Resistant starch (RS) reduces or delays the digestion of carbohydrates and glucose synthesis, thereby lowering postprandial blood glucose levels. The wheat starch-Lonicera caerulea berry polyphenols (WS-LCBP) complex was constructed using high hydrostatic pressure (HHP). The effects of intragastric administration of WS or WS-LCBP on blood glucose in T2DM model mice. RS in the composite preparation formed by HHP and 10 % LCBP at 600 MPa for 30 min increased from 7.65 % to 49.66 %. WS-LCBP formed an A + V-type crystal structure of the polyhydroxyl non-inclusion complex, which hindered the digestion of WS into glucose. Compared with LCBP intake, which caused 8.3 % reduction in 2-h postprandial blood glucose (p < 0.05), Homeostatic model assessment for insulin resistance demonstrated a 35.3 % decrease (p < 0.001) with WS-LCBP administration. Western blotting demonstrated that exposure to WS-LCBP activated the GLP-1R/PI3K/AKT signaling pathway in the liver tissue of T2DM mice, reducing insulin resistance. Furthermore, the concentration of short-chain fatty acids was markedly elevated. The structure and abundance of the intestinal flora were enhanced. The WS-LCBP complex demonstrated a more pronounced improvement than LCBP supplementation alone. This study offers a novel perspective and theoretical foundation for the regulation of postprandial blood glucose levels by polyphenol starch-based food biomacromolecules and their potential applications in starchy foods.
Keywords: Intestinal microbiota; Postprandial blood glucose; Short-chain fatty acids; Starch-polyphenol complex; T2DM.
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