Acetanilide: From Pain Relief to Industrial Chemistry

What is Acetanilide?

Acetanilide, or N-phenylacetamide, is an aromatic compound consisting of a phenyl ring attached to an acetamido group (-NHCOCH3).

Properties of Acetanilide

Chemical Properties

• Formation and Decomposition: Reacting aniline with acetic anhydride or acetyl chloride forms it. The formation reaction is reversible, and the presence of water limits the extent of the reaction, as it can partially decompose it.
• Reactivity: It is relatively stable but can undergo certain reactions. When treated with nitrous acid, it forms nitroso-acetanilide, an unstable compound that decomposes upon heating. Reducing agents can regenerate acetanilide from nitroso-acetanilide.
• Derivatives: Various its derivatives have been synthesized, including those with alkyl or alkoxy substituents on the aromatic ring. Some derivatives exhibit biological activities, such as antitumor and antidiabetic properties.

Physical Properties

• Appearance and Solubility: This compound is a white crystalline solid without a distinct odor. It is moderately soluble in water (1 g/100 mL at 20°C) and easily dissolves in alcohol, ether, and benzene.
• Volatility: It is somewhat volatile at low temperatures, volatilizing around 95°C. Care must be taken during drying and weighing to prevent material loss.
• Polymorphism: The compound exists in different crystalline forms, called polymorphs. Some derivatives have α and β forms with distinct physical properties and stabilities.

Production of Acetanilide

Conventional Synthesis Methods

• Acetylation of aniline with acetic anhydride in the presence of a base like sodium acetate or pyridine, followed by purification. This method is widely used but generates waste and requires harsh conditions.
• Reaction of aniline with acetyl chloride in the presence of a base like sodium hydroxide or potassium carbonate. This method is efficient but involves corrosive reagents.

Improved and Green Synthesis Methods

• Acetylation of aniline with acetic acid under solvent-free conditions, using catalysts like zinc oxide, calcium oxide, or ionic liquids. These methods are environmentally friendly, with high atom economy and selectivity.
• Microwave-assisted synthesis of it from aniline and acetic acid, using catalysts like zeolites or metal oxides. This method is rapid, energy-efficient, and minimizes waste.
• Enzymatic synthesis of it using lipases or proteases as biocatalysts. This method is eco-friendly and highly selective, but has lower yields.

Production Processes and Techniques

• Continuous flow synthesis of it using microreactors or flow reactors. This method offers better control, scalability, and safety compared to batch processes.
• Optimization of reaction conditions like temperature, time, and catalyst loading to improve yield and selectivity.
• Purification techniques like recrystallization, distillation, or column chromatography to obtain high-purity one.
• Process safety considerations, such as handling of corrosive reagents, proper waste disposal, and minimizing environmental impact.

Applications of Acetanilide

Pharmaceutical Applications

• Anticancer agents: The compound has shown excellent inhibitory effects against human leukemia and cervical cancer cells, making it a potential antitumor reagent or medicinal compound for cancer treatment.
• Diabetes treatment: The α-form and β-form crystals of (R)-2-(2-aminothiazol-4-yl)-4′-[2-[(2-hydroxy-2-phenylethyl)amino]ethyl]acetanilide are useful ingredients for producing diabetes remedies.
• 5-lipoxygenase inhibitors: Certain its derivatives have been investigated as potential 5-lipoxygenase inhibitors for therapeutic applications.

Agrochemical Applications

Herbicidal Formulations: Develop aqueous concentrates with encapsulated acetanilide herbicides like acetochlor and oxidase inhibitors like fomesafen for effective weed control.

Organic Synthesis

• Synthesis of Aroma Chemicals: This compound acts as a precursor or intermediate for synthesizing various aroma chemicals used in perfumes and flavors.
• Green Synthesis Methods: Researchers have worked on efficient and eco-friendly synthesis methods, focusing on safe and convenient laboratory preparations.

Material Science Applications

Corrosion Inhibition: A mixture of acetanilide and para-hydroxy acetanilide effectively inhibits corrosion in alloyed zinc electrodes in chloride solutions, offering potential applications in corrosion prevention.

Application Cases

Product/Project	Technical Outcomes	Application Scenarios
Acetanilide-based Anticancer Compound	Exhibited excellent inhibitory effects against human leukaemia and cervical cancer cells, making it a potential antitumor reagent or medicinal compound for cancer treatment.	Pharmaceutical industry for developing new anticancer drugs and therapies.
Acetanilide-based 5-Lipoxygenase Inhibitors	Certain acetanilide derivatives have been investigated as potential 5-lipoxygenase inhibitors, which could have therapeutic applications in treating inflammatory diseases.	Pharmaceutical industry for developing new anti-inflammatory drugs.
Encapsulated Acetanilide Herbicides	Aqueous herbicidal concentrate compositions containing encapsulated acetanilide herbicides like acetochlor, along with protoporphyrinogen oxidase inhibitors (e.g., fomesafen), have been developed for effective weed control.	Agricultural industry for developing new herbicidal formulations for weed management.
Acetanilide-based Insecticides	Acetanilide derivatives have been explored as potential insecticides, offering a new class of compounds for pest control in agriculture.	Agricultural industry for developing new insecticidal formulations for pest management.

Latest innovations of Acetanilide

Pharmaceutical Compositions

Recent research has focused on developing its derivatives, such as 3-chloro-4-hydroxy-acetanilide, with enhanced potency and reduced hepatotoxicity compared to paracetamol (acetaminophen). These derivatives exhibit improved analgesic, antipyretic, and anti-inflammatory properties, making them potential investigational new drugs.

Synthetic Methodologies

Researchers explore new synthetic routes and reaction conditions to prepare its derivatives, achieving significant advances. Furthermore, these investigations aim to boost reaction yields, selectivity, and overall efficiency. However, specific methodologies remain limited in the provided search results.

Structural Modifications

Researchers have explored structural modifications of the acetanilide scaffold to modulate its physicochemical properties and biological activities. These modifications may involve substitutions on the aromatic ring, alterations to the amide functionality, or the introduction of additional functional groups. The search results do not provide specific examples of these modifications.

Technical Challenges

Enhancing Potency and Reducing Hepatotoxicity	Developing acetanilide derivatives with improved analgesic, antipyretic, and anti-inflammatory properties while minimising hepatotoxicity compared to paracetamol.
Efficient Synthetic Methodologies	Exploring new synthetic routes and reaction conditions for the preparation of acetanilide and its derivatives to improve reaction yields, selectivity, and overall efficiency.
Structural Modifications of Acetanilide Scaffold	Modulating the physicochemical properties and biological activities of acetanilide through structural modifications, such as substitutions on the aromatic ring, alterations to the amide functionality, or the introduction of additional functional groups.
Targeted Delivery of Acetanilide Derivatives	Developing targeted delivery systems or formulations to enhance the bioavailability and site-specific delivery of acetanilide derivatives, potentially improving their therapeutic efficacy and reducing off-target effects.
Elucidating Mechanisms of Action	Investigating the molecular mechanisms of action of acetanilide and its derivatives, including their interactions with target proteins, signalling pathways, and cellular processes, to facilitate the rational design of more potent and selective compounds.

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