纳米纤维组织工程支架,能够实现生长因子的递送。
Nano-fibrous tissue engineering scaffolds capable of growth factor delivery.
机构信息
Department of Biologic and Materials Sciences, The University of Michigan, 1011 North University Ave, Room 2211, Ann Arbor, Michigan 48109-1078, USA.
出版信息
Pharm Res. 2011 Jun;28(6):1273-81. doi: 10.1007/s11095-011-0367-z. Epub 2011 Jan 14.
Abstract
Tissue engineering aims at constructing biological substitutes to repair damaged tissues. Three-dimensional (3D) porous scaffolds are commonly utilized to define the 3D geometry of tissue engineering constructs and provide adequate pore space and surface to support cell attachment, migration, proliferation, differentiation and neo tissue genesis. Biomimetic 3D scaffolds provide synthetic microenvironments that mimic the natural regeneration microenvironments and promote tissue regeneration process. While nano-fibrous (NF) scaffolds are constructed to mimic the architecture of NF extracellular matrix, controlled-release growth factors are incorporated to modulate the regeneration process. The present article summarizes current advances in methods to fabricate NF polymer scaffolds and the technologies to incorporate controlled growth factor delivery systems into 3D scaffolds, followed by examples of accelerated regeneration when the scaffolds with growth factor releasing capacity are applied in animal models.
摘要
组织工程旨在构建生物替代品来修复受损组织。三维(3D)多孔支架常用于定义组织工程构建物的 3D 几何形状,并提供足够的孔空间和表面以支持细胞附着、迁移、增殖、分化和新组织生成。仿生 3D 支架提供了模仿自然再生微环境的合成微环境,促进了组织再生过程。虽然纳米纤维(NF)支架是为了模仿 NF 细胞外基质的结构而构建的,但可以掺入控制释放的生长因子来调节再生过程。本文总结了目前制造 NF 聚合物支架的方法的进展,以及将控制生长因子释放系统纳入 3D 支架的技术,然后介绍了在动物模型中应用具有生长因子释放能力的支架时加速再生的实例。
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