Metal-based porous hydrogels for highly conductive biomaterial scaffolds

IF 2.9 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY
Christina M Tringides, Marjolaine Boulingre, David J Mooney
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引用次数: 2

Abstract

Abstract Multielectrode arrays are fabricated from thin films of highly conductive and ductile metals, which cannot mimic the natural environment of biological tissues. These properties limit the conformability of the electrode to the underlying target tissue and present challenges in developing seamless interfaces. By introducing porous, hydrogel materials that are embedded with metal additives, highly conductive hydrogels can be formed. Tuning the hydrogel composition, % volume and aspect ratio of different additive(s), and the processing conditions of these composite materials can alter the mechanical and electrical properties. The resulting materials have a high surface area and can be used as biomaterial scaffolds to support the growth of macrophages for 5 days. Further optimization can enable the use of the materials for the electrodes in implantable arrays, or as living electrode platforms, to study and modulate various cellular cultures. These advancements would benefit both in vivo and in vitro applications of tissue engineering.
高导电性生物材料支架用金属基多孔水凝胶
摘要多电极阵列是由高导电性和延展性的金属薄膜制成的,它不能模拟生物组织的自然环境。这些特性限制了电极与潜在目标组织的一致性,并给开发无缝界面带来了挑战。通过引入嵌入金属添加剂的多孔水凝胶材料,可以形成高导电性的水凝胶。调整不同添加剂的水凝胶组成、体积百分比和长径比以及这些复合材料的加工条件可以改变其力学和电学性能。所得材料具有较高的比表面积,可作为生物材料支架支持巨噬细胞生长5天。进一步的优化可以使材料用于可植入阵列的电极,或作为活电极平台,以研究和调节各种细胞培养。这些进展将有利于组织工程在体内和体外的应用。
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
CiteScore
3.60
自引率
0.00%
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审稿时长
7 weeks
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