Fabrication of bacterial cellulose/PVP nanofiber composites by electrospinning

IF 3.2 4区 生物学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY Biopolymers Pub Date : 2024-06-18 DOI:10.1002/bip.23606
Nevra Pelin Cesur, Kosar Zad Ghaffari Vahdat, Nelisa Türkoğlu Laçin
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Abstract

This study aimed to address a significant challenge in the application of bacterial cellulose (BC) within tissue engineering and regenerative medicine by tackling its inherent insolubility in water and organic solvents. Our team introduced a groundbreaking approach by utilizing zinc sulfate (ZnSO4) as a solvent to render BC soluble, a novel contribution to the literature. Subsequently, the obtained soluble BC was combined with varying concentrations of polyvinylpyrrolidone (PVP). Notably, we pioneered the fabrication of BC/PVP composite scaffolds with customizable fiber surface morphology and regulated degradation rates through the electrospun technique. Several key parameters, such as PVP concentration (8%, 15%, 12%, and 20% w/v), applied voltage (22, 15, and 12 kV), and a fixed nozzle-collector distance of 10 cm with a flow rate of 0.9 mL/h, were systematically evaluated so as to find the optimum parameter created BC/PVP product with electrospun. For electrospun BC/PVP products, a voltage of 12 kV was found to be optimal. Intriguingly, our findings revealed enhanced cell adhesion and proliferation in BC/PVP electrospun products compared with using PVP membranes alone. Specifically, cell viability for PVP and PVP/BC electrospun products was determined as 50.73% and 79.95%, respectively. In terms of thermal properties, the BC/PVP electrospun product exhibited a mass loss of 82.6% at 380°C, while PVP alone experienced 90.2% mass loss at around 280°C. Furthermore, the protein adhesion capacities were measured at 62.3 ± 1.2 μg for PVP and 99.4 ± 2 μg for BC/PVP electrospun products, whereas product showed no biodegradation over 28 days and had notable water retention capacity. In conclusion, our research not only successfully attained nanofiber morphology but also showcased enhanced cell attachment and proliferation on the BC/PVP electrospun product.

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利用电纺丝技术制造细菌纤维素/PVP 纳米纤维复合材料。
本研究旨在解决细菌纤维素(BC)在水和有机溶剂中固有的不溶性问题,从而解决其在组织工程和再生医学中应用所面临的重大挑战。我们的团队采用了一种开创性的方法,利用硫酸锌(ZnSO4)作为溶剂使细菌纤维素可溶,这是对文献的一种新贡献。随后,将获得的可溶性 BC 与不同浓度的聚乙烯吡咯烷酮(PVP)结合。值得注意的是,我们率先通过电纺技术制造出了具有可定制纤维表面形态和可调降解率的 BC/PVP 复合支架。我们系统地评估了几个关键参数,如 PVP 浓度(8%、15%、12% 和 20% w/v)、应用电压(22、15 和 12 kV)以及固定的喷嘴-收集器距离(10 cm)和 0.9 mL/h 的流速,从而找到了电纺 BC/PVP 产品的最佳参数。对于电纺 BC/PVP 产品,12 kV 的电压是最佳的。有趣的是,我们的研究结果表明,与单独使用 PVP 膜相比,BC/PVP 电纺产品的细胞粘附力和增殖能力都有所增强。具体而言,PVP 和 PVP/BC 电纺产品的细胞存活率分别为 50.73% 和 79.95%。在热性能方面,BC/PVP 电纺产品在 380°C 时的质量损失为 82.6%,而单独使用 PVP 时在 280°C 左右的质量损失为 90.2%。此外,经测量,PVP 的蛋白质粘附能力为 62.3 ± 1.2 μg,而 BC/PVP 电纺产品的蛋白质粘附能力为 99.4 ± 2 μg。总之,我们的研究不仅成功地获得了纳米纤维形态,而且还展示了 BC/PVP 电纺产品上细胞附着和增殖能力的增强。
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来源期刊
Biopolymers
Biopolymers 生物-生化与分子生物学
CiteScore
5.30
自引率
0.00%
发文量
48
审稿时长
3 months
期刊介绍: Founded in 1963, Biopolymers publishes strictly peer-reviewed papers examining naturally occurring and synthetic biological macromolecules. By including experimental and theoretical studies on the fundamental behaviour as well as applications of biopolymers, the journal serves the interdisciplinary biochemical, biophysical, biomaterials and biomedical research communities.
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