Ginger Brechtel

Obesity/insulin resistance is associated with endothelial dysfunction. Implications for the syndrome of insulin resistance.

To test the hypothesis that obesity/insulin resistance impairs both endothelium-dependent vasodilation and insulin-mediated augmentation of endothelium-dependent vasodilation, we studied leg blood flow (LBF) responses to graded intrafemoral artery infusions of methacholine chloride (MCh) or sodium nitroprusside (SNP) during saline infusion and euglycemic hyperinsulinemia in lean insulin-sensitive controls (C), in obese insulin-resistant subjects (OB), and in subjects with non-insulin-dependent diabetes mellitus (NIDDM). MCh induced increments in LBF were approximately 40% and 55% lower in OB and NIDDM, respectively, as compared with C (P < 0.05). Euglycemic hyperinsulinemia augmented the LBF response to MCh by - 50% in C (P < 0.05 vs saline) but not in OB and NIDDM. SNP caused comparable increments in LBF in all groups. Regression analysis revealed a significant inverse correlation between the maximal LBF change in response to MCh and body fat content. Thus, obesity/insulin resistance is associated with (a) blunted endothelium-dependent, but normal endothelium-independent vasodilation and (b) failure of euglycemic hyperinsulinemia to augment endothelium-dependent vasodilation. Therefore, obese/insulin-resistant subjects are characterized by endothelial dysfunction and endothelial resistance to insulins effect on enhancement of endothelium-dependent vasodilation. This endothelial dysfunction could contribute to the increased risk of atherosclerosis in obese insulin-resistant subjects.

Insulin-mediated skeletal muscle vasodilation is nitric oxide dependent. A novel action of insulin to increase nitric oxide release.

The purpose of this study was to examine whether insulins effect to vasodilate skeletal muscle vasculature is mediated by endothelium-derived nitric oxide (EDNO). N-monomethyl-L-arginine (L-NMMA), a specific inhibitor of NO synthase, was administered directly into the femoral artery of normal subjects at a dose of 16 mg/min and leg blood flow (LBF) was measured during an infusion of saline (NS) or during a euglycemic hyperinsulinemic clamp (HIC) designed to approximately double LBF. In response to the intrafemoral artery infusion of L-NMMA, LBF decreased from 0.296 +/- 0.032 to 0.235 +/- 0.022 liters/min during NS and from 0.479 +/- 0.118 to 0.266 +/- 0.052 liters/min during HIC, P < 0.03. The proportion of NO-dependent LBF during NS and HIC was approximately 20% and approximately 40%, respectively, P < 0.003 (NS vs. HIC). To elucidate whether insulin increases EDNO synthesis/release or EDNO action, vasodilative responses to graded intrafemoral artery infusions of the endothelium-dependent vasodilator methacholine chloride (MCh) or the endothelium-independent vasodilator sodium nitroprusside (SNP) were studied in normal subjects during either NS or HIC. LBF increments in response to intrafemoral artery infusions of MCh but not SNP were augmented during HIC versus NS, P < 0.03. In summary, insulin-mediated vasodilation is EDNO dependent. Insulin vasodilation of skeletal muscle vasculature most likely occurs via increasing EDNO synthesis/release. Thus, insulin appears to be a novel modulator of the EDNO system.

Decreased effect of insulin to stimulate skeletal muscle blood flow in obese man. A novel mechanism for insulin resistance.

Obesity is characterized by decreased rates of skeletal muscle insulin-mediated glucose uptake (IMGU). Since IMGU equals the product of the arteriovenous glucose difference (AVGd) across muscle and blood flow into muscle, reduced blood flow and/or tissue activity (AVGd) can lead to decreased IMGU. To examine this issue, we studied six lean (weight 68 +/- 3 kg, mean +/- SEM) and six obese (94 +/- 3 kg) men. The insulin dose-response curves for whole body and leg IMGU were constructed using the euglycemic clamp and leg balance techniques over a large range of serum insulin concentrations. In lean and obese subjects, whole body IMGU, AVGd, blood flow, and leg IMGU increased in a dose dependent fashion and maximal rates of all parameters were reduced in obese subjects compared to lean subjects. The dose-response curves for whole body IMGU, leg IMGU, and AVGd were right-shifted in obese subjects with an ED50 two- to threefold higher than that of lean subjects for each parameter. Leg blood flow increased approximately twofold from basal 2.7 +/- 0.2 to 4.4 +/- 0.2 dl/min in lean, P less than 0.01, and from 2.5 +/- 0.3 to 4.4 +/- 0.4 dl/min in obese subjects, P less than 0.01. The ED50 for insulins effect to increase leg blood flow was about fourfold higher for obese (957 pmol/liter) than lean subjects (266 pmol/liter), P less than 0.01. Therefore, decreased insulin sensitivity in human obesity is not only due to lower glucose extraction in insulin-sensitive tissues but also to lower blood flow to these tissues. Thus, in vivo insulin resistance can be due to a defect in insulin action at the tissue level and/or a defect in insulins hemodynamic action to increase blood flow to insulin sensitive tissues.

