art, checkpoint inhibitor therapy is a form of cancer immunotherapy. The therapy targets immune checkpoints, which are key regulators of the immune system that, when stimulated, can weaken the immune response to an immune stimulus. Checkpoint inhibitors are molecules that can block immune checkpoint proteins. As a result, checkpoint inhibitors enhance the immune response and promote the elimination of cancer cells.

[0089] Currently approved checkpoint inhibitors are generally antibodies that target the molecules CTLA4, PD-1, and PD-L1, and these checkpoint inhibitors may be called anti-PD1, anti-PDL1, or anti-CTLA4 checkpoint inhibitors.

[0090] The conclusions for Example 6.1 below are as follows: These results suggest that, apart from its anticancer effects against tumor cells, ABTL0812 stimulates the immune system into a pro-inflammatory phenotype, alters the tumor microenvironment, promotes the recruitment of other immune cells as cytotoxic T lymphocytes, and thus transforms a “cold” tumor that induces immunosuppression into a “hot” immunogenic tumor, highlighting the potential combination of ABTL0812 with certain immune checkpoint inhibitors to enhance anticancer efficacy by promoting a pro-inflammatory and anti-tumor microenvironment.

[0091] The conclusions for Example 7 below are as follows: "...The immunomodulatory effects of ABTL0812 in vivo demonstrate how it induces T lymphocyte infiltration within tumor lesions, indicating the presence of a pro-inflammatory antitumor microenvironment that promotes the infiltration of immune cells to kill cancer cells... It highlights its potential combination, particularly with immune checkpoint inhibitors, to enhance anticancer efficacy."

[0092] Therefore, the experimental data herein (see Examples 6-8) provide reasonable evidence that ABTL08112 itself has a positive immunomodulatory effect with respect to immunotherapy for cancer and other conditions, particularly with respect to the use of immune checkpoint inhibitors.

[0093] Tumors can manipulate the PD-1 / PD-L1 immune checkpoint pathway to block cancer-targeted T cells. Therefore, in some embodiments, compound (B3) is a checkpoint inhibitor that targets the PD-1 / PD-L1 pathway, which can enable T cells to eliminate cancer cells, and is also called anti-PD-1 or anti-PD-L1.

[0094] CTLA-4 is another pathway that can be targeted by checkpoint inhibitors that can block the CTLA-4 receptor. In some embodiments, compound (B3) is a checkpoint inhibitor that targets CTLA-4.

[0095] In some embodiments, the checkpoint inhibitor may be an antibody-based drug or a non-antibody-based drug (e.g., a small molecule or peptide).

[0096] In certain embodiments, the checkpoint inhibitor is a checkpoint inhibitor antibody. Examples of checkpoint inhibitors that target the PD-1 / PDL-1 pathway include atezolizumab, avelumab, semiprimab, durvalumab, nivolumab, and pembrolizumab. Ipilimumab is an example of a checkpoint inhibitor that targets the CTLA-4 pathway.

[0097] In another embodiment, checkpoint inhibitors are non-antibody-based drugs (e.g., small molecules or peptides). Examples of small molecule checkpoint inhibitors are peptide-based immunomodulators. In particular, certain macrocyclic peptides have been demonstrated to inhibit PD-1 and PD-L-1. Furthermore, hydrolyzable D peptides have also been demonstrated to antagonize PD-L1. Other examples of immunomodulatory small molecules characterized as checkpoint inhibitors include sulfamonomethoxyline and sulfamethisole derivatives (sulfamides), biaryl derivative compounds, and non-peptide molecules converted into small molecules that mimic or are inspired by peptides.

[0098] In other embodiments, checkpoint inhibitors can target the VISTA and CD47 / SIRPα signaling pathways, which play a role in tumor immune evasion and cancer progression. Non-antibody peptides targeting these pathways are examples of small immunomodulatory molecules with antitumor effects.

[0099] Preferably, compound (B3) is at least one immunotherapy compound selected from the group consisting of: A checkpoint inhibitor antibody (preferably an anti-PD1, anti-PDL1, or anti-CTLA4 checkpoint inhibitor antibody).

[0100] As understood in the current context, in relation to any of the preferred enumerated examples of compound (B3), it is most preferable that compound (A) is COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812).

[0101] Preferred anti-PD1 checkpoint inhibitor antibodies include nivolumab, pembrolizumab, or spartalizumab.

[0102] In the examples described herein, positive results were obtained with anti-PD1 checkpoint inhibitor antibodies that appear to be equivalent to pembrolizumab. In short, pembrolizumab is intended for human use, and in the examples described herein, a modified version optimized for use in the mouse model used in the examples described herein was used.

[0103] Therefore, in a preferred embodiment, the anti-PD1 checkpoint inhibitor antibody is pembrolizumab.

[0104] Preferred anti-PDL1 checkpoint inhibitor antibodies include atezolizumab, avelumab, or durvalumab.

[0105] A preferred example of an anti-CTLA4 checkpoint inhibitor antibody is ipilimumab.

[0106] Example 8 of this specification shows positive results with respect to the use of an anti-PD1 checkpoint inhibitor antibody, and therefore preferred embodiments relate to the case where compound (B3) is an anti-PD1 checkpoint inhibitor antibody (preferably nivolumab, pembrolizumab, or spartalizumab), and in particular compound (A) is ABTL0812.

[0107] The compound (B3) of the third embodiment may preferably contain two or more different checkpoint inhibitor antibodies (especially when compound (A) is COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812)).

[0108] As can be understood by those skilled in the art in the current circumstances, the use of compound (B3) may be combined with other cancer treatment-related drugs / compounds, such as one or more chemotherapeutic compounds.

[0109] In particular, when the cancer is lung cancer, it is especially preferable that compound (A) is ABTL0812 and compound (B3) is an anti-PD1 checkpoint inhibitor antibody (most preferably pembrolizumab) (see Example 8.1 for an example of this preferred embodiment).

[0110] In particular, when the cancer is lung cancer, compound (A) is ABTL0812 and compound (B3) is an anti-PD1 checkpoint inhibitor antibody (most preferably pembrolizumab), and they are especially preferably administered in combination with at least one compound (B1), for example, paclitaxel and carboplatin (see Examples 8.2 and 8.3 for an example of this preferred embodiment).

[0111] Preferably, the pharmaceutically acceptable combinations discussed herein are such that compound (A) is ABTL0812, - Compound (B3) is an anti-PD1 checkpoint inhibitor antibody, particularly pembrolizumab, and the cancer is lung cancer, or - Compound (B3) is an anti-PD1 checkpoint inhibitor antibody (most preferably pembrolizumab), administered in combination with at least one compound (B1), particularly paclitaxel and carboplatin, and the cancer is lung cancer.

[0112] The conclusions of Example 6.7 are as follows (emphasis added): "ABTL0812 helps induce ICD (immunogenic cell death) in tumors, making them more immunogenic and targetable to the immune system, and transforming 'cold' tumors that induce immune system suppression into 'hot' immunogenic tumors..."

[0113] The conclusions of Example 6.9 are as follows (emphasis added): "ABTL0812 promotes the secretion of pro-inflammatory factors and suppresses the release of immunosuppressive factors in cancer cells. These data, combined with enhancement of the M1 macrophage phenotype and suppression of the M2 phenotype, highlight the potential for combination with other immunotherapies to enhance efficacy against tumors, particularly highly immunosuppressive tumors such as pancreatic cancer, by promoting a pro-inflammatory antitumor environment for its effects on immune cells."

[0114] Therefore, the experimental data herein (see Examples 6-8) provide reasonable evidence that ABTL0812 itself has a positive immunomodulatory effect that enhances the anticancer efficacy of therapies that interact with immune system responses and their regulation (e.g., cytokines) other than checkpoint inhibitors. Thus, it is clear to those skilled in the art that ABTL0812 can enhance the anticancer effects of immunomodulatory factors.

[0115] Therefore, in some embodiments, compound (B3) is an anti-cancer immunomodulatory compound. The term “anti-cancer immunomodulatory compound” (also called “anti-cancer immunomodulatory compound” is used herein to refer to immunomodulators as molecules that target pathways that modulate the activity of the immune system and can improve its ability to attack and eliminate cancer cells. Immunomodulators are molecules of a known group within cancer immunotherapy agents and may include, for example, checkpoint inhibitors, cytokines, agonists, and adjuvants. Modulation of the immune system includes stimulation or inhibition of immune system mechanisms.

[0116] In some embodiments, compound (B3) is an immunotherapy compound that is an anti-cancer immunomodulatory compound that is a cytokine. Cytokines are messenger molecules that regulate the maturation, proliferation, and responsiveness of immune cells. Examples of immunomodulatory cytokines are cytokines that target the IL-2 / IL-2R pathway and cytokines that target the IFNAR1 and / or IFNAR2 pathway. Aldesleukin (Proleukin®) is an example of an immunomodulatory cytokine that targets the IL-2 / IL-2R pathway. Examples of immunomodulatory cytokines that target the IFNAR1 and / or IFNAR2 pathway are interferon alpha-2a, interferon alpha-2b (Intron AA®), and pegylated interferon alpha-2b (Sylatron® / PEG-Intron®). Another example of a cytokine is granulocyte-macrophage colony-stimulating factor (GM-CSF) for the treatment of neuroblastoma.

[0117] In some embodiments, compound (B3) is an immunotherapy compound that is an anti-cancer immunomodulatory compound that is an agonist. An agonist is a molecule that can activate pathways that promote adaptive immune responses. For example, an immunomodulatory agonist can enhance the activation of "killer" T cells or stimulate the activity of innate immune cells (e.g., dendritic cells).

[0118] In some embodiments, compound (B3) is an immunotherapy compound that is an adjuvant, an anti-cancer immunomodulatory compound. An adjuvant is a molecule that can activate pathways involved in the innate immune system that can stimulate a general immune response and ultimately promote an adaptive immune response. Examples of immunomodulatory adjuvants are those that target Toll-like receptors (e.g., TLR7 or TLR3). Imiquimod and polyICLC (Hiltonol®) are examples of Toll-like receptor-targeting adjuvants for the treatment of cancer.

[0119] Compound (A) (particularly ABTL0812) is preferably administered orally.

[0120] The dose administered of compound (A) (particularly ABTL0812) is preferably 200 mg to 7000 mg per day, more preferably 1500 mg to 5000 mg per day, even more preferably 3000 mg to 4700 mg per day, and most preferably 3500 mg to 4300 mg per day.

[0121] Preferably, the daily dose of compound (A) (especially ABTL0812) is administered three times a day, most preferably 1200-1400 mg in three doses.

[0122] Radiation therapy treatment - fourth aspect Preferably, radiotherapy is performed with a radiation dose of 2 to 200 Gy, for example, 5 to 100 Gy, or more preferably 15 to 85 Gy.

[0123] In the case of lymphoma, it is preferable that radiotherapy be administered with a radiation dose of 15 to 45 Gy.

[0124] In the case of solid tumors, radiotherapy is preferably performed with a radiation dose of 55-85 Gy.

[0125] Preferably, the radiation dose is administered after the administration of compound (A) (preferably ABTL0812), for example, at least one day after the first administration of compound (A) (preferably ABTL0812).

[0126] As understood in the current context, with respect to any embodiment of the radiotherapy treatment described herein, it is most preferable that compound (A) is COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812).

[0127] As understood by those skilled in the art in the current circumstances, radiotherapy may be combined with the use of relevant cancer treatment-related drugs / compounds, such as one or more chemotherapeutic compounds.

[0128] In relation to the use of radiotherapy in the fourth aspect, preferably, the cancer is glioblastoma carcinoma.

[0129] With regard to the use of radiotherapy in the fourth embodiment, it is particularly preferable that compound (A) is ABTL0812, especially when the cancer is glioblastoma. (See Example 4 of this preferred embodiment for an example.)

[0130] With regard to the use of radiotherapy in the fourth aspect, it is particularly preferable that compound (A) is ABTL0812 administered in combination with at least one compound (B1) (chemotherapeutic compound). In particular, compound (B1) is temozolomide or topotecan. In particular, the cancer is glioblastoma.

[0131] Compound (A) (particularly ABTL0812) is preferably administered orally.

[0132] The dose administered of compound (A) (particularly ABTL0812) is preferably 200 mg to 7000 mg per day, more preferably 1500 mg to 5000 mg per day, even more preferably 3000 mg to 4700 mg per day, and most preferably 3500 mg to 4300 mg per day.

[0133] Preferably, the daily dose of compound (A) (especially ABTL0812) is administered three times a day, most preferably 1200-1400 mg in three doses.

[0134] Preferred chemotherapeutic agent - Fifth embodiment In relation to the fifth aspect discussed above, preferably, compound (B1) is at least one chemotherapeutic compound selected from the group consisting of: Temozolomide, Topotecan, Fluorouracil, Oxaliplatin, and Leucovorin.

[0135] In other embodiments, compound (B1) is at least one chemotherapeutic compound selected from the group consisting of: Irinotecan, Fluorouracil, Oxaliplatin, and Leucovorin.

[0136] In other embodiments, compound (B1) is at least one chemotherapeutic agent selected from the group consisting of: Carboplatin, and Paclitaxel.

[0137] As understood in the current context, in relation to any of the preferred enumerated examples of compound (B1), it is most preferable that compound (A) is COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812).

[0138] It is preferable that compound (B1) of the fifth embodiment contains two or more different chemotherapeutic agents (especially when compound (A) is COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812)) - for example, preferably compound (B1) of the first embodiment contains: Irinotecan, leucovorin, oxaliplatin, and fluorouracil, or Irinotecan, topotecan, and cyclophosphamide.

[0139] As can be understood by those skilled in the art in the current circumstances, the use of compound (B1) may be combined with other cancer treatment-related drugs / compounds, such as one or more targeted therapy agents.

[0140] In particular, when the cancer is neuroblastoma, it is especially preferable that compound (A) is ABTL0812 and compound (B1) is temozolomide (see Example 1.1 for an example of this preferred embodiment).

[0141] In particular, when the cancer is neuroblastoma, it is especially preferable that compound (A) is ABTL0812 and compound (B1) is topotecan. (See Example 1.2 of this specification for an example of this preferred embodiment). In other embodiments, particularly when the cancer is pancreatic cancer or glioblastoma, compound (A) is ABTL0812 and compound (B1) is topotecan.

[0142] In particular, when the cancer is neuroblastoma, it is especially preferable that compound (A) is ABTL0812 and compound (B1) is irinotecan. (See Example 1.3 of this specification for an example of this preferred embodiment). In other embodiments, particularly when the cancer is pancreatic cancer or glioblastoma, compound (A) is ABTL0812 and compound (B1) is irinotecan.

[0143] In particular, when the cancer is neuroblastoma, it is especially preferable that compound (A) is ABTL0812 and compound (B1) is cyclophosphamide. (For an example of this preferred embodiment, see Example 1.4 of this specification.)

[0144] In particular, when the cancer is pancreatic cancer, it is especially preferable that compound (A) is ABTL0812 and compound (B1) is irinotecan, leucovorin, oxaliplatin, and fluorouracil. (For example, see Example 3.1 of this preferred embodiment.)

[0145] In particular, when the cancer is endometrial cell carcinoma, it is especially preferable that compound (A) is ABTL0812 and compound (B1) is doxorubicin. (For an example of this preferred embodiment, see Example 3.2 of this specification.)

[0146] In particular, when the cancer is glioblastoma, it is especially preferable that compound (A) is ABTL0812 and compound (B1) is temozolomide. (For an example of this preferred embodiment, see Example 3.3 of this specification.)

[0147] Preferably, the pharmaceutically acceptable combinations discussed herein are such that compound (A) is ABTL0812, - Compound (B1) is temozolomide, and the cancer is neuroblastoma. - Compound (B1) is topotecan, and the cancer is neuroblastoma. - Compound (B1) is irinotecan, and the cancer is neuroblastoma. - Compound (B1) is cyclophosphamide, and the cancer is neuroblastoma. - Compound (B1) is irinotecan, leucovorin, oxaliplatin, and fluorouracil, and the cancer is pancreatic cancer. - Compound (B1) is doxorubicin, and the cancer is endometrial cancer, or - Compound (B1) is temozolomide, and the cancer is glioblastoma.

[0148] Compound (A) (particularly ABTL0812) is preferably administered orally.

[0149] The dose administered of compound (A) (particularly ABTL0812) is preferably 200 mg to 7000 mg per day, more preferably 1500 mg to 5000 mg per day, even more preferably 3000 mg to 4700 mg per day, and most preferably 3500 mg to 4300 mg per day.

[0150] Preferably, the daily dose of compound (A) (especially ABTL0812) is administered three times a day, most preferably 1200-1400 mg in three doses.

[0151] Other specific combinations relating to all aspects of this specification In the examples described herein, positive results were obtained with three combinations of compound (A), compound (B1), and compound (B3).

[0152] Therefore, the present invention also, (A): Compounds that are polyunsaturated fatty acids of the formula COOR1-CHR2-(CH2)a-(CH=CHCH2)b-(CH2)c-CH3, pharmaceutically acceptable salts thereof, or combinations thereof (i) a can be any integer value from 0 to 7, (ii)b can be any integer value between 2 and 7, (iii) c can be any integer value from 0 to 7, (iv) R1 is H, Na, K, CH3, CH3-CH2, or PO(O-CH2-CH3)2, (v) A compound, a pharmaceutically acceptable salt thereof, or a combination thereof, in which R2 is OH, OCH3, O-CH2COOH, CH3, Cl, CH2OH, OPO(O-CH2-CH3)2, N(OH)2, F, HCOO, or N(OCH2CH3)2 (B1): Chemotherapy agent compounds, (B3): An immunotherapy compound, This relates to pharmaceutical combinations, including immunotherapy compounds, for simultaneous, separate, or sequential use in the treatment of cancer in human patients.

