Periwal V, Chow CC, Bergman RN, Ricks M, Vega GL, Sumner AE. Evaluation of quantitative models of the effect of insulin on lipolysis and glucose disposal. Am J Physiol Regul Integr Comp Physiol 295: R1089 -R1096, 2008. First published August 6, 2008 doi:10.1152/ajpregu.90426.2008.-The effects of insulin on the suppression of lipolysis are neither fully understood nor quantified. We examined a variety of mathematical models analogous to the minimal model of glucose disposal (MMG) to quantify the combined influence of insulin on lipolysis and glucose disposal during an insulin-modified frequently sampled intravenous glucose tolerance test. The tested models, which include two previously published ones, consisted of separate compartments for plasma free fatty acids (FFA), glucose, and insulin. They differed in the number of compartments and in the action of insulin to suppress lipolysis that decreased the plasma FFA level. In one category of models, a single insulin compartment acted on both glucose and FFA simultaneously. In a second category, there were two insulin compartments, each acting on FFA and glucose independently. For each of these two categories, we tested 11 variations of how insulin suppressed lipolysis. We also tested a model with an additional glucose compartment that acted on FFA. These 23 models were fit to the plasma FFA and glucose concentrations of 102 subjects individually. Using Bayesian model comparison methods, we selected the model that best balanced fit and minimized model complexity. In the best model, insulin suppressed lipolysis via a Hill function through a remote compartment that acted on both glucose and FFA simultaneously, and glucose dynamics obeyed the classic MMG. free fatty acids; insulin resistance; mathematical model INSULIN RESISTANCE is a primary risk factor for several common diseases, including diabetes, cardiovascular disease, hypertension, and some forms of cancer. The mechanisms underlying insulin resistance are not completely understood. One important gap in our understanding relates to defects in insulin's ability to regulate lipolysis, leading to relative elevations of plasma free fatty acids (FFA). FFA elevation has been implicated in the modification of insulin action in various tissues as well as altering intermediates in the insulin signaling pathway and mitochondrial enzymes (6, 23). Therefore, methods to quantify insulin's effects on lipolysis and plasma FFA levels in various conditions of insulin resistance would be useful.The pace of development of quantitative methods to assess insulin's effect on FFA has lagged behind that of quantifying insulin's action on glucose disposal. For example, the hyperinsulinemic euglycemic clamp and the minimal model of glucose disposal (MMG) (1, 8) provide a quantitative index of the glucoregulatory action of insulin as a single value, such as glucose infusion rate divided by steady-state insulin concentration (M/I) for the clamp and the insulin sensitivity index (S I ) for the MMG.The current method for quantifying insuli...