Impaired Insulin-Mediated Skeletal Muscle Blood Flow in Patients With NIDDM

Patients with non-insulin-dependent diabetes metlitus (NIDDM) exhibit decreased rates of skeletal muscle insulin-mediated glucose uptake (IMGU). Because IMGU is equal to the product of the arteriovenous glucose difference (AVGΔ) across and blood flow (F) into muscle (IMGU = AVGΔ × F), reduced tissue permeability (AVGΔ) and/or glucose and insulin delivery (F) can potentially lead to decreased IMGU. The components of skeletal muscle IMGU were studied in six obese NIDDM subjects (103 ± 9 kg) and compared with those previously determined in six lean (weight 68 ± 3 kg), and six obese (94 ± 3 kg) with normal glucose tolerance. The insulin dose-response curves for whole body and leg muscle IMGU were constructed using the combined euglycemic clamp and leg balance techniques during sequential insulin infusions (range of serum insulin 130–80,000 pmol/L). In lean, obese, and NIDDM subjects, whole body IMGU, femoral AVGΔ, and leg IMGU increased in a dose-dependent fashion over the range of insulin with an ED50 of 400–500 pmol/L in lean, 1000–1200 pmol/L in obese, and 4000–7000 pmol/L in NIDDM subjects (P < 0.01 lean vs. obese and NIDDM). In lean and obese subjects, maximally effective insulin concentrations increased leg blood flow ∼2-fold from basal with an ED50 of 266 pmol/L and 957 pmol/L, respectively (P < 0.01 lean vs. obese). In contrast, leg F did not increase from the basal value in NIDDM subjects (2.7 ± 0.1 vs. 3.5 ± 0.5 dl/min, NS). In the physiological range of insulin concentrations NIDDM subjects had lower body IMGU, leg F, femoral AVGΔ, and leg IMGU than obese and lean subjects, but at maximally effective insulin concentrations, femoral AVGA did not differ between obese and NIDDM subjects. Thus, 1) both reduced skeletal muscle tissue permeability and blood flow are found in NIDDM subjects and 2) impaired insulin-mediated augmentation of skeletal muscle blood flow in obese NIDDM patients is due to the diabetic state per se and not to the obesity status. Whether reduced skeletal muscle blood flow is the result or the cause of insulin resistance in patients with NIDDM remains to be elucidated.

Insulin-mediated skeletal muscle vasodilation contributes to both insulin sensitivity and responsiveness in lean humans.

Whether insulin-mediated vasodilation is important in determining insulins overall action to stimulate glucose uptake is unknown. To this end, we measured leg glucose uptake during euglycemic hyperinsulinemic clamps performed at two insulin doses (40 mU/m2 per min, n = 6 and 120 mU/m2 per min, n = 15) alone and during a superimposed intrafemoral artery infusion of GN-monomethyl-L-arginine (L-NMMA) designed to blunt insulin-mediated vasodilation. During the higher dose study, hyperinsulinemia resulted in about a twofold rise in basal leg blood flow from 0.24 +/- 0.02 to 0.45 +/- 0.05 liter/min, P < 0.0001. L-NMMA infusion resulted in a net 21% reduction in leg glucose uptake from 114 +/- 18 mg/min to 85 +/- 13 mg/min, P < 0.001. We also found a significant relationship between the rate of insulin-stimulated whole body glucose uptake and the magnitude of flow dependent glucose uptake (r = 0.57, P = 0.02). Data obtained during the lower dose insulin infusion resulted in similar findings. In conclusion, in healthy lean subjects, insulin-stimulated muscle blood flow contributes to both insulin responsiveness and insulin sensitivity. The most insulin-sensitive subjects appear to be the most reliant on muscle perfusion for insulin action. Insulin-mediated vasodilation is an important physiological determinant of insulin action.

Multiple defects in muscle glycogen synthase activity contribute to reduced glycogen synthesis in non-insulin dependent diabetes mellitus.

