Tumor necrosis factor alpha is associated with insulin-mediated suppression of free fatty acids and net lipid oxidation in HIV-infected patients with lipodystrophy

Tumor necrosis factor alpha (TNF-alpha) stimulates lipolysis in man. We examined whether plasma TNF-alpha is associated with the degree by which insulin suppresses markers of lipolysis, for example, plasma free fatty acid (FFA) and net lipid oxidation (LIPOX) rate in HIV-infected patients with lipodystrophy (LIPO) and those without (controls). LIPOX was estimated by indirect calorimetry during fasting and steady state of a hyperinsulinemic euglycemic clamp in 36 (18 LIPO and 18 controls) normoglycemic HIV-infected men on highly active antiretroviral therapy. In LIPO, TNF-alpha correlated with clamp FFA (r = 0.67, P < .01), clamp LIPOX (r = 0.47, P < .05), incremental FFA (r = 0.69, P < .01), and incremental LIPOX (r = 0.64, P < .01), all of which, but not the clamp LIPOX correlation (r = 0.29, P > .05), remained significant after correction for insulin sensitivity. None of these correlations were significant in controls. In all patients, TNF-alpha correlated with clamp FFA (r = 0.61, P < .001), clamp LIPOX (r = 0.43, P < .01), and incremental FFA (r = 0.43, P < .01), with the 2 former correlations remaining significant after correction for insulin sensitivity. LIPOX and FFA (fasting and clamp values combined) correlated strongly and positively in both LIPO (R2 = 0.43, P < .001) and controls (R2 = 0.60, P < .0001). Fasting FFA and LIPOX did not differ between study groups; however, the insulin-mediated suppression of FFA and LIPOX was attenuated in LIPO (P's < .05). Our data indicate that higher TNF-alpha, independently of insulin sensitivity, is associated with attenuated insulin-mediated suppression of FFA and LIPOX in HIV-LIPO, suggesting in turn that TNF-alpha stimulates lipolysis in this syndrome. Furthermore, FFA may be a major determinant of LIPOX in HIV-infected patients on highly active antiretroviral therapy.     

Insulin-like growth factors, insulin-like growth factor-binding proteins, insulin-like growth factor-binding protein-3 protease, and growth hormone-binding protein in lipodystrophic human immunodeficiency virus-infected patients

Human immunodeficiency virus (HIV)-lipodystrophy is associated with impaired growth hormone (GH) secretion. It remains to be elucidated whether insulin-like growth factors (IGFs), IGF-binding proteins (IGFBPs), IGFBP-3 protease, and GH-binding protein (GHBP) are abnormal in HIV-lipodystrophy. These parameters were measured in overnight fasting serum samples from 16 Caucasian males with HIV-lipodystrophy (LIPO) and 15 Caucasian HIV-infected males without lipodystrophy (NONLIPO) matched for age, weight, duration of HIV infection, and antiretroviral therapy. In LIPO, abdominal fat mass and insulin concentration were increased (>90%, P < .01) and insulin sensitivity (Log10ISI(composite)) was decreased (-50%, P < .001). Total and free IGF-I, IGF-II, IGFBP-3, and IGFBP-3 protease were similar between groups (all P > .5), whereas, in LIPO, IGFBP-1 and IGFBP-2 were reduced (-36%, P < .05 and -50%, P < .01). In pooled groups, total IGF-I, free IGF-I, total IGF-II, and IGFBP-3, respectively, correlated inversely with age (all P < .01). In pooled groups, IGFBP-1 and IGFBP-2 correlated positively with insulin sensitivity (age-adjusted all P < .05). IGFBP-3 protease correlated with free IGF-I in pooled groups (r(p) = 0.47, P < .02), and in LIPO (r(p) = 0.71, P < .007) controlling for age, total IGF-I, and IGFBP-3. GHBP was increased, whereas GH was decreased in LIPO (all P < .05). GH correlated inversely with GHBP in pooled groups (P < .05). Taken together the similar IGFs and IGFBP-3 concentrations between study groups, including suppressed GH, and increased GHBP in LIPO, argue against GH resistance of GH-sensitive tissues in LIPO compared with NONLIPO; however, this notion awaits examination in dose-response studies. Furthermore, our data suggest that IGFBP-3 protease is a significant regulator of bioactive IGF-I in HIV-lipodystrophy.     

