Energy Management for Personalized Weight Reduction (EMPOWER) Program: Three-Year Outcome Data.

BACKGROUND: The current consensus guidelines for management of pediatric obesity recommend clinic-based, family-centered, multi-disciplinary interventions. It is well reported that these programs often only lead to modest improvements in BMI status. The individual factors that differentiate which patient's BMI status will improve vs. worsen remains understudied. A retrospective cohort study was conducted to evaluate the outcomes of EMPOWER clinic and identify the participant specific characteristics that predicted BMI status improvement in this population. METHODS: Youth who completed at least 6 visits in EMPOWER were included. Paired t-test was utilized to evaluate the mean change in zBMI, modified BMIz and %BMIp95 from baseline to 6th visit, and multivariate mixed effect models were utilized to analyze effect of baseline characteristics on change in BMI status. RESULTS: 92 participants were included in the analysis, 87% with severe obesity and 66% Hispanic. At the 6th visit, there was a significant reduction in zBMI (-0.09 SD, p <0.001) and modified BMIz (-0.0003 SD, p = 0.04) with a small reduction in %BMIp95 (-1.15 %, p = 0.20). Lower BMI status (p < 0.001) and absence of a comorbidity (p < 0.05) at baseline were predictors of BMI status improvement whereas age, gender, ethnicity, family history of obesity and insurance status were not significant predictors. CONCLUSIONS: Given that implementation of the current guidelines for management of obesity in pediatrics only results in modest BMI status reduction, further investigation is required to understand how the determinants of obesity-related health outcomes can guide development of more innovative, effective interventions for this high risk population.

An addiction model-based mobile health weight loss intervention in adolescents with obesity.

BACKGROUND: Clinical approaches to treating childhood obesity can be expensive and poorly reimbursed, and often produce suboptimal results. It has been theorized that overeating may have addictive qualities, and a sizable number of adolescents with obesity endorse addictive habits. Interestingly, few weight management interventions have tested techniques founded in addiction medicine principles. We therefore performed a pilot study of an addiction model based mHealth weight loss intervention in adolescents. METHODS: Adolescents with obesity were recruited from an multidisciplinary weight management clinic (EMPOWER). Adolescents without significant obesity comorbidities, who exhibited signs of addictive eating, based on the Yale Food Addiction Scale, were enrolled in a pilot study of an interactive, addiction-based, weight loss smartphone app with coaching (http://clinicaltrials.gov: NCT02689154). The app was designed to help subjects omit problem foods, avoid snacking and reduce meal size. A contemporary cohort of adolescents who completed the EMPOWER program were evaluated. Feasibility of recruitment, adherence, retention rates, BMI change and cost of intervention were examined. RESULTS: Eighteen participants were recruited to app intervention. App participants had higher retention (100% vs. 37%) and lower total cost per patient ($855.15 vs. $1428.00) than the EMPOWER clinic participants. App participants exhibited a significant decrease in zBMI and %BMIp95 over the 6 months (p < 0.001 and p = 0.001), which was comparable to the age-matched EMPOWER program completers (p = 0.31 and p = 0.06). CONCLUSIONS: An addiction medicine-based mHealth intervention targeted for adolescents was feasible to implement, resulted in high retention and adherence rates, and reduced zBMI and %BMIp95 in a more cost-effective manner than an in-clinic intervention.

Effects of exenatide on weight and appetite in overweight adolescents and young adults with Prader-Willi syndrome.

BACKGROUND: Prader-Willi syndrome (PWS) is associated with hyperphagia and hyperghrelinemia with major morbidity because of obesity without effective medical treatment targeting hyperphagia. Exenatide (Byetta [synthetic Exendin-4]; AstraZeneca, Wilmington DE) is a GLP-1 receptor agonist which reduces appetite and weight and may be an effective treatment in PWS. OBJECTIVE: The objective of this study is to determine the effect of a 6-month trial of exenatide on appetite, weight and gut hormones in youth with PWS. METHODS: Ten overweight and obese subjects with PWS (13-25 years) were recruited for a 6-month open-label, non-randomized, longitudinal study conducted at Children's Hospital Los Angeles. Exenatide was given using standard diabetes dosing without dietary modifications. Weight, body mass index (BMI), truncal fat, appetite and plasma acylated ghrelin were measured over 6 months. Mixed meal tolerance tests were performed at 0 and 6 months. RESULTS: Appetite scores significantly decreased from baseline (32.2 ± 8.7) after 1, 3 and 6 moths of treatment (27.5 ± 8.8, 25.4 ± 9.3, and 25.4 ± 7.2 respectively; p = 0.004). Hemoglobin A1c decreased significantly after treatment, but weight, BMI z-score and adiposity did not. There was no significant change in ghrelin. CONCLUSIONS: This is the first longitudinal investigation of the effects of exenatide in subjects with PWS. It was effective in decreasing appetite, without change in weight or BMI in the short term. Larger, controlled, longer-term trials in patients with PWS are needed to confirm the efficacy and safety of exenatide and to evaluate whether its use might induce weight loss when given in conjunction with behavioural modification.