To define the mechanisms of impaired muscle glycogen synthase and reduced glycogen formation in non-insulin dependent diabetes mellitus (NIDDM), glycogen synthase activity was kinetically analyzed during the basal state and three glucose clamp studies (insulin approximately equal to 300, 700, and 33,400 pmol/liter) in eight matched nonobese NIDDM and eight control subjects. Muscle glycogen content was measured in the basal state and following clamps at insulin levels of 33,400 pmol/liter. NIDDM subjects had glucose uptake matched to controls in each clamp by raising serum glucose to 15-20 mmol/liter. The insulin concentration required to half-maximally activate glycogen synthase (ED50) was approximately fourfold greater for NIDDM than control subjects (1,004 +/- 264 vs. 257 +/- 110 pmol/liter, P less than 0.02) but the maximal insulin effect was similar. Total glycogen synthase activity was reduced approximately 38% and glycogen content was approximately 30% lower in NIDDM. A positive correlation was present between glycogen content and glycogen synthase activity (r = 0.51, P less than 0.01). In summary, defects in muscle glycogen synthase activity and reduced glycogen content are present in NIDDM. NIDDM subjects also have less total glycogen synthase activity consistent with reduced functional mass of the enzyme. These findings and the correlation between glycogen synthase activity and glycogen content support the theory that multiple defects in glycogen synthase activity combine to cause reduced glycogen formation in NIDDM.

Effects of Aging on Insulin Secretion

Aging is associated with hyperinsulinemia, but reports vary on the contributions of altered insulin clearance versus insulin secretion to this phenomenon. To elucidate the role of insulin secretion in the hyperinsulinemia of aging, 10 elderly (age 66 ± 4 yr, body mass index 25 ± kg/m2) and 8 young (age 30 ± 5 yr, body mass index 24 ± 3 kg/m2) subjects were studied to determine rates of insulin secretion in response to fasting, mixed meals, and intravenous glucose administration. Insulin secretion was determined with a two-compartment model based on individual C-peptide kinetic parameters derived after bolus injection of biosynthetic human C-peptide. Basal insulin secretion rates were increased in elderly subjects (82.5 ± 9.0 vs. 62.8 ± 6.1 pmol · min−1 · m−2; P < .05). This was reflected in elevated serum insulin levels in elderly subjects (62.8 ± 10.1 vs. 41.1 ± 5.0 pM, P < .05). During a 24-h mixed-meal profile, elderly subjects had an increase in their glucose response (P < .01 by analysis of variance [ANOVA]) and total insulin secretion (261 ± 28 vs. 195 ± 22 nmol · 24 h−1 · m−2; P < .05) compared with young subjects. However, the relative total increases in both glycemia and insulin secretion, calculated as a function of basal levels, were similar between the groups (both NS). To experimentally control for differences in glycemia, both groups underwent a 16.8-mM hyperglycemic clamp and a stepped intravenous glucose infusion to match glycemia. Under these steady-state and dynamic conditions, insulin secretion profiles were nearly identical (NS by ANOVA). However, during the stepped infusion, relative insulin secretion in elderly subjects, calculated as a function of basal levels, was significantly lower than insulin secretion in young subjects (change from basal 209 vs. 322%; P < .05). These changes could not be accounted for by relative differences in glycemia. To determine if diminished insulin clearance is present and contributes to hyperinsulinemia, endogenous insulin clearance was calculated from the ratio of total area under the insulin-secretion rate curve to the peripheral insulin-concentration curve during basal and mixed-meal conditions. Basal endogenous insulin clearance was 1.38 ± 0.22 L · min−1 · m−2 in elderly subjects vs. 1.34 ± 0.14 L · min−1 · m−2 in young subjects (NS). In response to mixed meals, endogenous insulin clearance was also similar between groups (0.813 ± 0.100 vs. 0.876 ± 0.048 L · min−1 · m−2 in elderly and young subjects, respectively; NS). In conclusion, physiological hyperinsulinemia of aging is caused by increased insulin secretion rather than decreased insulin clearance as demonstrated under basal conditions and in response to mixed meals. Under physiological conditions, the insulin-secretion response is appropriate for the prevailing level of glucose. However, although the β-cell secretory response to intravenous glucose is normal in absolute terms, it is disproportionately low when relative differences in glycemia and insulin sensitivity between elderly and young subjects are considered and may indicate reduced insulin secretion with aging under such conditions.

Reduced capacity and affinity of skeletal muscle for insulin-mediated glucose uptake in noninsulin-dependent diabetic subjects. Effects of insulin therapy.

