Using <i>in situ</i> nanocellulose‐coating technology based on dynamic bacterial cultures for upgrading conventional biomedical materials and reinforcing nanocellulose hydrogels

Zhang, Peng; Lin, Chao; Zhang, Qingsong; Jönsson, Leif J.; Hong, Feng

doi:10.1002/btpr.2280

Cited by 12 publications

(6 citation statements)

References 32 publications

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“…Biomedical sector -Further current developments in the BNC field mainly concern novel carrier materials for cell cultivation [122,137,138], encapsulation of cells/immobilization of enzymes [139], coating of medical devices [140], and the production of BNC materials using the well-known oxygen-transparent silicone supports [141,142]. In case of medical implants a lot of results is reported not only in the field of soft tissue implants (see Section In vivo scaffolds) but also regarding materials for bone regeneration [121,143,144].…”

Section: Recent Developments In Bnc Materialsmentioning

confidence: 99%

“…Using an in situ nanocellulose-coating technology based on dynamic bacterial cultures, Zhang et al [140] upgraded conventional biomedical materials, i.e., medical cotton gauze or other mesh materials. This fabric-reinforced BNC hydrogel was equivalent in gel characteristics of native BNC, and exhibited a qualitative improvement with regard to its mechanical properties.…”

Section: Recent Developments In Bnc Materialsmentioning

confidence: 99%

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Nanocellulose as a natural source for groundbreaking applications in materials science: Today’s state

et al. 2018

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Nanocelluloses are natural materials with at least one dimension in the nano-scale. They combine important cellulose properties with the features of nanomaterials and open new horizons for materials science and its applications. The field of nanocellulose materials is subdivided into three domains: biotechnologically produced bacterial nanocellulose hydrogels, mechanically delaminated cellulose nanofibers, and hydrolytically extracted cellulose nanocrystals. This review article describes today's state regarding the production, structural details, physicochemical properties, and innovative applications of these nanocelluloses. Promising technical applications including gels/foams, thickeners/stabilizers as well as reinforcing agents have been proposed and research from last five years indicates new potential for groundbreaking innovations in the areas of cosmetic products, wound dressings, drug carriers, medical implants, tissue engineering, food and composites. The current state of worldwide commercialization and the challenge of reducing nanocellulose production costs are also discussed.

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Section: Recent Developments In Bnc Materialsmentioning

confidence: 99%

Section: Recent Developments In Bnc Materialsmentioning

confidence: 99%

Nanocellulose as a natural source for groundbreaking applications in materials science: Today’s state

et al. 2018

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“…It has been reported that K. xylinus cells accumulate at the air/liquid interface (Tang et al , ), and the liquid phase that is far away from air might contain less oxygen, causing fewer cells to be distributed in the liquid phase. In the cellulose membrane, the living cells also have non‐uniform distribution in the vertical direction, where living cells mainly distribute in the shallow outer region of BNC membrane that is close to the air/oxygen, while in the deep inner region living cells can hardly be observed (Tang et al , ; Zhang et al , ). The limitation of this work is that the current living cell results are only relevant to the free cells suspended in the liquid phase.…”

Section: Resultsmentioning

confidence: 99%

Determination of live and dead Komagataeibacter xylinus cells and first attempt at precise control of inoculation in nanocellulose production

Zou

Zhang

Chen

et al. 2019

Microbial Biotechnology

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Summary The timely enumeration of cells of nanocellulose‐producing bacteria is challenging due to their unique growth properties. To better understand the metabolism of the bacteria and better control the concentration of living cells during cultivation, a prompt cell counting technology is crucial and urgently required. In this work, two fluorescent dyes, the asymmetrical anthocyanidin dye SYBR Green I (SG) and propidium iodide (PI), were first combined for Komagataeibacter xylinus species to determine live/dead bacterial cells quantitatively and promptly. The number of live and dead K. xylinus cells determined using an epifluorescence microscope corresponded well to the results obtained using a fluorescence microplate reader. The R2 values were 0.9986 and 0.9920, respectively, and were similar to those obtained with the LIVE/DEAD® BacLightTM commercial kit. SG/PI double‐staining showed proper efficiency in distinguishing live/dead cells for the K. xylinus strain (R2 = 0.9898). The technology was applied to standardize four different K. xylinus strains, and the initial cell concentration of the strains was precisely controlled (no significant difference among the strains, P> 0.05). The cellulose yield per live cell was calculated, and significant differences (P < 0.05) were found among the four strains in the following order: DHU‐ATCC‐1> DHU‐ZCY‐1> DHU‐ZGD‐1> ATCC 23770. The study shows (i) the application of the SG/PI staining to standardizing inocula for bacterial cellulose production so that a more accurate comparison can be made between different strains, and (ii) the lower cost of using SG rather than the SYTO 9 of the commercially available LIVE/DEAD® BacLightTM kit.

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“…RDB can also be applied to the material coating. Zhang [58] used a roller-equipped horizontal bioreactor for in situ coating of cotton gauzes with BC, which also allowed cotton to act as an adequate material for K. xylinus culture, as porous matrices are more suitable for bacteria immobilization in RDB. Faster and higher productivity was observed when compared to static culture, with RDB-BC showing 2.61 mm sheets of BC and 1.62 g L À1 of BC in 3 days against 2.34 mm and 1.49 g L À1 of BC in 10 days in static culture.…”

Section: Rotating Disk Bioreactormentioning

confidence: 99%

“…[ [48][49][50][51][52][53]55] Vascular Grafts Water holding capacity, elasticity, biocompatibility or low inflammatory, makes BC a suitable material for artificial blood vessels. [57,58] Food applications Emulsion stabilizer BC NPs act as an oil-in-water emulsion stabilizer. [ [ 83,84] Energy production Bioethanol BC use as an alternative to lignocellulose from plants.…”

Section: Type Description Referencementioning

confidence: 99%

Current progress on the production, modification, and applications of bacterial cellulose

Blanco

Santoso

Chou

et al. 2020

Critical Reviews in Biotechnology

166

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Adoption of biomass for the development of biobased products has become a routine agenda in evolutionary metabolic engineering. Cellulose produced by bacteria is a "rising star" for this sustainable development. Unlike plant cellulose, bacterial cellulose (BC) shows several unique properties like a high degree of crystallinity, high purity, high water retention, high mechanical strength, and enhanced biocompatibility. Favored with those extraordinary properties, BC could serve as ideal biomass for the development of various industrial products. However, a low yield and the requirement for large growth media have been a persistent challenge in mass production of BC. A significant number of techniques has been developed in achieving efficient BC production. This includes the modification of bioreactors, fermentation parameters, and growth media. In this article, we summarize progress in metabolic engineering in order to solve BC growth limitation. This article emphasizes current engineered BC production by using various bioreactors, as well as highlighting the structure of BC fermented by different types of engineered-bioreactors. The comprehensive overview of the future applications of BC, aims to provide readers with insight into new economic opportunities of BC and their modifiable properties for various industrial applications. Modifications in chemical composition, structure, and genetic regulation, which preceded the advancement of BC applications, were also emphasized.

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Using in situ nanocellulose‐coating technology based on dynamic bacterial cultures for upgrading conventional biomedical materials and reinforcing nanocellulose hydrogels

Cited by 12 publications

References 32 publications

Nanocellulose as a natural source for groundbreaking applications in materials science: Today’s state

Nanocellulose as a natural source for groundbreaking applications in materials science: Today’s state

Determination of live and dead Komagataeibacter xylinus cells and first attempt at precise control of inoculation in nanocellulose production

Current progress on the production, modification, and applications of bacterial cellulose

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