医疗保健中的水凝胶:从静态到动态材料微环境
Hydrogels in Healthcare: From Static to Dynamic Material Microenvironments.
作者信息
Kirschner Chelsea M, Anseth Kristi S
机构信息
Department of Chemical and Biological Engineering, University of Colorado, Boulder, Colorado, USA.
出版信息
Acta Mater. 2013 Feb 1;61(3):931-944. doi: 10.1016/j.actamat.2012.10.037.
Abstract
Advances in hydrogel design have revolutionized the way biomaterials are applied to address biomedical needs. Hydrogels were introduced in medicine over 50 years ago and have evolved from static, bioinert materials to dynamic, bioactive microenvironments, which can be used to direct specific biological responses such as cellular ingrowth in wound healing or on-demand delivery of therapeutics. Two general classes of mechanisms, those defined by the user and those dictated by the endogenous cells and tissues, can control dynamic hydrogel microenvironments. These highly tunable materials have provided bioengineers and biological scientists with new ways to not only treat patients in the clinic but to study the fundamental cellular responses to engineered microenvironments as well. Here, we provide a brief history of hydrogels in medicine and follow with a discussion of the synthesis and implementation of dynamic hydrogel microenvironments for healthcare-related applications.
摘要
水凝胶设计的进展彻底改变了生物材料用于满足生物医学需求的方式。水凝胶在50多年前被引入医学领域,已从静态、生物惰性材料演变为动态、生物活性微环境,可用于引导特定的生物学反应,如伤口愈合中的细胞向内生长或按需递送治疗药物。两类一般机制,即由使用者定义的机制和由内源性细胞和组织决定的机制,可以控制动态水凝胶微环境。这些高度可调节的材料为生物工程师和生物科学家提供了新的方法,不仅可以在临床上治疗患者,还可以研究细胞对工程微环境的基本反应。在此,我们简要介绍水凝胶在医学领域的历史,随后讨论用于医疗相关应用的动态水凝胶微环境的合成与应用。
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