[0153] In certain embodiments, (i)a can be any integer value from 5 to 7, (ii)b can be any integer value from 2 to 4, and (iii)c can be any integer value from 1 to 5. In another embodiment, R1 is H and R2 is OH.

[0154] In certain embodiments, compound (A) is at least one compound selected from the group consisting of the following, or a pharmaceutically acceptable salt thereof: COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812), COOH-CHOH-(CH2)6-(CH=CH-CH2)3-CH3(183A1), COOH-CHOH-(CH2)3-(CH=CH-CH2)3-(CH2)3-CH3(183A2), COOH-CHOH-(CH2)2-(CH=CH-CH2)4-(CH2)3-CH3(204A1), COOH-CHOH-(CH2)2-(CH=CH-CH2)5-CH3(205A1), and COOH-CHOH-CH2-(CH=CH-CH2)6-CH3(226A1).

[0155] In particular, compound (A) is COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812) or a pharmaceutically acceptable salt thereof. More specifically, compound (A) is the sodium salt of COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812).

[0156] In some embodiments, the cancer is at least one cancer selected from the group consisting of: lung cancer, Non-small cell lung cancer, Squamous cell carcinoma, adenocarcinoma, Endometrial cancer, serous endometrial cancer, Endometrioid carcinoma, Pancreatic cancer, Glioblastoma, Resistant recurrent breast cancer, Head and neck cancer, Multiple myeloma cancer, Neuroblastoma, and Bile duct cancer.

[0157] In some embodiments, compound (B3) is an immunotherapy compound that is an anti-cancer immunomodulatory compound. In certain embodiments, compound (B3) is a checkpoint inhibitor. Specific embodiments and examples are described in the section “Immunotherapy Agents - Compound (B3) of a Third Embodiment” of this description.

[0158] In some embodiments, compound (B3) is at least one immunotherapy compound selected from the group consisting of: checkpoint inhibitors, preferably checkpoint inhibitor antibodies. Preferably, the checkpoint inhibitor antibody is an anti-PD1 antibody, an anti-PDL1 antibody, or an anti-CTLA4 antibody.

[0159] In some embodiments, compound (B3) is at least one immunotherapy compound selected from the group consisting of: -An anti-PD1 antibody, preferably the anti-PD1 antibody is nivolumab, pembrolizumab, or spartalizumab, -An anti-PDL1 antibody, preferably the anti-PDL1 antibody is atezolizumab, avelumab, or durvalumab, -An anti-CTLA4 antibody, preferably an anti-CTLA4 antibody that is ipilimumab.

[0160] In particular, compound (B3) is an anti-PD1 antibody, and preferably the anti-PD1 antibody is pembrolizumab.

[0161] In some embodiments, - Compound (B3) is an anti-PD1 checkpoint inhibitor antibody, specifically pembrolizumab, and the cancer is lung cancer or - Compound (B3) is an anti-PD1 checkpoint inhibitor antibody, preferably pembrolizumab, and is administered in combination with at least one compound (B1), preferably paclitaxel and carboplatin, and the cancer is lung cancer.

[0162] In some embodiments, compound (B1) is at least one chemotherapeutic compound selected from the group consisting of: Temozolomide, Topotecan, Irinotecan, Cyclophosphamide, Fluorouracil, Cisplatin, Carboplatin, Oxaliplatin, Leucovorin, Doxorubicin, Bleomycin, Capecitabine, Mitomycin B, Paclitaxel, Nab-paclitaxel, Docetaxel, Gemcitabine, Methotrexate, Pemetrexed, 5-Fluorouracil, Cytarabine, Mercaptopurine, Gluphosphamide, Ixabepylon, Nimstine, Carmustine, Romustine, Mitoxantrone, Etoposide, Vincristine, Vinblastine, and Tamoxifen.

[0163] In certain embodiments, compound (B1) is at least one chemotherapeutic compound selected from the group consisting of: Temozolomide, Topotecan, Irinotecan, Cyclophosphamide, Fluorouracil, Oxaliplatin, Leucovorin, and Doxorubicin.

[0164] In particular, compound (B1) is at least one chemotherapeutic compound selected from the group consisting of the following: Temozolomide, Topotecan, Fluorouracil, Oxaliplatin, and Leucovorin.

[0165] In another embodiment, compound (B1) is at least one chemotherapeutic agent compound selected from the group consisting of: Irinotecan, Fluorouracil, Oxaliplatin, and Leucovorin.

[0166] In another embodiment, compound (B1) is at least one chemotherapeutic agent compound selected from the group consisting of: Carboplatin, and Paclitaxel.

[0167] In another embodiment, compound (B1) is at least one chemotherapeutic agent compound selected from the group consisting of: Temozolomide, Topotecan, Irinotecan, Cyclophosphamide, Fluorouracil, Oxaliplatin, Leucovorin, Doxorubicin, Carboplatin, and Paclitaxel.

[0168] In particular, compound (B1) is paclitaxel and carboplatin.

[0169] In another embodiment, compound (B1) is irinotecan, leucovorin, oxaliplatin, and fluorouracil.

[0170] In a particular embodiment, compound (A) is ABTL0812, compound (B1) is paclitaxel and carboplatin, and compound (B3) is an anti-PD1 checkpoint inhibitor antibody.

[0171] In one embodiment, compound (A) is ABTL0812, compound (B1) is irinotecan, leucovorin, oxaliplatin, and fluorouracil, and compound (B3) is an anti-PD1 checkpoint inhibitor antibody. In particular, compound (B3) is an anti-PD1 checkpoint inhibitor antibody selected from nivolumab, pembrolizumab, and spartalizumab, preferably pembrolizumab.

[0172] It is particularly preferable that compound (A) is ABTL0812, compound (B1) contains paclitaxel / carboplatin, and compound (B3) is an anti-PD1 checkpoint inhibitor antibody. In certain embodiments, the cancer is lung cancer (see Examples 8.2 and 8.3 for an example of this preferred embodiment).

[0173] It is particularly preferable that compound (A) is ABTL0812, compound (B1) comprises irinotecan, leucovorin, oxaliplatin, and fluorouracil, and compound (B3) is an anti-PD1 checkpoint inhibitor antibody. In certain embodiments, the cancer is pancreatic cancer (see Example 8.5 for an example of this preferred embodiment).

[0174] Depending on the type of compound (B1), it may be administered intravenously (e.g., in the case of antibodies) or orally (e.g., in the case of small molecules). In particular, compound (3) is administered intravenously via an infusion solution.

[0175] In particular, compound (A) is administered orally. In certain embodiments, the dose of compound (A) administered is a daily dose of 200 mg to 7000 mg, more preferably 1500 mg to 5000 mg, even more preferably 3000 mg to 4700 mg, and most preferably 3500 mg to 4300 mg.

[0176] Cancers related to all aspects of this specification Regarding any one of the first to fifth aspects of this specification, more preferably, the cancer is at least one cancer selected from the group consisting of: Lung cancer, Non-small cell lung cancer, Squamous cell carcinoma, Adenocarcinoma, Endometrial cancer, Serous endometrial cancer, Endometrioid cancer, Pancreatic cancer, Glioblastoma, Resistant recurrent breast cancer, Head and neck cancer, Multiple myeloma cancer, Neuroblastoma, and Cholangiocarcinoma.

[0177] More preferably, the cancer is at least one cancer selected from the group consisting of: Non-small cell lung cancer, Squamous cell carcinoma, Endometrial cancer, Pancreatic cancer, Glioblastoma, Breast cancer, Multiple myeloma cancer, Neuroblastoma, and Cholangiocarcinoma.

[0178] More specifically, the cancer is at least one cancer selected from the group consisting of: Lung cancer, Endometrial cancer, Pancreatic cancer, Glioblastoma, Breast cancer, Neuroblastoma, and [[ID={}68]]Cholangiocarcinoma.

[0179] In certain embodiments, cancer is a solid tumor. A “solid tumor” or solid cancer is a neoplasm (new proliferation of cells) or lesion (damage to an anatomical structure or impairment of physiological function) formed by the abnormal proliferation of somatic tissue cells other than blood, bone marrow, or lymphocytes. A solid tumor consists of an abnormal mass of cells that may originate from different types of tissue, such as the liver, colon, breast, or lung, and it initially proliferates in the organ of its cell origin. However, such cancers can spread to other organs through the growth of metastatic tumors in advanced stages of the disease.

[0180] In certain embodiments, cancer is a carcinoma, sarcoma, germ cell tumor, or blastoma.

[0181] In certain embodiments, cancer is a carcinoma. A carcinoma is a cancer that originates from epithelial cells, and because epithelial tissue is the most abundant tissue in the body, it accounts for 80% to 90% of all cancer cases. In certain embodiments, cancer includes many of the most common cancers, in particular, for example, lung cancer, colorectal cancer, pancreatic cancer, laryngeal cancer, tongue cancer, prostate cancer, breast cancer, ovarian cancer, liver cancer, head and neck cancer, esophageal cancer, kidney cancer, endometrial cancer, gallbladder cancer, bladder cancer, or stomach cancer.

[0182] There are two types of cancer: adenocarcinoma and squamous cell carcinoma. Adenocarcinoma originates in epithelial cells or glands, while squamous cell carcinoma originates in squamous epithelium. Adenocarcinoma can affect mucous membranes and initially appears as thickened, plaque-like white mucosa. These are rapidly spreading cancers.

[0183] In certain embodiments, the cancer is adenocarcinoma.

[0184] In certain embodiments, the cancer may be lung cancer, endometrial cancer, or pancreatic cancer.

[0185] In certain embodiments, the cancer is lung cancer, more specifically non-small cell lung cancer.

[0186] In certain embodiments, the cancer is squamous cell carcinoma.

[0187] In certain embodiments, the cancer is endometrial cancer, more specifically endometrioid carcinoma or serous endometrial cancer.

[0188] In certain embodiments, cancer is pancreatic cancer. More specifically, pancreatic cancer is either exocrine pancreatic cancer (the most common type) or neuroendocrine pancreatic cancer.

[0189] In certain embodiments, the cancer is bile duct cancer.

[0190] In certain embodiments, the cancer is breast cancer, and more specifically, drug-resistant recurrent breast cancer.

[0191] In certain embodiments, the cancer is head and neck cancer.

[0192] In certain embodiments, cancer is a sarcoma. A sarcoma is a cancer that arises from connective tissue such as muscle, bone, cartilage, and fat. In certain embodiments, a sarcoma is, for example, osteosarcoma (of bone), chondrosarcoma (of cartilage), leiomyosarcoma (smooth muscle), rhabdomyosarcoma (skeletal muscle), mesosarcoma or mesothelioma (interior lining of body cavities), fibrosarcoma (fibrous tissue), angiosarcoma or hemangioendothelioma (blood vessels), liposarcoma (fat or adipose tissue), glioma or astrocytoma (neurogenic connective tissue found in the brain), myxosarcoma (primitive embryonic connective tissue), or mesenchymal or mixed mesodermal tumor (mixed connective tissue type).

[0193] In certain embodiments, the cancer is brain cancer. More specifically, the brain cancer is a glioma. More specifically, the glioma is a glioblastoma.

[0194] In certain embodiments, cancer is a germ cell tumor. A germ cell tumor refers to a tumor derived from pluripotent cells, most often found in the testes or ovaries (semiterminate and undifferentiated germ cell tumors, respectively).

[0195] In certain embodiments, the cancer is a blastoma. A blastoma is a cancer that originates from immature progenitor cells or embryonic tissue. Blastomas are more common in children than in older adults. In certain embodiments, blastomas are, for example, hepatoblastoma, neuroblastoma, medulloblastoma, nephroblastoma, pancreatoblastoma, pleuropulmonaryblastoma, retinoblastoma, or glioblastoma multiforme. In certain embodiments, the cancer is a neuroblastoma.

[0196] Cancers that can be treated by the pharmaceutically acceptable combination of the present invention include solid tumors such as lung cancer, colorectal cancer, pancreatic cancer, laryngeal cancer, tongue cancer, breast cancer, ovarian cancer, prostate cancer, liver cancer, head and neck cancer, esophageal cancer, squamous cell carcinoma, basal cell carcinoma, adenocarcinoma, sweat gland cancer, sebaceous gland cancer, papillary carcinoma, papillary adenocarcinoma, cystadenocarcinoma, medullary carcinoma, bronchogenic carcinoma, renal cell carcinoma, hepatocellular carcinoma, cholangiocarcinoma, choriocarcinoma, seminomas, undifferentiated germ cell tumors, embryonal carcinoma, Wilms' tumor, cervical cancer, testicular cancer, bladder cancer, epithelial carcinoma, glioma, astrocytoma, medulloblastoma, craniopharyngioma, ependymoma, pineal glandoma, hemangioblastoma, acoustic neuroma, oligodendroglioma, meningioma, melanoma, neuroblastoma, and retinoblastoma.

[0197] In certain embodiments, the cancer is metastatic or progressive cancer.

[0198] In certain embodiments, cancer is a hematological malignancy. The term “hematological malignancy” refers to a type of cancer that affects the blood, bone marrow, and lymph nodes, and includes lymphoma, myeloma, and leukemia. Historically, scientists and physicians have classified these diseases by their location in the body, the appearance of the diseased cells under a microscope, and the natural progression of the disease. In leukemia, cancer cells are found circulating in the blood and bone marrow, while in lymphoma, cells tend to aggregate and form clumps or tumors in lymphoid tissue. Myeloma is a tumor of the bone marrow and involves a specific subset of white blood cells that produce their own proteins.

[0199] In certain embodiments, the hematological malignancies are leukemia, lymphoma, or myeloma.

[0200] In certain embodiments, hematological malignancies are leukemias. More specifically, leukemias include, for example, acute myeloid leukemia (AML), acute lymphoblastic leukemia (ALL), chronic lymphocytic leukemia (CLL), chronic myeloid leukemia (CML), and acute monocytic leukemia (AMoL).

[0201] In certain embodiments, the hematological malignancy is a lymphoma. More specifically, the lymphoma is either Hodgkin lymphoma (HL) or non-Hodgkin lymphoma (NHL).

[0202] In certain embodiments, the hematological malignancy is myeloma, also known as multiple myeloma (i.e., cancer of plasma cells, usually white blood cells, that typically produce antibodies).

[0203] In another specific embodiment, a hematological malignancy is in a precancerous stage. As used herein, the term “precancerous stage” refers to a hyperproliferative disorder or precancerous condition that may develop into cancer.

[0204] Dosage of compound (A) and / or compound (B) relating to all aspects of this specification: As discussed above, and in relation to any of the first to fifth aspects of this specification, it is not important whether the two compounds (A) and (B) are administered simultaneously, for example, as a single composition, or sequentially, for example, as two separate compositions, with respect to the combination therapies discussed herein. The important issue is that an effective amount of the first administered compound / drug is present in the patient's body and / or that the second compound / drug exerts its effect in the patient's body when it is administered.

[0205] In this specification, when compound (B) is used in general, it is understood to refer to any of compound (B1), compound (B2), and / or compound (B3).

[0206] The pharmaceutical combinations discussed herein may preferably be a single composition containing both compound (A) and compound (B).

[0207] Compound (A) (particularly ABTL0812) is preferably administered orally.

[0208] The dose administered of compound (A) (particularly ABTL0812) is preferably 200 mg to 7000 mg per day, more preferably 1500 mg to 5000 mg per day, even more preferably 3000 mg to 4700 mg per day, and most preferably 3500 mg to 4300 mg per day.

[0209] Preferably, the daily dose of compound (A) (especially ABTL0812) is administered three times a day, most preferably 1200-1400 mg in three doses.

[0210] In this specification, relevant human clinical trials using ABTL0812 were successfully conducted at a daily dose of 3900 mg administered in three 1300 mg doses.

[0211] Therefore, when compound (A) is ABTL0812 and is administered in three doses of 1300 mg, it is most preferable that the administered dose be 3800 mg to 4000 mg (most preferably 3900 mg).

[0212] With respect to compound (B), the preferred route of administration will generally depend on the benefits of compound (B). Those skilled in the art may routinely determine a preferred route of administration for the benefit of a particular compound (B).

[0213] The preferred route of administration for preferred compound (B) is briefly described below. Temozolomide; preferably administered via oral capsules or tablets; Topotecan; - Preferably administered intravenously via an infusion solution; Irinotecan; - Preferably administered intravenously via an infusion solution; Cyclophosphamide; preferably administered intravenously via an infusion solution; Fluorouracil; preferably administered intravenously via an infusion solution; Oxaliplatin; - Preferably administered intravenously via an infusion solution; Leucovorin; - Preferably administered intravenously via an infusion solution; Doxorubicin; - Preferably administered intravenously via an infusion solution; Bortezomib; - Preferably administered intravenously via an infusion solution; Olaparib; - Preferably administered via oral capsule or tablet; Bevacizumab; preferably administered intravenously via an infusion solution; anti-PD1 checkpoint inhibitor antibody; preferably administered intravenously via an infusion solution.

[0214] Aspects / embodiments of the present invention in so-called claim form: This “Claim Form” section is divided into six subsections, each covering the first to fifth aspects and their embodiments, as discussed herein.

