A set of kinesio taping for treating patellar tendon endopathy

By designing a rehabilitation patch with specific layering and tension settings, the pain and swelling problems of patellar tendon end disease were solved, achieving significant pain relief and functional recovery, and improving the stability and biomechanical performance of the patellar tendon area.

CN122163397APending Publication Date: 2026-06-09PEKING UNIVERSITY THIRD HOSPITAL (THE THIRD CLINICAL MEDICAL SCHOOL OF PEKING UNIVERSITY)

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
PEKING UNIVERSITY THIRD HOSPITAL (THE THIRD CLINICAL MEDICAL SCHOOL OF PEKING UNIVERSITY)
Filing Date
2026-03-27
Publication Date
2026-06-09

AI Technical Summary

Technical Problem

Current technologies lack effective rehabilitation measures to alleviate pain and swelling, and improve the stability and functional recovery of the patellar tendon region when treating patellar tendonopathy.

Method used

A rehabilitation patch combination was designed, consisting of a first kinesiology patch group, a second kinesiology patch group, and a third kinesiology patch. Through specific layering and tension settings, it enhances sensory input in the subcutaneous space, promotes lymphatic and blood circulation, relieves pressure and drainage, and provides mechanical support and corrective effects.

Benefits of technology

It significantly relieved pain and swelling in patients with patellar tendinopathy, improved functional recovery, and enhanced running biomechanics and muscle strength, with even more significant effects after 8 weeks of intervention.

✦ Generated by Eureka AI based on patent content.

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Abstract

The present application relates to the technical field of sports protection, in particular to a set of intramuscular effect patches for treating patellar tendon end disease. The rehabilitation combination patch of the present application is composed of a first muscle patch group, a second muscle patch group and a third muscle patch group. The first muscle patch group is composed of at least two layers of intramuscular effect patch cloths which are cross-stacked. Each layer of intramuscular effect patch cloth is composed of a solid base at both ends and a plurality of dispersed branches at the middle part. Each branch extends continuously from one solid base to another solid base, and all branches are in the shape of radiating from the two end solid bases to the middle. The present application is proved by experiments that the use of the combination patch of the present application has a positive effect on the treatment of PT patients. Especially after 8 weeks of intervention, the improvement is more obvious, indicating that the combination patch of the present application has a more positive effect in long-term rehabilitation.
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Description

Technical Field

[0001] This invention relates to the field of sports protection technology, and in particular to a group of kinesiology patches for treating patellar tendinopathy. Background Technology

[0002] In the field of sports protective technology, kinesiology tape is sometimes used. Kinesiology tape is mainly composed of drug-free waterproof elastic fabric, medical acrylic adhesive, and backing paper. Compared to traditional tapes (white tape), the biggest characteristic of kinesiology tape is its elasticity under tension; when the tension is removed, the tape retracts, exhibiting elasticity. Within a certain range, the greater the tension applied to the tape, the greater the stability and support it provides to the corresponding body position. Compared to tension, the elasticity of the tape is a crucial factor in its clinical therapeutic effect. Kinesiology tape primarily utilizes the interaction between the elastic recoil of the material and the skin surface to exert its therapeutic effect.

[0003] The patellar tendon, one of the main tendons in the human body, is formed by the quadriceps tendon, which extends through the patella and eventually attaches to the tibial tuberosity. Summary of the Invention

[0004] In order to improve the rehabilitation effect of patellar tendinopathy, the inventors of this invention conducted extensive and long-term clinical research and finally invented a set of effective rehabilitation combination patches.

[0005] The rehabilitation patch of the present invention comprises a first kinesiology patch group, a second kinesiology patch group, and a third kinesiology patch group, wherein,

[0006] The first kinesiology tape group consists of at least two layers of kinesiology tape that are cross-stacked. Each layer of kinesiology tape consists of a solid base at both ends and several dispersed branches in the middle. Each branch extends continuously from one solid base to the other solid base, and all branches radiate outward from the solid bases at both ends toward the middle.

