Lowering the predicted glycemic index of pasta using dried onions as functional ingredients

Reduced Predicted Glycaemic Response and Inhibitory Effects on Lipid-Digesting Enzymes of Pasta Enriched With Flour of Malus domestica "Annurca cv." Pulp or Peel

Pasta is widely consumed, and incorporating certain components can transform it into a functional food with health advantages. These components include antioxidants, dietary fiber, and enzyme inhibitors associated with a decreased risk of various health issues. The Malus domestica variety Annurca is abundant in bioactive compounds, making it a suitable candidate for producing functional foods. We developed durum wheat tagliatelle enriched with dried and powdered Annurca pulp or peels at two distinct supplementation levels (3% and 6%) on a laboratory scale. The in vitro ability to inhibit digestive enzymes and the predicted glycaemic value of the enriched pasta were evaluated. Every formulation demonstrated inhibition of α-amylase, α-glucosidase, cholesterol esterase, and lipase in vitro. All the samples exhibited a low predicted glycaemic index (pGI), ranging from 41.25 to 45.76. These low pGI values indicate that fortified pasta has a lower impact on blood sugar levels and a slower digestion rate. The predicted glycaemic indices for pasta enriched with 3% or 6% pulp flour were 18.7% and 26.7% lower, respectively, than those for control pasta with durum wheat semolina alone. The reductions were similar for peel-enriched pasta at 3% and 6% (24.4% and 24.7%, respectively). Our in vitro results indicate that Annurca apple-fortified pasta has lipid- and glucose-lowering effects. Adding Annurca fruit flour with valuable and functional compounds could be relevant for obtaining pasta with potential health benefits.

Macromolecular, thermal, and nonthermal technologies for reduction of glycemic index in food-A review

Consumers rely on product labels to make healthy choices, especially with regard to the glycemic index (GI) and glycemic load (GL), which identify foods that stabilize blood sugar. Employing both thermal and nonthermal processing techniques can potentially reduce the GI, contributing to improved blood sugar regulation and overall metabolic health. This study concentrates on the most current advances in GI-reduction food processing technologies. Food structure combines fiber, healthy fats, and proteins to slow digestion, reducing GI. The influence of thermal approaches on the physical and chemical modification of starch led to decreased GI. The duration of heating and the availability of moisture also determine the degree of hydrolysis of starch and the glycemic effects on food. At a lower temperature, the parboiling revealed less gelatinization and increased moisture. The internal temperature of the product is raised during thermal and nonthermal treatment, speeds up retrogradation, and reduces the rate of starch breakdown.