[0215] First aspect and related embodiments - (B1): Chemotherapy agents - Second-line treatment for cancer 1. Pharmaceutical combinations, (A): Compounds that are polyunsaturated fatty acids of the formula COOR1-CHR2-(CH2)a-(CH=CHCH2)b-(CH2)c-CH3, pharmaceutically acceptable salts thereof, or combinations thereof (i) a can be any integer value from 0 to 7, (ii)b can be any integer value between 2 and 7, (iii) c can be any integer value from 0 to 7, (iv) R1 is H, Na, K, CH3, CH3-CH2, or PO(O-CH2-CH3)2, (v) R2 is OH, OCH3, O-CH2COOH, CH3, Cl, CH2OH, OPO(O-CH2-CH3)2, N(OH)2, F, HCOO, or N(OCH2CH3)2. Compounds, their pharmaceutically acceptable salts, or combinations thereof, (B1): A chemotherapeutic agent compound, A pharmaceutical combination comprising a chemotherapeutic agent compound for simultaneous, separate, or sequential use in the treatment of cancer in human patients, wherein the treatment is a second-line therapy for cancer.

[0216] 2. (i) a can be any integer value between 5 and 7, (ii) b can be any integer value between 2 and 4, (iii) The pharmaceutical combination according to claim 1, wherein c can be any integer value from 1 to 5.

[0217] 3. The pharmaceutical combination according to any one of the prior claims, wherein R1 is H and R2 is OH.

[0218] 4. The pharmaceutically acceptable combination according to any one of the prior claims, wherein compound (A) is at least one compound selected from the group consisting of the following, or a pharmaceutically acceptable salt thereof. COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812), COOH-CHOH-(CH2)6-(CH=CH-CH2)3-CH3(183A1), COOH-CHOH-(CH2)3-(CH=CH-CH2)3-(CH2)3-CH3(183A2), COOH-CHOH-(CH2)2-(CH=CH-CH2)4-(CH2)3-CH3(204A1), COOH-CHOH-(CH2)2-(CH=CH-CH2)5-CH3(205A1), and COOH-CHOH-CH2-(CH=CH-CH2)6-CH3(226A1).

[0219] 5. The pharmaceutically acceptable combination according to any one of the prior claims, wherein compound (A) is COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812) or a pharmaceutically acceptable salt thereof.

[0220] 6. The pharmaceutical combination according to claim 5, wherein compound (A) is the sodium salt of COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812).

[0221] 7. The pharmaceutical combination according to any one of the prior claims, wherein the cancer is at least one cancer selected from the group consisting of the following: lung cancer, Non-small cell lung cancer, Squamous cell carcinoma, adenocarcinoma, Endometrial cancer, serous endometrial cancer, Endometrioid carcinoma, Pancreatic cancer, Glioblastoma, Resistant recurrent breast cancer, Head and neck cancer, Multiple myeloma cancer, Neuroblastoma, and Bile duct cancer.

[0222] 8. The pharmaceutically acceptable combination according to any one of the prior claims, wherein compound (B1) is at least one chemotherapeutic compound selected from the group consisting of the following: Temozolomide, Topotecan, Irinotecan, Cyclophosphamide, Fluorouracil, Cisplatin, Carboplatin, Oxaliplatin, Leucovorin, Doxorubicin, Bleomycin, Capecitabine, Mitomycin B, Paclitaxel, Nab-paclitaxel, Docetaxel, Gemcitabine, Methotrexate, Pemetrexed, 5-Fluorouracil, Cytarabine, Mercaptopurine, Gluphosphamide, Ixabepylon, Nimstine, Carmustine, Romustine, Mitoxantrone, Etoposide, Vincristine, Vinblastine, and Tamoxifen

[0223] 9. The pharmaceutically acceptable combination according to claim 8, wherein compound (B1) is at least one chemotherapeutic compound selected from the group consisting of the following. Temozolomide, Topotecan, Irinotecan, Cyclophosphamide, Fluorouracil, Oxaliplatin, Leucovorin, and Doxorubicin

[0224] 10. The pharmaceutically acceptable combination according to claim 9, wherein compound (B1) is at least one chemotherapeutic compound selected from the group consisting of the following. Temozolomide, Topotecan, Fluorouracil, Oxaliplatin, and Leucovorin

[0225] 11. The pharmaceutically acceptable combination according to any one of claims 8 to 10, wherein compound (A) is COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812) or a pharmaceutically acceptable salt thereof.

[0226] 12. - Compound (B1) is temozolomide, and the cancer is neuroblastoma. - Compound (B1) is topotecan, and the cancer is neuroblastoma. - Compound (B1) is irinotecan, and the cancer is neuroblastoma. - Compound (B1) is cyclophosphamide, and the cancer is neuroblastoma. - Compound (B1) is irinotecan, leucovorin, oxaliplatin, and fluorouracil, and the cancer is pancreatic cancer. - Compound (B1) is doxorubicin, and the cancer is endometrial cancer, or -The pharmaceutical combination according to claim 11, wherein compound (B1) is temozolomide and the cancer is glioblastoma.

[0227] 13. The pharmaceutical combination according to any one of the prior claims, wherein the pharmaceutical combination is a single composition comprising both compound (A) and compound (B1).

[0228] 14. A pharmaceutically acceptable combination according to any one of the prior claims, wherein compound (A) is administered orally.

[0229] 15. The pharmaceutical combination according to any one of the prior claims, wherein the dose administered of compound (A) is a daily dose of 200 mg to 7000 mg, more preferably 1500 mg to 5000 mg, even more preferably 3000 mg to 4700 mg, and most preferably 3500 mg to 4300 mg.

[0230] 16. The pharmaceutically acceptable combination according to claim 14 or 15, wherein compound (A) is COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812) or a pharmaceutically acceptable salt thereof.

[0231] 17. Compound (B1) is temozolomide, which is administered via oral capsules or tablets. Compound (B1) is topotecan, which is administered intravenously via an infusion solution. Compound (B1) is irinotecan, which is administered intravenously via an infusion solution. Compound (B1) is cyclophosphamide, which is administered intravenously via an infusion solution. Compound (B1) is fluorouracil, which is administered intravenously via an infusion solution. Compound (B1) is oxaliplatin, which is administered intravenously via an infusion solution. Compound (B1) is leucovorin, which is administered intravenously via an infusion solution, or The pharmaceutically acceptable combination according to claim 16, wherein compound (B1) is doxorubicin, which is administered intravenously via an infusion solution.

[0232] Second aspect and related embodiments - (B2): Targeted therapy compounds - Targeted therapy for cancer 1. Pharmaceutical combinations, (A): Compounds that are polyunsaturated fatty acids of the formula COOR1-CHR2-(CH2)a-(CH=CHCH2)b-(CH2)c-CH3, pharmaceutically acceptable salts thereof, or combinations thereof (i) a can be any integer value from 0 to 7, (ii)b can be any integer value between 2 and 7, (iii) c can be any integer value from 0 to 7, (iv) R1 is H, Na, K, CH3, CH3-CH2, or PO(O-CH2-CH3)2, (v) R2 is OH, OCH3, O-CH2COOH, CH3, Cl, CH2OH, OPO(O-CH2-CH3)2, N(OH)2, F, HCOO, or N(OCH2CH3)2. Compounds, their pharmaceutically acceptable salts, or combinations thereof, (B2): A targeted therapy compound, A pharmaceutical combination comprising a targeted therapy compound, which is intended for simultaneous, separate, or sequential use in the treatment of cancer in human patients, wherein the treatment is a targeted therapy for cancer.

[0233] 2. (i) a can be any integer value between 5 and 7, (ii) b can be any integer value between 2 and 4, (iii) The pharmaceutical combination according to claim 1, wherein c can be any integer value from 1 to 5.

[0234] 3. The pharmaceutical combination according to any one of the prior claims, wherein R1 is H and R2 is OH.

[0235] 4. The pharmaceutically acceptable combination according to any one of the prior claims, wherein compound (A) is at least one compound selected from the group consisting of the following, or a pharmaceutically acceptable salt thereof. COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812), COOH-CHOH-(CH2)6-(CH=CH-CH2)3-CH3(183A1), COOH-CHOH-(CH2)3-(CH=CH-CH2)3-(CH2)3-CH3(183A2), COOH-CHOH-(CH2)2-(CH=CH-CH2)4-(CH2)3-CH3(204A1), COOH-CHOH-(CH2)2-(CH=CH-CH2)5-CH3(205A1), and COOH-CHOH-CH2-(CH=CH-CH2)6-CH3(226A1).

[0236] 5. The pharmaceutically acceptable combination according to any one of the prior claims, wherein compound (A) is COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812) or a pharmaceutically acceptable salt thereof.

[0237] 6. The pharmaceutical combination according to claim 5, wherein compound (A) is the sodium salt of COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812).

[0238] 7. The pharmaceutical combination according to any one of the prior claims, wherein the cancer is at least one cancer selected from the group consisting of the following: lung cancer, Non-small cell lung cancer, Squamous cell carcinoma, adenocarcinoma, Endometrial cancer, serous endometrial cancer, Endometrioid carcinoma, Pancreatic cancer, Glioblastoma, Resistant recurrent breast cancer, Head and neck cancer, Multiple myeloma cancer, Neuroblastoma, and Bile duct cancer.

[0239] 8. The pharmaceutically acceptable combination according to any one of the prior claims, wherein compound (B2) is at least one targeted therapeutic agent compound selected from the group consisting of the following: Imatinib, Gefitinib, Erlotinib, Sorafenib, Sunitinib, Dasatinib, Lapatinib, Nilotinib, Proteasome inhibitors (preferably carfilzomib, ixazomib, or bortezomib), Tamoxifen, Janus kinase inhibitors (preferably tofacitinib), ALK inhibitors (preferably crizotinib), Bcl-2 inhibitors (preferably ovatocrax, navitocrax, or gossypol), PARP inhibitors (preferably iniparib or olaparib), PI3K inhibitor (preferably perifosine), Apatinib, Braf inhibitors (preferably vemurafenib or dabrafenib), MEK inhibitors (preferably trametinib), CDK inhibitors, Hsp90 inhibitors, Salinomycin, VAL-083 (Dianhydrogalactitol), Vintafolide, Serine / threonine kinase inhibitors (preferably temsirolimus, everolimus, vemurafenib, trametinib, or dabrafenib), and Monoclonal antibodies (preferably anti-VEGF mAb, rituximab, trastuzumab, alemtuzumab, cetuximab, panitumumab, or bevacizumab).

[0240] 9. The pharmaceutically acceptable combination according to claim 8, wherein compound (B2) is at least one targeted therapeutic agent compound selected from the group consisting of the following. Proteasome inhibitors (preferably carfilzomib, ixazomib, or bortezomib), PARP inhibitors (preferably iniparib or olaparib), and Monoclonal antibodies (preferably anti-VEGF mAb, rituximab, trastuzumab, alemtuzumab, cetuximab, panitumumab, or bevacizumab).

[0241] 10. The pharmaceutically acceptable combination according to claim 9, wherein compound (B2) is at least one targeted therapeutic agent compound selected from the group consisting of the following. Bortezomib, Olaparib, and Bevacizumab.

[0242] 11. The pharmaceutically acceptable combination according to any one of claims 8 to 10, wherein compound (A) is COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812) or a pharmaceutically acceptable salt thereof.

[0243] 12. - Compound (B2) is bortezomib, and the cancer is multiple myeloma cancer. - Compound (B2) is olaparib, and the cancer is endometrial cancer, or -The pharmaceutically acceptable combination according to claim 11, wherein compound (B2) is bevacizumab and the cancer is endometrial cancer.

[0244] 13. The pharmaceutical combination according to any one of the prior claims, wherein the pharmaceutical combination is a single composition comprising both compound (A) and compound (B2).

[0245] 14. A pharmaceutically acceptable combination according to any one of the prior claims, wherein compound (A) is administered orally.

[0246] 15. The pharmaceutical combination according to any one of the prior claims, wherein the dose administered of compound (A) is a daily dose of 200 mg to 7000 mg, more preferably 1500 mg to 5000 mg, even more preferably 3000 mg to 4700 mg, and most preferably 3500 mg to 4300 mg.

[0247] 16. The pharmaceutically acceptable combination according to claim 14 or 15, wherein compound (A) is COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812) or a pharmaceutically acceptable salt thereof.

[0248] 17. Compound (B2) is bortezomib, which is administered intravenously via an infusion solution. Compound (B2) is olaparib, which is administered via oral capsules or tablets, or The pharmaceutically acceptable combination according to claim 16, wherein compound (B2) is bevacizumab, which is administered intravenously via an infusion solution.

[0249] Third aspect and related embodiments - (B3): Immunotherapy compound - Immunotherapy for cancer 1. Pharmaceutical combinations, (A): Compounds that are polyunsaturated fatty acids of the formula COOR1-CHR2-(CH2)a-(CH=CHCH2)b-(CH2)c-CH3, pharmaceutically acceptable salts thereof, or combinations thereof (i) a can be any integer value from 0 to 7, (ii)b can be any integer value between 2 and 7, (iii) c can be any integer value from 0 to 7, (iv) R1 is H, Na, K, CH3, CH3-CH2, or PO(O-CH2-CH3)2, (v) R2 is OH, OCH3, O-CH2COOH, CH3, Cl, CH2OH, OPO(O-CH2-CH3)2, N(OH)2, F, HCOO, or N(OCH2CH3)2. Compounds, their pharmaceutically acceptable salts, or combinations thereof, (B3): An immunotherapy compound, A pharmaceutical combination comprising an immunotherapy compound, for simultaneous, separate, or sequential use in the treatment of cancer in human patients, wherein the treatment is an immunotherapy treatment for cancer.

[0250] 2. (i) a can be any integer value between 5 and 7, (ii) b can be any integer value between 2 and 4, (iii) The pharmaceutical combination according to claim 1, wherein c can be any integer value from 1 to 5.

[0251] 3. The pharmaceutical combination according to any one of the prior claims, wherein R1 is H and R2 is OH.

[0252] 4. The pharmaceutically acceptable combination according to any one of the prior claims, wherein compound (A) is at least one compound selected from the group consisting of the following, or a pharmaceutically acceptable salt thereof. COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812), COOH-CHOH-(CH2)6-(CH=CH-CH2)3-CH3(183A1), COOH-CHOH-(CH2)3-(CH=CH-CH2)3-(CH2)3-CH3(183A2), COOH-CHOH-(CH2)2-(CH=CH-CH2)4-(CH2)3-CH3(204A1), COOH-CHOH-(CH2)2-(CH=CH-CH2)5-CH3(205A1), and COOH-CHOH-CH2-(CH=CH-CH2)6-CH3(226A1).

[0253] 5. The pharmaceutically acceptable combination according to any one of the prior claims, wherein compound (A) is COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812) or a pharmaceutically acceptable salt thereof.

[0254] 6. The pharmaceutical combination according to claim 5, wherein compound (A) is the sodium salt of COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812).

[0255] 7. The pharmaceutical combination according to any one of the prior claims, wherein the cancer is at least one cancer selected from the group consisting of the following: lung cancer, Non-small cell lung cancer, Squamous cell carcinoma, adenocarcinoma, Endometrial cancer, serous endometrial cancer, Endometrioid carcinoma, Pancreatic cancer, Glioblastoma, Resistant recurrent breast cancer, Head and neck cancer, Multiple myeloma cancer, Neuroblastoma, and Bile duct cancer.

[0256] 8. Compound (B3) The pharmaceutically acceptable combination according to any one of the prior claims, wherein the checkpoint inhibitor antibody is preferably at least one immunotherapy compound selected from the group consisting of checkpoint inhibitor antibodies, wherein the checkpoint inhibitor antibody is an anti-PD1 antibody, an anti-PDL1 antibody, or an anti-CTLA4 antibody.

[0257] 9. Compound (B3) -An anti-PD1 antibody, preferably the anti-PD1 antibody is nivolumab, pembrolizumab, or spartalizumab, -An anti-PDL1 antibody, preferably the anti-PDL1 antibody is atezolizumab, avelumab, or durvalumab, - The pharmaceutically acceptable combination according to claim 8, wherein the anti-CTLA4 antibody is preferably ipilimumab, and the combination is at least one immunotherapy compound selected from the group consisting of anti-CTLA4 antibodies.

[0258] 10. The pharmaceutical combination according to claim 9, wherein compound (B3) is an anti-PD1 antibody, and the anti-PD1 antibody is pembrolizumab.

[0259] 11. The pharmaceutically acceptable combination according to any one of claims 8 to 10, wherein compound (A) is COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812) or a pharmaceutically acceptable salt thereof.

[0260] 12. - Compound (B3) is an anti-PD1 checkpoint inhibitor antibody, particularly pembrolizumab, and the cancer is lung cancer, or -The pharmaceutically acceptable combination according to claim 11, wherein compound (B3) is an anti-PD1 checkpoint inhibitor antibody, preferably pembrolizumab, and is administered in combination with at least one compound (B1), preferably paclitaxel and carboplatin, and the cancer is lung cancer.

[0261] 13. The pharmaceutical combination according to any one of the prior claims, wherein the pharmaceutical combination is a single composition comprising both compound (A) and compound (B3).

[0262] 14. A pharmaceutically acceptable combination according to any one of the prior claims, wherein compound (A) is administered orally.