We have estimated the capacity and affinity of insulin-mediated glucose uptake (IMGU) in whole body and in leg muscle of obese non-insulin-dependent diabetics (NIDDM, n = 6) with severe hyperglycemia, glycohemoglobin (GHb 14.4 +/- 1.2%), lean controls (ln, n = 7) and obese nondiabetic controls (ob, n = 7). Mean +/- SEM weight (kg) was 67 +/- 2 (ln), 100 +/- 7 (ob), and 114 +/- 11 (NIDDM), P = NS between obese groups. NIDDM were also studied after 3 wk of intensive insulin therapy, GHb post therapy was 10.1 +/- 0.9, P less than 0.01 vs. pretherapy. Insulin (120 mu/m2 per min) was infused and the arterial blood glucose (G) sequentially maintained at approximately 4, 7, 12, and 21 mmol/liter utilizing the G clamp technique. Leg glucose uptake (LGU) was calculated as the product of the femoral arteriovenous glucose difference (FAVGd) and leg blood flow measured by thermodilution. Compared to ln, ob and NIDDM had significantly lower rates of whole body IMGU and LGU at all G levels. Compared to ob, the NIDDM exhibited approximately 50% and approximately 40% lower rates of whole body IMGU over the first two G levels (P less than 0.02) but did not differ at the highest G, P = NS. LGU was 83% lower in NIDDM vs. ob, P less than 0.05 at the first G level only. After insulin therapy NIDDM were indistinguishable from ob with respect to whole body IMGU or LGU at all G levels. A significant correlation was noted between the percent GHb and the EG50 (G at which 1/2 maximal FAVGd occurs) r = 0.73, P less than 0.05. Thus, (a) insulin resistance in NIDDM and obese subjects are characterized by similar decreases in capacity for skeletal muscle IMGU, but differs in that poorly controlled NIDDM display a decrease in affinity for skeletal muscle IMGU, and (b) this affinity defect is related to the degree of antecedent glycemic control and is reversible with insulin therapy, suggesting that it is an acquired defect.

Kinetics of In Vivo Muscle Insulin-Mediated Glucose Uptake in Human Obesity

The kinetics of in vivo insulin-mediated glucose uptake in human obesity have not been previously studied. To examine this, we used the glucose-clamp technique to measure whole-body and leg muscle glucose uptake in seven lean and six obese men during hyperinsulinemia (∼2000 pM) at four glucose levels (∼4.5, ∼8.3, ∼13.5, and ∼23.5 mM). To measure leg glucose uptake, the femoral artery and vein were catheterized, and blood flow was measured by thermodilution (leg glucose uptake = arteriovenous glucose difference × blood flow). With this approach, we found that rates of whole-body and leg glucose uptake were significantly lower in obese than in lean subjects at each glucose plateau. Leg blood flow rates increased from 4.3 ± 0.4 to 6.5 ± 0.8 dl/min over the range of glucose in lean subjects (P < 0.05) but remained unchanged in obese subjects. The apparent maximal capacity (Vmax), based on whole-body and leg glucose uptake, was reduced in obese compared with lean subjects, but the apparent Km was similar in the lean and obese subjects (6-9 mM, NS). To assess the affinity of muscle for glucose extraction independent of changes in muscle plasma flow, we determined the mean half-maximal effective glucose concentration (EG50) and found it was similar in the lean and obese subjects (6.0 ± 0.3 vs. 6.0 ± 0.8 mM, NS). We conclude that 1) the kinetics of in vivo insulin-mediated glucose uptake in skeletal muscle in human obesity are characterized by reduced Vmax but normal Km; 2) the EG50 for insulin-mediated glucose extraction in skeletal muscle was 6 mM in both lean and obese subjects, consistent with a Km characteristic of the glucose-transport system; 3) obese subjects were unable to generate increases in blood flow in response to hyperglycemia under hyperinsulinemic conditions, and this contributed significantly to lower rates of leg and whole-body glucose uptake.

Evidence that glucose transport is rate-limiting for in vivo glucose uptake

To determine whether glucose transport or intracellular glucose metabolism is rate-limiting for in vivo glucose uptake, rates of glucose disposal were measured in a group of normal subjects at varying levels of hyperglycemia designed to attain saturating rates of glucose disposal at low and high physiological insulin concentrations. At insulin levels of approximately 200 pmol/L, glucose disposal rates were 2.9 +/- 0.4, 4.7 +/- 0.5, 6.4 +/- 0.6, and 6.5 +/- 0.8 mg/kg/min at plasma glucose concentrations of 5.55, 11.10, 13.88, and 19.43 mmol/L (or 100, 200, 250, and 350 mg/dL, respectively). At insulin levels of approximately 750 pmol/L, glucose disposal rates were 1.7 to 2.1-fold higher: 6.2 +/- 0.7, 9.2 +/- 1.1, 11.0 +/- 1.1, and 12.3 +/- 1.4 mg/kg/min at glucose levels of 5.55, 11.10, 13.88, and 19.43 mmol/L. Thus, during both the 15- and 40-mU/m2/min insulin infusions, glucose disposal increased in a linear fashion from 5.55 to 13.88 mmol/L (r = .90) and then effectively plateaued at the same plasma glucose level. If the plateau of glucose disposal during the 40-mU/m2/min insulin infusion was due to saturation of the intracellular capacity to metabolize glucose, then when plasma glucose was increased from 13.88 to 19.43 mmol/L at the lower insulin level, the glucose disposal should have continued to increase and not plateau, since the rate of glucose disposal was only approximately 50% of that attained at the higher insulin infusion rate.(ABSTRACT TRUNCATED AT 250 WORDS)