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Static Culture Combined with Aeration in Biosynthesis of Bacterial Cellulose.

Nadezhda A ShavyrkinaEkaterina A SkibaAnastasia E KazantsevaEvgenia K GladyshevaVera V BudaevaNikolay V BychinYulia A GismatulinaEkaterina I KashcheyevaGalina F MironovaAnna A KorchaginaIgor N PavlovGennady V Sakovich
Published in: Polymers (2021)
One of the ways to enhance the yield of bacterial cellulose (BC) is by using dynamic aeration and different-type bioreactors because the microbial producers are strict aerobes. But in this case, the BC quality tends to worsen. Here we have combined static culture with aeration in the biosynthesis of BC by symbiotic Medusomyces gisevii Sa-12 for the first time. A new aeration method by feeding the air onto the growth medium surface is proposed herein. The culture was performed in a Binder-400 climate chamber. The study found that the air feed at a rate of 6.3 L/min allows a 25% increase in the BC yield. Moreover, this aeration mode resulted in BC samples of stable quality. The thermogravimetric and X-ray structural characteristics were retained: the crystallinity index in reflection and transmission geometries were 89% and 92%, respectively, and the allomorph Iα content was 94%. Slight decreases in the degree of polymerization (by 12.0% compared to the control-no aeration) and elastic modulus (by 12.6%) are not critical. Thus, the simple aeration by feeding the air onto the culture medium surface has turned out to be an excellent alternative to dynamic aeration. Usually, when the cultivation conditions, including the aeration ones, are changed, characteristics of the resultant BC are altered either, due to the sensitivity of individual microbial strains. In our case, the stable parameters of BC samples under variable aeration conditions are explained by the concomitant factors: the new efficient aeration method and the highly adaptive microbial producer-symbiotic Medusomyces gisevii Sa-12.
Keyphrases
  • microbial community
  • magnetic resonance imaging
  • climate change
  • wastewater treatment
  • mass spectrometry
  • dual energy
  • cell wall