[0007] The second kinesiology tape set contains at least two layers of cross-overlapping kinesiology tape. A ring-shaped kinesiology tape is placed outside the outermost kinesiology tape. Each layer of cross-overlapping kinesiology tape has a hole at its center. The tape on the two opposite edges of the hole extends outward from the hole to form several branches, which are dispersed from each other. The ring-shaped kinesiology tape covers the ends of each branch.

[0008] The third kinesiology tape consists of a rectangular kinesiology tape, which is divided into a fixation base at both ends and a central action part in the middle.

[0009] Using the patient's patellar tendon pain area as a reference, the first kinesiology tape group, the second kinesiology tape group, and the third kinesiology tape group are arranged from the inside out. The first and second kinesiology tape groups correspond to the patient's patellar tendon pain area, while the middle part of the third kinesiology tape corresponds laterally to the patient's patellar tendon pain area and covers 1 / 3 to 1 / 2 of the lower pole of the patella.

[0010] In this technical solution, the first and second kinesiology tape groups can enhance sensory input from the skin to the superficial fascia layer, improve the subcutaneous space, relieve pressure and drain the painful and swollen area, and promote lymphatic and blood circulation, thereby improving pain and swelling; the third kinesiology tape plays a role in guiding the correction of muscles, tendons / ligaments, and in mechanical and functional correction.

[0011] In the second kinesiology patch group, the overlapping patches mainly diffuse and drain from the pores to the branches, with the pores and branches working together.

[0012] Cross-overlay: This refers to layering the patches sequentially from the inside out. The "inside" refers to the side closer to the patient's patellar tendon, and the "outside" refers to the side farther away from the patient's patellar tendon. The layers cross each other from the perspective of the patient's patellar tendon. The crossing can be at any angle, such as 90 degrees, 80 degrees, etc., depending on the actual needs, with the goal of covering the painful area.

[0013] Covering 1 / 3 to 1 / 2 of the lower pole of the patella means: the upper edge of the middle part of the third kinesiology tape is located at 1 / 3 to 1 / 2 of the height of the patella, from bottom to top.

[0014] As a preferred technical solution, the branches of the first kinesiology tape group cover the painful area of ​​the patellar tendon, and the center of the first kinesiology tape group corresponds to the center of the painful area of ​​the patient's patellar tendon. This solution can more comprehensively and evenly cover the painful area for better decompression, drainage, and improvement of pain and swelling.

[0015] As a preferred technical solution, the branches of the second kinesiology tape cover the painful area of ​​the patellar tendon, and the holes of the second kinesiology tape correspond to the center of the painful area of ​​the patient's patellar tendon. This solution can more comprehensively and evenly cover the painful area for better decompression, drainage, and improvement of pain and swelling.

[0016] As a preferred technical solution, the central active part of the third kinesiology tape laterally covers the entire patellar tendon pain area.

[0017] As a preferred technical solution, the first and second kinesiology tape groups are applied under natural tension or without tension, while the central working portion of the third kinesiology tape is applied under 50%-75% tension. The first and second kinesiology tape groups, being applied under natural tension or without tension, can better enhance sensory input, provide extensive pressure relief and drainage around the painful and swollen area, improve subcutaneous space, and promote lymphatic and blood circulation, thereby improving swelling and pain. The central working portion of the third kinesiology tape, with 50%-75% tension, can better distribute local pressure on the patellar tendon and provide mechanical support.

[0018] Natural tensile force refers to the tensile force of the patch being applied at only 5%-10% of its maximum tensile force.

[0019] Tension-free means that the patch is not subjected to any external tension.

[0020] Applying 50%-75% tension means that the patch is subjected to 50%-75% of its maximum tension.

[0021] Maximum tensile force refers to the tensile force at which the patch cannot generate elastic recoil force to achieve a therapeutic effect.

[0022] When the middle working part of the third kinesiology tape is subjected to a tension of 50%-75%, the length (L2) of the middle working part of the tape is: (L2) = (L1-L0) × (50%-75%) + L0.

