Polysaccharide Hydrogels for the Protection of Dairy-Related Microorganisms in Adverse Environmental Conditions.
Ilja Gasan Osojnik ČrnivecTigran NeresyanYuliana GatinaVid Kolmanič BučarMihaela SkrtIztok DogsaBojana Bogovič MatijašićIrina KulikovaAleksei LodyginNatasa Poklar UlrihPublished in: Molecules (Basel, Switzerland) (2021)
Adverse environmental conditions are severely limiting the use of microorganisms in food systems, such as probiotic delivery, where low pH causes a rapid decrease in the survival of ingested bacteria, and mixed-culture fermentation, where stepwise changes and/or metabolites of individual microbial groups can hinder overall growth and production. In our study, model probiotic lactic acid bacteria ( L. plantarum ATCC 8014, L. rhamnosus GG) and yeasts native to dairy mixed cultures ( K. marxianus ZIM 1868) were entrapped in an optimized (cell, alginate and hardening solution concentration, electrostatic working parameters) Ca-alginate system. Encapsulated cultures were examined for short-term survival in the absence of nutrients (lactic acid bacteria) and long-term performance in acidified conditions (yeasts). In particular, the use of encapsulated yeasts in these conditions has not been previously examined. Electrostatic manufacturing allowed for the preparation of well-defined alginate microbeads (180-260 µm diameter), high cell-entrapment (95%) and viability (90%), and uniform distribution of the encapsulated cells throughout the hydrogel matrix. The entrapped L. plantarum maintained improved viabilities during 180 min at pH 2.0 (19% higher when compared to the free culture), whereas, L. rhamnosus appeared to be less robust. The encapsulated K. marxianus exhibited double product yields in lactose- and lactic acid-modified MRS growth media (compared to an unfavorable growth environment for freely suspended cells). Even within a conventional encapsulation system, the pH responsive features of alginate provided superior protection and production of encapsulated yeasts, allowing several applications in lacto-fermented or acidified growth environments, further options for process optimization, and novel carrier design strategies based on inhibitor charge expulsion.
Keyphrases
- lactic acid
- induced apoptosis
- wound healing
- tissue engineering
- saccharomyces cerevisiae
- cell cycle arrest
- single cell
- oxidative stress
- cell therapy
- emergency department
- microbial community
- stem cells
- molecular dynamics simulations
- heavy metals
- ms ms
- bone marrow
- signaling pathway
- hyaluronic acid
- adverse drug
- climate change
- sensitive detection
- water soluble