Abstract
Improving the proliferation of probiotics (ca. Bifidobacterium) and inhibiting the growth of pathogenic bacteria (ca. Escherichia coli) is crucial for human health. This study demonstrates the fabrication of core–shell structure fibers using electrohydrodynamic 3D printing to help improve gastrointestinal tract microbial content. These fibers have various geometries and are capable of encapsulating stachyose into cellulose acetate (shell layer) and loading proteoglycan into polyacrylic resin II (core layer). The impact of membrane geometry on drug release behavior and the effect of exchanging the loading site on physicochemical properties of the resulting fibers were studied. The printed fibrous membranes possess a biphasic drug release profile in simulated intestinal fluid with a burst release within the first 12 h and a slower sustained release up to 72 h. The speed order priority for drug release rate of the printed membrane was whole-circle > semi-circle > square. Moreover, the membranes exhibit good biocompatibility on L929 cells and excellent improvement effects on Bifidobacterium bifidum, combining inhibition effects on Escherichia coli. In summary, the dual-drug fibrous membranes presented here and their precision-fabricated patterns pave a new direction for improving the gastrointestinal tract microbial ecosystem health in the human body.
Highlights
The gastrointestinal tract is a complex microbial ecosystem and crucial for maintaining human health [1]
Morphology assessment of drug-loading membrane polyacrylic resin II (PRII) has been used in tablets [30], the encapsulation of polyacrylic resin into core–shell fibers is still challenge
The printed fibers with core–shell structure can be observed via optical microscopy by replacing PRO with Rhodamine B into loaded PRII-core layer, as shown in figure 2(a), confirming core/shell structure existing
Summary
The gastrointestinal tract is a complex microbial ecosystem and crucial for maintaining human health [1]. The tract comprises a trillion microbial cells across approximately 1000 species [2]. These cells colonize in the gut in a naturally commensal way [3]. The gastrointestinal microbiota can provide a source of energy for biogenesis [5] and biosynthesize vitamins [6], but it can provide essential nutrients and promote digestion of cellulose and angiogenesis [1]. The gastrointestinal microbiota can be potentially harmful to the host when the gastrointestinal microbial ecosystem undergoes abnormal changes-symbiosis, resulting in obesity, allergies, diabetes, bowel inflammation, and even cancer [7, 8]. Only in a harmonious symbiotic relationship can the host’s well-being be offered from gastrointestinal microbiota
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