[0023] The length of the middle working part of the patch under natural tension is (L2) = (L1-L0) × (5%-10%) + L0.

[0024] When there is no tension, the length of the middle working part of the patch is (L0).

[0025] Where L0 is the original length of the intermediate working part in its natural state (L0), and L1 is the length of the intermediate working part of the patch stretched to its maximum stretch length, i.e., 100% stretchable length (L1).

[0026] As a specific embodiment, the circular kinesiology tape in the second kinesiology tape set can be formed by wrapping a rectangular tape around it.

[0027] As a specific embodiment, viewed from a perspective opposite to the patient's patellar tendon, the circular kinesiology tape in the second kinesiology tape group can be formed by wrapping a rectangular tape clockwise around the patient.

[0028] As a preferred technical solution, the first kinesiology tape assembly consists of two layers of kinesiology tape overlapping each other. More preferably, each layer of tape contains 6 branches. More specifically, the width of each branch can be 0.8-0.9 cm.

[0029] As a preferred technical solution, the third set of kinesiology tape has a tape width of 5cm and a length of 15cm.

[0030] As a preferred technical solution, the second kinesiology tape assembly comprises two layers of cross-overlaid kinesiology tape. More preferably, each layer of the cross-overlaid kinesiology tape contains 4 pairs of branches, i.e., 8 branches. More preferably, each branch has a width of 0.6-0.7 cm. More preferably, the distance between the edge of the hole and the starting end of the branch is 1-2 cm. More preferably, the hole is circular or rhomboid. Even more preferably, the hole is a circle with a diameter of 1 cm or a rhomboid with a diagonal length of 1 cm.

[0031] The application of the aforementioned rehabilitation patch in the preparation of products for the rehabilitation of patellar tendinopathy also falls within the scope of protection of this invention. Patellar tendinopathy is a common overuse disease of the patellar tendon, specifically referring to load-related pain in the area of ​​the inferior pole of the patella and its distal attachment point.

[0032] The most prominent symptoms of patellar tendinopathy are swelling and pain in the patellar tendon area.

[0033] This invention demonstrates through experiments that the combination patch of this invention significantly improves pain relief, functional scores, peak knee flexion angle during the running stance phase, knee extension torque, knee joint power generation, absorbed power, and peak torque of the extensor muscles at 60° / s, thus positively impacting the treatment effect for PT patients. The improvement is particularly pronounced after 8 weeks of intervention, indicating that the combination patch of this invention has a more positive effect on long-term rehabilitation. Attached Figure Description

[0034] Figure 1 This is a schematic diagram of the structure of the first kinesiology tape assembly.

[0035] Figure 2 This is a schematic diagram of the structure of the second kinesiology patch.

[0036] Figure 3 This is a schematic diagram of the third type of kinesiology tape. Detailed Implementation

[0037] The following are some specific embodiments of the present invention. Unless otherwise specified, the technical means or reagents used are conventional methods and reagents known in the art.

[0038] 1 First solid base; 2 Branch in the first kinesiology tape group; 3 Second solid base; 4 Branch in the second kinesiology tape group; 5 Hole; 6 Circular kinesiology tape; 7 Intermediate working part; 8 First fixation base; 9 Second fixation base.

[0039] Example

[0040] The rehabilitation patch combination used in this embodiment consists of a first patch group, a second patch group, and a third patch group, wherein...

[0041] The first kinesiology tape set consists of two layers of kinesiology tape stacked on top of each other. Each layer of kinesiology tape consists of two solid bases 1 and 3 at the two ends and six dispersed branches 2 in the middle. Each branch extends continuously from one solid base 1 to the other solid base 3, and all branches radiate outward from the two solid bases at both ends towards the middle. Each layer of tape contains six branches, and the width of each branch can be 0.8-0.9 cm.