Impaired proinsulin secretion before and during oral glucose stimulation in HIV-infected patients who display fat redistribution

The beta-cell function of HIV-infected patients on highly active antiretroviral therapy who display lipodystrophy may be impaired. An early defect in beta-cell function may be characterized by an increase in secretion of 32-33 split proinsulin (SP) and intact proinsulin (IP). To address this issue, the secretion patterns of SP and IP of 16 HIV-infected men with lipodystrophy (LIPO) and 15 HIV-infected men without lipodystrophy (NONLIPO) were studied during an oral glucose tolerance test (OGTT). All patients received highly active antiretroviral therapy. Insulin secretion rates were determined by deconvolution of plasma C-peptide concentrations. More LIPO than NONLIPO patients displayed diabetes mellitus and impaired glucose tolerance than normal glucose tolerance (LIPO 2/8/6 vs NONLIPO 1/2/12, P = .05). LIPO patients had increased fasting levels of SP and IP, ratio of SP/IP, and area under the curve of SP and IP during the early phase (0, 10, and 20 minutes) and during the late phase (45, 75, and 105 minutes) of the OGTT compared with NONLIPO patients (Ps < .05). LIPO patients exhibited significantly increased fasting SP/IP ratio, fasting SP/insulin ratio, and total proinsulin to C-peptide ratio during the OGTT. LIPO patients displayed increased incremental secretion of IP during the first 10 minutes of the OGTT (P < .05), although the incremental insulin secretion during this period did not differ between LIPO and NONLIPO patients. These data suggest that HIV-infected patients with lipodystrophy display major perturbations of proinsulin secretion in the fasting state and during an OGTT, which is compatible with the notion of a beta-cell dysfunction of such patients.     

Assessment of growth hormone dynamics in human immunodeficiency virus-related lipodystrophy

Human immunodeficiency virus (HIV) lipodystrophy (LIPO) is characterized by increased visceral adiposity, peripheral fat atrophy, dyslipidemia, and insulin resistance. GH concentrations are known to vary inversely with excess weight and body fat but have not been investigated in HIV lipodystrophy. Twenty-one subjects with HIV LIPO, 20 HIV-infected nonlipodystrophy subjects (NONLIPO), and 20 control (C) subjects were prospectively recruited for this study and compared. Subjects in the three groups were all male, age-matched [median, 47 yr old (interquartile range, 37-50) LIPO; 41 (37-44) NONLIPO; and 43 (37-49) C], and body mass index-matched [median, 24.3 kg/m(2) (interquartile range, 22.2-26.6) LIPO; 24.4 (23.3-25.9) NONLIPO; and 24.8 (22.7-26.1) C] (P: > 0.05 for all comparisons). Visceral abdominal fat [16,124 mm(2) (11,246-19,790) LIPO; 7,559 (5,134-11,201) NONLIPO; and 8,803 (6,165-11,623) C; P < 0.01 LIPO vs. NONLIPO and LIPO vs. C] and the ratio of visceral abdominal fat to sc abdominal fat [1.37 (0.71-2.44) LIPO vs. 0.57 (0.47-0.78) NONLIPO vs. 0.55 (0.41-0.71) C, P < 0.01 LIPO vs. NONLIPO and LIPO vs. C] were significantly increased in the LIPO subjects but were not significantly different between NONLIPO and C. The mean overnight GH concentration, determined from frequent sampling every 20 min (from 2000 h to 0800 h) was decreased in the LIPO subjects [0.38 microg/L (0.13-0.67) LIPO vs. 0.96 (0.53-1.30) NONLIPO vs. 0.81 (0.49-1.03) C, P < 0.05 LIPO vs. NONLIPO and LIPO vs. C] and not significantly different between NONLIPO and C. Pulse analysis demonstrated decreased baseline GH [0.08 microg/L (0.06-0.21) LIPO vs. 0.19 (0.10-0.32) NONLIPO vs. 0.17 (0.12-0.57) C, P < 0.05 LIPO vs. NONLIPO and LIPO vs. C] and GH peak amplitude [1.06 microg/L (0.46-1.94) LIPO vs. 2.47 (1.22-3.43) NONLIPO and 2.27 (1.36-4.25) C, P < 0.05 LIPO vs. NONLIPO and LIPO vs. C] in the LIPO subjects but no significant difference in pulse frequency. No significant differences were observed between NONLIPO and C for any GH parameter. Insulin-like growth factor-I was not different between the groups. Total body fat (r = -0.40, P = 0.01) and visceral fat (r = -0.58, P = 0.0001) correlated inversely with mean overnight GH concentrations in the HIV-infected patients. In a multivariate regression model, controlling for age, body mass index, body fat, and visceral fat, only visceral fat was a significant predictor of mean GH concentrations (P = 0.0036, r(2) for model = 0.40). These data demonstrate normal GH pulse frequency and insulin-like growth factor-I concentrations but reduced mean GH concentrations, basal GH concentrations, and GH pulse amplitude in patients with HIV lipodystrophy. Increased visceral adiposity is the strongest predictor of reduced GH concentrations in HIV lipodystrophy. Further studies are necessary to determine the clinical significance of reduced GH in patients with HIV lipodystrophy.     

