Gabriela Martins de Paiva, Fernanda Palladino, Edson Romano Nucci, Alan Rodrigues Teixeira Machado, Carlos Augusto Rosa, Igor José Boggione Santos
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Therefore, the present work aims to statically produce BNC using waste from the brewing industry and use BNC as an adsorbent for treating waste from the mining industry. It was possible to obtain approximately 1532 mg of bacterial nanocellulose through the batch system using the hydrolyzate of residual brewing yeast at pH 7 and 5 days of incubation. When used as an adsorbent, the material obtained a maximum adsorption capacity for the metals Co (II), Ni (II), Cu (II) and Fe (III) of, respectively, 0.0739, 0.2504, 0.3945 and 0.02841 mg·g<sup>−1</sup>. For the same metals, the removal rate of the synthetic solutions studied was, respectively, 62.56, 39.13, 61.64 and 24.42%. For the analysis of isotherms, the Freundlich model proved to be the most effective for describing the system. Regarding the adsorption kinetics, it was more effective in the Elovich model. This data shows that nanocellulose produced by bacteria and using agro-industrial subproducts becomes a good alternative for remediation processes in a sustainable way.</p></div>","PeriodicalId":659,"journal":{"name":"Journal of Polymers and the Environment","volume":"32 12","pages":"6803 - 6819"},"PeriodicalIF":4.7000,"publicationDate":"2024-09-10","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Bacterial Nanocellulose Produced as a By-product of the Brewing Industry and Used as an Adsorbent for Synthetic Solutions of Co(II), Cu(II), Ni(II) AND Fe(III)\",\"authors\":\"Gabriela Martins de Paiva, Fernanda Palladino, Edson Romano Nucci, Alan Rodrigues Teixeira Machado, Carlos Augusto Rosa, Igor José Boggione Santos\",\"doi\":\"10.1007/s10924-024-03389-0\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<div><p>An economically and environmentally viable alternative for treating waste from iron ore production in Brazil is the use of bacterial nanocellulose (BNC) as an adsorbent for the metals present in the waste composition, due to its biocompatibility and biodegradability properties. However, to reduce production costs, it is necessary to study alternative substrates, such as waste from the brewing industry, which are nutritionally rich and, therefore, excellent candidates for substrate for bacteria that produce bacterial nanocellulose. Therefore, the present work aims to statically produce BNC using waste from the brewing industry and use BNC as an adsorbent for treating waste from the mining industry. It was possible to obtain approximately 1532 mg of bacterial nanocellulose through the batch system using the hydrolyzate of residual brewing yeast at pH 7 and 5 days of incubation. When used as an adsorbent, the material obtained a maximum adsorption capacity for the metals Co (II), Ni (II), Cu (II) and Fe (III) of, respectively, 0.0739, 0.2504, 0.3945 and 0.02841 mg·g<sup>−1</sup>. For the same metals, the removal rate of the synthetic solutions studied was, respectively, 62.56, 39.13, 61.64 and 24.42%. For the analysis of isotherms, the Freundlich model proved to be the most effective for describing the system. Regarding the adsorption kinetics, it was more effective in the Elovich model. 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引用次数: 0
摘要
细菌纳米纤维素(BNC)具有生物相容性和生物可降解性,是处理巴西铁矿石生产废料的一种经济和环保可行的替代方法,可作为废料成分中金属的吸附剂。然而,为了降低生产成本,有必要研究其他基质,如酿造业产生的废物,这些废物营养丰富,因此是生产细菌纳米纤维素的细菌基质的极佳候选物。因此,本研究旨在利用酿造业废料静态生产 BNC,并将 BNC 用作处理采矿业废料的吸附剂。在 pH 值为 7 和培养 5 天的条件下,利用残留酿造酵母的水解物,通过批处理系统可获得约 1532 毫克的细菌纳米纤维素。该材料用作吸附剂时,对金属 Co (II)、Ni (II)、Cu (II) 和 Fe (III) 的最大吸附容量分别为 0.0739、0.2504、0.3945 和 0.02841 mg-g-1。对于相同的金属,合成溶液的去除率分别为 62.56%、39.13%、61.64% 和 24.42%。在分析等温线时,事实证明 Freundlich 模型对系统的描述最为有效。在吸附动力学方面,Elovich 模型更为有效。这些数据表明,利用细菌和农用工业副产品生产的纳米纤维素是可持续修复过程的良好替代品。
Bacterial Nanocellulose Produced as a By-product of the Brewing Industry and Used as an Adsorbent for Synthetic Solutions of Co(II), Cu(II), Ni(II) AND Fe(III)
An economically and environmentally viable alternative for treating waste from iron ore production in Brazil is the use of bacterial nanocellulose (BNC) as an adsorbent for the metals present in the waste composition, due to its biocompatibility and biodegradability properties. However, to reduce production costs, it is necessary to study alternative substrates, such as waste from the brewing industry, which are nutritionally rich and, therefore, excellent candidates for substrate for bacteria that produce bacterial nanocellulose. Therefore, the present work aims to statically produce BNC using waste from the brewing industry and use BNC as an adsorbent for treating waste from the mining industry. It was possible to obtain approximately 1532 mg of bacterial nanocellulose through the batch system using the hydrolyzate of residual brewing yeast at pH 7 and 5 days of incubation. When used as an adsorbent, the material obtained a maximum adsorption capacity for the metals Co (II), Ni (II), Cu (II) and Fe (III) of, respectively, 0.0739, 0.2504, 0.3945 and 0.02841 mg·g−1. For the same metals, the removal rate of the synthetic solutions studied was, respectively, 62.56, 39.13, 61.64 and 24.42%. For the analysis of isotherms, the Freundlich model proved to be the most effective for describing the system. Regarding the adsorption kinetics, it was more effective in the Elovich model. This data shows that nanocellulose produced by bacteria and using agro-industrial subproducts becomes a good alternative for remediation processes in a sustainable way.
期刊介绍:
The Journal of Polymers and the Environment fills the need for an international forum in this diverse and rapidly expanding field. The journal serves a crucial role for the publication of information from a wide range of disciplines and is a central outlet for the publication of high-quality peer-reviewed original papers, review articles and short communications. The journal is intentionally interdisciplinary in regard to contributions and covers the following subjects - polymers, environmentally degradable polymers, and degradation pathways: biological, photochemical, oxidative and hydrolytic; new environmental materials: derived by chemical and biosynthetic routes; environmental blends and composites; developments in processing and reactive processing of environmental polymers; characterization of environmental materials: mechanical, physical, thermal, rheological, morphological, and others; recyclable polymers and plastics recycling environmental testing: in-laboratory simulations, outdoor exposures, and standardization of methodologies; environmental fate: end products and intermediates of biodegradation; microbiology and enzymology of polymer biodegradation; solid-waste management and public legislation specific to environmental polymers; and other related topics.