[0042] The second kinesiology tape set contains two layers of cross-overlapping kinesiology tape. A third layer of circular kinesiology tape 6 is placed outside the outermost layer. Each layer of cross-overlapping kinesiology tape has a hole 5 at its center. The tape on each of the two opposite edges of the hole extends outwards from the hole, forming four branches 4 (four pairs of eight branches in total), which are dispersed among each other. The circular kinesiology tape 6 covers the ends of each branch. Each branch is 0.6-0.7 cm wide. The distance between the edge of the hole and the beginning of the branch is 1-2 cm. The hole is circular with a diameter of 1 cm.

[0043] The third kinesiology tape consists of a rectangular kinesiology tape, which is divided into a fixation base 8 and 9 at the two ends and a central action part 7 in the middle; the tape of the third group is 5cm wide and 15cm long.

[0044] Using the patient's patellar tendon as a reference point, the layers from the inside out are the first kinesiology tape group, the second kinesiology tape group, and the third kinesiology tape group. The first and second kinesiology tape groups correspond to the painful area of ​​the patient's patellar tendon. The central part of the third kinesiology tape group corresponds laterally to the painful area of ​​the patient's patellar tendon and covers 1 / 3 to 1 / 2 of the lower pole of the patella. Viewed from the perspective opposite the patient's patellar tendon, the circular kinesiology tape in the second kinesiology tape group is formed by wrapping a rectangular tape clockwise around the patient.

[0045] The first kinesiology tape group has branches covering the patellar tendon pain area, with the center of the first kinesiology tape group corresponding to the center of the patient's patellar tendon pain area. The second kinesiology tape group has branches covering the patellar tendon pain area, with the holes of the second kinesiology tape group corresponding to the center of the patient's patellar tendon pain area. The central active part of the third kinesiology tape laterally covers the entire patellar tendon pain area.

[0046] The first and second kinesiology tapes are applied under natural tension or without tension, while the middle working part of the third kinesiology tape is applied under 50%-75% tension.

[0047] Natural tensile force refers to the tensile force of the patch being applied at only 5%-10% of its maximum tensile force.

[0048] Tension-free means that the patch is not subjected to any external tension.

[0049] Applying 50%-75% tension means that the patch is subjected to 50%-75% of its maximum tension.

[0050] Maximum tensile force refers to the tensile force at which the patch cannot generate elastic recoil force to achieve a therapeutic effect.

[0051] A total of 21 patients with patellar tendinopathy (PT) underwent rehabilitation using the above-mentioned kinesiology tape combination.

[0052] Inclusion criteria for 21 patients

[0053] (1) People aged 18-40 who have a habit of exercising should exercise for 150-300 minutes per week;

[0054] (2) Doppler ultrasound examination revealed structural tendon changes and / or increased tendon vessels;

[0055] (3) Swelling was present in the area of ​​the lower pole of the patella and the tibial tuberosity, and the patient showed positive tenderness upon palpation;

[0056] (4) Positive knee extension resistance and / or patellar tendon pain during single-leg squat test;

[0057] (5) No allergic reaction to kinesiology patches.

[0058] Exclusion criteria

[0059] (1) History of knee joint injury;

[0060] (2) Has a history of knee surgery;

[0061] (3) Taking painkillers in the past two weeks;

[0062] (4) Other knee joint diseases exist, such as knee joint tumors, rheumatoid arthritis, tuberculosis, etc.;

[0063] (5) Those who have an allergic reaction to kinesiology patches.

[0064] All procedures in this study were performed by the same trained person. The treatment area was first wiped with an alcohol swab to clean the skin surface and allow it to completely evaporate before applying the tape. The specific steps were as follows: With the patient's knee bent at 60°, two layers of the first kinesiology tape were applied to the painful area of ​​the patellar tendon under natural tension, with the center of the painful area aligned with the center of the tape. Then, two layers of the second kinesiology tape were applied under natural tension, followed by the circular tape of the second kinesiology tape, with the holes of the second tape aligned with the center of the painful area. Next, the middle working part of the third kinesiology tape was stretched to 50%-75% tension and applied laterally to the painful area of ​​the patellar tendon, covering 1 / 3 to 1 / 2 of the lower pole of the patella. The ends were then secured without tension, starting from the middle and working outwards.

