静电纺聚l -乳酸的大气等离子体表面改性:对材料性能和细胞培养的影响

M. Alessandri, L. Calzà, V. Colombo, L. S. Dolci, A. Fiorani, M. L. Focarete, E. Ghedini, M. Gherardi, C. Gualandi, R. Laurita, A. Liguori, S. Quiroga, P. Sanibondi
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引用次数: 2

摘要

只提供摘要形式。材料科学应用于再生医学和组织工程研究生物相容性人工组织的成就,以改善,自我修复或有利于细胞治疗。各种研究证明了等离子体修饰聚合物支架表面的能力,通过减少接触角和增加表面能来改善亲水性和表面粗糙度,而不改变体性能。此外,与原始材料相比,血浆修饰支架上的细胞培养具有更好的增殖和活力。本文主要研究了常压非热等离子体对静电纺聚乳酸(PLLA)无纺布垫的表面改性。静电纺丝技术允许制造具有高多孔结构、相互连接的孔和大比表面积的聚合物材料支架,模拟细胞外基质(ECM)。在这项工作中,我们将介绍在大气压下三种不同的等离子体源:浮电极介质阻挡放电(FE-DBD)、线性电晕放电和DBD滚轮所产生的等离子体区域中暴露电纺丝支架的过程。已经使用了一种高压发生器,能够产生上升速率约为kV/ns的脉冲。在“大面积处理”方法的框架下,所有的源都很容易按比例放大。等离子体源的表征是通过一系列广泛的测量、改变操作条件、几何形状和等离子体气体成分来进行的,这是多步骤工艺优化方法的基本阶段。本文将研究等离子体处理对聚乳酸静电纺纳米纤维毡的形貌、热力学和表面性能的影响。我们将讨论在PLLA电纺丝支架上引入COOH官能团的结果,以及在血浆处理和未处理的PLLA电纺丝支架上生长的大鼠胚胎干细胞(RESCs)的增殖情况。
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Atmospheric plasma surface modification of electrospun poly(L-lactic acid): Effect on mat properties and cell culturing
Summary form only given.Material science applied to regenerative medicine and tissue engineering study the achievement of biocompatible artificial tissues to improve, self-repair or favour cellular therapies. Various studies prove plasma ability to modify polymeric scaffold surface, with an improvement of hydrophilicity and surface roughness demonstrated by a reduction of contact angle and by an increase of surface energy without altering bulk properties. Furthermore, it was demonstrated that cell cultures on plasma modified scaffolds display better proliferation and viability compared to pristine materials. In this work we focus on the use of atmospheric pressure non-thermal plasma for surface modification of electrospun poly(L-lactic acid) (PLLA) non-woven mats. The electrospinning technology allows to fabricate scaffolds of polymeric materials with highly porous structure, interconnected pores and large specific surface area, that mimic extracellular matrix (ECM). In this work results will be presented concerning the process of exposure of electrospun scaffolds to the plasma region generated by three different plasma sources operated at atmospheric pressure: a floating electrode dielectric barrier discharge (FE-DBD), a linear corona discharge and a DBD roller. A high voltage generator capable of producing pulses with a rise rate in the order of some kV/ns has been used. All the sources are easily scaled-up in the frame of a “large area treatment” approach. Plasma sources characterization has been carried out through a wide set of measurements, changing operating conditions, geometry and plasma gas composition, as the fundamental stage in a multi-step approach for process optimization. In this work, results on the effect of plasma treatment on morphology, thermo-mechanical and surface properties of PLLA electrospun nanofibrous mats will be presented. Results for the introduction of COOH functional group on PLLA electrospun scaffold and for the proliferation of rat embryonic stem cells (RESCs) grown on plasma treated and untreated PLLA electrospun scaffolds will be presented and discussed.
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