Glucose-stimulated prehepatic insulin secretion is associated with circulating alanine, triglyceride, glucagon, lactate and TNF-alpha in patients with HIV-lipodystrophy

OBJECTIVES: We examined whether insulin-resistant lipodystrophic HIV-infected patients with known high fasting prehepatic insulin secretion rates (FISRs) displayed alterations in first-phase prehepatic insulin response to intravenous glucose (ISREG0-10 min). METHODS: Eighteen normoglycaemic lipodystrophic HIV-infected (LIPO) patients and 25 normoglycaemic nonlipodystrophic HIV-infected patients (controls) were included in the study. The prehepatic insulin secretion rate was estimated by deconvolution of C-peptide concentrations, and insulin sensitivity (SIRd) was estimated by the glucose clamp technique. The disposition index (Di=ISREG0-10 min x SIRd) was calculated to estimate the beta-cell response relative to insulin sensitivity. RESULTS: FISR was increased by 69% (P<0.001), whereas median Di was decreased by 75% (P<0.01), primarily as a result of a reduction of SI(Rd) by 60% (P<0.001) in LIPO patients compared with controls. Three LIPO groups were identified arbitrarily according to their FISR and ISREG0-10 min values relative to those of controls. Four LIPO patients displayed high FISR [+3 standard deviations (SD), P<0.001], high ISREG0-10 min (+3 SD, P<0.001) and low SIRd (P<0.01), suggesting an intact B-cell capacity to compensate insulin resistance; six LIPO patients exhibited high FISR (+3SD, P<0.001), low ISREG0-10min (-1 SD, P=0.01), and low SIRd (P<0.01), suggesting depletion of readily releasable insulin stores; the remaining eight LIPO patients and controls displayed identical FISR and ISREG0-10 min. Increased concentrations of the nonglucose insulin secretagogues triglyceride (+124%), alanine (+35%) and glucagon (+88%), and also lactate (+96%) and tumour necrosis factor (TNF)-alpha (+62%) were observed in the 10 LIPO patients with aberrations in FISR and ISREG0-10 min compared with the remaining HIV-infected patients (all P<0.05). CONCLUSION: Plasma triglyceride, alanine, glucagon, lactate and TNF-alpha may be associated with alterations in the first-phase prehepatic insulin secretion response to intravenous glucose in normoglycaemic lipodystrophic HIV-infected patients.     

Elevated concentrations of free fatty acids are associated with increased insulin response to standard glucose challenge in human immunodeficiency virus-infected subjects with fat redistribution

Fat redistribution, defined by both increased abdominal visceral fat and/or decreased abdominal, extremity, and facial subcutaneous fat, is increasingly recognized among human immunodeficiency virus (HIV)-infected patients treated with combination antiretroviral therapy. Fat redistribution in this population is associated with insulin resistance and dyslipidemia and is often referred to as the HIV lipodystrophy syndrome (LIPO). Fatty acids are known to modulate insulin resistance in other disease states, but a comprehensive evaluation of fatty acids has not been undertaken among HIV-infected patients with fat redistribution. In this study, we investigated fatty acid concentrations in 64 HIV-infected individuals (45 men and 19 women) with evidence of fat redistribution (LIPO) in comparison to 30 HIV-infected individuals (20 men and 10 women) without evidence of fat redistribution (NONLIPO) and 32 HIV-negative healthy control subjects (C) (21 males and 11 females) of similar age and body mass index (BMI). Glucose, insulin, and free fatty acid (FFA) levels were measured in response to a 75-g oral glucose tolerance test (OGTT) in the LIPO, NONLIPO, and C subjects. In addition, fasting lipids were obtained, and body composition was determined by anthropometric measurements and dual-energy x-ray absorptiometry (DXA). Fasting FFA concentrations were significantly increased in the LIPO group as compared with NONLIPO and C subjects (0.74 +/- 0.03 v 0.60 +/- 0.04 [mean +/- SEM] mmol/L, P =.002, LIPO v NONLIPO; 0.74 +/- 0.03 v 0.59 +/- 0.03 mmol/L, P =.001, LIPO v C). In contrast, fasting FFA concentrations were not increased in the NONLIPO group (0.60 +/- 0.04 v 0.59 +/- 0.03, P =.909, NONLIPO v C). Similarly, fasting triglycerides and 120-minute OGTT FFA were significantly increased in the LIPO group as compared with the NONLIPO and C group. FFA decreased in HIV-infected LIPO, NONLIPO, and C subjects in response to OGTT, but the 120-minute FFA concentrations remained significantly elevated in LIPO patients compared with NONLIPO and C subjects. In a multivariate regression model of LIPO patients, fasting FFA (P =.027) was a strong independent predictor of insulin area under the curve (AUC), controlling for age, BMI, gender, and body composition (r(2) for model =.31). No differences were observed in FFA concentrations in the LIPO group in an analysis based on current protease inhibitor (PI) use. These data suggest that FFA concentrations are increased in HIV-infected patients with fat redistribution. Increased fasting concentrations of fatty acids are associated with abnormal insulin responses to standard glucose challenge in HIV-infected patients with fat redistribution. Further studies are necessary to determine the mechanism of increased fatty acid concentrations and the role played by increased FFA in mediating insulin resistance in this population.     