[0065] To ensure that the tension of the patch is consistent for each subject during application, the original length (L0) of the patch is measured with a tape measure before application, and then the patch is stretched to its maximum stretch length, i.e., 100% stretchable length (L1).

[0066] When the middle working part of the third kinesiology tape is subjected to a tension of 50%-75%, the length (L2) of the middle working part of the tape is: (L2) = (L1-L0) × (50%-75%) + L0.

[0067] The length of the middle working part of the patch under natural tension is (L2) = (L1-L0) × (5%-10%) + L0.

[0068] When there is no tension, the length of the middle working part of the patch is (L0).

[0069] Where L0 is the original length of the intermediate working part in its natural state (L0), and L1 is the length of the intermediate working part of the patch stretched to its maximum stretch length, i.e., 100% stretchable length (L1).

[0070] Three-dimensional gait testing and isokinetic muscle strength testing were performed on subjects before intervention and at 4 and 8 weeks after intervention. VAS and VISA-P questionnaire scores were also collected before and after intervention. The testing procedure is as follows:

[0071] 3D gait testing equipment

[0072] Thirty-five reflective markers and two electromyographic electrodes were attached to the bony areas of the subjects. A 12-camera infrared high-speed motion capture system (Vicon, Vero 2.2) was used to acquire static and dynamic three-dimensional motion information of the subjects at a frequency of 1000 Hz. The model used was an optimized version of the internationally recognized plug-in-gait model. Two three-dimensional force tables (AMTI, BP400600) were used to acquire dynamic parameters at a frequency of 1000 Hz. Kinematic and dynamic data were synchronized via a synchronization box (AMTI, GEN5). During the test, the infrared high-speed motion capture system and the force tables simultaneously acquired kinematic and dynamic data of the subjects' lower limbs. All three-dimensional coordinates of the markers acquired in this study were smoothed using the Butterworth low-pass filter method with a cutoff frequency of 12 Hz. Ground reaction force was also smoothed using the Butterworth low-pass filter method with a cutoff frequency of 75 Hz. An infrared high-speed motion capture system and a force platform were used to simultaneously acquire kinematic and dynamic data of the subjects' lower limbs. Simultaneously, a Delsys wireless surface electromyography (EMG) device (made in the USA) was used to measure and acquire EMG signals of the lower limb muscles during the subjects' gait. EMG signals of the rectus femoris muscles in both lower limbs were acquired in this experiment.

[0073] Three-dimensional gait testing method

[0074] Jogging test: Subjects start from a pre-measured starting point and jog at a speed of (2.6±0.2 m / s). The test is designed to be pain-free and comfortable for the patient. The interval between two tests is set so that the patient does not feel fatigued, and five valid data points are collected for each test. Electromyographic signals of important muscles in the lower limbs are collected simultaneously during the jogging test.

[0075] Jogging test indicators

[0076] Maximum knee flexion and eversion angles during the support phase of jogging.

[0077] Maximum knee extension and eversion torque during the support phase of jogging.

[0078] The maximum power generated and absorbed by the knee joint during the support phase of jogging.

[0079] Electromyography (EMG) signal test indicators

[0080] The parameters collected and analyzed using the Delsys surface electromyography (EMG) system include: maximum isometric contraction (MVC) and root mean square (RMS). Specific muscles included are the gluteus medius, rectus femoris, vastus lateralis, and vastus medialis. The RMS values ​​of the vastus medialis, rectus femoris, vastus lateralis, and gluteus medius were assessed at the moment of maximum knee flexion during the running stance phase. These RMS values ​​were then divided by the standard MVC of their respective muscles; the resulting RMS ratio represents the degree of muscle activation during jogging.

[0081] Root mean square amplitude: This refers to the root mean square value of all amplitudes over a period of time, primarily used to reveal the magnitude variation of electromyographic signals. Amplitude is often used to describe the degree of muscle activation and the peak value of muscle activity.

