Fenbendazole: Chemical Properties and Classification

Fenbendazole, ​a widely used anthelmintic drug in veterinary medicine, belongs to the benzimidazole ‌class of compounds. ‌This article explores the chemical properties and classification of fenbendazole,providing an overview of its molecular ⁣structure,physical characteristics,and pharmacological categorization. Understanding​ these aspects is ‌essential for researchers,⁣ veterinarians, and pharmaceutical professionals working with this significant antiparasitic agent.

Table ‌of Contents

• Chemical Structure and Molecular Properties of Fenbendazole
• Pharmacological Classification and Mechanism of Action
• Physical Characteristics and ⁢Stability ‌of Fenbendazole
• Synthesis and Manufacturing Process of Fenbendazole
• Analytical Methods⁣ for Fenbendazole Detection⁣ and Quantification
• Regulatory Status and applications in Veterinary Medicine
• Q&A
• Key Takeaways

Chemical ‌Structure and Molecular⁤ Properties of Fenbendazole

Fenbendazole is a‌ benzimidazole compound with ⁢the molecular⁣ formula C₁₅H₁₃N₃O₂S.Its systematic name is methyl N-[6-(phenylsulfanyl)-1H-benzimidazol-2-yl]carbamate. The compound features a benzimidazole core structure with a phenylthio group attached at the 6-position ‍and a methylcarbamate‌ moiety linked to the 2-position.‍ This arrangement of atoms contributes to‌ its unique chemical properties and biological​ activity.

Key molecular properties of fenbendazole include:

• Molecular weight: ​ 299.35 g/mol
• LogP: 3.3 (indicating moderate lipophilicity)
• Hydrogen bond donors: 2
• Hydrogen bond​ acceptors: 4
• Rotatable bonds: 4

These properties contribute to fenbendazole’s ability⁢ to penetrate cell membranes and interact⁢ with its target proteins. The compound’s relatively low solubility in water ​(approximately 0.007 mg/mL at 25°C) influences‌ its pharmacokinetic behavior‍ and necessitates specific formulation strategies for ⁢effective⁣ drug delivery.

Pharmacological Classification and Mechanism of Action

Fenbendazole belongs‌ to the benzimidazole class of anthelmintic drugs, which ⁢are widely used for treating parasitic ⁢worm infections⁢ in both humans and animals.Its primary‌ mechanism of action‍ involves binding to β-tubulin in parasitic‌ cells, disrupting ⁤microtubule formation and ultimately leading to the death​ of ‍the parasite. This‍ selective toxicity allows fenbendazole to effectively target helminths while minimizing adverse effects on the host ‌organism.

along with‍ its anthelmintic properties, fenbendazole has shown⁣ potential ⁢as an‌ anticancer agent. Recent studies suggest that⁤ it may⁤ inhibit glucose uptake in cancer cells, interfere with microtubule ⁢formation, and induce apoptosis⁤ in tumor cells.⁣ These multifaceted pharmacological effects have sparked interest in repurposing fenbendazole for various therapeutic applications beyond its ‍traditional use as an antiparasitic⁣ medication.

• Primary classification: Benzimidazole⁢ anthelmintic
• Secondary classification: Potential anticancer agent
• Key mechanisms: ⁤ β-tubulin binding, microtubule disruption, glucose uptake inhibition

Physical Characteristics and Stability of Fenbendazole

Fenbendazole presents as a white to off-white ⁣crystalline solid at room temperature. Its⁤ molecular structure consists of‍ a benzimidazole ring fused with a carbamate group, contributing to its unique chemical properties. This compound exhibits low solubility ‍in water but dissolves readily ‍in organic solvents such as dimethyl sulfoxide⁤ (DMSO) and methanol. The ⁤melting point of fenbendazole typically ranges between 233°C and 240°C, indicating its ‌thermal stability under normal‌ conditions.

The stability⁤ of fenbendazole is a crucial factor ‍in its storage and request. This compound ‌demonstrates​ remarkable resilience to environmental factors, maintaining its efficacy for extended periods when ⁢stored properly.⁢ However,exposure to⁤ extreme temperatures,humidity,or​ direct sunlight​ may compromise its structural integrity.To ensure optimal stability,⁣ it is indeed recommended⁢ to store fenbendazole in the following conditions:

• Keep in a cool, dry⁤ place
• Protect from direct light exposure
• Store​ in airtight containers
• Avoid temperature fluctuations

Note: Adherence ​to proper storage guidelines is essential for maintaining the compound’s effectiveness and safety profile.

Synthesis and⁢ Manufacturing Process of Fenbendazole

The production of fenbendazole involves a multi-step chemical ⁣process that begins with⁢ the synthesis of its core structure.Chemists typically start with 2-aminobenzimidazole as the primary ⁢building block, which undergoes⁣ a series of reactions to form the benzimidazole carbamate skeleton. This intermediate compound is then⁢ further modified through alkylation and sulfuration steps to yield‌ the final fenbendazole molecule.

