An Overview of Nanofiber Applications for Development of Phytopharmaceuticals

IF 0.2 Q4 MEDICINE, GENERAL & INTERNAL
İmren Esentürk-Güzel, Lüceyn Abdo, Evren Alğın Yapar, Engin Esentürk, Derya Büyükkayhan, Rakesh K. Sindhu
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Abstract

Herbal sources contain a variety of bio-actives, which are also called phytochemicals. Many of the herbal bio-actives have therapeutic effects and distinguished chemical properties that allow them favorable candidates for phytomedicines. The history of traditional herbal medicines, which are the precursors of phytopharmaceuticals, dates back to ancient times. Today, many of the officially approved and widely used medicines are produced by isolating active substances from herbal sources. Although traditional pharmaceutical dosage forms such as tablets, capsules, syrups, solutions, decoctions and ointments are still used today, problems related with the absorption, biotransformation and stability of phytochemicals reduces the efficacy, bioavailability and in some cases safety of herbal medicines. Also, conventional pharmaceutical dosage forms are often providing an immediate release of phytoconstituents. Besides the use of advanced drug delivery systems offer advantages to overcome mentioned problems, they also provide extended release with maximum efficacy associated with minimum side effects. Researches on development of herbal formulations by using novel drug delivery systems have gain attention and the use of nanotechnology-based a huge potential to improve in vivo simulated tests in drug development studies (9). Additionally, nanofibers play an important role in the field of regenerative medicine, which can recover important tissues such as heart, blood vessels, nerves, bones, cartilages, tendons, and joints. This is possible with the combination of 3D printing and electrospinning techniques to form biomimicking nanofiber scaffolds and patches loaded with stem cells (9,10). The unique specifications of nanofibers have made them widely used in treatment of different diseases such as infections, allergy, hypertension, rheumatic diseases, inflammatory autoimmune diseases, diabetes, intracranial aneurism, Alzheimer’s, cardiovascular diseases, gastrointestinal diseases, AIDS, and cancers (11,12). Mechanical properties of nanofibers such as high surface area-to-volume ratio, high porosity, amorphous structure, and flexibility of the nanofiber-based carrier systems to deliver herbal bio-actives through various drug application routes is overviewed.
纳米纤维在植物药物开发中的应用综述
草药来源含有多种生物活性物质,也称为植物化学物质。许多草药生物活性物质具有治疗作用和独特的化学特性,使其成为植物药物的有利候选者。传统草药是植物药物的前身,其历史可以追溯到古代。如今,许多官方批准和广泛使用的药物都是通过从草药中分离活性物质来生产的。尽管传统的药物剂型,如片剂、胶囊、糖浆、溶液、煎剂和软膏至今仍在使用,但与植物化学物质的吸收、生物转化和稳定性有关的问题降低了草药的疗效、生物利用度,在某些情况下还降低了安全性。此外,常规药物剂型通常提供植物成分的立即释放。除了使用先进的药物递送系统提供了克服上述问题的优势外,它们还提供了具有最大疗效和最小副作用的缓释。通过使用新型药物递送系统开发草药配方的研究已经引起了人们的关注,并且基于纳米技术的使用在改进药物开发研究中的体内模拟测试方面具有巨大潜力(9)。此外,纳米纤维在再生医学领域发挥着重要作用,再生医学可以恢复心脏、血管、神经、骨骼、软骨、肌腱和关节等重要组织。这可以通过3D打印和静电纺丝技术的结合来形成载有干细胞的仿生纳米纤维支架和贴片(9,10)。纳米纤维的独特规格使其广泛用于治疗不同的疾病,如感染、过敏、高血压、风湿性疾病、炎症性自身免疫性疾病、糖尿病、颅内动脉瘤、阿尔茨海默氏症、心血管疾病、胃肠道疾病、艾滋病和癌症(11,12)。综述了纳米纤维的机械性能,如高表面积与体积比、高孔隙率、无定形结构和纳米纤维载体系统的灵活性,以通过各种药物应用途径递送草药生物活性物质。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Bezmialem Science
Bezmialem Science MEDICINE, GENERAL & INTERNAL-
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