Biossíntese e recentes avanços na produção de celulose bacteriana

Donini, Ígor Augusto Negri; Salvi, Denise Toledo Bonemer De; Fukumoto, Fabiana Keiko; Lustri, Wilton R.; Barud, Hernane da Silva; Marchetto, Reinaldo; Messaddeq, Younès; Ribeiro, Sidney José Lima

doi:10.26850/1678-4618eqj.v35.4.2010.p165-178

Cited by 13 publications

(12 citation statements)

References 19 publications

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“…Fourier Transform Infrared (FTIR) spectra of microbial cellulose textiles before (MC) and after lecithin tanning (LT). Inset: schematic depiction of proposed cross-linking mechanism with phosphate, methylene and carboxyl group bridges (left to right) for LT. 9); indigo after one (9), three (10) and six (11) dips; (12) brown color removed by 0.5 M NaOH soak; black created by chemical interaction of tannic acid from black tea with iron acetate, extracted from discarded nails (13); and myrobalan overdyed with logwood and dipped in iron acetate (14); (15)(16) as-fabricated MC treated with texture created by application of soy wax heated to 80C. Control of color modulation through: Shibori/Adire folding techniques (17); and partial submergence of biotextile in indigo vat (18).…”

Section: Conclusion and Future Outlookmentioning

confidence: 99%

“…Importantly, MC can offer a rapidly renewable raw material for textiles while eliminating the land, water and chemicals usage of production of agricultural (13) and wood pulp cellulose (14). For instance, the amount of cellulose produced by eucalyptus in a 10,000 m 2 area of land over 7 years could be achieved at higher purity by microbial fermentation in a 500 m 3 bioreactor in 22 days (15). However, like many naturally occurring biopolymers, including the aforementioned biobased leather alternatives, the hygroscopicity of as-fabricated MC results in a brittleness that hinders translation to textile applications (16).…”

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Microbial Nanocellulose Biotextiles for a Circular Materials Economy

Schiros

Antrobus

Farías

et al. 2021

Preprint

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Harnessing microbial biofabrication and inspired by indigenous practices, we engineer high-performance microbial nanocellulose (MC) biotextiles with a sustainable circular life cycle. Specifically, our plant-based lecithin phosphocholine treatment modulates cellulose cross-linking through phosphate and methylene groups, to yield a biodegradable material with superior mechanical and flame-retardant properties. Coloration is achieved using natural dyes and waste-to-resource strategies. Life cycle impact assessment reveals MC biotextiles mitigate the carcinogenics of leather by a factor of 103 and the carbon footprint of synthetic leather and cotton by ~97%, for widespread application in fashion, interiors, and construction. The translational potential of this approach is tremendous, as using microbes and green chemistry to engineer regenerative, high-performance products will disrupt linear production models and mitigate its environmental threats in a circular economy.

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Section: Conclusion and Future Outlookmentioning

confidence: 99%

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confidence: 99%

Microbial Nanocellulose Biotextiles for a Circular Materials Economy

Schiros

Antrobus

Farías

et al. 2021

Preprint

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“…A celulose vegetal pode ser classificada como um biopolímero, por se tratar de um polímero extraído de fontes naturais renováveis (PEREIRA et al, 2013;AIROLDI et al, 2008). Além disso, é o polímero natural mais abundante do planeta, sendo um dos constituintes da maior parte da biomassa das plantas, situado na parede celular vegetal (DONINI et al, 2010).…”

Section: Introductionunclassified

“…Uma alternativa é a síntese de celulose por meio de bactérias. A celulose bacteriana, em oposição à celulose vegetal, não apresenta contaminação pelos polissacarídeos lignina e hemicelulose, tornando os métodos de isolamento destes desnecessários, possibilitando a economia de energia envolvida nos processos e descartando tratamentos químicos mais complexos (DONINI et al, 2010).…”

Section: Introductionunclassified

Biosynthesis and Characterization of Bacterial Cellulose From the Kombucha Tea

Alves¹,

Beverari²,

Florentino³

et al. 2019

PTQ

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Cellulose is an important biopolymer, used as a raw material for different industrial applications. This represents the most abundant natural polymer on the planet, because it is present as the constituent of most of the biomass of the plants, located in the plant cell wall. With the technological advance, different alternatives different alternatives to develop this material in a sustainable and productive way are searched, one of them is the production of cellulose from microbial metabolism. Kombucha consists of a broth fermented from a symbiotic association between bacteria and yeasts capable of producing bacterial cellulose (CB). The obtained cellulose was treated with water and with NaOH, and through Scanning Electron Microscopy (SEM), we observed greater preservation in the integrity of the fiber in the treatment with water. This was confirmed in the filtration test where the CB (H2O) presented a reduction of 82.8% in the microbial population of the water coming from a stream, followed by 47.9% in the CB (NaOH). Infrared spectrometry (FT-IR) revealed a subtle difference between the two treatments, while the tensile test showed that the alkaline treatment reduces the resistance limit of the fiber by more than 2 times. Based on the results obtained we can assess that the cellulose obtained from kombucha has interesting characteristics for commercial use in several segments as use in human grafts to coat the skin and as a filter for retention of biological particles Indoors as airplanes and even hospital use to contain the dissemination of pathogens.

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“…However, only in 2003, after the patents arising from this study were licensed to the Xylos Corporation, the XCell® product started to be manufactured and comercialized for the treatment of wounds (Sindhu et al, 2014). In Brazil, the main producer of cellulose membranes for treatment of wounds and skin burns is the company Bionext Biotechnological Products Ltd. (Donini et al, 2010). Besides Brazil, there are several companies in Canada, the United States and Japan, manufacturing e selling BC products for biomedical purposes (Sindhu et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

Bacterial Cellulose Production by Komagataeibacter hansenii ATCC 23769 Using Sisal Juice - An Agroindustry Waste

Lima

Nascimento

Andrade

et al. 2017

Braz. J. Chem. Eng.

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-In this study, we have optimized production of bacterial cellulose (BC) by Komagataeibacter hansenii ATCC 23769 in a static cultivation using sisal juice, an agroindustrial residue, as substrate. Optimization of fermentation parameters has been carried out using the one-variable-at-a-time method. Effect of initial sugar concentration, pH, nitrogen supplement, and cultivation time was evaluated. The influence of nitrogen source and quantity for bacterial cellulose production was studied using a central composite rotational design (CCRD).The highest production of BC (3.38 g/L) was obtained after 10 days of cultivation, using sisal juice (pH 5) at 15 g/L of sugars and supplemented with 7.5 g/L of extract yeast. The cellulose production yield in selected sisal culture conditions was three times higher than the yield in synthetic medium, indicating that sisal juice is a suitable substrate for BC production.

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Biossíntese e recentes avanços na produção de celulose bacteriana

Cited by 13 publications

References 19 publications

Microbial Nanocellulose Biotextiles for a Circular Materials Economy

Microbial Nanocellulose Biotextiles for a Circular Materials Economy

Biosynthesis and Characterization of Bacterial Cellulose From the Kombucha Tea

Bacterial Cellulose Production by Komagataeibacter hansenii ATCC 23769 Using Sisal Juice - An Agroindustry Waste

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