Industrial-scale manufacturing of ‍fenbendazole⁤ relies on carefully controlled conditions to ensure high‍ purity and yield. Key aspects ⁤of the process include:

• Temperature regulation during ⁢critical reaction‌ stages
• Precise pH control ‌to optimize⁤ product formation
• Solvent selection ‌for efficient extraction ⁤and⁤ purification
• Specialized filtration techniques to remove impurities

Analytical Methods for Fenbendazole Detection and ⁢Quantification

Several refined‍ techniques are ‍employed to detect and quantify ​fenbendazole in‌ various matrices. High-performance liquid chromatography (HPLC) coupled with ⁣UV detection is widely used due to its sensitivity and accuracy. This method allows for precise separation⁤ and identification of fenbendazole and its metabolites. Additionally, ⁣ liquid chromatography-mass ​spectrometry ⁣(LC-MS) offers enhanced selectivity and lower detection limits, making it⁢ ideal for trace analysis in⁣ complex⁣ biological samples.

Other analytical approaches include:

• Gas chromatography-mass spectrometry (GC-MS)
• Enzyme-linked immunosorbent assay (ELISA)
• Thin-layer chromatography (TLC)

Each method has ⁤its strengths ⁢and limitations, with selection⁤ depending on factors such as ‍sample type, ⁣required sensitivity, and available ⁤resources. Researchers continue ⁢to develop and refine these‌ techniques to improve detection limits and expand their applicability across various⁢ matrices, ⁣from pharmaceutical formulations to environmental samples.

Regulatory⁣ Status and Applications in Veterinary Medicine

fenbendazole’s use in veterinary medicine is subject to various regulatory frameworks across⁤ different countries. ⁣In‍ the United ⁤States, it is indeed⁢ approved by⁢ the Food and Drug⁤ Administration (FDA) for use in multiple animal ⁤species, including cattle, horses, dogs, and⁣ cats. The European Medicines Agency (EMA) has also authorized its use⁣ in veterinary practice within the European Union. Though, regulations may vary in other regions, and veterinarians must adhere ​to local guidelines when prescribing this anthelmintic drug.

The applications of fenbendazole in veterinary medicine are diverse, targeting a wide range of ‍parasitic infections. It is commonly used to treat:

• Gastrointestinal roundworms
• lungworms
• Tapeworms in some species
• Certain protozoan infections

Its broad-spectrum efficacy and relatively low toxicity ⁣make it a valuable tool in veterinary​ practice. Though, as with ⁢any​ medication, proper dosing and administration are crucial to ensure​ both safety and⁤ effectiveness in treating parasitic infections in ‍animals.

Q&A

Q: What is fenbendazole?
A: Fenbendazole is a broad-spectrum anthelmintic medication used primarily in veterinary medicine to treat various parasitic worm infections in ‍animals.

Q: What is the chemical formula ‌of Fenbendazole?
A: The​ chemical formula‍ of Fenbendazole is C15H13N3O2S.

Q: what is the IUPAC name for Fenbendazole?
A: The IUPAC name for Fenbendazole is​ Methyl N-[6-(phenylsulfanyl)-1H-benzimidazol-2-yl]carbamate.

Q: What is the molecular weight of ⁢Fenbendazole?
A:‌ The molecular weight of Fenbendazole is ‌299.35 g/mol.

Q: What is ‍the physical appearance of ‍Fenbendazole?
A: Fenbendazole appears as a white to off-white crystalline solid at⁣ room​ temperature.

Q: To‍ which class of compounds⁣ does Fenbendazole belong?
A: Fenbendazole⁢ belongs ⁣to the benzimidazole class of compounds.

Q: What is‌ the ⁤mechanism of action of ‍Fenbendazole?
A:‍ Fenbendazole works by binding ⁢to and inhibiting the‌ polymerization of tubulin in parasitic worms, disrupting their cellular structure and metabolism.

Q: Is Fenbendazole water-soluble?
A: No, Fenbendazole has very low water solubility. It is practically insoluble in ‍water.

Q: In which​ solvents is Fenbendazole soluble?
A:‌ Fenbendazole is soluble in dimethylsulfoxide (DMSO) and slightly soluble in methanol and ethanol.

Q: What is ​the melting point of Fenbendazole?
A: ​The melting point of Fenbendazole is approximately⁣ 233°C (451.4°F).

Key Takeaways

fenbendazole’s chemical properties and classification place ‍it firmly within the benzimidazole family of ‍anthelmintic drugs. ‍Its ​molecular‍ structure, solubility characteristics, and mechanism of action contribute to its effectiveness against various⁢ parasitic worms. As ​a broad-spectrum​ antiparasitic ‍agent, ‍fenbendazole continues‌ to play ‌a ‍significant role in​ veterinary medicine and, increasingly, in⁢ potential human applications. Further research into this compound may reveal additional uses and refinements ‍in its administration and efficacy.