Design and development of chromene-3-carboxylate derivatives as antidiabetic agents: Exploring the antidiabetic potential via dual inhibition of angiotensin II type 1 receptor and neprilysin enzyme

Diabetes mellitus, particularly type II diabetes mellitus, is a metabolic condition that has a substantial impact on the health of individuals. The implication of diabetes with increased risk of cardiovascular diseases (CVD) and, consequently, myocardial infarction is well established. However, developing new antidiabetic drugs with an established efficacy on cardiovascular health is an underdeveloped area of research. To address this, in the present study, a new series of chromene-3-carboxylate derivatives (1B1–1B22) as dual inhibitors of Angiotensin II Type 1 Receptor (AT1R) and Neprilysin (NEP), which are recognized targets in diabetes with CVD, is reported. The compounds were rationally designed and synthesized, considering the pharmacophoric features of these two targets. The evaluation was performed via glucose uptake, α-amylase, AT1R, and NEP inhibition assay. The derivatives were found to increase glucose uptake and inhibit all three targets, of which compound 1B15 was the most active. The most active compound, 1B15, reduced the oxidative stress and restored the mitochondrial membrane potential. The biological findings were further corroborated by in silico studies, which included molecular modelling and dynamics. It was deduced that 1B15 remains unionized in acidic to weak basic pH and may be passively absorbed. Further, the molecule was found to undergo hydroxylation as a means of Phase I metabolism and glucuronic conjugation in Phase II. The wet lab experiments on 1B15 further validated the in-silico absorption and metabolism prediction. The compounds, particularly 1B15, could be explored further as a lead for its utility as an antidiabetic with profound implications on cardiovascular health.