Early injury to cortical and cancellous bone from induction chemotherapy for adolescents and young adults treated for acute lymphoblastic leukemia.

Diminished bone density and skeletal fractures are common morbidities during and following therapy for acute lymphoblastic leukemia (ALL). While cumulative doses of osteotoxic chemotherapy for ALL have been reported to adversely impact bone density, the timing of onset of this effect as well as other changes to bone structure is not well characterized. We therefore conducted a prospective cohort study in pre-adolescent and adolescent patients (10-21years) newly diagnosed with ALL (n=38) to explore leukemia-related changes to bone at diagnosis and the subsequent impact of the first phase of chemotherapy ("Induction"). Using quantitative computerized tomography (QCT), we found that pre-chemotherapy bone properties were similar to age- and sex-matched controls. Subsequently over the one month Induction period, however, cancellous volumetric bone mineral density (vBMD) decreased markedly (-26.8%, p<0.001) with sparing of cortical vBMD (tibia -0.0%, p=0.860, femur -0.7%, p=0.290). The tibia underwent significant cortical thinning (average cortical thickness-1.2%, p<0.001; cortical area-0.4%, p=0.014), while the femur was less affected. Areal BMD (aBMD) concurrently measured by dual-energy X-ray absorptiometry (DXA) underestimated changes from baseline as compared to vBMD. Biochemical evidence revealed prevalent Vitamin D insufficiency and a net resorptive state at start and end of Induction. Our findings demonstrate for the first time that significant alterations to cancellous and cortical bone develop during the first month of treatment, far earlier during ALL therapy than previously considered. Given that osteotoxic chemotherapy is integral to curative regimens for ALL, these results provide reason to re-evaluate traditional approaches toward chemotherapy-associated bone toxicity and highlight the urgent need for investigation into interventions to mitigate this common adverse effect.

A novel biopsy method to increase yield of subcutaneous abdominal adipose tissue.

Collection of abdominal subcutaneous adipose tissue (SAT) for research testing is traditionally performed using punch biopsy or needle aspiration techniques, yielding small amounts of very superficial SAT (100-500 mg). Although liposuction techniques can be used to obtain large amounts of SAT, these approaches can compromise the integrity of the adipose tissue. Therefore, we investigated a novel method using a 6-mm Bergström side-cutting biopsy needle to acquire suitable amounts of intact abdominal SAT for multiple complex studies such as flow cytometry, RNA extraction, ex vivo expression of molecular and post-translational protein mediators, and histology. Fifty biopsies were obtained from 29 participants using a Bergström biopsy needle, applying transient manual suction and shearing large pieces of fat within the inner-cutting trochar. Eighteen of the biopsies were performed under ultrasound guidance, whereby we successfully sampled deep SAT (dSAT) from below Scarpa's fascia. The average weight of SAT sampled was 1.5 ± 0.4 g. There was no clinically important bleeding or ecchymosis on the abdominal wall and no infection occurred with this procedure. The 6-mm Bergström biopsy needle yielded substantially more SAT than what has been obtained from superficial procedures and, for the first time, allowed sampling of dSAT by a percutaneous approach.

Adipocyte differentiation is affected by media height above the cell layer.

