Protein delivery from biodegradable microspheres.

Q4 Pharmacology, Toxicology and Pharmaceutics
J L Cleland
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引用次数: 105

Abstract

The key components to the successful development of a biodegradable microsphere formulation for the delivery of proteins are polymer chemistry, engineering, and protein stability. These areas are intricately related and require a thorough investigation prior to embarking on the encapsulation of proteins. While each of these components is important for the development of a biodegradable microsphere formulation for protein delivery, other critical issues should also be considered. In particular, preclinical studies in the appropriate animal model are usually necessary to assess the potential feasibility of a continuous-release dosage form. These studies should be performed at the earliest possible stage of development to validate the feasibility of a controlled release formulation. After the utility of a controlled release formulation has been demonstrated, the polymer matrix should be chosen and bench-scale production of microspheres initiated. The only polymers presently approved for human use for controlled delivery are the polylactides [poly(lactic acid), poly(glycolic acid), and poly(lactic-coglycolic) acid]. These polymers require multiphase processes involving several steps to produce microspheres containing the desired protein. A thorough review of previous work on encapsulation with these polymers should provide some insight into conditions to be assessed in developing a process. Once a process is chosen, it must be optimized to provide the highest possible yield of microspheres with the desired characteristics (e.g., loading, release, size, etc.). Finally, the final aseptic process should be validated and methods generated to assess the final product. The clinical studies should then start upon approval of the IND application. In the future, the biotechnology industry, and the pharmaceutical industry in general, will be seeking new methods to improve the delivery of therapeutic agents such as proteins and peptides. Formulations like biodegradable microspheres significantly reduce health-care costs since fewer administrations are needed, and they provide a competitive advantage in markets with several competing products (e.g., LHRH agonist market). Further, many new indications such as neurological diseases may require a long-term delivery system. The future success of biodegradable microsphere formulations will primarily depend on the commitment of the pharmaceutical and biotechnology industries to the development of this technology.

由可生物降解的微球传递蛋白质。
成功开发生物可降解微球制剂用于蛋白质递送的关键因素是聚合物化学、工程和蛋白质稳定性。这些区域是复杂相关的,需要在开始对蛋白质进行封装之前进行彻底的调查。虽然这些成分中的每一个对于开发用于蛋白质递送的可生物降解微球配方都很重要,但也应考虑其他关键问题。特别是,通常需要在适当的动物模型中进行临床前研究,以评估持续释放剂型的潜在可行性。这些研究应在尽可能早的开发阶段进行,以验证控释制剂的可行性。在控释制剂的效用得到证实后,应该选择聚合物基质,并开始微球的实验规模生产。目前唯一被批准用于人类控制递送的聚合物是聚乳酸[聚乳酸,聚乙醇酸,聚乳酸-乙醇酸]。这些聚合物需要多相过程,包括几个步骤来生产含有所需蛋白质的微球。对以前用这些聚合物进行封装的工作进行彻底的回顾,应该会对开发过程中需要评估的条件提供一些见解。一旦选择了一种工艺,必须对其进行优化,以提供具有所需特性(例如,负载、释放、尺寸等)的微球的最高产量。最后,应验证最终的无菌工艺,并制定评估最终产品的方法。临床研究应在IND申请获批后开始。在未来,生物技术行业,以及一般的制药行业,将寻求新的方法来改善诸如蛋白质和多肽等治疗剂的输送。可生物降解微球等制剂大大降低了保健费用,因为需要的药物较少,而且它们在有几种竞争产品的市场(例如LHRH激动剂市场)中具有竞争优势。此外,许多新的适应症,如神经系统疾病,可能需要一个长期的输送系统。生物可降解微球制剂未来的成功将主要取决于制药和生物技术工业对这项技术发展的承诺。
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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