Independent influence of age on basal insulin secretion in nondiabetic humans. European Group for the Study of Insulin Resistance

Glucose tolerance deteriorates with aging. To test whether age per se impairs basal beta-cell function, we analyzed retrospective clamp data from a large group (n = 957) of nondiabetic Europeans over the 18-85 yr age range (the European Group for the Study of Insulin Resistance database). In this cohort, the fasting posthepatic insulin delivery rate [IDR, obtained as the product of clamp-derived posthepatic insulin MCR and fasting plasma insulin concentration] was 8.9 (6.6) mU/min (median and interquartile range), and it gradually increased with age. In univariate association, IDR was positively related to body mass index (P < 0.0001), fasting plasma glucose (P < 0.01), and waist-to-hip ratio (P < 0.001), and negatively related to insulin sensitivity (P < 0.0001). After controlling for these factors in a multivariate model, IDR declined significantly with age (P < 0.0001). This intrinsic effect of age on IDR was similar in men and women, and it averaged 25% between 18-85 yr. In the same statistical model, insulin MCR (but not fasting plasma insulin concentration) showed a significant (P < 0.0001) inverse relation to age. We conclude that, in nondiabetic Caucasian subjects of either sex, senescence per se is associated with a progressive decline in both insulin clearance and basal insulin release.     

Hyperandrogenemia in human immunodeficiency virus-infected women with the lipodystrophy syndrome

A novel lipodystrophy syndrome characterized by insulin resistance, hypertriglyceridemia, and fat redistribution has recently been described in human immunodeficiency virus (HIV)-infected men and women. Women with the HIV lipodystrophy syndrome exhibit a marked increase in waist-to-hip ratio and truncal adiposity; however, it is unknown whether androgen levels are increased in these patients. In this study, we assessed androgen levels in female patients with clinical lipodystrophy based on evidence of significant fat redistribution in the trunk, extremities, neck and/or face (LIPO: n = 9; age, 35.7+/-1.7 yr; BMI, 24.7+/-0.8 kg/m2) in comparison with age- and BMI-matched nonlipodystrophic HIV-infected females (NONLIPO: n = 14; age, 37.6+/-1.1 yr; BMI, 23.4+/-0.6 kg/m2) and healthy non-HIV-infected control subjects (C: n = 16; age, 35.8+/-0.9 yr; BMI, 23.1+/-0.4 kg/m2). Fasting insulin, lipid levels, virologic parameters, and regional body composition using dual energy x-ray absorptiometry were also assessed. Total testosterone [ LIPO, 33+/-6 ng/dL (1.1+/-0.2 nmol/L); NONLIPO, 17+/-2 ng/dL (0.6+/-0.1 nmol/L); C, 23+/-2 ng/dL (0.8+/-0.1 nmol/L); P < 0.05 LIPO vs. C and LIPO vs. NONLIPO] and free testosterone determined by equilibrium dialysis [LIPO, 4.5+/-0.9 pg/mL (16+/-3 pmol/L); NONLIPO, 1.7+/-0.2 pg/mL (6+/-1 pmol/L); C, 2.4+/-0.2 pg/mL (8+/-1 pmol/L); P < 0.05 LIPO vs. C and LIPO vs. NONLIPO] were increased in the lipodystrophic patients. Sex hormone-binding globulin levels were not significantly different between LIPO and C, but were significantly lower in the LIPO vs. NONLIPO patients (LIPO 84+/-7 vs. NONLIPO 149+/-17 nmol/L, P < 0.05). The LH/FSH ratio was significantly increased in the LIPO group compared with the NONLIPO and C subjects (LIPO, 2.0+/-0.6; NONLIPO, 1.1+/-0.1; C, 0.8+/-0.1; P < 0.05 LIPO vs. NONLIPO and LIPO vs. C). Body fat distribution was significantly different between LIPO and C subjects. Trunk to extremity fat ratio (1.46+/-0.17 vs. 0.75+/-0.05, LIPO vs. C, P < 0.05) was increased and extremity to total fat ratio decreased (0.40+/-0.03 vs. 0.55+/-0.01, LIPO vs. C, P < 0.05). In contrast, fat distribution was not different in the NONLIPO group vs. control subjects. Among the HIV-infected patients, free testosterone correlated with percent truncal fat (trunk fat/trunk mass) (r = 0.43, P = 0.04). These data suggest that hyperandrogenemia is another potentially important feature of the HIV-lipodystrophy syndrome in women. Additional studies are necessary to determine the clinical significance of increased androgen levels and the relationship of hyperandrogenism to fat redistribution and insulin resistance in this population of patients.     

