A novel polyelectrolyte complex (PEC) hydrogel for controlled drug delivery to the distal intestine

The Open Drug Delivery Journal Pub Date : 2007-11-30 DOI:10.2174/1874126600701010068

Chiara Zaino, Y. Zambito, G. Mollica, M. Geppi, M. F. Serafini, V. Carelli, G. Colo

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引用次数: 12

Abstract

This work was aimed at preparing and evaluating a physically crosslinked hydrogel for the controlled release of diverse drugs to the distal intestine. A solution of fluorescein isothiocyanate dextran, MW 4400 Da (FD4), or a dispersion of micronized dexamethasone (DMS) was microencapsulated into a PEC hydrogel, composed of polycationic N-trimethyl chitosan (TMC) and polyanionic N-carboxymethyl chitosan (CMCh). A fine spray of a 1% CMCh solution containing 1% FD4 in solution or 0.1% DMS in dispersion was directed into a 2% TMC solution, then the resulting microcapsules (MCPS) were lyophilized. MCPS were analyzed by SEM and solid-state NMR. Drug release from MCPS was too fast, so these were compressed into matrices (weight 20 mg; diameter 6 mm; drug load 2.5%, with FD4, or 3.7%, with DMS) which were enteric coated. Drug release from matrices was studied simulating matrix transit across GI environments of different pHs, from stomach to proximal colon. The enteric film hindered release in stomach and proximal small intestine. After film dissolution at ileum pH, release occurred with a pattern described by the Peppas equation (n=0.6, with DMS; n=0.7, with FD4). As the pH changed from 7.4 to 6 (from ileum to ascending colon) MCPS were liberated from matrix surface. This phenomenon sustained the release rate. The present MCPS allow controlled doses of macromolecular or mi- croparticulate drugs being uniformly loaded into controlled-release matrices based on a physically crosslinked, biodegrad- able hydrogel.

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一种新型的多电解质复合物(PEC)水凝胶，用于控制远端肠的药物递送

本工作旨在制备和评估一种物理交联水凝胶，用于控制多种药物在远端肠道的释放。将异硫氰酸荧光素葡聚糖(MW 4400 Da, FD4)溶液或微细化地塞米松(DMS)分散体微胶囊入聚阳离子n -三甲基壳聚糖(TMC)和聚阴离子n -羧甲基壳聚糖(CMCh)组成的PEC水凝胶中。将含有1% FD4溶液或0.1% DMS分散体的1% CMCh溶液的细喷雾定向到2% TMC溶液中，然后将所得微胶囊(MCPS)冻干。用SEM和固体核磁共振对MCPS进行了分析。MCPS的药物释放速度太快，因此将其压缩成基质(重量为20mg;直径6毫米;含FD4的药量为2.5%，含DMS的药量为3.7%)。通过模拟基质在不同ph值的胃肠道环境(从胃到近端结肠)中的转运，研究了基质的药物释放。肠膜阻滞了胃和近端小肠的释放。膜在回肠pH下溶解后，释放模式由Peppas方程描述(n=0.6, DMS;n=0.7, FD4)。当pH值从7.4到6(从回肠到升结肠)时，MCPS从基质表面释放出来。这种现象维持了释放速度。目前的MCPS允许控制剂量的大分子或微颗粒药物均匀地装载到基于物理交联的可生物降解水凝胶的控释基质中。

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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The Open Drug Delivery Journal

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