Synthesis of Novel Bacterial Cellulose Based Silver-Metal Organic Frameworks (BC@Ag-MOF) as Antibacterial Wound Healing

Fine Chemical Engineering Pub Date : 2023-07-21 DOI:10.37256/fce.4220233120

N. Puspitasari, David Arief, S. Ismadji, V. Saraswaty, S. Santoso, Ery Susiany Retnoningtyas, J. N. Putro, C. Gunarto

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Abstract

Bacterial Cellulose (BC) is a polymer derived from the bacterium Komagataeibacter xylinus with great potential for biomedical applications due to its high biocompatibility and biodegradability. In addition, the polymer is naturally biosynthesized by bacteria as hydrogels which can be used as optimal substrates for wound healing. However, the drawback of BC is the absence of antibacterial properties. Nowadays, some infections become more prevalent and harder to treat because of antimicrobial resistance, therefore, it is necessary to develop a strategy for modifying BC as wound healing that provides protection against bacterial contamination. In this work, silver-based Metal Organic Frameworks (MOFs) were immobilized into Bacterial Cellulose (BC). MOFs are porous coordination materials consisting of metal ions and multidentate organic ligands that have the potential as a matrix for metal ions due to their ability to gradually release metal ions. The structure and morphology of BC@Ag-MOF were successfully confirmed by Fourier-Transform Infrared spectroscopy (FTIR) and Scanning Electron Microscope (SEM). Evidently, BC@Ag-MOF exhibited a higher silver content (63.19%) than BC@Ag without immobilization into MOF (48.46%). Therefore, it indicated that MOF has large pores for enhancing the capacity for silver ion absorption in BC. The modified BC has never been reported and achieved the highest antibacterial activity of 99.99% against Gram-negative bacteria Escherichia coli. Moreover, BC@Ag-MOF has a higher antibacterial efficiency of 97% compared to BC@Ag without matrix. This study expands the potential application of BC modification in the field of biological antibacterial. has never been reported and achieved the highest antibacterial activity of 99.99% against Gram-negative bacteria Escherichia coli. Moreover, BC@Ag-MOF has a higher antibacterial efficiency of 97% compared to BC@Ag without matrix. This study expands the potential application of BC modification in the field of biological antibacterial.

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新型细菌纤维素基银金属有机框架的合成(BC@Ag-MOF)抗菌伤口愈合

细菌纤维素(BC)是一种从木林菌Komagataeibacter xylinus中提取的聚合物，具有很高的生物相容性和可生物降解性，在生物医学领域具有很大的应用潜力。此外，该聚合物是由细菌自然生物合成的水凝胶，可作为伤口愈合的最佳底物。然而，BC的缺点是缺乏抗菌性能。如今，由于抗菌素耐药性，一些感染变得更加普遍和难以治疗，因此，有必要制定一种策略来修改BC作为伤口愈合，提供对细菌污染的保护。本研究将银基金属有机框架(mof)固定化到细菌纤维素(BC)中。mof是由金属离子和多齿有机配体组成的多孔配位材料，由于其逐渐释放金属离子的能力，具有作为金属离子基质的潜力。通过傅里叶变换红外光谱(FTIR)和扫描电镜(SEM)成功地证实了BC@Ag-MOF的结构和形态。显然，BC@Ag-MOF的银含量(63.19%)高于未固定在MOF中的BC@Ag(48.46%)。因此，这表明MOF具有较大的孔隙，可以提高BC对银离子的吸收能力。改性BC对革兰氏阴性大肠杆菌的抑菌活性最高，达到99.99%。与不含基质的BC@Ag相比，BC@Ag-MOF的抗菌效率高达97%。本研究拓展了BC改性在生物抗菌领域的潜在应用。对革兰氏阴性大肠杆菌抑菌活性最高达99.99%。与不含基质的BC@Ag相比，BC@Ag-MOF的抗菌效率高达97%。本研究拓展了BC改性在生物抗菌领域的潜在应用。

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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Fine Chemical Engineering

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