Circulating fatty acids, non-high density lipoprotein cholesterol, and insulin-infused fat oxidation acutely influence whole body insulin sensitivity in nondiabetic men

Circulating lipids and tissue lipid depots predict insulin sensitivity. Associations between fat oxidation and insulin sensitivity are variable. We examined whether circulating lipids and fat oxidation independently influence insulin sensitivity. We also examined interrelationships among circulating lipids, fat oxidation, and tissue lipid depots. Fifty-nine nondiabetic males (age, 45.4 +/- 2 yr; body mass index, 29.1 +/- 0.5 kg/m(2)) had fasting circulating nonesterified fatty acids (NEFAs) and lipids measured, euglycemic-hyperinsulinemic clamp for whole body insulin sensitivity [glucose infusion rate (GIR)], substrate oxidation, body composition (determined by dual energy x-ray absorptiometry), and skeletal muscle triglyceride (SMT) measurements. GIR inversely correlated with fasting NEFAs (r = -0.47; P = 0.0002), insulin-infused NEFAs (n = 38; r = -0.62; P < 0.0001), low-density lipoprotein cholesterol (r = -0.50; P < 0.0001), non-high-density lipoprotein cholesterol (r = -0.52; P < 0.0001), basal fat oxidation (r = -0.32; P = 0.03), insulin-infused fat oxidation (r = -0.40; P = 0.02), SMT (r = -0.28; P < 0.05), and central fat (percentage; r = -0.59; P < 0.0001). NEFA levels correlated with central fat, but not with total body fat or SMT. Multiple regression analysis showed non-high-density lipoprotein cholesterol, fasting NEFAs, insulin-infused fat oxidation, and central fat to independently predict GIR, accounting for approximately 60% of the variance. Circulating fatty acids, although closely correlated with central fat, independently predict insulin sensitivity. Insulin-infused fat oxidation independently predicts insulin sensitivity across a wide range of adiposity. Therefore, lipolytic regulation as well as amount of central fat are important in modulating insulin sensitivity.     

Different growth hormone sensitivity of target tissues and growth hormone response to glucose in HIV-infected patients with and without lipodystrophy

Growth hormone (GH)-secretion in HIV-lipodystrophy is impaired; however, GH-sensitivity of GH-target tissues remains to be evaluated. We measured overnight fasting concentrations of GH-sensitive insulin-like growth-factor-I (IGF-I) and IGF binding protein-3 (IGFBP-3) including GH binding protein (GHBP), a marker of GH-receptor sensitivity, in antiretroviral treated HIV-infected patients with (LIPO) and without lipodystrophy (NONLIPO) and antiretroviral naive HIV-infected patients (NAIVE). Three h GH-suppression tests using oral glucose were undertaken to determine dynamics of GH-secretion. IGF-I and IGFBP-3 were increased in LIPO compared with NONLIPO (p <0.05), but did not differ significantly between NONLIPO and NAIVE. Area under the curve of GH (AUC-GH) during the GH-suppression test was decreased in LIPO compared with NONLIPO (p <0.05). Ratio of limb to trunk fat, which was decreased in LIPO compared to NONLIPO and NAIVE (p <0.001), correlated positively with AUC-GH and rebound-GH (p <0.05). All groups displayed suppression of GH during the suppression test (p <0.05) and all groups, except LIPO, displayed a rebound of GH (p <0.05), which probably is explained by persistently increased plasma glucose in LIPO compared with NONLIPO and NAIVE (p <0.01). GHBP was inversely correlated with AUC-GH (p <0.01). Our data suggest that GH-target tissues in LIPO are at least as GH-sensitive as in HIV-infected patients without lipodystrophy.     

