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Interfacial interactions between protective, surface-engineered shells and encapsulated bacteria with different cell surface composition

Hao Wei, Xiaoyu Yang, Wei Geng, Henny C. van der Mei, Henk J. Busscher

2021Nanoscale20 citationsDOIOpen Access PDF

Abstract

nanoparticles yielding a yolk-shell (weak-interaction across a void between shells and bacterial surfaces). The surface of probiotic Lactobacillus acidophilus was rich in protein, yielding a hydrophilic, positively-charged surface below and a negatively-charged one above pH 4.0. Probiotic Bifidobacterium infantis had a hydrophilic, uncharged surface, rich in polysaccharides with little proteins. Although amino groups are required for coordinate-covalent bonding of zinc and hydrogen bonding of alginate, both L. acidophilus and B. infantis could be encapsulated using ZIF-8 biomineralization and alginate gelation. Weakly, intermediately and strongly interacting shells all yielded porous shells. The strongly interacting ZIF-8 biomineralized shell made encapsulated bacteria more susceptible to antibiotics, presumably due to the cell wall damage already inflicted during Zif-8 biomineralization. Overall, weakly interacting yolk-shells and intermediately interacting alginate gels protected best and maintained probiotic activity of encapsulated bacteria. The impact of interfacial-interactions between shells and encapsulated bacteria on different aspect of protection described here, contributes to the further development of effective surface-engineered shells and its application for protecting bacteria.

Topics & Concepts

Surface (topology)Composition (language)Materials scienceBacteriaNanotechnologyChemical engineeringBiologyEngineeringMathematicsPhilosophyGeneticsLinguisticsGeometryProbiotics and Fermented FoodsBacteriophages and microbial interactionsProteins in Food Systems
Interfacial interactions between protective, surface-engineered shells and encapsulated bacteria with different cell surface composition | Litcius