血液透析过程中的污垢--组件设计和膜表面化学性质的影响

Christine Jurene O. Bacal , Catherine J. Munro , Blaise Tardy , James W. Maina , Julie A. Sharp , Joselito M. Razal , George W. Greene , Harshal H. Nandurkar , Karen M. Dwyer , Ludovic F. Dumée
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引用次数: 0

摘要

血液透析是一种人工肾脏,可选择性地清除肾衰竭患者主血流中的特定毒素、生物化合物或液体。目前的流程采用基于超滤的膜技术,半渗透材料可根据某些化合物的大小,有选择性地提取尿毒症潴留产物等化学物质,或清除血液中多余的水分。在血液透析过程中,当糖、脂肪、蛋白质、生物大分子、细胞和血小板进入并穿过管状膜时,膜的表面就会开始变脏,从而导致重大的操作挑战,包括随着操作时间的增加压力急剧下降。设计具有更强生物相容性和防污特性的膜是提高膜使用寿命的一个途径,同时还能促进设备运行,减轻患者的压力和不适感。本综述介绍了血液透析中使用的血液成分与膜材料之间的界面相互作用。讨论分析了血液透析器模块设计、膜材料形态和表面化学对血液透析器长期运行和性能的影响。此外,还讨论了开发下一代膜材料的途径以及加强选择性去除血液中有毒化合物的新策略。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Fouling during hemodialysis – Influence of module design and membrane surface chemistry

Fouling during hemodialysis – Influence of module design and membrane surface chemistry

Hemodialysis acts as an artificial kidney that selectively removes specific toxins, bio-compounds, or fluid from the main blood stream in a patient with kidney failure. The current process uses ultrafiltration-based membrane technology, where a semi-permeable material selectively extracts chemicals, such as uremic retention products, or remove excess water from blood by retaining certain compounds based on their size. As sugars, fats, proteins, biomolecules, cells, and platelets move into and across the tubular membrane in the hemodialysis process, the surface of the membrane begins to foul, which leads to major operational challenges that include sharp pressure drops with increasing operation times. The design of membranes with enhanced biocompatibility and anti-fouling properties is one avenue to increase the lifespan of the membrane used while facilitating the device operation and limiting the stress and discomfort of patients. This review presents interfacial interactions between blood components and membrane materials used in hemodialysis. The discussion analyzes the impacts of the hemodialyzer module design, membrane material morphology and surface chemistry on the long-term operation and performance of the hemodialyzers. Avenues for the development of next-generation-membrane-materials as well as new strategies to enhance the selective removal of toxic compounds from blood are also discussed.

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