In vivo evidence of impaired peripheral fatty acid trapping in patients with human immunodeficiency virus-associated lipodystrophy

The use of antiretroviral combination therapy in HIV has been associated with lipodystrophy and several metabolic risk factors. We postulated that patients with HIV-lipodystrophy have impaired adipose tissue free fatty acid (FFA) trapping and, consequently, increased hepatic FFA delivery. We investigated FFA, hydroxybutyric acid (HBA; reflecting hepatic FFA oxidation), and triglyceride (TG) changes after a high fat meal in HIV-infected males with (LIPO; n = 26) and without (NONLIPO; n = 12) lipodystrophy and in healthy males (n = 35). Because defective peripheral FFA trapping has been associated with impaired action of complement component 3 (C3), we also determined postprandial C3 concentrations. The LIPO group had higher homeostasis model assessment scores compared with the other groups. Areas under the curve (AUCs) for FFA, HBA, and TG were higher in the LIPO group than in the NONLIPO group or the controls. No differences in TG-AUC, FFA-AUC, and HBA-AUC were observed between the NONLIPO group and controls. In HIV-infected patients, FFA-AUC and HBA-AUC were inversely related to sc adipose tissue area. Plasma C3 showed a postprandial increase in healthy controls, but not in the HIV-infected groups. C3 was not related to body fat distribution, postprandial FFA, or HBA. The present data suggest disturbed postprandial FFA metabolism in patients with HIV-lipodystrophy, most likely due to inadequate incorporation of FFA into TG in sc adipose tissue, but do not support a major role for C3 in these patients. The higher postprandial HBA levels reflect increased hepatic FFA delivery and may aggravate insulin resistance and dyslipidemia, leading to increased cardiovascular risk.     

Beta-cell hypersecretion and not reduced hepatic insulin extraction is the main cause of hyperinsulinemia in obese nondiabetic subjects.

Obesity is characterized by peripheral hyperinsulinemia, for which either beta-cell hypersecretion, diminished hepatic insulin extraction, or both may be responsible. To clarify this issue, we investigated insulin secretion and hormone hepatic extraction in 18 nondiabetic obese patients (body mass index [BMI], 39 +/- 1.3 kg/m2) and 18 healthy, lean control subjects (BMI, 21.3 +/- 0.7 kg/m2). Body fat distribution was calculated by measuring the waist to hip ratio (WHR). A highly reduced tissue insulin sensitivity (2.4 +/- 0.5 v 9.5 +/- 1.5 10(4).min-1/[microU/mL], P > .0005) and glucose effectiveness, ie, glucose's ability to stimulate its own disappearance at basal insulin (16 +/- 2 v 30 +/- 3 10(3).min-1, P > .005), were found in the overweight subjects compared with the controls. The basal (76 +/- 14 v 37 +/- 4 pmol/L/min) and total (377,848 +/- 5,562 v 16,864 +/- 1,850 pmol/L) prehepatic insulin secretion and the basal (15 +/- 2 v 7 +/- 0.7 pmol/L/min) and total (8,286 +/- 2,009 v 2,840 +/- 210 pmol/L) posthepatic insulin delivery were significantly higher in the overweight subjects compared with the controls (P < .005), whereas the mean hepatic insulin extraction did not differ (77.8% +/- 2.6% v 79.5% +/- 2.6%). A significant inverse correlation was found between the hepatic insulin extraction and the WHR (r = .5, P > .04), signifying the importance of fat distribution in insulin metabolism. The obese patients were subdivided into two subgroups according to their glucose tolerance; eight patients exhibited a normal tolerance and the remaining 10 were intolerant.(ABSTRACT TRUNCATED AT 250 WORDS)     

Increased rates of lipolysis among human immunodeficiency virus-infected men receiving highly active antiretroviral therapy

Human immunodeficiency virus (HIV) lipodystrophy is associated with fat redistribution, dyslipidemia, and insulin resistance; however, the mechanism of insulin resistance remains unknown. We hypothesized that HIV-infected subjects with fat redistribution have increased rates of lipolysis and increased circulating free fatty acid (FFA) levels that contribute to insulin resistance. Anthrompometric and body composition data were obtained and a standard 75-g oral glucose tolerance test (OGTT) was performed on day 1 of the study. Stable isotope infusions of glycerol and palmitate were completed following an overnight fast to assess rates of lipolysis and FFA flux in HIV-infected men (n = 19) with and without fat redistribution and healthy controls (n = 8) on day 2. Total FFA levels after standard glucose challenge were increased among HIV-infected subjects and positively associated with abdominal visceral adipose tissue area. In contrast, fasting total FFA levels were inversely associated with subcutaneous fat area. Rates of basal lipolysis were significantly increased among HIV-infected subjects (rate of appearance [Ra] glycerol, 4.1 +/- 0.2 v 3.3 +/- 0.2 micromol/kg/min in controls; P =.02). Among HIV-infected subjects, use of stavudine (P =.006) and the rate of lipolysis (ie, Ra glycerol, P =.02) were strong positive predictors of insulin resistance as measured by insulin response to glucose challenge, controlling for effects of age, body mass index (BMI), waist-to-hip ratio (WHR), and protease inhibitor (PI) exposure. These data demonstrate increased rates of lipolysis and increased total FFA levels in HIV-infected subjects and suggest that increased lipolysis may contribute to insulin resistance in this patient population.     

