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Bacterial cellulose biosynthesis in the presence of raw moist olive pomace: A green sustainable approach that enhances biopolymer production and properties
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Advisor(s)
Abstract(s)
In this study, the biosynthesis of bacterial cellulose (BC) by Komagataeibacter intermedius strain isolated from
Kombucha tea in the presence of raw moist olive pomace (MOP) (concentration up to 40 % in the fermentation
media) was studied. The BC membranes were characterized by their antioxidant activity, structural character-
istics, crystallinity, thermal stability, and mechanical behavior. Using raw MOP activated the inherent activity of
the phenolic compounds, leading to cellular adaptation under unfavorable conditions and increased BC pro-
duction for all tested MOP concentrations (p < 0.0001). This led to a 166.61 % increase for the 20 % MOP group
compared to the control (HS medium). For this sample, enhanced antioxidant activity (~40-fold higher than the
control) was found, which might be associated with the molecular interactions established between hydroxyls of
BC and phenolic compounds. Moreover, an increase of 603.03 % in strain capacity, and a 376.01 % improvement
in stress at break compared to the control was observed. The study confirmed that BC can be synthesized using
MOP in its natural state, supporting a sustainable circular economy while enhancing the biosynthesis of a value-
added product. By reducing synthetic media and utilizing MOP, a greener bioprocess can be achieved, and BC’s
applicability can be expanded.
Description
Keywords
Bacterial stress Biopolymer Komagataeibacter intermedius Circular economy Sustainable alternativ
Pedagogical Context
Citation
Crugeira, Pedro; Khelifa, Halima; Barreira, Luísa Maria; Halla, Noureddine; Peres, António M.; Schreiner, Tatiana B.; Barreiro, Filomena; Rodrigues, Paula (2025). Bacterial cellulose biosynthesis in the presence of raw moist olive pomace: A green sustainable approach that enhances biopolymer production and properties. Biomass & Bioenergy. ISSN 0961-9534. 197, p. 1-7
Publisher
Elsevier