Cholestatic drug‐induced liver injury (DILI) induced by drugs or other xenobiotics is a severe and even fatal clinical syndrome. Here, living materials of hierarchy‐assembled dual probiotics system are fabricated by sequentially encapsulating probiotic Lactobacillus delbrueckii subsp. bulgaricus (LDB) and Lactobacillus rhamnosus GG (LGG) into Ca2+‐complexed polymer microspheres for effective prevention of cholestatic DILI. Upon entering intestinal tract of the constructed living materials, LGG is released because of pH‐triggered dissolution of outer enteric polymer coating. The released LGG can inhibit hepatic bile acids (BAs) synthesis by activating intestinal farnesoid X receptor‐fibroblast growth factor 15(FGF‐15) signaling pathway. BAs excretion is also facilitated by LGG through increasing the abundance of bile salt hydrolase (BSH)‐active gut commensal bacteria. Furthermore, exposed positively‐charged chitosan shell can absorb the excessive BAs via electrostatic interaction, which leads to steady BAs fixation by the imprisoned LDB, decreasing the total BAs amounts in enterohepatic circulation. Together, the fabricated living materials, obtained here, can effectively prevent cholestatic DILI through dredging cholestasis via gut‐liver axis modulation. The therapeutic effect is demonstrated in α‐naphthylisothiocyanate and clinical antiepileptic drug valproate acid‐induced cholestatic DILI mouse models, which reveal the great potential for effective cholestatic DILI management.
Systematic administration of antibiotics to treat infections often leads to the rapid evolution and spread of multidrug‐resistant bacteria. Here, an in situ‐formed biotherapeutic gel that controls multidrug‐resistant bacterial infections and accelerates wound healing is reported. This biotherapeutic gel is constructed by incorporating stable microbial communities (kombucha) capable of producing antimicrobial substances and organic acids into thermosensitive Pluronic F127 (polyethylene‐polypropylene glycol) solutions. Furthermore, it is found that the stable microbial communities‐based biotherapeutic gel possesses a broad antimicrobial spectrum and strong antibacterial effects in diverse pathogenic bacteria‐derived xenograft infection models, as well as in patient‐derived multidrug‐resistant bacterial xenograft infection models. The biotherapeutic gel system considerably outperforms the commercial broad‐spectrum antibacterial gel (0.1% polyaminopropyl biguanide) in pathogen removal and infected wound healing. Collectively, this biotherapeutic strategy of exploiting stable symbiotic consortiums to repel pathogens provides a paradigm for developing efficient antibacterial biomaterials and overcomes the failure of antibiotics to treat multidrug‐resistant bacterial infections.
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