Evaluation of the quantitative insulin sensitivity check index as an estimate of insulin sensitivity in humans

The goal of this study was to compare estimates of insulin resistance generated by the quantitative insulin sensitivity check index (QUICKI) with a direct measure of insulin-mediated glucose disposal in healthy, nondiabetic volunteers. For this purpose, the results of measurements of plasma glucose and insulin concentrations in 490 nondiabetic, healthy subjects were used to compute several surrogate estimates of insulin resistance, and these values were compared with a direct measure of insulin-mediated glucose disposal. The results of this analysis showed that estimates of insulin resistance derived from use of QUICKI were significantly correlated (r = -.60, P <.001) with direct measures of insulin-mediated glucose in the 490 subjects studied. It was also noted that QUICKI estimates of insulin resistance were highly correlated with fasting insulin concentrations (r = -.98) and the homeostasis model assessment for insulin resistance (HOMA-IR, r = -.99). On the other hand, the correlation between all 3 of the surrogate methods for estimating insulin resistance and the direct assessment of insulin-mediated glucose disposal was relatively weak, i.e., r =.61, r =.64, and r = -.60) for fasting insulin concentration, HOMA-IR, and QUICKI, respectively. The results of these comparisons do not provide support for the superiority of QUICKI over other commonly used surrogate measures of insulin resistance based upon use of fasting insulin concentration or equations utilizing fasting insulin and glucose concentration. Furthermore, none of the 3 surrogate estimates can account for more than approximately 40% of the variability of the difference in insulin-mediated glucose disposal measured directly in 490 healthy, nondiabetic volunteers.     

QUICKI does not accurately reflect changes in insulin sensitivity with exercise training.

A novel index of insulin sensitivity, the quick insulin sensitivity check index, termed QUICKI (1/[log (insulin) + log (glucose)]), was recently developed. We examined whether QUICKI accurately reflects changes in insulin sensitivity after exercise training, a perturbation known to improve insulin sensitivity. Sedentary, nondiabetic adults underwent a frequently sampled iv glucose tolerance test before and after 6 months of training. Insulin sensitivity was estimated from the glucose tolerance test using Bergman's minimal model (insulin sensitivity-minimal model), and QUICKI was calculated from basal insulin and glucose. Exercise increased (P = 0.003) insulin sensitivity-minimal model but did not change (P = 0.12) QUICKI. Before and after training, the rank-correlation between QUICKI and insulin sensitivity-minimal model was significant (r = 0.79, P = 0.0005; r = 0.56, P = 0.03, respectively). However, the rank-correlation between fasting insulin alone with insulin sensitivity-minimal model was as good (before training r = -0.77, P = 0.0009; after training r = -0.55, P = 0.03) as that between QUICKI and insulin sensitivity-minimal model. Fasting glucose was not related to insulin sensitivity-minimal model at either time. When difference scores (i.e. after pretraining values) were examined, neither QUICKI nor fasting insulin correlated with insulin sensitivity-minimal model (QUICKI vs. insulin sensitivity-minimal model r = 0.24, P = 0.39; fasting insulin vs. insulin sensitivity-minimal model r = -0.40, P = 0.14). We conclude that fasting insulin is equivalent to fasting insulin plus glucose (i.e. QUICKI) at estimating basal insulin sensitivity in nondiabetic adults. However, QUICKI does not accurately reflect exercise-induced changes in insulin sensitivity within individual subjects.     