[0263] 15. The pharmaceutical combination according to any one of the prior claims, wherein the dose administered of compound (A) is a daily dose of 200 mg to 7000 mg, more preferably 1500 mg to 5000 mg, even more preferably 3000 mg to 4700 mg, and most preferably 3500 mg to 4300 mg.

[0264] 16. The pharmaceutically acceptable combination according to any one of the prior claims, wherein compound (A) (particularly ABTL0812) is administered prior to the administration of immunotherapy compound (B3).

[0265] 17. The pharmaceutically acceptable combination according to any one of claims 14 to 16, wherein compound (A) is COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812) or a pharmaceutically acceptable salt thereof.

[0266] 18. The pharmaceutically acceptable combination according to claim 17, wherein compound (B3) is an anti-PD1 checkpoint inhibitor antibody, preferably pembrolizumab, which is administered intravenously via an infusion solution.

[0267] Fourth aspect and related embodiments - Radiotherapy for cancer 1. A pharmaceutical composition, (A): Compounds that are polyunsaturated fatty acids of the formula COOR1-CHR2-(CH2)a-(CH=CHCH2)b-(CH2)c-CH3, pharmaceutically acceptable salts thereof, or combinations thereof (i) a can be any integer value from 0 to 7, (ii)b can be any integer value between 2 and 7, (iii) c can be any integer value from 0 to 7, (iv) R1 is H, Na, K, CH3, CH3-CH2, or PO(O-CH2-CH3)2, (v) R2 is OH, OCH3, O-CH2COOH, CH3, Cl, CH2OH, OPO(O-CH2-CH3)2, N(OH)2, F, HCOO, or N(OCH2CH3)2, A pharmaceutical composition comprising a compound, a pharmaceutically acceptable salt thereof, or a combination thereof, for use in the treatment of cancer in human patients, wherein the treatment is radiotherapy for cancer.

[0268] 2. (i) a can be any integer value between 5 and 7, (ii) b can be any integer value between 2 and 4, (iii) The pharmaceutical composition according to claim 1, wherein c may be any integer value from 1 to 5.

[0269] 3. The pharmaceutical composition according to any one of the prior claims, wherein R1 is H and R2 is OH.

[0270] 4. The pharmaceutical composition according to any one of the prior claims, wherein compound (A) is at least one compound selected from the group consisting of the following, or a pharmaceutically acceptable salt thereof. COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812), COOH-CHOH-(CH2)6-(CH=CH-CH2)3-CH3(183A1), COOH-CHOH-(CH2)3-(CH=CH-CH2)3-(CH2)3-CH3(183A2), COOH-CHOH-(CH2)2-(CH=CH-CH2)4-(CH2)3-CH3(204A1), COOH-CHOH-(CH2)2-(CH=CH-CH2)5-CH3(205A1), and COOH-CHOH-CH2-(CH=CH-CH2)6-CH3(226A1).

[0271] 5. A pharmaceutical composition according to any one of the prior claims, wherein compound (A) is COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812) or a pharmaceutically acceptable salt thereof.

[0272] 6. The pharmaceutical composition according to claim 5, wherein compound (A) is the sodium salt of COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812).

[0273] 7. The pharmaceutical composition according to any one of the prior claims, wherein the cancer is at least one cancer selected from the group consisting of the following: lung cancer, Non-small cell lung cancer, Squamous cell carcinoma, adenocarcinoma, Endometrial cancer, serous endometrial cancer, Endometrioid carcinoma, Pancreatic cancer, Glioblastoma, Resistant recurrent breast cancer, Head and neck cancer, Multiple myeloma cancer, Neuroblastoma, and Bile duct cancer.

[0274] 8. The pharmaceutical composition according to any one of the prior claims, wherein the radiotherapy treatment is performed with a radiation dose of 2 to 200 Gy, preferably 5 to 100 Gy, or more preferably 15 to 85 Gy.

[0275] 9. The pharmaceutical composition according to claim 8, wherein compound (A) is COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812) or a pharmaceutically acceptable salt thereof.

[0276] 10. The pharmaceutical composition according to any one of the prior claims, wherein the radiation dose is administered after the administration of compound (A), preferably at least one day after the first administration of compound (A).

[0277] 11. The pharmaceutical composition according to claim 10, wherein compound (A) is COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812) or a pharmaceutically acceptable salt thereof.

[0278] 12. A pharmaceutical composition according to any one of the prior claims, wherein compound (A) is administered orally.

[0279] 13. The pharmaceutical composition according to any one of the prior claims, wherein the dose administered of compound (A) is a daily dose of 200 mg to 7000 mg, more preferably 1500 mg to 5000 mg, even more preferably 3000 mg to 4700 mg, and most preferably 3500 mg to 4300 mg.

[0280] 14. The pharmaceutical composition according to claim 12 or 13, wherein compound (A) is COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812) or a pharmaceutically acceptable salt thereof.

[0281] 15. The pharmaceutical composition according to any one of the prior claims, wherein the cancer is glioblastoma.

[0282] 16. The pharmaceutical composition according to claim 15, wherein compound (A) is COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812) or a pharmaceutically acceptable salt thereof.

[0283] Fifth aspect and related embodiments - Preferred (B1) chemotherapeutic compound - Treatment of common cancers 1. Pharmaceutical combinations, (A): Compounds that are polyunsaturated fatty acids of the formula COOR1-CHR2-(CH2)a-(CH=CHCH2)b-(CH2)c-CH3, pharmaceutically acceptable salts thereof, or combinations thereof (i) a can be any integer value from 0 to 7, (ii)b can be any integer value between 2 and 7, (iii) c can be any integer value from 0 to 7, (iv) R1 is H, Na, K, CH3, CH3-CH2, or PO(O-CH2-CH3)2, (v) R2 is OH, OCH3, O-CH2COOH, CH3, Cl, CH2OH, OPO(O-CH2-CH3)2, N(OH)2, F, HCOO, or N(OCH2CH3)2. Compounds, their pharmaceutically acceptable salts, or combinations thereof, (B1): A chemotherapeutic agent compound, For simultaneous, separate, or sequential use in the treatment of cancer in human patients, compound (B1) is Temozolomide, Topotecan, Irinotecan, Cyclophosphamide, Fluorouracil, Oxaliplatin, Leucovorin, and A pharmaceutical combination comprising a chemotherapeutic compound, which is at least one chemotherapeutic compound selected from the group consisting of doxorubicin.

[0284] 2. (i) a can be any integer value between 5 and 7, (ii) b can be any integer value between 2 and 4, (iii) The pharmaceutical combination according to claim 1, wherein c can be any integer value from 1 to 5.

[0285] 3. The pharmaceutical combination according to any one of the prior claims, wherein R1 is H and R2 is OH.

[0286] 4. The pharmaceutically acceptable combination according to any one of the prior claims, wherein compound (A) is at least one compound selected from the group consisting of the following, or a pharmaceutically acceptable salt thereof. COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812), COOH-CHOH-(CH2)6-(CH=CH-CH2)3-CH3(183A1), COOH-CHOH-(CH2)3-(CH=CH-CH2)3-(CH2)3-CH3(183A2), COOH-CHOH-(CH2)2-(CH=CH-CH2)4-(CH2)3-CH3(204A1), COOH-CHOH-(CH2)2-(CH=CH-CH2)5-CH3(205A1), and COOH-CHOH-CH2-(CH=CH-CH2)6-CH3(226A1).

[0287] 5. The pharmaceutically acceptable combination according to any one of the prior claims, wherein compound (A) is COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812) or a pharmaceutically acceptable salt thereof.

[0288] 6. The pharmaceutical combination according to claim 5, wherein compound (A) is the sodium salt of COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812).

[0289] 7. The pharmaceutical combination according to any one of the prior claims, wherein the cancer is at least one cancer selected from the group consisting of the following: lung cancer, Non-small cell lung cancer, Squamous cell carcinoma, adenocarcinoma, Endometrial cancer, serous endometrial cancer, Endometrioid carcinoma, Pancreatic cancer, Glioblastoma, Resistant recurrent breast cancer, Head and neck cancer, Multiple myeloma cancer, Neuroblastoma, and Bile duct cancer.

[0290] 8. The pharmaceutically acceptable combination according to any one of the prior claims, wherein compound (B1) is at least one chemotherapeutic compound selected from the group consisting of the following: Temozolomide, Topotecan, Fluorouracil, Oxaliplatin, and Leucovorin.

[0291] 9. The pharmaceutically acceptable combination according to claim 8, wherein compound (A) is COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812) or a pharmaceutically acceptable salt thereof.

[0292] 10. - Compound (B1) is temozolomide, and the cancer is neuroblastoma. - Compound (B1) is topotecan, and the cancer is neuroblastoma. - Compound (B1) is irinotecan, and the cancer is neuroblastoma. - Compound (B1) is cyclophosphamide, and the cancer is neuroblastoma. - Compound (B1) is irinotecan, leucovorin, oxaliplatin, and fluorouracil, and the cancer is pancreatic cancer. - Compound (B1) is doxorubicin, and the cancer is endometrial cancer, or -The pharmaceutical combination according to claim 9, wherein compound (B1) is temozolomide and the cancer is glioblastoma.

[0293] 11. The pharmaceutical combination according to any one of the prior claims, wherein the pharmaceutical combination is a single composition comprising both compound (A) and compound (B1).

[0294] 12. A pharmaceutically acceptable combination according to any one of the prior claims, wherein compound (A) is administered orally.

[0295] 13. The pharmaceutical combination according to any one of the prior claims, wherein the dose administered of compound (A) is a daily dose of 200 mg to 7000 mg, more preferably 1500 mg to 5000 mg, even more preferably 3000 mg to 4700 mg, and most preferably 3500 mg to 4300 mg.

[0296] 14. The pharmaceutically acceptable combination according to claim 12 or 13, wherein compound (A) is COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812) or a pharmaceutically acceptable salt thereof.

[0297] 15. Compound (B1) is temozolomide, which is administered via oral capsules or tablets. Compound (B1) is topotecan, which is administered intravenously via an infusion solution. Compound (B1) is irinotecan, which is administered intravenously via an infusion solution. Compound (B1) is cyclophosphamide, which is administered intravenously via an infusion solution. Compound (B1) is fluorouracil, which is administered intravenously via an infusion solution. Compound (B1) is oxaliplatin, which is administered intravenously via an infusion solution. Compound (B1) is leucovorin, which is administered intravenously via an infusion solution, or The pharmaceutically acceptable combination according to claim 14, wherein compound (B1) is doxorubicin, which is administered intravenously via an infusion solution.

[0298] Other specific combinations related to all aspects of this specification—combinations of (A) and two or more compounds (B). 1. Pharmaceutical combinations, (A): Compounds that are polyunsaturated fatty acids of the formula COOR1-CHR2-(CH2)a-(CH=CHCH2)b-(CH2)c-CH3, pharmaceutically acceptable salts thereof, or combinations thereof (i) a can be any integer value from 0 to 7, (ii)b can be any integer value between 2 and 7, (iii) c can be any integer value from 0 to 7, (iv) R1 is H, Na, K, CH3, CH3-CH2, or PO(O-CH2-CH3)2, (v) A compound, a pharmaceutically acceptable salt thereof, or a combination thereof, in which R2 is OH, OCH3, O-CH2COOH, CH3, Cl, CH2OH, OPO(O-CH2-CH3)2, N(OH)2, F, HCOO, or N(OCH2CH3)2 (B1): Chemotherapy agent compounds, (B3): An immunotherapy compound, A pharmaceutical combination comprising an immunotherapy compound intended for simultaneous, separate, or sequential use in the treatment of cancer in human patients.

[0299] 2. (i) a can be any integer value between 5 and 7, (ii) b can be any integer value between 2 and 4, (iii) The pharmaceutical combination according to claim 1, wherein c can be any integer value from 1 to 5.

[0300] 3. The pharmaceutical combination according to any one of the prior claims, wherein R1 is H and R2 is OH.

[0301] 4. The pharmaceutically acceptable combination according to any one of the prior claims, wherein compound (A) is at least one compound selected from the group consisting of the following, or a pharmaceutically acceptable salt thereof. COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812), COOH-CHOH-(CH2)6-(CH=CH-CH2)3-CH3(183A1), COOH-CHOH-(CH2)3-(CH=CH-CH2)3-(CH2)3-CH3(183A2), COOH-CHOH-(CH2)2-(CH=CH-CH2)4-(CH2)3-CH3(204A1), COOH-CHOH-(CH2)2-(CH=CH-CH2)5-CH3(205A1), and COOH-CHOH-CH2-(CH=CH-CH2)6-CH3(226A1).

[0302] 5. The pharmaceutically acceptable combination according to any one of the prior claims, wherein compound (A) is COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812) or a pharmaceutically acceptable salt thereof.

[0303] 6. The pharmaceutical combination according to claim 5, wherein compound (A) is the sodium salt of COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812).

[0304] 7. The pharmaceutical combination according to any one of the prior claims, wherein the cancer is at least one cancer selected from the group consisting of the following: lung cancer, Non-small cell lung cancer, Squamous cell carcinoma, adenocarcinoma, Endometrial cancer, serous endometrial cancer, Endometrioid carcinoma, Pancreatic cancer, Glioblastoma, Resistant recurrent breast cancer, Head and neck cancer, Multiple myeloma cancer, Neuroblastoma, and Bile duct cancer.

[0305] 8. Compound (B3) The pharmaceutically acceptable combination according to any one of the prior claims, wherein the checkpoint inhibitor antibody is preferably at least one immunotherapy compound selected from the group consisting of checkpoint inhibitor antibodies, wherein the checkpoint inhibitor antibody is an anti-PD1 antibody, an anti-PDL1 antibody, or an anti-CTLA4 antibody.

[0306] 9. Compound (B3) -An anti-PD1 antibody, preferably the anti-PD1 antibody is nivolumab, pembrolizumab, or spartalizumab, -An anti-PDL1 antibody, preferably the anti-PDL1 antibody is atezolizumab, avelumab, or durvalumab, - The pharmaceutically acceptable combination according to claim 8, wherein the anti-CTLA4 antibody is preferably ipilimumab, and the combination is at least one immunotherapy compound selected from the group consisting of anti-CTLA4 antibodies.

[0307] 10. The pharmaceutically acceptable combination according to claim 9, wherein compound (B3) is an anti-PD1 antibody, and preferably the anti-PD1 antibody is pembrolizumab.

[0308] 11. The pharmaceutically acceptable combination according to any one of claims 8 to 10, wherein compound (A) is COOH-CHOH-(CH2)6-(CH=CH-CH2)2-(CH2)3-CH3(ABTL0812) or a pharmaceutically acceptable salt thereof.

[0309] 12. - Compound (B3) is an anti-PD1 checkpoint inhibitor antibody, particularly pembrolizumab, and the cancer is lung cancer, or -The pharmaceutically acceptable combination according to claim 11, wherein compound (B3) is an anti-PD1 checkpoint inhibitor antibody, preferably pembrolizumab, and is administered in combination with at least one compound (B1), preferably paclitaxel and carboplatin, and the cancer is lung cancer.

[0310] 13. The pharmaceutically acceptable combination according to any one of the prior claims, wherein compound (B1) is at least one chemotherapeutic compound selected from the group consisting of the following: Temozolomide, Topotecan, Irinotecan, Cyclophosphamide, Fluorouracil, Cisplatin, Carboplatin, Oxaliplatin, Leucovorin, Doxorubicin, Bleomycin, Capecitabine, Mitomycin B, Paclitaxel, Nab-paclitaxel, Docetaxel, Gemcitabine, Methotrexate, Pemetrexed, 5-Fluorouracil, Cytarabine, Mercaptopurine, Gluphosphamide, Ixabepylon, Nimstine, Carmustine, Romustine, Mitoxantrone, Etoposide, Vincristine, Vinblastine, and Tamoxifen.

[0311] 14. The pharmaceutically acceptable combination according to claim 13, wherein compound (B1) is at least one chemotherapeutic compound selected from the group consisting of the following. Temozolomide, Topotecan, Irinotecan, Cyclophosphamide, Fluorouracil, Oxaliplatin, Leucovorin, and Doxorubicin.

[0312] 15. The pharmaceutically acceptable combination according to claim 13, wherein compound (B1) is at least one chemotherapeutic compound selected from the group consisting of the following. Temozolomide, Topotecan, Fluorouracil, Oxaliplatin, and Leucovorin.

[0313] 16. The pharmaceutically acceptable combination according to claim 13, wherein compound (B1) is at least one chemotherapeutic compound selected from the group consisting of the following. Irinotecan, Fluorouracil, Oxaliplatin, and Leucovorin.

[0314] 17. The pharmaceutically acceptable combination according to claim 13, wherein compound (B1) is at least one chemotherapeutic compound selected from the group consisting of the following. Carboplatin, and Paclitaxel.

[0315] 18. The pharmaceutically acceptable combination according to claim 17, wherein compound (B1) is paclitaxel and carboplatin.

[0316] 19. The pharmaceutically acceptable combination according to claim 16, wherein compound (B1) is irinotecan, leucovorin, oxaliplatin, and fluorouracil.

[0317] 20. The pharmaceutical combination according to any one of claims 1 to 19, wherein compound (A) is ABTL0812, compound (B1) is paclitaxel and carboplatin, and compound (B3) is an anti-PD1 checkpoint inhibitor antibody.

[0318] 21. The pharmaceutical combination according to any one of claims 1 to 19, wherein compound (A) is ABTL0812, compound (B1) is irinotecan, leucovorin, oxaliplatin, and fluorouracil, and compound (B3) is an anti-PD1 checkpoint inhibitor antibody.

