Revolutionizing Sustainable Fashion: Jute–Mycelium Vegan Leather Reinforced with Polyhydroxyalkanoate Biopolymer Crosslinking from Novel Bacteria

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2024-05-03 DOI:10.1155/2024/1304800
Sumaia Akhter, Md Sarwar Jahan, Md. Latifur Rahman, Tania Akter Ruhane, Maruf Ahmed, Mubarak Ahmad Khan
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Abstract

Vegan leather derived from mushroom mycelium is a revolutionary technology that addresses the issues raised by bovine and synthetic leather. Jute–mycelium-based vegan leather was constructed using hessian jute fabric, natural rubber solution, and extracted polyhydroxyalkanoate (PHA) biopolymer from Bacillus subtilis strain FPP-K isolated from fermented herbal black tea liquor waste. The bacterial strain was confirmed using 16S rRNA genomic sequencing. The structural characteristics of sustainable mycelium vegan leather were identified using FTIR, SEM, and TGA methods. To address the functional features of the developed vegan leather, solubility, swelling degree, WVP, WCA, and mechanical strength were also evaluated. Mycelium networking was further validated by micromorphological examination (SEM) of the leather sample’s cross-sectional area. Jute–mycelium leather demonstrated a tensile strength of 8.62 MPa and a % elongation of 8.34, which were significantly greater than the control sample. Vegan leather displayed a strong peak in the O ═ H group of carbohydrates in the examination of chemical bonds. A high-frequency infrared wavelength of 1,462 cm−1 revealed the amide group of protein due to the presence of mycelium, while the absorption peak at 1,703 cm−1 in leather indicated the crosslinking of PHA. Moreover, the TGA study finalized the thermal stability of leather. The enhanced hydrophobicity and reduced swelling degree and solubility also endorsed the water resistance properties of the leather. The results of the investigation substantiated the potential properties of mycelium vegan leather as animal- and environment-free leather.

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革新可持续时装:用新型细菌产生的聚羟基烷酸生物聚合物交联强化的黄麻菌丝体素皮
从蘑菇菌丝体中提取的素皮革是一项革命性技术,它解决了牛皮革和合成皮革所带来的问题。以黄麻菌丝体为基础的素皮是利用麻黄织物、天然橡胶溶液和从发酵凉茶红茶废液中分离出的枯草芽孢杆菌菌株 FPP-K 提取的聚羟基烷酸(PHA)生物聚合物制成的。通过 16S rRNA 基因组测序确认了该菌株。利用傅立叶变换红外光谱、扫描电镜和热重分析方法确定了可持续菌丝素皮革的结构特征。针对所开发素皮的功能特性,还对其溶解度、膨胀度、WVP、WCA 和机械强度进行了评估。通过对皮革样品横截面积进行微观形态学检查(扫描电镜),进一步验证了菌丝体网络的有效性。黄麻菌丝体皮革的拉伸强度为 8.62 兆帕,伸长率为 8.34%,明显高于对照样品。在化学键检测中,素皮在碳水化合物的 O ═ H 组中显示出一个强峰值。由于菌丝的存在,1,462 厘米-1 的高频红外波长显示了蛋白质的酰胺基,而皮革中 1,703 厘米-1 的吸收峰显示了 PHA 的交联。此外,TGA 研究确定了皮革的热稳定性。疏水性的增强、膨胀度和溶解度的降低也证明了皮革的耐水性能。研究结果证实了菌丝素皮革作为无动物和环境污染皮革的潜在特性。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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