Insulin resistance and insulin pulsatility in essential hypertension

OBJECTIVE: Studies in normal humans and in patients with type 2 diabetes mellitus have demonstrated a close inverse relationship between peripheral insulin sensitivity and the frequency of short-term insulin secretory pulses in the systemic circulation. Our objective was to study this relationship in essential hypertension. DESIGN: Study of insulin sensitivity and insulin pulse characteristics in hypertensive subjects and normotensive controls using well-established techniques. METHODS: Twelve subjects with essential hypertension and 12 age- and sex-matched normotensive controls were recruited. Insulin action was measured using the glucose clamp technique combined with isotope dilution methodology. Insulin pulsatility in the peripheral circulation was assessed by sampling every 2 min for 90 min after an overnight fast Pulses were identified using the computer program Pulsar. RESULTS: Insulin sensitivity index (glucose infusion rate/ serum insulin) was lower in the hypertensive patients (P= 0.01) and fasting insulin was increased (P= 0.008) compared to controls. The frequency and amplitude of insulin pulses were similar in the two groups. Insulin pulse frequency and insulin sensitivity were inversely related in the normotensive group (r= -0.68, P= 0.015), but not in the hypertensive group (r= -0.23, P= 0.48). Insulin clearance was reduced in the hypertensive group (P= 0.03), and was inversely related to insulin pulse frequency in the two groups combined (r = -0.51, P= 0.01). CONCLUSIONS: Insulin action was not related to insulin pulse frequency in essential hypertension, in contrast to the situation in normal man.     

Growth hormone (GH) responses to GH-releasing hormone-arginine testing in human immunodeficiency virus lipodystrophy

Prior studies suggest reduced overnight GH secretion in association with excess visceral adiposity among patients with HIV lipodystrophy (LIPO, i.e. with fat redistribution). We now investigate GH responses to standardized GHRH-arginine in LIPO patients (n = 39) in comparison with body mass index- and age-matched control groups [HIV patients without fat distribution (NONLIPO, n = 17)] and healthy subjects (C, n = 16). IGF-I [242 +/- 17; 345 +/- 38; 291 +/- 27 ng/ml (P < 0.05 vs. NONLIPO)] was lowest in the LIPO group. Our data demonstrate failure rates of 18% for the LIPO group vs. 5.9% for the NONLIPO group and 0% for the C group, using a stringent criterion of 3.3 ng/ml for peak GH response to GHRH-arginine (P < 0.05 LIPO vs. C). Using less stringent cutoffs, the failure rate in the LIPO group rises to 38.5% at 7.5 ng/ml. Among the LIPO patients, the peak GH response to GHRH-arginine was significantly predicted by visceral adipose tissue (P = 0.008), free fatty acid (P = 0.04), and insulin level (P = 0.007) in regression modeling controlling for age, body mass index, sc fat area, and triglyceride level. These data demonstrate increased failure rates to standardized stimulation testing with GHRH-arginine in LIPO patients, in association with increased visceral adiposity. The effects of low-dose GH should be assessed in the large subset of LIPO patients with abnormal GH stimulation testing.     

Beta-cell dysfunction and low insulin clearance in insulin-resistant human immunodeficiency virus (HIV)-infected patients with lipodystrophy

OBJECTIVE: To obtain a better understanding of the physiological aspects of glucose homeostasis in human immunodeficiency virus (HIV)-infected patients with lipodystrophy, we evaluated separately beta-cell function and insulin sensitivity after an oral glucose load. DESIGN: Beta-cell function was investigated during an oral glucose tolerance test (OGTT) (75 g, 180 min) in 16 lipodystrophic HIV-infected patients and in 15 age- and weight-matched nonlipodystrophic HIV-infected patients. All participants were sedentary Caucasian males, who were on highly active antiretroviral therapy with no history of diabetes mellitus or impaired glucose tolerance. Prehepatic insulin secretion rates were estimated by deconvolution of C-peptide concentrations. A composite measure of insulin sensitivity was derived from the OGTT. RESULTS: Beta-cell secretory capacity (i.e. the rate of change in insulin secretion per unit change in glucose concentration) was similar in lipodystrophic and nonlipodystrophic patients (6.2 +/- 1.0 mU kg(-1) min(-1) mg(-1) dl vs. 5.4 +/- 0.4, P > 0.4), but insulin sensitivity was reduced by 61% in lipodystrophic patients (P < 0.004). The disposition index (insulin capacity multiplied with insulin sensitivity) and insulin clearance rate were reduced in lipodystrophic patients (-55%, P < 0.003 and -31%, P < 0.004). Insulin clearance rate correlated strongly with insulin sensitivity (r = 0.82, P < 0.001). More lipodystrophic than nonlipodystrophic patients exhibited impaired glucose tolerance and diabetes mellitus (63%vs. 20%, P < 0.05). CONCLUSIONS: Our data support the concept that impaired glucose tolerance in lipodystrophic HIV-infected patients relates to a failure of the beta-cells to fully compensate for decrements in insulin sensitivity despite simultaneous reduction in insulin clearance.