[0082] Isokinetic muscle strength testing method

[0083] The test was conducted by the same test subject on an isokinetic apparatus (Con-Trex MJ, Germany). The subject was seated with the hip flexed at approximately 85 degrees. The distal end of the dynamic rod was fixed to the proximal end of the medial malleolus, and the trunk, pelvis, and mid-thigh were stabilized to prevent compensation from other parts of the body when the thigh exerted force. The axis of motion of the knee joint was determined with the lateral femoral condyle as the axis. The test angular velocity was 60° / s (90°-10°) concentrically for the quadriceps, repeated 5 times. A submaximal warm-up was performed 2-3 times before the test.

[0084] Isokinetic muscle strength test indicators

[0085] The parameters collected by the isokinetic muscle strength testing instrument include: peak torque of the quadriceps muscle at 60° / s concentric and 60° / s concentric and eccentric.

[0086] Peak torque: The maximum torque a muscle can generate during contraction, representing the maximum muscle force produced by muscle contraction. Peak torque is the gold standard for assessing muscle strength.

[0087] Scale assessment

[0088] The Visual Analogue Scale (VAS) was used to assess pain levels in two groups of patients; the Victoria Institute of Sports Medicine PT Assessment Questionnaire (VISA-P) was used to assess patients' functional status.

[0089] (1) VAS scale: The VAS scale is usually a horizontal or vertical line, 10 cm long, with “0” and “10” marked at the two ends. “0” represents “no pain”, while “10” represents “worst possible pain”, which is used to assess the degree of pain.

[0090] (2) VISA-P scale: The Victoria Institute for Exercise Assessment in Australia developed a scoring scale specifically for PT. It has good reliability and validity and is a reliable indicator for evaluating the severity of PT and the degree of pain. The VISA-P scale includes three aspects: symptoms, function and motor ability. There are a total of 8 questions with a full score of 100. Theoretically, the lowest score is 0. The higher the score, the less the pain affects the patient.

[0091] Experimental results:

[0092] Table 1 Comparison of pain scores of PT patients before and after intervention ( ±S)

[0093]

[0094] Table 2 Comparison of VISA-P scores of PT patients before and after intervention ( ±S)

[0095]

[0096] Table 3 Comparison of knee flexion angles in PT patients before and after intervention (°) during the support phase of running (PT) ±S)

[0097]

[0098] Table 4. Comparison of knee extension torque during the support phase of running in PT patients before and after intervention (BW) BH) ±S)

[0099]

[0100] Table 5. Comparison of knee joint power during the support phase of running in PT patients before and after intervention (w / kg) ±S)

[0101]

[0102] Table 6 Comparison of rectus femoris activation rate in the support phase of running in PT patients before and after intervention (%) ±S)

[0103]

[0104] Table 7. Comparison of peak torque of knee extensor muscles between the two groups before and after intervention (N·m / kg) ±S)

[0105]

[0106] This experiment involved intervention with the combination patch of this invention in PT patients and analyzed the treatment effect after 8 weeks of intervention. The study systematically evaluated the effects of the combination patch on pain intensity, functional status, running biomechanical characteristics, and lower limb isokinetic muscle strength in PT patients. The results showed that the combination patch of this invention exhibited a more significant improvement trend in multiple indicators and demonstrated a more positive rehabilitation effect after 8 weeks of intervention.

[0107] Regarding pain and functional improvement, after 4 weeks of intervention, the pain scores of PT patients were significantly lower than before the intervention, and the VISA-P scale functional scores improved. After 8 weeks of intervention, the pain reduction of PT patients was even greater, and the improvement of VISA-P functional scores was more significant.

[0108] Regarding running biomechanical characteristics, PT patients showed a significant increase in knee flexion angle during the running stance phase at both 4 and 8 weeks after intervention, without inducing pain. Peak knee extension torque was significantly improved in PT patients after 8 weeks of intervention compared to before intervention. Knee power analysis showed increased knee power generation during the running stance phase at 8 weeks after intervention, and increased knee power absorption during the running stance phase at both 4 and 8 weeks after intervention. In terms of muscle activation, the degree of rectus femoris activation was significantly enhanced in PT patients after 8 weeks of intervention compared to before intervention.

