Targeted release of live probiotics from alginate-based nanofibers in a simulated gastrointestinal tract†

RSC Applied Polymers Pub Date : 2024-05-21 DOI:10.1039/D4LP00023D

Emily Diep and Jessica D. Schiffman

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Abstract

Gut bacteria influence human health by digesting nutrients, modulating immune responses, and communicating with the nervous system. Orally delivered probiotics must survive the harsh environment of stomach acid to reach the gut microbiome and incur a health benefit. Here, the probiotic Lactococcus lactis was encapsulated via coaxial electrospinning into alginate-based nanofibers containing the antacid calcium carbonate. Though the high molecular weight polyethylene oxide was used to facilitate fiber formation, crosslinking the nanofibers in an aqueous solution allowed the polyethylene oxide to diffuse out of the nanofiber to form a safe for oral consumption formulation. The antacid protected the encapsulated living bacteria against acidic insults; thus, bacteria remained viable and encapsulated during submersion in a simulated stomach model. After transfer to the intestinal phase, up to 120 000 viable probiotic cells were released per gram of nanofibers demonstrating the pH-dependent delivery of the electrospun alginate nanofibers.

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藻酸盐纳米纤维在模拟胃肠道中定向释放活益生菌†.

肠道细菌通过消化营养物质、调节免疫反应以及与神经系统沟通来影响人体健康。口服益生菌必须在胃酸的恶劣环境中存活下来，才能进入肠道微生物群，为健康带来益处。在这里，益生菌乳酸乳球菌通过同轴电纺丝被封装到含有抗酸剂碳酸钙的藻酸盐基纳米纤维中。虽然高分子量聚氧化乙烯被用来促进纤维的形成，但在水溶液中交联纳米纤维可使聚氧化乙烯从纳米纤维中扩散出来，形成一种可安全口服的配方。抗酸剂能保护封装的活细菌免受酸性物质的侵袭；因此，细菌在模拟胃模型中浸泡期间仍能存活并被封装。在转移到肠道阶段后，每克纳米纤维释放出多达 12 万个活的益生菌细胞，这表明电纺海藻酸盐纳米纤维的递送受 pH 值的影响。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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RSC Applied Polymers

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