[0319] 22. The pharmaceutically acceptable combination according to claim 20 or 21, wherein compound (B3) is an anti-PD1 checkpoint inhibitor antibody selected from nivolumab, pembrolizumab, and spartalizumab, preferably pembrolizumab.

[0320] 23. The pharmaceutical combination according to any one of the prior claims, wherein compound (B1) is administered intravenously via an infusion solution.

[0321] 24. A pharmaceutically acceptable combination according to any one of the prior claims, wherein compound (A) is administered orally.

[0322] 25. The pharmaceutical combination according to any one of the prior claims, wherein the dose administered of compound (A) is a daily dose of 200 mg to 7000 mg, more preferably 1500 mg to 5000 mg, even more preferably 3000 mg to 4700 mg, and most preferably 3500 mg to 4300 mg.

[0323] 26. The pharmaceutically acceptable combination according to any one of claims 1 to 7, 13 to 19, and 23 to 25, wherein compound (B3) is an anti-cancer immunomodulatory compound.

[0324] 27. The pharmaceutically acceptable combination according to claim 26, wherein compound (B3) is an anti-cancer immunomodulatory compound selected from the group consisting of cytokines, checkpoint inhibitors, agonists, and adjuvants. [Examples]

[0325] Example 1: ABTL0812 in vitro assay in combination with different / additional chemotherapeutic agents 1.1: Cell viability assay in neuroblastoma using ABTL0812 alone or in combination with temozolomide Objective: To investigate the potential synergistic effects of ABTL0812 when added to temozolomide in neuroblastoma cell lines SK-N-BE(2) and LA1-5S. Temozolomide is a common chemotherapeutic agent used, for example, as a backbone in second-line treatment for high-risk neuroblastoma. Therefore, it is of interest to know whether there is an enhancing effect between ABTL0812 and temozolomide.

[0326] Methods: LA1-5S and SK-N-BE(2) cells were incubated with increasing concentrations of temozolomide (500 μM, 1000 μM, and 1500 μM) and ABTL0812 at subIC50 fixed concentrations (30 μM for SK-N-BE(2) and 40 μM for LA1-5S). Cells were treated with IMDM containing 0.5% FBS for 48 hours. Cell viability was assessed by the crystal violet assay. Different doses were evaluated in six replicates, and the results shown are the mean of two independent experiments. Statistical analysis was performed using GraphPad Prism® 5.0 software according to the principle of the t-test.

[0327] Results: Addition of ABTL0812 at 30 μM or 40 μM increased the cytotoxicity of temozolomide. This increase was statistically significant at all concentrations (**p<0.01, ***p<0.001) - see Figure 1 herein.

[0328] Conclusion: ABTL0812 enhances the cytotoxic effect of temozolomide in vitro in neuroblastoma cell lines SK-N-BE(2) and LA1-5S. These results support in vivo studies of the combination of both drugs.

[0329] 1.2: Cell viability assay with ABTL0812 alone or in combination with topotecan in neuroblastoma Objective: To investigate the potential synergistic effect of ABTL0812 when added to topotecan in neuroblastoma cell line LA1-5S. Topotecan is a common chemotherapeutic agent used, for example, as a backbone in second-line treatment for high-risk neuroblastoma. Therefore, it is of interest to know whether there is an enhancing effect between ABTL0812 and topotecan.

[0330] Methods: LA1-5S cells were incubated with increasing concentrations of topotecan (0.5 μM, 1 μM, and 2 μM) and a fixed concentration of ABTL0812 (30 μM). Cells were treated with IMDM containing 0.5% FBS for 72 hours. Cell viability was assessed by the crystal violet assay. Data are expressed as the mean ± SEM of three independent experiments. Statistical analysis was performed using GraphPad Prism® 5.0 software according to the principle of the t-test.

[0331] Results: Addition of ABTL0812 at 30 μM significantly increased the cytotoxicity of topotecan. (*p<0.05, **p<0.01 compared to the vehicle; compared to the matched concentrations of each drug as a single agent) $ (p<0.05). See Figure 2 in this specification.

[0332] Conclusion: ABTL0812 enhances the cytotoxic effect of topotecan in vitro in the neuroblastoma cell line SLA1-5S. These results support in vivo studies of the combination of both drugs.

[0333] 1.3: Cell viability assay with ABTL0812 alone or in combination with irinotecan in neuroblastoma Objective: To investigate the potential synergistic effect of ABTL0812 when added to irinotecan in neuroblastoma cell line LA1-5S. Irinotecan is a common chemotherapeutic agent used, for example, as a backbone in second-line treatment for high-risk neuroblastoma. Therefore, it is of interest to know whether there is an enhancing effect between ABTL0812 and irinotecan.

[0334] Methods: LA1-5S cells were incubated with increasing concentrations of irinotecan (4 μM, 8 μM, and 16 μM) and a fixed concentration of ABTL0812 (30 μM). Cells were treated with IMDM containing 0.5% FBS for 72 hours. Cell viability was assessed by the crystal violet assay. Data are expressed as the mean ± SEM of three independent experiments. Statistical analysis was performed using GraphPad Prism® 5.0 software according to the principle of t-tests (*p<0.05, **p<0.01, ***p<0.001).

[0335] Results: Addition of ABTL0812 at 30 μM significantly increased the cytotoxicity of irinotecan. (*p<0.05, **p<0.01 compared to the vehicle; compared to ABTL0812 as a monotherapy) # p<0.05; compared to the matched concentrations of each drug as a single agent. $ (p<0.05). See Figure 3 in this specification.

[0336] Conclusion: ABTL0812 enhances the cytotoxic effect of irinotecan in vitro in the neuroblastoma cell line SLA1-5S. These results support in vivo studies of the combination of both drugs.

[0337] 1.4: Cell viability assay in neuroblastoma using ABTL0812 alone or in combination with cyclophosphamide Objective: To investigate the potential synergistic effect of ABTL0812 when added to cyclophosphamide in the neuroblastoma cell line LA1-5S. Cyclophosphamide is a common chemotherapeutic agent used, for example, as a backbone in second-line treatment for high-risk neuroblastoma. Therefore, it is of interest to know whether there is an enhancing effect between ABTL0812 and cyclophosphamide.

[0338] Methods: LA1-5S cells were incubated with increasing concentrations of cyclophosphamide (1 μM, 1.5 μM, and 2 μM) and ABTL0812 (30 μM) at subIC50 fixed concentrations. Cells were treated with IMDM containing 0.5% FBS for 72 hours. Cell viability was assessed by the crystal violet assay. Data are expressed as the mean ± SEM of three independent experiments. Statistical analysis was performed using GraphPad Prism® 5.0 software according to the principle of t-tests (*p<0.05, **p<0.01, ***p<0.001).

[0339] Results: Addition of ABTL0812 at 30 μM significantly increased the cytotoxicity of cyclophosphamide at 1 μM (compared to the matched concentrations of each drug as a single agent). $ (p<0.05). See Figure 4 in this specification.

[0340] Conclusion: ABTL0812 enhances the cytotoxic effect of cyclophosphamide in vitro in the neuroblastoma cell line SLA1-5S. These results support in vivo studies of the combination of both drugs.

[0341] Example 2: ABTL0812 in vitro assay in combination with targeted therapy 2.1: Cell viability assay with ABTL0812 alone or in combination with bortezomib in multiple myeloma Objective: To investigate the potential synergistic effects of ABTL0812 in addition to bortezomib in multiple myeloma cell lines JJN-3 and OPM2. Bortezomib is a first-in-class proteasome inhibitor targeted therapy approved for the treatment of patients with multiple myeloma. Therefore, it is interesting to know if there is an additive effect between the two drugs.

[0342] Methods: JJN-3 and OPM2 cells were seeded in 24-well plates and treated with ABTL0812 (5 μM), bortezomib (0.5 and 1 nM, respectively), or a combination of both drugs, and incubated for 48 hours (0.5% FBS). Cell viability was studied by MTT assay, and combination indices were determined to assess possible synergistic effects.

[0343] Results: JJN-3 cells were incubated with 5 μM (Sub IC50 concentration) ABTL0812 and 0.5 nM (Sub IC50 concentration) bortezomib, which induced approximately 10% and 15% cell death, respectively. Combining both drugs enhanced cell death, inducing approximately 40% cell death. Cell viability was assessed by MTT assay in all cases, and a combination index (CI) to assess the synergistic effect was calculated according to the method of Chou and Talalay (Chou 2006; Chou 2010) as follows: CI = (D)1 / (Dx)1 + (D)2 / (Dx)2 (wherein CI < 1, = 1, and > 1 represent synergistic, additive, and antagonistic effects, respectively). In the denominator, (Dx)1 represents D1 "alone" inhibiting x% of the system, and (Dx)2 represents D2 "alone" inhibiting x% of the system. At the molecular level, the "combination" of (D)1 and (D)2 also inhibits by x%. The CI of this combination is 0.049, indicating a very high synergistic effect. In the case of OPM2 cells, they were incubated with 5 μM (Sub IC50 concentration) of ABTL0812 and 5 nM (Sub IC50 concentration) of bortezomib, which induce approximately 20% and 10% cell death, respectively. Combining both drugs enhances cell death, inducing approximately 55% cell death. The combination index is 0.50, indicating a synergistic effect—see Figure 5 herein.

[0344] Conclusion: ABTL0812 and bortezomib exhibit potent synergistic effects in vitro in multiple myeloma cell lines JJN-3 and OPM2. Combining both drugs at sub IC50 concentrations enhances anticancer activity, thus demonstrating a synergistic effect between the two drugs. These results broaden the opportunities for in vivo combination of both drugs.

[0345] Example 3: ABTL0812 in vivo assay in combination with different chemotherapeutic agents 3.1: Anticancer activity of ABTL0812 alone or in combination with FOLFIRINOX (5-FU, leucovorin, irinotecan, and oxaliplatin) in a human pancreatic cancer xenograft model using MiaPAca2 cells transplanted into nude mice. Test system: Nu / nu female mice.

[0346] Objective: To investigate the antitumor activity of ABTL0812 alone and in combination with FOLFIRINOX, a standard treatment for pancreatic cancer.

[0347] Method: To induce tumor formation, 5 x 10⁶ granules were placed on one side of the flank of the mouse. 6 MiaPaca2 cells were injected. The tumor volume was approximately 100 mm². 3 At this point, animals were uniformly randomized and initiated with different treatments. ABTL0812 was administered orally at 120 mg / kg / day. A combination of FOLFIRINOX chemotherapy was administered intraperitoneally once weekly for a total of four doses. 30 mg / kg of 5-FU, 50 mg / kg of leucovorin, 50 mg / kg of irinotecan, and 2.5 mg / kg of oxaliplatin were administered intraperitoneally over two different days. 5-FU and leucovorin were administered on Tuesdays, and irinotecan and oxaliplatin on Thursdays. Tumor volume and body weight were monitored three times a week.

[0348] Results: The combination of ABTL0812 and FOLFIRINOX dramatically increased the therapeutic potential of chemotherapy and showed the highest tumor volume reduction compared to FOLFIRINOX, ABTL0812, and vehicle groups. Statistical analysis showed that the combination therapy significantly improved tumor growth reduction compared to FOLFIRINOX alone, the standard treatment for advanced pancreatic cancer (p<0.001 by t-test). Furthermore, no decrease in body weight or hematological counts was observed in any of the treatment groups, including when ABTL0812 was administered with FOLFIRINOX (not shown), suggesting that this combination had no toxic effects. See Figure 6 in this specification.

[0349] Conclusion: ABTL0812 significantly enhances the anticancer effect of FOLFIRINOX in a human pancreatic cancer xenograft model using MiaPaca2 cells transplanted into nude mice, without increasing toxicity. Since FOLFIRINOX is a standard treatment for patients with advanced pancreatic cancer, these results suggest that the combination therapy of ABTL0812 plus FOLFIRINOX may have clinical interest in the treatment of pancreatic cancer.

[0350] 3.2: Anticancer activity of ABTL0812 alone or in combination with doxorubicin in a human endometrial cancer xenograft model using Ishikawa cells transplanted into nude mice. Objective: To investigate the antitumor activity of ABTL0812 alone and in combination with doxorubicin, a reference second-line treatment for endometrial cancer.

[0351] Method: To induce tumor formation, 4 × 10¹⁶ granules were placed on one side of the flank of the mouse. 6 Ishikawa cells were injected. The tumor volume was approximately 50 mm. 3 At this point, animals were uniformly randomized and initiated with different treatments. ABTL0812 was administered orally at a dose of 120 mg / kg / day. Doxorubicin 5 mg / kg was administered intraperitoneally once weekly. Tumor volume and body weight were monitored three times a week.

[0352] Results: ABTL0812 and doxorubicin significantly reduced tumor volume compared to control animals (ANOVA and subsequent t-test). The efficacy of ABTL0812 was indeed similar to that observed with doxorubicin treatment alone. Interestingly, ABTL0812 enhanced the antitumor effect of docetaxel. Statistical analysis showed that this combination therapy significantly improved the reduction of tumor growth compared to doxorubicin alone (by t-test, *p<0.05). Furthermore, no decrease in body weight or hematological counts was observed in any of the treatment groups, including when ABTL0812 was administered with doxorubicin (not shown), suggesting that this combination had no toxic effects. See Figure 7 in this specification.

[0353] Conclusion: ABTL0812 reduces tumor growth in a xenograft model of endometrial cancer derived from Ishikawa cells. In this model, ABTL0812 exhibits similar efficacy to SOC doxorubicin. ABTL0812 enhances the antitumor activity of doxorubicin without toxic effects. These results suggest that combination therapy with ABTL0812 plus doxorubicin may have clinical interest in the treatment of endometrial cancer.

[0354] 3.3: Anticancer activity of ABTL0812 alone or in combination with temozolomide in a human glioblastoma orthotopic xenograft model using U87MG cells transplanted into the brains of nude mice. Objective: To investigate the antitumor activity of ABTL0812 alone and in combination with temozolomide, a reference drug for the treatment of glioblastoma.

[0355] Methods: Luciferase-transfected U87MG cells were intracerebral-injected into mice. Animals were randomized 5 days after cell inoculation and initiation of treatment. ABTL0812 was administered orally at 240 mg / kg every 5 days / week, and temozolomide was administered orally at 32 mg / kg for the first 5 days. Tumors were measured by quantification of bioluminescence intensity (BLI) in the area of ​​interest.

[0356] Results: ABTL0812 and temozolomide, used as monotherapies, significantly increased disease-free survival in animals with glioblastoma tumors in the brain. Interestingly, the combination of ABTL0812 and temozolomide was significantly more effective than monotherapy. See Figure 8 in this specification.

[0357] Conclusion: ABTL0812 as a monotherapy increased disease-free survival in tumor-bearing mice and enhanced the antitumor activity of temozolomide. These results suggest that combination therapy with ABTL0812 plus temozolomide may have clinical interest in the treatment of glioblastoma.

[0358] Example 4: ABTL0812 in combination with radiotherapy: In vivo assay 4.1 Anti-cancer activity of ABTL0812 alone or in combination with radiotherapy in a human glioblastoma subcutaneous xenograft model using U87MG cells transplanted into the brains of nude mice Objective: To investigate the antitumor activities of ABTL0812 alone and in combination with radiotherapy, which are the main treatment strategies for glioblastoma.

[0359] Methods: To induce tumor formation, 1x10 6 U87MG or T98G cells were subcutaneously injected into each flank of the mice. When the tumor volume reached 0.8 - 1.3 cm 3 , the animals were evenly randomized and different treatments were initiated. ABTL0812 was orally administered at 240 mg / kg, 5 days / week, and radiotherapy was administered as a single dose of 4 Gy on day 3.

[0360] Results: ABTL0812 as a single agent significantly decreased the growth of glioblastoma subcutaneous tumors. Furthermore, the combination of ABTL0812 and radiotherapy was significantly more effective than ABTL0812 or radiotherapy as single treatments. See Figure 9 of this specification.

[0361] Conclusion: ABTL0812 as a single agent decreases the growth of glioblastoma tumors and enhances the antitumor activity of radiotherapy. These results suggest that the combination therapy of ABTL0812 + radiotherapy may have clinical interest for the treatment of glioblastoma.

[0362] 4.2 Anti-cancer activity of ABTL0812 alone or in combination with radiotherapy in a human glioblastoma orthotopic xenograft model using U87MG cells transplanted into the brains of nude mice Objective: To investigate the antitumor activities of ABTL0812 alone and in combination with radiotherapy, which are the main treatment strategies for glioblastoma.

[0363] Methods: Luciferase-transfected U87MG cells were intracerebral-injected into mice. Animals were randomized 5 days after cell inoculation and initiation of treatment. ABTL0812 was administered orally at 240 mg / kg every 5 days / week, and radiotherapy was administered as a single dose of 4 Gy on day 10. Tumors were measured by quantification of bioluminescence intensity (BLI) in the area of ​​interest.

[0364] Results: ABTL0812 as a monotherapy and radiotherapy significantly increased disease-free survival in animals with glioblastoma tumors in the brain. Interestingly, the combination of ABTL0812 and radiotherapy was significantly more effective than monotherapy. See Figure 10 in this specification.

[0365] Conclusion: ABTL0812 as a monotherapy increased disease-free survival in tumor-bearing mice and enhanced the antitumor activity of radiotherapy. These results suggest that combination therapy of ABTL0812 plus radiotherapy may have clinical interest in the treatment of glioblastoma.

