An Overview of Transferosomal Technology

Q3 Medicine

Current Nanomedicine Pub Date : 2024-05-20 DOI:10.2174/0124681873281058240509114133

Neha Kumari, Sumit Sharma

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引用次数: 0

Abstract

Ever since the invention of liposomes by Bangham in 1963, researchers have been fascinated by the vesicular carriers. Liposomes and niosomes have been used extensively by researchers for various routes such as oral and nasal. However, lately, it has been understood that traditional liposomes are not very significant when it comes to penetration. The use of nanovesicles in transdermal drug delivery systems has been enhanced exponentially ever since the discovery of ultra- deformable liposomes known as transfersomes or transferosomes. Transferosomes have numerous advantages, such as biocompatibility, biodegradability, flexibility, and deformability, so that they can pass through narrow constrictions. They have good entrapment efficiency and can act as a depot to sustain the release of drugs. The methods of preparation include the rotary film evaporation method, reverse phase evaporation method, vortexing sonication method, ethanol injection method, and freeze-thaw method. Transfersomes are characterized by particle size, zeta potential, polydispersity index, surface morphology, and encapsulation efficiency. Transferosomes have been successfully exploited for the enhancement of efficacy of many drugs like Hydroquinone, Itraconazole, Ivabradine, lornoxicam, minoxidil etc., via transdermal and nasal routes. The technology is easy to scale up. Consequently, it can be inferred that transfersomes are the future of transdermal drug delivery systems.

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转运体技术概述

自 1963 年 Bangham 发明脂质体以来，研究人员一直对这种囊状载体着迷不已。研究人员在口腔和鼻腔等各种途径中广泛使用了脂质体和niosomes。然而，最近人们认识到，传统的脂质体在渗透方面并不十分显著。自从发现了被称为转运体或转移体的超变形脂质体后，纳米颗粒皮内给药系统的使用呈指数级增长。转移体具有生物相容性、生物可降解性、柔韧性和可变形性等诸多优点，因此可以穿过狭窄的空间。转运体具有良好的夹持效率，可以作为药物的储存库来维持药物的释放。其制备方法包括旋转薄膜蒸发法、反相蒸发法、涡旋超声法、乙醇注射法和冻融法。转移体的特征包括粒度、ZETA电位、多分散指数、表面形态和封装效率。转移体已被成功用于通过透皮和鼻腔途径提高氢醌、伊曲康唑、伊伐布雷定、洛诺昔康、米诺地尔等多种药物的疗效。该技术易于推广。因此，可以推断转移体是透皮给药系统的未来。

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

Current Nanomedicine Medicine-Medicine (miscellaneous)

CiteScore

2.00

自引率

0.00%

发文量