A uniaxially oriented nanofibrous cellulose scaffold from pellicles produced by Gluconacetobacter xylinus in dissolved oxygen culture

•Cellulose pellicle by G. xylinus in dissolved oxygen culture was capable of being stretched.•G. xylinus in dissolved oxygen culture produced the fewer and thinner nanofibers.•The nanofibers were highly crystalline, dominant with the metastable cellulose Iα.•The stretched nanofibrous film exhibited...

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Bibliographic Details
Published in:Carbohydrate polymers 2016-01, Vol.135, p.215-224
Main Authors: Nagashima, Aya, Tsuji, Tsubasa, Kondo, Tetsuo
Format: Article
Language:English
Subjects:
Cellulose - chemistry
Cellulose - metabolism
Crystallization
Culture Media
Culture using dissolved oxygen
Elasticity
Gluconacetobacter xylinus
Gluconacetobacter xylinus - metabolism
Humidity
Magnetic Resonance Spectroscopy
Microscopy, Electron, Scanning
Microscopy, Electron, Transmission
Nano-orientation
Nanofibers - chemistry
Nanofibers - ultrastructure
Nanofibrous film
Oxygen - metabolism
Spectroscopy, Fourier Transform Infrared
Stretchable nanocellulose pellicle
Tensile Strength
Viscosity
Wettability
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Summary:•Cellulose pellicle by G. xylinus in dissolved oxygen culture was capable of being stretched.•G. xylinus in dissolved oxygen culture produced the fewer and thinner nanofibers.•The nanofibers were highly crystalline, dominant with the metastable cellulose Iα.•The stretched nanofibrous film exhibited unique and anisotropic characteristics. An aerobic, Gram-negative bacterium, Gluconacetobacter xylinus, was successfully employed to produce a stretchable cellulose nanofiber pellicle using dissolved oxygen in a conventional cultured medium. The obtained nanofibers were highly crystalline with the metastable cellulose Iα phase being apparently the dominant phase by more than 90%. The obtained pellicle could be stretched by up to 1.5 times to provide oriented crystalline nanofibrous films. Low heating of the nanofibrous film induced the transformation of the dominant cellulose Iα crystalline phase into the Iβ crystalline phase without a loss of crystallinity or the high Young's modulus. The film also exhibited unique and anisotropic viscoelastic and mechanical properties as well as superior thermal stability compared with conventional high-performance synthetic polymeric materials. In addition, when G. xylinus cells were transferred to the oriented surface after stretched, they started to synthesize cellulose ribbons that parallel the nanofiber orientation of the substrate. This function as a template was evidenced by direct video imaging of the motion of the bacteria. The application of a bacterial culture using dissolved oxygen in the medium offers the fabrication of novel anisotropic and nanofibrous scaffold of cellulose Iα.
ISSN:0144-8617
1879-1344
DOI:10.1016/j.carbpol.2015.08.077