[0366] Example 5: ABTL0812 in vivo assay in combination with targeted therapy 5.1: Anticancer activity of ABTL0812 alone or in combination with olaparib in a human endometrial cancer model using Ishikawa cells transplanted into nude mice. Objective: To investigate the antitumor activity of ABTL0812 alone and in combination with olaparib, a reference drug for the treatment of endometrial cancer.

[0367] Method: To induce tumor formation, 4 × 10¹⁶ granules were placed on one side of the flank of the mouse. 6 Ishikawa cells were injected. The tumor volume was approximately 50 mm. 3 At this point, animals were uniformly randomized and initiated with different treatments: ABTL0812 was administered orally at 120 mg / kg / day, or olaparib was administered orally at 50 mg / kg / day. Tumor volume and body weight were monitored three times a week.

[0368] Results: ABTL0812 and olaparib significantly reduced tumor volume compared to control animals (ANOVA and subsequent t-test). The efficacy of ABTL0812 was indeed similar to that observed with olaparib treatment. Interestingly, ABTL0812 enhanced the antitumor effect of docetaxel. Statistical analysis showed that this combination therapy significantly improved the reduction of tumor growth compared to olaparib alone (by t-test, **p<0.01**). Furthermore, no decrease in body weight or hematological counts was observed in any of the treatment groups, including when ABTL0812 was administered with olaparib (not shown), suggesting that this combination had no toxic effects. See Figure 11 in this specification.

[0369] Conclusion: ABTL0812 reduces tumor growth in a xenograft model of endometrial cancer derived from Ishikawa cells. In this model, ABTL0812 exhibits similar efficacy to olaparib treatment. ABTL0812 enhances the antitumor activity of olaparib without toxic effects. These results suggest that combination therapy of ABTL0812 plus olaparib may have clinical interest in the treatment of endometrial cancer.

[0370] 5.2: Anticancer activity of ABTL0812 alone or in combination with bevacizumab in a human endometrial cancer model using Ishikawa cells transplanted into nude mice. Objective: To investigate the antitumor activity of ABTL0812 alone and in combination with bevacizumab, which has shown potential efficacy in endometrial cancer.

[0371] Method: To induce tumor formation, 4 × 10¹⁶ granules were placed on one side of the flank of the mouse. 6 Ishikawa cells were injected. The tumor volume was approximately 50 mm. 3 At this point, animals were uniformly randomized and initiated with different treatments. ABTL0812 was administered orally at a dose of 120 mg / kg / day. Bevacizumab was administered intraperitoneally at a dose of 100 μg / dose every 4 days for up to 4 doses. Tumor volume and body weight were monitored three times a week.

[0372] Results: ABTL0812 and bevacizumab significantly reduced tumor volume compared to control animals (ANOVA and subsequent t-test). The efficacy of ABTL0812 was indeed similar to that observed with bevacizumab treatment. Interestingly, ABTL0812 enhanced the antitumor effect of docetaxel. Statistical analysis showed that this combination therapy significantly improved the reduction of tumor growth compared to bevacizumab alone (by t-test, *p<0.05). Furthermore, no decrease in body weight or hematological counts was observed in any of the treatment groups, including when ABTL0812 was administered with bevacizumab (not shown), suggesting that this combination had no toxic effects. See Figure 12 in this specification.

[0373] Conclusion: ABTL0812 reduces tumor growth in a xenograft model of endometrial cancer derived from Ishikawa cells. In this model, ABTL0812 exhibits similar efficacy to bevacizumab therapy. ABTL0812 enhances the antitumor activity of bevacizumab without toxic effects. These results suggest that combination therapy of ABTL0812 plus bevacizumab may have clinical interest in the treatment of endometrial cancer.

[0374] Example 6: Immunomodulatory effect of ABTL0812: In vitro assay 6.1: Immunomodulatory effects of ABTL0812 on human THP-1 human macrophage cells by enhancing M1 pro-inflammatory activity and suppressing M2 anti-inflammatory phenotypes. Objective: To investigate the immunomodulatory effects of ABTL0812 on macrophage polarization into M1 phenotype (pro-inflammatory and antitumor) and M2 phenotype (anti-inflammatory pro-tumor) that affect the tumor microenvironment during ABTL0812 treatment.

[0375] Methods: THP-1 monocytes growing in suspension were differentiated into macrophages by incubation with PMA for 24 hours, inducing their attachment to plates. Once THP-1 differentiated into macrophages, they were polarized to M1 by incubation with LPS in the presence of ABTL0812 (50 or 100 μM) for 6 or 24 hours. In parallel, the differentiated macrophages were polarized to M2 by incubation with IL-4 and IL-13 in the presence of ABTL0812 (50 μM) for 24 hours. The polarized macrophages were then lysed, total RNA was extracted and reverse transcribed into cDNA, and mRNA levels of IL1β, TNFα (M1 marker), and IL-10 (M2 marker) were evaluated by RT-qPCR using specific probes.

[0376] Results: The immunomodulatory effect of ABTL0812 significantly enhances IL-1β and TNFα mRNA levels when macrophages are polarized to M1, and significantly suppresses IL-10 mRNA levels when macrophages are polarized to M2 (t-tests **p<0.01 and ***p<0.001). When differentiated macrophages are incubated with ABTL0812 alone without polarization, ABTL0812 can significantly induce IL-1β expression, highlighting its immunomodulatory effect on human THP-1 cells. See Figure 13 herein.

[0377] Conclusion: ABTL0812 enhances the polarization of human THP-1 monocytes to M1 and significantly increases the gene expression of IL-1β and TNFα, which promotes a pro-inflammatory environment that exerts an antitumor effect. Furthermore, ABTL0812 suppresses the polarization of human THP-1 monocytes to M2 and significantly decreases the gene expression of IL-10, thus avoiding immunosuppression mediated by M2 macrophages, a common mechanism that tumor cells use to evade the immune system. "These results suggest that, apart from its anticancer effects on tumor cells, ABTL0812 stimulates the immune system into a pro-inflammatory phenotype, mobilizing other immune cells as cytotoxic T lymphocytes and thus transforming 'cold' tumors that induce immunosuppression into 'hot' immunogenic tumors, highlighting the potential combination of ABTL0812 with certain immune checkpoint inhibitors that enhances anticancer efficacy by promoting a pro-inflammatory and antitumor microenvironment."

[0378] 6.2: Induction of PDL1 expression in cancer cells treated with ABTL0812 Objective: To investigate the immunomodulatory effects of ABTL0812 on PDL1 expression in cancer cells, either alone or in combination with IFNγ, a well-documented master regulator of PDL1 expression.

[0379] Methods: Human cancer cell lines were incubated with 100 μM ABTL0812 for 48 hours and collected for staining with fluorophore-labeled anti-PDL1 antibody. After staining with anti-PDL1 antibody, the cells were analyzed by flow cytometry (Facs Canto) to determine PDL1 levels in cancer cells. Furthermore, Panc-1 cells were incubated with ABTL0812 (50 μM), IFNγ (2.5 ng / ml), a master regulator of PDL1 expression, or a combination of both. The cells were then collected, stained with anti-PDL1 antibody, and PDL1 expression was analyzed by flow cytometry.

[0380] Results: ABTL0812 induced PDL1 expression in all cancer cell lines tested with similar potency, ranging from 34% (MiaPaca2 cells) to 86% (Capan-2 cells) from baseline levels (T-test *p<0.05, **p<0.01). When PDL1 levels were analyzed in Panc-1 cells incubated with IFNγ with or without ABTL0812, IFNγ induced significantly higher levels of PDL1 compared to ABTL0812 (T-test **p<0.01). Interestingly, cells incubated with ABTL0812 and IFNγ induced similar PDL1 levels as the sum of the ABTL0812-mediated and IFNγ-mediated effects. ABTL0812 combined with IFNγ induces significantly higher PDL1 levels compared to ABTL0812 treatment alone (T-test ***p<0.001), but this increase is not significant compared to IFNγ treatment alone, suggesting an additive effect on PDL1 expression when both drugs are administered together. See Figure 14 in this specification.

[0381] Conclusion: ABTL0812 induces PDL1 expression in human pancreatic and endometrial cancer cells. IFNγ, a master regulator of PDL1 expression, induces higher PDL1 levels compared to ABTL0812; however, when both drugs are administered together, there is an additive effect on PDL1 expression levels, inducing even higher levels. ABTL0812 is cytotoxic to cancer cells, stimulating macrophages against a pro-inflammatory phenotype, which, among other things, produces high levels of IFNγ. These results highlight the potential combination of ABTL0812 with immune checkpoint inhibitors, as the mediated induction of PDL1 levels makes cancer cells targetable to immune checkpoint inhibitors.

[0382] 6.3: Induction of a pro-inflammatory environment in macrophages Objective: After evaluating the immunomodulatory effects of ABTL0812 on human macrophages, we investigated the effects of ABTL0812 on cancer cells and how the conditioned medium for cancer cells treated with ABTL0812 affects the survival rate and polarization of human macrophages.

[0383] Methods: MiaPaca2 cells were incubated with 40 μM ABTL0812 for 72 hours, and the conditioned medium (RPMI) of these ABTL0812-treated cells was collected. In parallel, human THP-1 cells were differentiated into macrophages and their adhesion to plates was induced by incubation with PMA (phorbol myristate acetate) for 24 hours. Next, the conditioned medium of ABTL0812-treated MiaPaca2 cells was transferred to PMA-activated THP-1 macrophages, which were incubated for 24 hours for RT-qPCR analysis of M1 phenotypic markers IL-1β and TNF-α, or for 48 hours for cell viability studies using MTT assays. For M1 marker analysis, cells were collected, RNA was extracted, and reverse transcription was performed to evaluate cDNA and mRNA levels of IL-1β and TNF-α by RT-qPCR.

[0384] Results: Previous results have shown that ABTL0812 exhibits cytotoxicity to MiaPaca2 cells, with an IC50 of 50 μM, which also indicates that it induces the release of different factors into the culture medium. When this medium of MiaPaca2 cells treated with ABTL0812 is transferred to activated THP-1 macrophages, it induces their metabolic activation and significantly increases the viability of THP-1 cells. Furthermore, ABTL0812-conditioned medium induces polarization of THP-1 macrophages toward a pro-inflammatory antitumor phenotype and significantly increases the gene expression of IL-1β and TNF-α, thus confirming the immunomodulatory effect of ABTL0812 mediated by its effect on cancer cells. See Figure 15 herein.

[0385] Conclusion: ABTL0812 exhibits not only a direct effect on macrophage polarization but also an immunomodulatory effect through its effect on cancer cells, because ABTL0812-conditioned medium from MiaPaca2 cells can induce polarization to M1 by increasing the viability and metabolic activity of human THP-1 macrophages, as well as by increasing the expression of IL-1β and TNF-α in these macrophages. These data, combined with the induction of ICD (Example 6.7) and inhibition of immunosuppressive factor secretion (Example 6.6), strongly suggest that ABTL0812 can immunomodulate the tumor microenvironment through its anti-cancer effect on cancer cells, in addition to its direct effect on human macrophages, thereby transforming "cold" tumors into "hot" tumors and making them targetable to the immune system, thus highlighting its potential combination with immune checkpoint inhibitors to enhance anti-cancer efficacy.

[0386] 6.4: Induction of PDL1 expression in cancer cells treated with ABTL0812 Objective: To investigate the immunomodulatory effects of ABTL0812 on PDL1 expression in cancer cells, which may potentially expose cancer cells to immunotherapy with immune checkpoint inhibitors.

[0387] Methods: Human pancreatic cancer cell lines (MiaPaca2, Panc-1, Capan-2, and SU.86.86) and human endometrial cancer cell lines (Ishikawa, ANC3, Hec-1A, Ark1, and Ark2) were incubated with ABTL0812 at doses ranging from 0 to 80 μM for 24 hours. Subsequently, cells were collected and stained with anti-PDL1 antibody for flow cytometry analysis of the percentage of PDL1-positive cells.

[0388] Results: ABTL0812 induces PDL1 expression in all cancer cell lines tested, ranging from 34% to 86% increase in pancreatic cancer cells and from 10% to 35% in endometrial cancer cells (T-test *p<0.05, **p<0.01). See Figure 19 in this specification.

[0389] Conclusion: ABTL0812 induces PDL1 expression in human pancreatic and endometrial cancer cells, potentially creating cancer cells that can be targeted by immune checkpoint inhibitors. These results support the potential synergistic effects of ABTL0812 and immunotherapy for treating cancer.

[0390] 6.5: Inhibition of PD1 expression in primary human CD4 and CD8 T cells from peripheral blood of healthy donors treated ex vivo with ABTL0812. Objective: To investigate the immunomodulatory effects of ABTL0812 on PD1 expression in primary human T cells activated or deactivated by CD3 and CD28.

[0391] Methods: Human PBMCs were purified from healthy donor peripheral blood using Ficoll and cultured in vitro. Human T cells were activated by 10-day incubation with IL-2 as well as CD3 and CD28 antibodies, followed by 6-hour treatment with ABTL0812. Finally, the level of PD1 expressed on the membrane of T cells was analyzed by flow cytometry using specific antibodies. Results are shown as % of positive cells and represent the mean of three independent experiments (t-test **p<0.01 and ***p<0.001).

[0392] Results: ABTL0812 induces inhibition of PD1 expression in inactivated and activated human primary CD4 and CD8 T lymphocytes. See Figure 20 in this specification.

[0393] Conclusion: ABTL0812 induces inhibition of PD1 expression in both activated and inactivated primary human CD4 and CD8 T cells purified from healthy donor blood. This may potentially enhance the immune system against cancer cells by blocking PD1-mediated immunosuppression and T cell inactivation.

[0394] 6.6: Immunomodulatory effects of ABTL0812 on the secretome of human pancreatic cancer cells Objective: To investigate the immunomodulatory effects of ABTL0812 on the secretome of cancer cells by analyzing secreted factors in culture media using a protein microarray that detects up to 38 different chemokines.

[0395] Methods: Human pancreatic cancer cells were treated with 100 μM ABTL0812 for 24 hours, and culture medium was collected for incubation using the RayBio C-series human chemokine antibody array C1 (RayBiotec). The culture medium was incubated with a membrane containing antibodies against 38 different chemokines. The membrane was then incubated with a secondary antibody and further developed using an HRP substrate. Signal intensity was assessed using densitometry, and images show the results of three different biological replications.

[0396] Results: The immunomodulatory effect of ABTL0812 induces a reduction in the immunosuppressive chemokines CXCL6 (associated with immunosuppression, invasion, and poor prognosis), CXCL16 (promotes tumor invasion, which is upregulated in pancreatic cancer), angiogenin (promotes immunosuppression and angiogenesis), and CCL5 (promotes Treg tumor invasion and immunosuppression). See Figure 21 herein.

[0397] Conclusion: ABTL0812 promotes inhibition of immunosuppressive factor release in human pancreatic cancer cells. These data suggest that the effect of ABTL0812 on the secretome of cancer cells modulates the tumor microenvironment to a more pro-inflammatory and antitumor phenotype and inhibits the secretion of immunosuppressive factors.

[0398] 6.7: Immunomodulatory effects of ABTL0812 on human pancreatic cancer cells by induction of immunogenic cell death. Objective: To investigate the immunomodulatory effects of ABTL0812 on cancer cells by evaluating the induction of immunogenic cell death (ICD).

[0399] Methods: Human pancreatic cancer cells were treated with increasing concentrations of ABTL0812 (ranging from 0 to 150 μM) for 24 hours, and the activation of extracellular Hmgb1 and ATP, surface calreticulin, and caspases 3 and 8, which are characteristic of ICD, was evaluated by ELISA (Hmgb1 and ATP), flow cytometry (calreticulin), and immunoblotting (caspases 3 and 8). For extracellular Hmgb1 and ATP, culture media from cells treated with ABTL0812 were collected and incubated with specific antibodies for further detection using a colorimetric assay. For surface calreticulin, cancer cells were collected and incubated with specific antibodies for further detection using flow cytometry. For the activation of caspases 3 and 8, cancer cells were collected, protein lysates were obtained, incubated with specific antibodies for further detection using immunoblotting, and finally quantified using densitometry.

[0400] Results: The immunomodulatory effect of ABTL0812, when detected by ELISA, luciferase assay, flow cytometry, and fluorescence-based substrate assay, induces dose-dependent increases in all ICD features: extracellular Hmgb1 and ATP, surface calreticulin, and caspase 3 and 8 activation (t-tests **p<0.01 and ***p<0.001). See Figure 22 herein. Similar results were obtained in different human pancreatic cancer cell lines, and Figure 23 shows the results in MiaPaca2 cells as a representative experiment.

[0401] Conclusion: ABTL0812 induces ICD in human pancreatic cancer cells, as indicated by dose-dependent increases in ICD markers: extracellular Hmgb1 and ATP, surface calreticulin, and caspase 3 and 8 activation. These results suggest that ABTL0812 helps induce ICD in tumors, making them more immunogenic and targetable to the immune system, and transforming “cold” tumors that induce immunosuppression into “hot” immunogenic tumors. These data support the potential combination of immunotherapy and ABTL0812 for enhancing anticancer effects.

