Fasting Glucagon Concentrations Are Associated with Longitudinal Decline of β-cell Function in Non-diabetic Humans

Overview

Journal Metabolism

Specialty Endocrinology

Date 2020 Feb 12

PMID 32045582

Citations 11

Authors

Jon D Adams

Chiara Dalla Man

Marcello C Laurenti

M Daniela Hurtado Andrade

Claudio Cobelli

Robert A Rizza

Kent R Bailey

Adrian Vella

Affiliations

Soon will be listed here.

Abstract

Purpose: Abnormal glucagon concentrations are a feature of prediabetes but it is uncertain if α-cell dysfunction contributes to a longitudinal decline in β-cell function. We therefore sought to determine if a decline in β-cell function is associated with a higher nadir glucagon in the postprandial period or with higher fasting glucagon.

Methods: This was a longitudinal study in which 73 non-diabetic subjects were studied on 2 occasions 6.6 ± 0.3 years apart using a 2-hour, 7-sample oral glucose tolerance test. Disposition Index (DI) was calculated using the oral minimal model applied to the measurements of glucose, insulin, C-peptide concentrations during the studies. We subsequently examined the relationship of glucagon concentrations at baseline with change in DI (used as a measure of β-cell function) after adjusting for changes in weight and the baseline value of DI.

Results: After adjusting for covariates, nadir postprandial glucagon concentrations were not associated with changes in β-cell function as quantified by DI. On the other hand, fasting glucagon concentrations during the baseline study were inversely correlated with longitudinal changes in DI.

Conclusions: Defects in α-cell function, manifest as elevated fasting glucagon, are associated with a subsequent decline in β-cell function. It remains to be ascertained if abnormal α-cell function contributes directly to loss of β-cell secretory capacity in the pathogenesis of type 2 diabetes.

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