Litcius/Paper detail

Novel pectin-carboxymethylcellulose-based double-layered mucin/chitosan microcomposites successfully protect the next-generation probiotic Akkermansia muciniphila through simulated gastrointestinal transit and alter microbial communities within colonic ex vivo bioreactors

Linh Phuong Ta, Sarah Corrigan, Richard D. Horniblow

2024International Journal of Pharmaceutics11 citationsDOIOpen Access PDF

Abstract

• Novel hydrogel microcomposites were developed for A.muciniphila encapsulation. • Entrapment Deposition by Prilling enables encapsulation of surface-layered bacteria. • A.muciniphila is protected throughout simulated GI conditions. • Delivered A.muciniphila alters microbial composition in an ex vivo gut model. • Bacterial surface immobilisation represents a new approach for mucosal bacteria delivery. The rapid acceleration of microbiome research has identified many potential Next Generation Probiotics (NGPs). Conventional formulation processing methods are non-compatible, leading to reduced viability and unconfirmed incorporation into intestinal microbial communities; consequently, demand for more bespoke formulation strategies of such NGPs is apparent. In this study, Akkermansia muciniphil a ( A.muciniphila ) as a candidate NGP was investigated for its growth and metabolism properties, based on which a novel microcomposite-based oral formulation was formed. Initially, a chitosan-based microcomposite was coated with mucin to establish a surface culture of A.muciniphila. This was followed by ‘double encapsulation’ with pectin (PEC) using a novel Entrapment Deposition by Prilling method to create core–shell double-encapsulated microcapsules. The formulation of A.muciniphila was verified to require no oxygen-restriction properties, and additionally, biopolymers were selected, including carboxymethylcellulose (CMC), that support and enhance its growth; consequently, a high viability (6 log CFU/g) of A.muciniphila microencapsulated in PEC-CMC double-encapsulates was obtained. Subsequently, the high stability of the PEC-CMC double-encapsulates was verified in simulated gastric fluid, successfully protecting and then releasing the A.muciniphila under intestinal conditions. Finally, employing a model of gastrointestinal transit and faecal-inoculated colonic bioreactors, significant alterations in microbial communities following administration and successful establishment of A.muciniphila were demonstrated .

Topics & Concepts

Akkermansia muciniphilaProbioticEx vivoPectinMucinChitosanBioreactorGastrointestinal transitChemistryFood scienceMicrobiologyIn vivoBiochemistryGut floraBiologyBacteriaIn vitroBiotechnologyMedicineOrganic chemistryGeneticsGastroenterologyProbiotics and Fermented FoodsGut microbiota and healthInfant Nutrition and Health