[0402] 6.8: Immunomodulatory effects of ABTL0812 on immortalized THP-1 and human primary macrophage cells by enhancing M1 pro-inflammatory activity and suppressing M2 anti-inflammatory phenotypes. Objective: To investigate the immunomodulatory effects of ABTL0812 on immortalization into M1 phenotype (pro-inflammatory and antitumor) and M2 phenotype (anti-inflammatory pro-tumor) and polarization of primary macrophages, which affect the tumor microenvironment during ABTL0812 treatment.

[0403] Methods: THP-1 monocytes growing in suspension were differentiated into macrophages by incubation with PMA for 24 hours to induce their attachment to plates. Monocytes were differentiated into macrophages by incubation with 20 ng / mL M-CSF1 for 7 days. In parallel, whole blood was collected from healthy donors and circulating monocytes were purified using immunomagnetic separation. Monocytes were selected using anti-CD14 antibody conjugated to magnetic beads, retained on a magnetic column, and further eluted for in vitro culture. After obtaining activated macrophages (immortalized and primary), they were polarized to M1 by incubation with LPS+IFNγ in the presence of 100 μM ABTL0812 for 6 hours. In parallel, differentiated macrophages were polarized to M2 by incubation with IL-4 and IL-13 in the presence of ABTL0812 (100 μM) for 24 hours. Subsequently, polarized macrophages were lysed, total RNA was extracted, reverse transcribed into cDNA, and mRNA levels of IL1β, TNFα (M1 marker), and IL-10 (M2 marker) were evaluated by RT-qPCR using specific probes.

[0404] Results: The immunomodulatory effect of ABTL0812 significantly enhances IL-1β and TNFα mRNA levels when macrophages are polarized to M1, and significantly suppresses IL-10 mRNA levels when macrophages are polarized to M2 (t-tests **p<0.01 and ***p<0.001). When differentiated macrophages are incubated with ABTL0812 alone without polarization, ABTL0812 significantly induces IL-1β expression, highlighting its immunomodulatory effect on human THP-1 cells. See Figure 24 herein.

[0405] Conclusion: ABTL0812 enhances the M1 polarization of both human THP-1 and human primary macrophages, significantly increasing the gene expression of IL-1β and TNFα, which promotes a pro-inflammatory environment that exerts antitumor effects. Furthermore, ABTL0812 suppresses the M2 polarization of human THP-1 monocytes and significantly decreases the gene expression of IL-10, evading immunosuppression mediated by M2 macrophages, a common mechanism used by tumor cells to evade the immune system. These results suggest that, apart from its anticancer effects on tumor cells, ABTL0812 stimulates the immune system into a pro-inflammatory phenotype, mobilizing other immune cells as cytotoxic T lymphocytes, and thus transforming "cold" tumors that induce immunosuppression into "hot" immunogenic tumors. These results support the potential combination of immunotherapy and ABTL0812 for enhancing anticancer effects by promoting a pro-inflammatory and antitumor microenvironment.

[0406] 6.9: Immunomodulatory effects of ABTL0812 on the secretome of immortalized human THP1 macrophages and human primary macrophages as measured by protein microarrays. Objective: To investigate the immunomodulatory effects of ABTL0812 on immortalization and the secretome of primary macrophages by analyzing secreted factors in culture media using a protein microarray that detects up to 42 different cytokines after treatment with ABTL0812.

[0407] Methods: Whole blood was collected from healthy donors, and circulating monocytes were purified using immunomagnetic separation. Monocytes were selected using anti-CD14 antibody conjugated to magnetic beads, retained on a magnetic column, and further eluted for in vitro culture. Monocytes were incubated with 20 ng / mL M-CSF1 for 7 days to differentiate into macrophages. Once primary monocytes differentiated into macrophages, they were polarized to M1 by incubation with LPS in the presence of ABTL0812 (50 or 100 μM) for 6 or 24 hours. In parallel, differentiated macrophages were polarized to M2 by incubation with IL-4 and IL-13 in the presence of ABTL0812 (50 μM) for 24 hours. THP-1 monocytes growing in suspension were differentiated into macrophages by incubation with PMA for 24 hours to induce their attachment to plates. When THP-1 differentiated into macrophages, these were polarized to M1 by incubation with LPS in the presence of ABTL0812 (50 μM) for 6 or 24 hours. In parallel, differentiated macrophages were polarized to M2 by incubation with IL-4 and IL-13 in the presence of ABTL0812 (50 μM) for 24 hours. Culture media of M1, M2, and differentiated macrophages (M0) treated with ABTL0812 were incubated using the RayBio C-series human cytokine antibody array C3 (RayBiotec). The culture media were incubated with PVDF (polyvinylidene fluoride) membranes containing antibodies against 42 different cytokines. After incubation of the media, the membranes were incubated with secondary antibodies and further developed using HRP (horseradish peroxidase) substrate. Signal intensity was evaluated using densitometry, and images show the results of three different biological replications.

[0408] Results: The immunomodulatory effect of ABTL0812 induces a reduction in immunosuppressive chemokines and upregulation of different pro-inflammatory factors such as IL-1β and TNF-α. Of all the immunosuppressive cytokines inhibited by ABTL0812 treatment, five were most frequently observed in immortalized THP1 cells and primary macrophages: IL-10 (associated with immunosuppression, invasion, and poor prognosis in different cancers), CCL22 (associated with immunosuppression, invasion, and poor prognosis in different cancers), CCL17 (associated with immunosuppression, invasion, and poor prognosis in different cancers), CCL8 (associated with immunosuppression, proliferation, and invasion), and CCL7 (associated with immunosuppression and invasion). See Figure 25 of this specification.

[0409] Conclusion: ABTL0812 promotes the secretion of pro-inflammatory factors and suppresses the release of immunosuppressive factors in cancer cells. These data, combined with enhancement of the M1 macrophage phenotype and suppression of the M2 phenotype (Example 6.8), suggest that ABTL0812 can promote a pro-inflammatory antitumor environment for its effects on immune cells. These results support the potential combination of immunotherapy and ABTL0812 to enhance the therapeutic effect against tumors, particularly highly immunosuppressive tumors such as pancreatic cancer.

[0410] 6.10:ABTL0812 Immunomodulatory effects increase T cell cytotoxicity in cancer cells. Objective: To investigate the immunomodulatory effects of ABTL0812 on co-cultures of cancer cells with activated T cells.

[0411] Methods: Human PBMCs were purified from the peripheral blood of healthy donors using Ficoll and cultured in vitro. Human T cells were activated by 10-day incubation with IL-2 and CD3 and CD28 antibodies. In parallel, Ishikawa endometrial cancer cells were treated with 50 μM ABTL0812 for 6 hours and then co-cultured with activated T lymphocytes for 24 hours. Cell viability was then assessed by MTT assay. Untreated Ishikawa cells were used as a control. Results are shown as the mean of three different experiments (t-test * p < 0.05).

[0412] Results: The effect of ABTL0812 on cancer cells was to enhance the cytotoxic effect of activated T cells compared to cancer cells not treated with ABTL0812, which correlates with the promotion of an ABTL0812-mediated pro-inflammatory environment for cancer cells. See Figure 26 of this specification.

[0413] Conclusion: The effect of ABTL0812 on cancer cells is to promote the activation of the immune system and enhance the cytotoxic effect of activated primary cells against cancer cells.

[0414] Example 7: Immunomodulatory effect of ABTL0812: In vivo assay 7.1: Induction of PDL1 expression in cancer cells treated with ABTL0812 in a xenograft model of human lung cancer transplanted with H157 cells and a human pancreatic cancer model transplanted with MiaPaca2 cells. Objective: To verify the induction of PDL1 expression by ABTL0812, as observed in vitro, in two in vivo models using human squamous epithelial NSLC cell line H157 and human pancreatic cancer cell line MiaPAca2 transplanted into nude mice.

[0415] Method: To induce tumor formation, 4 x 10⁶ granules were placed on one side of the flank of the mouse. 6 H157 cells or 5x10 6 MiaPAca2 cells were injected. The tumor volume was approximately 50 mm². 3At this point, the animals were uniformly randomized and initiated with different treatments. ABTL0812 was administered orally at a dose of 120 mg / kg / day for 3 weeks. After treatment, the animals were sacrificed, tumors were extracted, and the PDL1 protein levels in cancer cells were analyzed by Western blotting.

[0416] Results: ABTL0812 increased tumor PDL1 protein levels in vivo, further validating previous in vitro results (Figure 14). These results highlight the potential combination of ABTL0812 with immune checkpoint inhibitors, as the mediated induction of PDL1 levels makes cancer cells targetable for immune checkpoint inhibitors.

[0417] 7.2: Induction of T cell infiltration within uterine tumor lesions from female mice with endometrial cancer treated with ABTL0812. Objective: To investigate the anticancer and immunomodulatory effects of ABTL0812 in a syngeneic model of endometrial carcinogenesis induced by PTEN deletion in epithelial cells, which ultimately leads to hyperplasia resulting in endometrioid intraepithelial neoplasia.

[0418] Methods: Mice were injected with tamoxifen to induce PTEN deletion. Three weeks after tamoxifen administration, if hyperplasia developed in the animals, they were administered ABTL0812 at 120 mg / kg daily or a vehicle for three weeks. At that point, animals treated with the vehicle (six weeks after tamoxifen injection) developed neoplasms, which were quantified by immunohistochemistry of extracted uteruses. After ABTL0812 treatment, the animals were sacrificed, and the uteruses were extracted in paraffin embedding for further immunohistochemical analysis with hematoxylin-eosin staining for carcinogenicity assessment or with anti-CD3 to assess T lymphocyte infiltration within tumor lesions, demonstrating immunomodulation of the tumor microenvironment.

[0419] Results: Mice with endometrial carcinogenesis treated with ABTL0812 showed a significant reduction in the development of endometrioid intraepithelial neoplasia (EIN) and halted the progression of carcinogenesis in hyperplasia (when mice treated with the vehicle showed 80% of animals with EIN compared to 80% of animals treated with ABTL0812 with hyperplasia, as analyzed by hematoxylin-eosin staining). When the treated uterus was analyzed for CD3 T lymphocyte expression, ABTL0812 induced CD3 T lymphocyte infiltration into the tumor lesion, whereas animals treated with the vehicle showed CD3 T lymphocytes in the peristroma within the tumor lesion without infiltration into the tumor. See Figure 23 herein.

[0420] Conclusion: The immunomodulatory effects of ABTL0812 in vivo demonstrate how it induces T lymphocyte infiltration within tumor lesions, indicating the presence of a pro-inflammatory antitumor microenvironment that promotes the infiltration of immune cells to kill cancer cells. These data highlight ABTL0812's potential combination with immune checkpoint inhibitors to enhance anticancer efficacy, correlating with superior efficacy outcomes when animals treated with the vehicle exhibit intraepithelial neoplasia.

[0421] Example 8: ABTL0812 in vivo assay in combination with an immunotherapy agent 8.1: Anticancer activity of ABTL0812 alone or in combination with anti-PD1 in a mouse model of lung cancer using LLC1 cells transplanted into C57BL6 mice Objective: To evaluate the antitumor activity of ABTL0812 alone and in combination with an anti-PD1 antibody, a reference drug for lung cancer treatment, in terms of survival rate, at 800 mm. 3 The study will be based on endpoint criteria that focus on identifying tumors and clinical signs of toxicity or distress exceeding a certain threshold. Pembrolizumab is an anti-PD1 checkpoint inhibitor for use in humans, and in this example, a corresponding modified version optimized for use in the mouse model used in this example was used.

[0422] Methods: Lewis lung cancer cells (LLC1) are a highly tumorigenic mouse cell line that first originates in the lungs of C57BL mice transplanted with primary Lewis lung cancer. These cells can be grown subcutaneously in syngeneic C57BL6 mice, developing highly aggressive tumors that can be used to evaluate immunotherapy treatments. To induce tumorigenesis, 0.25 x 10¹⁶ cells were placed in one flank of C57BL6 mice. 6 LLC1 cells were injected. The tumor volume was approximately 50 mm. 3 At this point, animals were uniformly randomized to treatment groups (n=7) and initiated with different therapies. ABTL0812 was administered orally at a dose of 120 mg / kg / day. Anti-PD1 antibody was administered intraperitoneally at a dose of 100 ug / dose every 3 days for a total of 4 doses. Tumor volume and body weight were monitored 3 times a week. The endpoint criterion was 800 mm². 3 This was based on tumors exceeding a certain size, or on clinical signs of toxicity, distress, or suffering suggesting euthanasia of the animal.

[0423] Results: Administration of ABTL0812 alone slightly increased the survival rate of mice compared to the vehicle and anti-PD1 treatment groups, showing a 15% survival rate after 14 days of treatment compared to a 0% survival rate in the vehicle and anti-PD1 groups. Interestingly, the two-combination of ABTL0812 + anti-PD1 antibody showed the best survival rate, with a 38% survival rate after 14 days of treatment. Nine days after treatment, the vehicle group showed a survival rate of 29%, the anti-PD1 group a survival rate of 15%, the ABTL0812 group a survival rate of 43%, and the ABTL0812 + anti-PD1 treatment showed a survival rate of 62%. See Figure 16 in this specification.

[0424] Conclusion: ABTL0812 combined with anti-PD1 therapy (immune checkpoint inhibitor) significantly increases mouse survival compared to vehicle, anti-PD1, and ABTL0812 therapy alone. While ABTL0812 alone slightly increased mouse survival after 14 days of treatment, its effect was greater and achieved in a shorter timeframe. These data suggest a synergistic effect between ABTL0812 and anti-PD1 therapy, increasing mouse survival and highlighting its potential combination for human patients.

[0425] 8.2: Anticancer activity of ABTL0812 alone or in combination with anti-PD1 / paclitaxel / carboplatin in a mouse model of lung cancer using LLC1 cells transplanted into C57BL6 mice Objective: To investigate the antitumor activity of ABTL0812 alone and in combination with an anti-PD1 antibody and carboplatin / paclitaxel, and to evaluate the potential synergistic effects between ABTL0812 and anti-PD1 + carboplatin / paclitaxel therapy in reducing tumor volume of subcutaneously growing LLC1 xenografts.

[0426] Methods: Lewis lung cancer cells (LLC1) are a highly tumorigenic mouse cell line that first originates in the lungs of C57BL mice transplanted with primary Lewis lung cancer. These cells can be grown subcutaneously in syngeneic C57BL6 mice, developing highly aggressive tumors that can be used to evaluate immunotherapy treatments. To induce tumorigenesis, 0.25 x 10¹⁶ cells were placed in one flank of C57BL6 mice. 6 LLC1 cells were injected. The day after tumor transplantation, the animals were divided into treatment groups and treatment was initiated (n=5). ABTL0812 was administered orally at 120 mg / kg / day, anti-PD1 antibody was administered intraperitoneally (ip) at 100 μg / dose every 3 days for a total of 5 doses, and carboplatin and paclitaxel were administered intraperitoneally once a week at 15 mg / kg and 5 mg / kg, respectively, for a total of 3 and 4 doses. Tumor volume and body weight were monitored three times a week.

[0427] Results: Treatment with ABTL0812 and anti-PD1 + paclitaxel / carboplatin significantly reduced tumor volume compared to control animals (ANOVA and subsequent t-test* p<0.05). The efficacy of ABTL0812 was indeed similar to that observed with docetaxel treatment. Interestingly, ABTL0812 enhanced the antitumor effect of docetaxel. Statistical analysis showed that this combination therapy significantly improved the reduction of tumor growth compared to docetaxel alone (by t-test, p<0.001). Furthermore, no decrease in body weight or hematological counts was observed in any of the treatment groups, including when ABTL0812 was administered with docetaxel (not shown), suggesting that this combination had no toxic effects. See Figure 17 in this specification.

[0428] Conclusion: Literature on LLC1 xenografts describes that while anti-PD1 therapy is ineffective in these tumors, the combination with paclitaxel / carboplatin, enhanced by anti-PD1 antibodies, shows significant tumor volume reduction compared to the vehicle control group. This is due to chemotherapy that makes tumor cells immunogenic and recognizable by the immune system. ABTL0812 administered alone shows similar efficacy to anti-PD1 + paclitaxel / carboplatin, but the combination of ABTL0812 + anti-PD1 + paclitaxel / carboplatin induces significant tumor volume reduction compared to anti-PD1 + paclitaxel / carboplatin and further demonstrates potential synergies among ABTL0812s, as it also acts as an immunomodulator that induces a pro-inflammatory antitumor microenvironment, in conjunction with immune checkpoint inhibitors to induce even greater tumor volume reduction. These results suggest that the combination therapy of ABTL0812 + anti-PD1 + paclitaxel / carboplatin, which is the standard treatment for lung cancer patients, may have clinical interest in the treatment of lung cancer.

[0429] 8.3: Anticancer activity of ABTL0812 alone or in combination with anti-PD1 / paclitaxel / carboplatin in a mouse model of lung cancer using LLC1 cells injected intraperitoneally into C57BL6 mice Objective: To investigate the antitumor activity of ABTL0812 alone and in combination with an anti-PD1 antibody and carboplatin / paclitaxel, and to evaluate the potential synergistic effects between ABTL0812 and anti-PD1 + carboplatin / paclitaxel therapy in reducing tumor volume of LLC1 tumors growing in the peritoneal cavity.

