Impact of Fiber Characteristics on the Interfacial Interaction of Mammalian Cells and Bacteria

Helna M. Baby, John Joseph, Maneesha K. Suresh, Raja Biswas, Deepthy Menon
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Abstract

An imperative requisite of tissue-engineered scaffolds is to promote host cell regeneration and concomitantly thwart microbial growth. Antibacterial agents are often added to prevent implant-related infections, which, however, aggravates the risk of bacterial resistance. For the first time, we report a fiber-based platform that selectively promotes the growth of mammalian cells and alleviates bacteria by varying fiber size, orientation, and material of polymeric yarns. The interactions of Gram-positive and -negative bacterial species with mammalian mesenchymal stem cells (MSC) were investigated on poly-€-caprolactone (PCL) yarns, polyethylene terephthalate (PET), poly-L-lactic acid (PLLA), and cotton. Various yarn configurations were studied by altering the fiber diameter (from nano- to microscale) and fiber orientations (aligned, twisted, and random) of PCL yarns. PCL nanofibrous yarn decreased the adhesion of S. aureus and E. coli, with a 2.7-fold and 1.5-fold reduction, respectively, compared to PCL microfibrous yarn. Among different fiber orientations, nanoaligned fibers resulted in an 8-fold and 30-fold reduction of S. aureus and E. coli adhesion compared to random fibers. Moreover, aligned orientation was superior in retarding the S. aureus adhesion by 14-fold compared to nanotwisted fibers. Our data demonstrate that polymeric yarns comprising fibers with nanoscale features and aligned orientation promote mammalian cell adhesion and spreading and concomitantly mitigate bacterial interaction. Moreover, we unveil the wicking of cells through polymeric yarns, facilitating early cell adhesion in fibrous scaffolds. Overall, this study provides insight to engineer scaffolds that couple superior interaction of mammalian cells with high-strength fibrous yarns for regenerative applications devoid of antibacterial agents or other surface modification strategies.
纤维特性对哺乳动物细胞和细菌界面相互作用的影响
组织工程支架的一个必要条件是促进宿主细胞再生,同时阻止微生物的生长。抗菌剂通常是为了防止植入物相关感染而添加的,然而,这增加了细菌耐药性的风险。我们首次报道了一种基于纤维的平台,该平台通过改变纤维的大小、方向和聚合物纱线的材料,选择性地促进哺乳动物细胞的生长,并减轻细菌。研究了革兰氏阳性和阴性菌种与哺乳动物间充质干细胞(MSC)在聚己内酯(PCL)纱线、聚对苯二甲酸乙二醇酯(PET)、聚l -乳酸(PLLA)和棉花上的相互作用。通过改变PCL纱线的纤维直径(从纳米级到微米级)和纤维取向(排列、扭曲和随机),研究了不同的纱线结构。与PCL微纤维纱相比,PCL纳米纤维纱降低了金黄色葡萄球菌和大肠杆菌的粘附力,分别降低了2.7倍和1.5倍。在不同的纤维取向中,纳米纤维与随机纤维相比,金黄色葡萄球菌和大肠杆菌的粘附力分别降低了8倍和30倍。此外,与纳米缠绕纤维相比,排列取向对金黄色葡萄球菌粘附的延缓作用强14倍。我们的数据表明,由具有纳米级特征和定向的纤维组成的聚合物纱线促进了哺乳动物细胞的粘附和扩散,并同时减轻了细菌的相互作用。此外,我们揭示了细胞通过聚合纱线的排芯,促进纤维支架中的早期细胞粘附。总的来说,这项研究为工程支架提供了见解,这些支架将哺乳动物细胞与高强度纤维纱线的良好相互作用结合起来,用于再生应用,无需抗菌剂或其他表面改性策略。
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