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将农业工业废弃物转化为生物塑料涂层薄膜。

Transforming Agro-Industrial Waste into Bioplastic Coating Films.

作者信息

Castillo-Patiño Diana Lucinda, Rosas-Mejía Humberto Geovani, Albalate-Ramírez Alonso, Rivas-García Pasiano, Carrillo-Castillo Amanda, Morones-Ramírez José Rubén

机构信息

Faculty of Chemical Sciences, Autonomous University of Nuevo León (UANL), San Nicolás de los Garza 66455, Mexico.

Center for Research in Biotechnology and Nanotechnology, Faculty of Chemical Sciences, Autonomous University of Nuevo León, Research and Technological Innovation Park, Apodaca 66628, Mexico.

出版信息

ACS Omega. 2024 Oct 10;9(42):42970-42989. doi: 10.1021/acsomega.4c05924. eCollection 2024 Oct 22.

DOI:10.1021/acsomega.4c05924
PMID:39464469
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11500142/
Abstract

Addressing the environmental impact of agro-industrial waste, this study explores the transformation of banana, potato, and orange peels into bioplastics suitable for thin coating films. We prepared six extracts at 100 g/L, encompassing individual (banana peel, BP; orange peel, OP; and potato peel, PP) and combined [BP/OP, BP/PP, and BP/OP/PP] formulations, with yeast mold (YM) medium serving as the control. Utilizing the spin-coating method, we applied 1 mL of each sample at 1000 rpm for 1 min to create the films. Notably, the OP extract demonstrated a twofold increase in bioplastic yield (860.33 mg/L) compared to the yields of BP (391.43 mg/L), PP (357.67 mg/L), BP/OP (469.40 mg/L), BP/PP (382.50 mg/L), BP/OP/PP (272.67 mg/L), and YM (416.33 mg/L) extracts. Atomic force microscopy analysis of the film surfaces revealed a roughness under 8 nm, with the OP extract recording the highest at 7.0275 nm, whereas the BP/OP mixture exhibited the lowest roughness at 0.2067 nm and also formed the thinnest film at 6.5 nm. With R trend values exceeding 0.9950, the films exhibited water vapor permeability values ranging from 3.05 × 10 to 4.44 × 10, with the OP film being the least permeable and the BP/PP films the most permeable. The OP film demonstrated the lowest solubility in both water and ethanol with values of 64.71 and 1.05%, respectively. The solubilities of all films were above 60% in water and below 4% in ethanol. Furthermore, the films exhibited antimicrobial efficacy against both Gram-positive and Gram-negative bacteria. Our findings confirm the potential of utilizing banana, orange, and potato peels as viable substrates for eco-friendly bioplastics in thin-film applications.

摘要

针对农用工业废弃物的环境影响,本研究探索了将香蕉皮、土豆皮和橙子皮转化为适用于薄膜涂层的生物塑料。我们制备了六种浓度为100 g/L的提取物,包括单一提取物(香蕉皮提取物,BP;橙子皮提取物,OP;土豆皮提取物,PP)以及混合提取物[BP/OP、BP/PP和BP/OP/PP],并以酵母霉菌(YM)培养基作为对照。利用旋涂法,我们在1000 rpm转速下,将1 mL每个样品涂覆1分钟以制备薄膜。值得注意的是,与BP(391.43 mg/L)、PP(357.67 mg/L)、BP/OP(469.40 mg/L)、BP/PP(382.50 mg/L)、BP/OP/PP(272.67 mg/L)和YM(416.33 mg/L)提取物的生物塑料产量相比,OP提取物的产量增加了两倍(860.33 mg/L)。薄膜表面的原子力显微镜分析显示粗糙度低于8 nm,其中OP提取物的粗糙度最高,为7.0275 nm,而BP/OP混合物的粗糙度最低,为0.2067 nm,并且还形成了最薄的薄膜,厚度为6.5 nm。薄膜的R趋势值超过0.9950,其水蒸气透过率值在3.05×10至4.44×10之间,其中OP薄膜的透过率最低,BP/PP薄膜的透过率最高。OP薄膜在水和乙醇中的溶解度最低,分别为64.71%和1.05%。所有薄膜在水中的溶解度均高于60%,在乙醇中的溶解度均低于4%。此外,这些薄膜对革兰氏阳性菌和革兰氏阴性菌均表现出抗菌效果。我们的研究结果证实了利用香蕉皮、橙子皮和土豆皮作为环保生物塑料在薄膜应用中的可行底物的潜力。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6a44/11500142/2b3621230ac6/ao4c05924_0016.jpg
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