[0430] Methods: Lewis lung cancer cells (LLC1) are a highly tumorigenic mouse cell line that first originates in the lungs of C57BL mice transplanted with primary Lewis lung cancer. These cells can be grown intraperitoneally in syngeneic C57BL6 mice, developing highly aggressive tumors that adhere to the intestines and can be used to evaluate immunotherapy treatments. To induce tumorigenesis, 1 x 10¹⁶ cells were introduced into the peritoneum of C57BL6 mice. 6 LLC1 cells were injected. The day after tumor transplantation, the animals were divided into treatment groups and treatment was initiated (n=2). ABTL0812 was administered orally at 120 mg / kg / day, anti-PD1 antibody was administered intraperitoneally at 100 ug / dose every 3 days for a total of 5 doses, and paclitaxel and carboplatin were administered intraperitoneally once a week at 15 mg / kg and 5 mg / kg, respectively, for a total of 3 and 4 doses. Fourteen days after treatment, the animals were euthanized and tumors growing in the intestines were collected.

[0431] Results: ABTL0812 combined with anti-PD1+ paclitaxel / carboplatin significantly reduced tumor volume, showing approximately half the size, compared to control, ABTL0812, and anti-PD1+ paclitaxel / carboplatin treatment in a xenograft model of intraperitoneal LLC1 cells in C57BL6 mice. See Figure 18 herein.

[0432] Conclusion: LLC1 cells can proliferate in the peritoneal cavity of C57BL6 mice and develop highly aggressive tumors that adhere to the intestines. The tripartite combination of ABTL0812 + anti-PD1 + paclitaxel / carboplatin reduces tumor growth compared to vehicle, ABTL0812, and anti-PD1 + paclitaxel / carboplatin therapy. These results suggest that the combination therapy of ABTL0812 + anti-PD1 + paclitaxel / carboplatin, which is the standard of care for lung cancer patients, may have clinical interest in the treatment of lung cancer.

[0433] 8.4: Anticancer activity and tumor microenvironment immunomodulation mediated by ABTL0812 in a mouse model of pancreatic cancer using MT5 cells transplanted into C57BL6 mice. Objective: To investigate the antitumor activity and tumor immunomodulatory in vivo effects of ABTL0812 alone and compare it with an anti-PD1 antibody, a reference drug for the treatment of different human cancer types. Anticancer efficacy is assessed by tumor volume reduction, and immunomodulation of the tumor microenvironment is assessed by tumor immune cell infiltration analysis. Pembrolizumab is an anti-PD1 checkpoint inhibitor for use in humans, and in this example, a corresponding modified version optimized for use in the mouse model used in this example was used.

[0434] Methods: MT5 cells are a highly tumorigenic mouse cell line with mutations in KRAS and p53, originally derived from the pancreas of triple transgenic KRAS-p53-Cre (KPC) mice with pancreatic ductal adenocarcinoma. These cells can be grown subcutaneously in syngeneic C57BL6 mice, developing highly aggressive tumors that can be used to evaluate immunotherapy treatments. To induce tumorigenesis, 2 x 10¹⁶ cells were placed in one flank of C57BL6 mice. 6 MT5 cells were injected. The tumor volume was approximately 50 mm². 3At this point, animals were uniformly randomized to treatment groups (n=9) and initiated with different therapies. The treatment groups were vehicle, ABTL0812, and anti-PD1. ABTL0812 was administered orally at 480 mg / kg / day. Anti-PD1 antibody was administered intraperitoneally at 200 μg / dose every 3 days. Tumor volume and body weight were monitored three times a week. At the end of treatment, mice were euthanized, tumors were collected, and single-cell suspensions were obtained by digesting the tumors using digestion media containing collagenase and lipase, and further treating with trypsin and DNAse. In addition, spleens were collected from treated mice, finely chopped using a strainer, and treated with trypsin and DNAse to obtain single cells. After obtaining the cell suspensions, cancer cells and immune cells infiltrating the tumors were stained using specific antibodies against different immune cell subsets and further analyzed using flow cytometry. The combinations used were: Th1 cells = CD45+ CD4+ CCR4- CXCR3+, Th2 cells = CD45+ CD4+ CCR4+ CXCR3-, bone marrow cells = CD45+ CD11b+ Ly6C+, and NK cells = CD45+ NK1.1+.

[0435] Results: Administration of ABTL0812 alone demonstrated anticancer efficacy against MT5 tumors, significantly reducing tumor volume compared to the vehicle treatment group and showing similar efficacy to anti-PD1 therapy administered alone. None of the treatments showed changes in mouse body weight or clinical signs of toxicity, distress, or pain in the animals. Furthermore, ABTL0812 induced an increase in myeloid cells within tumors, which correlates with its ability to enhance the M1 phenotype in vitro, and this is accompanied by an increase in the proportion of NK cells within tumors, which are cells with anticancer activity. In addition, the spleens of mice treated with ABTL0812 showed an increased Th1 / Th2 ratio, which indicates a pro-inflammatory immune system response (***p<0.001). See Figure 27 herein.

[0436] Conclusion: ABTL0812 demonstrates anticancer efficacy in a mouse pancreatic cancer model using MT5 cells by modulating the tumor microenvironment to a more pro-inflammatory and antitumor environment. ABTL0812 increases the spleen's Th1 / Th2 ratio, indicating a pro-inflammatory environment in the spleen, which is commonly used as an indicator or activation of the mouse immune system. As a result, ABTL0812 induces an increase in myeloid cells and NK cells within the tumor, indicating pro-inflammatory antitumor immune infiltration. Importantly, this immunomodulatory effect mediated by ABTL0812 is significantly higher compared to anti-PD1 therapy. Pancreatic cancer is considered a highly immunosuppressive and low-immunogenic tumor, and immunotherapy alone does not show very optimistic effects. These data suggest that ABTL0812 can more efficiently promote the transformation of cold pancreatic tumors into hot, more immunogenic tumors than anti-PD1, thus highlighting its potential combination of immunotherapy and chemotherapy for increased anticancer efficacy.

[0437] 8.5: Anticancer activity and tumor microenvironment immunomodulation mediated by ABTL0812 in combination with anti-PD1 and FOLFIRINOX in a mouse model of pancreatic cancer using MT5 cells transplanted into C57BL6 mice. Objective: To investigate the antitumor activity and in vivo tumor immunomodulatory effects of ABTL0812 administered in combination with an anti-PD1 inhibitor and FOLFIRINOX. Previous studies have shown the ability of ABTL0812 to enhance the anticancer efficacy of FOLFIRINOX, the standard treatment for human patients with advanced pancreatic cancer, in a xenograft model of human pancreatic cancer using MiaPaca2 cells transplanted into nude mice (Example 3.1). Based on the results of ABTL0812-mediated tumor microenvironment modification in vivo (Example 8.4), it was decided to test three combinations to evaluate its efficiency in tumor volume reduction. Pembrolizumab is an anti-PD1 checkpoint inhibitor for use in humans, and in this example, a corresponding modified version optimized for use in the mouse model used in this example was used.

[0438] Method: As in Example 8.4, 2 x 10¹⁶ C57BL6 mice were implanted in one flank to induce tumor formation. 6 MT5 cells were injected. The tumor volume was approximately 50 mm². 3 At this point, animals were uniformly randomized to treatment groups (n=9) and initiated with different therapies. The treatment groups consisted of three combinations: vehicle, anti-PD1, ABTL0812 + FOLFIRINOX, and ABTL0812 + anti-PD1 + FOLFIRINOX. ABTL0812 was administered orally at 480 mg / kg / day. The anti-PD1 antibody was administered intraperitoneally at 200 μg / dose every three days. The FOLFIRINOX chemotherapy combination was administered intraperitoneally once a week for a total of four doses. 30 mg / kg of 5-FU, 50 mg / kg of leucovorin, 50 mg / kg of irinotecan, and 2.5 mg / kg of oxaliplatin were administered intraperitoneally over two different days. 5-FU and leucovorin were administered on Tuesdays, and irinotecan and oxaliplatin on Thursdays. Tumor volume and body weight were monitored three times a week. At the end of treatment, mice were euthanized, tumors were collected, and single-cell suspensions were obtained by digesting the tumors using digestion media containing collagenase and lipase, and further treating them with trypsin and DNAse. After obtaining the cell suspensions, cancer cells and immune cells that had infiltrated the tumors were stained with specific antibodies against different immune cell subsets and further analyzed using flow cytometry. The combinations used were myeloid cells = CD45+ CD11b+ Ly6C+ and CD8 cells = CD45+ CD3- CD8+.

[0439] Results: The three combination therapies of ABTL0812, anti-PD1, and FOLFIRINOX showed the best antitumor efficacy with the most significant reduction in tumor volume compared to the other therapies. None of the therapies showed changes in mouse body weight or clinical signs of toxicity, distress, or pain in the animals. Analysis of tumor immune infiltration revealed that the anticancer efficacy against MT5 tumors was associated with a significant increase in myeloid cells and CD8 cells within the tumor, demonstrating anticancer activity and promoting a pro-inflammatory phenotype. None of the other therapies showed a significant increase in CD8 anticancer cells (****p<0.001). See Figure 28 in this specification.

[0440] Conclusion: ABTL0812 combined with anti-PD1 and FOLFIRINOX enhances anticancer efficacy in a mouse pancreatic cancer model using MT5 cells by modulating the tumor microenvironment to a more pro-inflammatory and antitumor environment. ABTL0812 increases myeloid cells within the tumor, associated with an increase in CD8 anti-cancer immune cells, which can be converted into a more pro-inflammatory and anti-cancer environment. Pancreatic cancer is considered a highly immunosuppressive and low-immunogenic tumor, and immunotherapy alone does not show very promising effects. These data suggest that the three-combination of ABTL0812 + anti-PD1 and FOLFIRINOX may offer a more effective alternative for treating this type of cancer.

[0441] References 1:EP2409963B1 (Lipopharma - filed in 2010) 2:Erazo,et al.;Clinical Cancer Research;22(10)May 15,2016 3:WO2018 / 210830A1(Ability Pharmaceuticals)

Claims

1. Aa pharmaceutical combination comprising: (A): Formula COOR 1 - CHR 2 - (CH 2 )a-(CH=CHCH 2 ) b-(CH 2 ) c-CH 3 Compounds that are polyunsaturated fatty acids, pharmaceutically acceptable salts thereof, or combinations thereof (i) a can have any integer value from 0 to 7, (ii) b can have any integer value from 2 to 7, (iii) c can have any integer value from 0 to 7, (iv) R 1 is H, Na, K, CH 3 , CH 3 -CH 2 , or PO(O-CH 2 -CH 3 ) 2 and (v) R 2 However, OH, OCH 3 O-CH 2 COOH, CH 3 Cl, CH 2 OH, OPO (O-CH 2 -CH 3 ) 2 , N(OH) 2 , F, HCOO, or N(OCH) 2 CH 3 ) 2 That is, a compound, its pharmaceutically acceptable salt, or a combination thereof, and (B3): an immunotherapeutic agent compound, for simultaneous, separate, or sequential use in the treatment of cancer in a human patient, wherein the treatment is an immunotherapy treatment for cancer, an immunotherapeutic agent compound, wherein (B3) is an immunotherapeutic agent compound that is a checkpoint inhibitor.

2. The pharmaceutical combination according to claim 1, wherein the compound (A) is at least one compound selected from the group consisting of or a pharmaceutically acceptable salt thereof. COOH-CHOH-(CH 2 ) 6 -(CH=CH-CH 2 ) 2 -(CH 2 ) 3 -CH 3 (ABTL0812)、 COOH-CHOH-(CH 2 ) 6 -(CH=CH-CH 2 ) 3 -CH 3 (183A1)、 COOH-CHOH-(CH 2 ) 3 -(CH=CH-CH 2 ) 3 -(CH 2 ) 3 -CH 3 (183A2)、 COOH-CHOH-(CH 2 ) 2 -(CH=CH-CH 2 ) 4 -(CH 2 ) 3 -CH 3 (204A1)、 COOH-CHOH-(CH 2 ) 2 -(CH=CH-CH 2 ) 5 -CH 3 (205A1), and COOH-CHOH-CH 2 -(CH=CH-CH 2 ) 6 -CH 3 (226A1)

3. Compound (A) is COOH-CHOH-(CH 2 ) 6 -(CH=CH-CH 2 ) 2 - (CH 2 ) 3 -CH 3 The pharmaceutically acceptable combination according to claim 1 or 2, wherein the combination is (ABTL0812) or a pharmaceutically acceptable salt thereof.

4. Compound (A) is COOH-CHOH-(CH 2 ) 6 -(CH=CH-CH 2 ) 2 - (CH 2 ) 3 -CH 3 The pharmaceutical combination according to claim 3, wherein the sodium salt is (ABTL0812).

5. The pharmaceutical combination according to any one of the preceding claims, wherein the cancer is at least one cancer selected from the group consisting of: lung cancer, non-small cell lung cancer, squamous cell carcinoma, adenocarcinoma, endometrial cancer, serous endometrial cancer, endometrioid cancer, pancreatic cancer, glioblastoma, drug-resistant recurrent breast cancer, head and neck cancer, multiple myeloma cancer, neuroblastoma, and cholangiocarcinoma

6. The compound (B3) is a checkpoint inhibitor antibody, particularly at least one immunotherapeutic agent compound selected from the group consisting of checkpoint inhibitor antibodies, wherein the checkpoint inhibitor antibody is an anti-PD1 antibody, an anti-PDL1 antibody, or an anti-CTLA4 antibody, according to any one of the preceding claims.

7. The compound (B3) is - an anti-PD1 antibody, particularly the anti-PD1 antibody is nivolumab, pembrolizumab, or spartalizumab, an anti-PD1 antibody, - an anti-PDL1 antibody, particularly the anti-PDL1 antibody is atezolizumab, avelumab, or durvalumab, an anti-PDL1 antibody, - an anti-CTLA4 antibody, particularly the anti-CTLA4 antibody is ipilimumab, at least one immunotherapeutic agent compound selected from the group consisting of anti-CTLA4 antibodies, according to claim 6.

8. The pharmaceutical combination according to claim 7, wherein the compound (B3) is an anti-PD1 antibody and the anti-PD1 antibody is pembrolizumab.

9. Compound (A) is COOH-CHOH-(CH 2 ) 6 -(CH=CH-CH 2 ) 2 - (CH 2 ) 3 -CH 3 The pharmaceutically acceptable combination according to any one of claims 6 to 8, wherein the combination is (ABTL0812) or a pharmaceutically acceptable salt thereof.

10. The pharmaceutical combination according to claim 9, wherein compound (B3) is an anti-PD1 checkpoint inhibitor antibody, particularly pembrolizumab, and the cancer is lung cancer.

11. The pharmaceutical combination according to any one of the prior claims, wherein the pharmaceutical combination is a single composition comprising both compound (A) and compound (B3).

12. The pharmaceutical combination according to any one of the prior claims, wherein compound (A) is administered orally, and the amount of compound (A) administered is a daily dose of 200 mg to 7000 mg, more specifically a daily dose of 1500 mg to 5000 mg, even more specifically a daily dose of 3000 mg to 4700 mg, and even more specifically a daily dose of 3500 mg to 4300 mg.

13. Compound (A) is COOH-CHOH-(CH 2 ) 6 -(CH=CH-CH 2 ) 2 - (CH 2 ) 3 -CH 3 The pharmaceutically acceptable combination according to claim 12, wherein the combination is (ABTL0812) or a pharmaceutically acceptable salt thereof.

14. The pharmaceutical combination according to claim 13, wherein ABTL0812 is administered before the administration of the immunotherapy compound (B3).

15. The pharmaceutically acceptable combination according to claim 13 or 14, wherein compound (B3) is an anti-PD1 checkpoint inhibitor antibody, particularly pembrolizumab, which is administered intravenously via an infusion solution.

16. The pharmaceutical combination according to any one of the prior claims, wherein the pharmaceutical combination further comprises at least one compound (B1), and compound (B1) is a chemotherapeutic agent compound.

17. The pharmaceutical combination according to claim 16, wherein compound (B1) is selected from the group consisting of the following. Temozolomide, Topotecan, Irinotecan, Cyclophosphamide, Fluorouracil, Cisplatin, Carboplatin, Oxaliplatin, Leucovorin, Doxorubicin, Bleomycin, Capecitabine, Mitomycin B, Paclitaxel, Nab-paclitaxel, Docetaxel, Gemcitabine, Methotrexate, Pemetrexed, Cytarabine, Mercaptopurine, Gluphosphamide, Ixabepylon, Nimstine, Carmustine, Romustine, Mitoxantrone, Etoposide, Vincristine, Vinblastine, and Tamoxifen

18. The pharmaceutical combination according to claim 16, wherein compound (B1) is selected from the group consisting of the following. Temozolomide, Topotecan, Irinotecan, Cyclophosphamide, Fluorouracil, Oxaliplatin, Leucovorin, Doxorubicin, Carboplatin, and Paclitaxel

19. The pharmaceutically acceptable combination according to claim 18, wherein compound (B1) is paclitaxel and carboplatin.

20. The pharmaceutically acceptable combination according to claim 18, wherein compound (B1) is irinotecan, leucovorin, oxaliplatin, and fluorouracil.

21. The pharmaceutical combination according to any one of claims 16 to 20, wherein compound (B3) is an anti-PD1 checkpoint inhibitor antibody.

22. The pharmaceutical combination according to claim 21, wherein compound (A) is ABTL0812, compound (B1) is paclitaxel and carboplatin, and compound (B3) is an anti-PD1 checkpoint inhibitor antibody.

23. The pharmaceutical combination according to claim 21, wherein compound (A) is ABTL0812, compound (B1) is irinotecan, leucovorin, oxaliplatin, and fluorouracil, and compound (B3) is an anti-PD1 checkpoint inhibitor antibody.