Carmen Limban, Diana Camelia Nuță, Miron Teodor Caproiu, Denisa Elena Dumitrescu, Șerban Iancu Papacocea, Alexandra Teodora Bordei, Florea Dumitrașcu
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Abstract
Carprofen, a nonsteroidal anti-inflammatory drug (NSAID) derived from propanoic acid, is known for its analgesic and antipyretic properties. Although it has long been employed in veterinary medicine as an anti-inflammatory agent, its use in humans was discontinued shortly after its market launch due to costly raw materials, complex synthesis, and labor-intensive production processes—factors that made it less competitive compared with other NSAIDs. Despite this, the carprofen molecule remains a subject of significant scientific interest. Recent advancements in its synthesis have introduced simplified and more cost-effective methods, reigniting its potential for both novel applications and drug repurposing. Exciting new research is exploring carprofen's broader therapeutic possibilities, extending beyond its original anti-inflammatory role. Studies are investigating its efficacy in antimicrobial therapy—including antibiofilm, anticancer, antiviral, and anti-Alzheimer's applications—opening doors to a wealth of untapped possibilities. This review delves into these emerging areas, highlighting how carprofen's molecular structure and derivatives can be leveraged to expand its therapeutic reach. The literature review was conducted using four databases: Web of Science, ScienceDirect, Scopus, Embase, and Reaxys. The review focused on English-language original research and review articles, examining carprofen and its derivatives in terms of their synthesis methods as well as their use as small molecules in various therapeutic applications, both human and veterinary. With ongoing research pushing the boundaries of its potential, carprofen remains a promising candidate for innovation in drug development and treatment strategies.
卡洛芬是一种从丙酸中提取的非甾体抗炎药(NSAID),以其镇痛和解热特性而闻名。尽管它长期以来被用作兽药抗炎剂,但由于原材料昂贵、合成复杂、生产过程劳动密集型,它在上市后不久就停止了对人类的使用——这些因素使它与其他非甾体抗炎药相比缺乏竞争力。尽管如此,卡洛芬分子仍然是一个重要的科学兴趣课题。其合成的最新进展引入了简化和更具成本效益的方法,重新点燃了其在新应用和药物再利用方面的潜力。令人兴奋的新研究正在探索卡洛芬更广泛的治疗可能性,超越其最初的抗炎作用。研究正在调查它在抗菌治疗中的功效——包括抗生素膜、抗癌、抗病毒和抗阿尔茨海默氏症的应用——为大量未开发的可能性打开了大门。这篇综述深入研究了这些新兴领域,强调了如何利用卡洛芬的分子结构和衍生物来扩大其治疗范围。文献综述使用Web of Science、ScienceDirect、Scopus、Embase和Reaxys四个数据库进行。这篇综述的重点是英语原创研究和评论文章,从合成方法以及小分子在各种治疗应用(包括人类和兽医)中的用途方面考察了卡洛芬及其衍生物。随着正在进行的研究推动其潜力的边界,卡洛芬仍然是药物开发和治疗策略创新的有希望的候选人。
期刊介绍:
Chemical Biology & Drug Design is a peer-reviewed scientific journal that is dedicated to the advancement of innovative science, technology and medicine with a focus on the multidisciplinary fields of chemical biology and drug design. It is the aim of Chemical Biology & Drug Design to capture significant research and drug discovery that highlights new concepts, insight and new findings within the scope of chemical biology and drug design.
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