[0109] Regarding isokinetic muscle strength, at a concentric angular velocity of 60° / s, the peak knee extension torque in PT patients significantly increased 8 weeks after intervention compared to before intervention.

[0110] In summary, the combination patch of this invention significantly improved pain relief, functional scores, peak knee flexion angle during the running stance phase, knee extension torque, knee joint power generation, absorbed power, and peak torque of the extensor muscles at 60° / s, thus positively impacting the treatment effect for PT patients. The improvements were particularly pronounced after 8 weeks of intervention, indicating a more positive role in long-term rehabilitation.

Claims

1. A rehabilitation patch for patellar tendon end disease rehabilitation, characterized in that: It consists of a first kinesiology tape set, a second kinesiology tape set, and a third kinesiology tape set, among which, The first kinesiology tape group consists of at least two layers of kinesiology tape that are cross-stacked. Each layer of kinesiology tape consists of a solid base at both ends and several dispersed branches in the middle. Each branch extends continuously from one solid base to the other solid base, and all branches radiate outward from the solid bases at both ends toward the middle. The second kinesiology tape set contains at least two layers of cross-overlapping kinesiology tape. A ring-shaped kinesiology tape is placed outside the outermost kinesiology tape. Each layer of cross-overlapping kinesiology tape has a hole at its center. The tape on the two opposite edges of the hole extends outward from the hole to form several branches, which are dispersed from each other. The ring-shaped kinesiology tape covers the ends of each branch. The third kinesiology tape consists of a rectangular kinesiology tape, which is divided into a fixation base at both ends and a central action part in the middle. Using the patient's patellar tendon pain area as a reference, from the inside out, there are three kinesiology tape groups: the first, the second, and the third. The first and second kinesiology tape groups correspond to the patient's patellar tendon pain area, while the middle part of the third kinesiology tape corresponds laterally to the patient's patellar tendon pain area and covers 1 / 3 to 1 / 2 of the lower pole of the patella.

2. The rehabilitation patch according to claim 1, characterized in that: The first kinesiology tape group has branches covering the painful area of ​​the patellar tendon, and the center of the first kinesiology tape group corresponds to the center of the painful area of ​​the patient's patellar tendon. The second kinesiology tape group has branches covering the painful area of ​​the patellar tendon, and the holes of the second kinesiology tape group correspond to the center of the painful area of ​​the patient's patellar tendon. The central part of the third kinesiology tape group covers the entire painful area of ​​the patellar tendon laterally.

3. The rehabilitation patch according to claim 1 or 2, characterized in that: The first and second kinesiology tapes are applied under natural tension or without tension, while the middle working part of the third kinesiology tape is applied under 50%-75% tension.

4. The rehabilitation patch according to claim 1 or 2, characterized in that: Viewed from the perspective of the patient's patellar tendon area, the circular kinesiology tape in the second kinesiology tape group is wrapped in a clockwise direction.

5. The rehabilitation patch according to claim 1 or 2, characterized in that: The first kinesiology tape set contains two layers of kinesiology tape overlapped together, and the second kinesiology tape set contains two layers of kinesiology tape overlapped together.

6. The rehabilitation patch according to claim 1 or 2, characterized in that: Each layer of kinesiology tape in the first kinesiology tape group contains 6 branches, each branch being 0.8-0.9cm wide.

7. The rehabilitation patch according to claim 1 or 2, characterized in that: In the second kinesiology tape group, each layer of the cross-overlaid kinesiology tape contains 4 pairs of branches, each branch being 0.6-0.7cm wide.

8. The rehabilitation patch according to claim 1 or 2, characterized in that: In the second kinesiology patch set, the holes are round or diamond-shaped.

9. The use of the rehabilitation patch according to any one of claims 1-8 in the preparation of a product for rehabilitation of patellar tendonitis.

10. The rehabilitation patch according to any one of claims 1-8 or the application according to claim 9, characterized in that: The patellar tendonopathy is characterized by load-related pain in the area of ​​the lower pole and distal attachment point of the patella.