Biomimetic engineering of a fully bio-based system in nanomedicine

2nd Middle East Conference on Biomedical Engineering Pub Date : 2014-04-07 DOI:10.1109/MECBME.2014.6783282

Parisa Pooyan, L. Brewster, R. Tannenbaum, H. Garmestani

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Abstract

Design of materials and devices by mimicking the fascinating systems found in nature, have enabled scientists to discover new techniques to treat diseases from diagnosis to therapeutic care. With the recent advances in nanomedicine, the length-scale of this design has further extended down into a nano-sized array. Inspired by the two natural assemblies found in nature; cellulose and collagen; we have designed a new class of green functional material with nano-sized arrangement. The fabricated material composed of collagen hydrogel reinforced by cellulose nanowhiskers in order to effectively enhance the rigidity of collagen and to better mimic the morphology and profile features existed in biological tissues. The biocompatibility of the hydrogel nanocomposite was also investigated by the invasion and proliferation of human bone marrow derived mesenchymal stem cells around the materials at 8 day of culture. We believe that our biomimetically-engineered platform in this study could increase the biomedical applications of fully bio-based systems such as scaffolding in tissue engineering.

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纳米医学中的全生物基系统仿生工程

通过模仿自然界中的奇妙系统设计材料和设备，科学家们发现了从诊断到治疗的疾病治疗新技术。随着纳米医学的最新进展，这种设计的长度范围进一步扩展到纳米级阵列。受大自然中纤维素和胶原蛋白这两种天然组合物的启发，我们设计出了一种具有纳米级排列的新型绿色功能材料。该材料由纤维素纳米须增强的胶原蛋白水凝胶组成，可有效增强胶原蛋白的刚性，更好地模拟生物组织的形态和轮廓特征。我们还通过培养 8 天的人骨髓间充质干细胞在材料周围的侵袭和增殖研究了纳米水凝胶复合材料的生物相容性。我们相信，本研究中的生物仿生工程平台可以增加全生物基系统（如组织工程中的支架）的生物医学应用。

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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2nd Middle East Conference on Biomedical Engineering

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