BACKGROUND: 3T3-L1 cells have been widely used as a model for adipogenesis. However, despite its popularity, differentiation of this cell line has been reported to be inconsistent with low efficiency. OBJECTIVE: To investigate the effect of media height during adipocyte differentiation on lipid accumulation and adipokine secretion in mature adipocytes. METHODS: Three cell lines (3T3-L1, OP9 and ChubS7) were used to test the influence of media volume on adipogenesis. Total lipid content and lipid droplet size and number were quantified. Adipocyte related gene expressions were quantified during the course of differentiation. Secretion of leptin and adiponectin from mature adipocytes were measured using enzyme-linked immunosorbent assays. The influence of oxygen partial pressure on adipogenesis was investigated using three oxygen percentages: 5, 21 and 30%. Insulin sensitivity was measured by insulin inhibition of isoproterenol-induced lipolysis and phosphorylation of insulin receptor substrate-1. RESULTS: A lower media height during adipogenesis increased total lipid accumulation, NEFA release and leptin and adiponectin secretion in mature adipocytes. Insulin sensitivity was not affected by media height during differentiation. CONCLUSION: Media height during adipogenesis was inversely correlated with lipid content in mature adipocytes. To achieve a high lipid content and greater adipokine secretion, it is best to use a low media volume during differentiation.

Autonomic and metabolic effects of OSA in childhood obesity.

This study investigates the effects of exposure to intermittent hypoxia on cardiovascular autonomic control and metabolic function in obese children with obstructive sleep apnea (OSA). Each subject underwent: (1) a polysomnography; (2) morning fasting blood samples and a subsequent FSIVGTT; (3) noninvasive measurement of respiration, arterial blood pressure, and heart rate during supine and standing postures. Assessment of adiposity was performed using a DEXA scan. From these measurements, we deduced the pertinent sleep parameters, Bergman minimal model parameters and the parameters characterizing a minimal model of cardiovascular variability. Results suggest that intermittent hypoxia in OSA contributes independently to insulin resistance and autonomic dysfunction in overweight children.

Differential effect of marrow adiposity and visceral and subcutaneous fat on cardiovascular risk in young, healthy adults.

BACKGROUND: Adipose tissue is an endocrine organ that influences many metabolic processes and accumulates in different depots, including the bone marrow. While the negative associations between visceral fat (VF) or subcutaneous fat (SF) and cardiovascular disease (CVD) risks are well known, the relation between marrow fat (MF) and metabolic risk is unexplored. OBJECTIVES: We examined the relations between these three fat depots and whether CVD risks are associated with marrow adiposity. DESIGN: Observational cross-sectional study. SUBJECTS AND METHODS: Computed tomography was used to measure VF, SF and MF depots in 131 healthy young adults (60 females, 71 males; 16-25 years of age). Weight, body mass index (BMI), waist and hip circumferences, blood pressure (BP), carotid intima-media thickness (CIMT) and serum levels of lipids, glucose and insulin were also measured. RESULTS: Regardless of gender, MF was not associated with values of VF or SF, anthropometric measures, or lipid or carbohydrate serum levels (P>0.05 for all). In contrast, VF was associated with SF (r values=0.74 for females, 0.78 for males; both P-values <0.0001) and these depots were related to anthropometric parameters (r values between 0.69 and 0.87; all P-values <0.0001) and to most measures of lipids, glucose or insulin (r values between 0.25 and 0.62). CONCLUSIONS: Marrow adiposity in young men and women is independent of VF and SF, and is not associated with CVD risk. These findings do not support the concept that marrow adiposity is involved in the comorbidities related to fat accumulation in other compartments.

Lack of hepatic "interregulation" during inhibition of glycogenolysis in a canine model.

It has been proposed that the glycogenolytic and gluconeogenic pathways contributing to endogenous glucose production are interrelated. Thus a change in one source of glucose 6-phosphate might be compensated for by an inverse change in the other pathway. We therefore investigated the effects of 1,4-dideoxy-1,4-imino-D-arabinitol (DAB), a potent glycogen phosphorylase inhibitor, on glucose production in fasted conscious dogs. When dogs were treated acutely with high glucagon, glucose production rose from 1.93 +/- 0.14 to 3.07 +/- 0.37 mg x kg(-1) x min(-1) (P < 0.01). When dogs were treated acutely with DAB in addition to high glucagon infusion, the stimulation of the glycogenolytic rate was completely suppressed. Glucose production rose from 1.85 +/- 0.20 to 2.41 +/- 0.17 mg x kg(-1) x min(-1) (P < 0.05), which was due to the increase in gluconeogenesis from 0.93 +/- 0.09 to 1.54 +/- 0.08 mg x kg(-1) x min(-1) (P < 0.001). In conclusion, infusion of DAB inhibited glycogenolysis; however, the absolute contribution of gluconeogenesis to glucose production was not affected. These results suggest that inhibition of glycogenolysis could be an effective antidiabetic treatment.

Central role of the adipocyte in the metabolic syndrome.

Insulin resistance is associated with a plethora of chronic illnesses, including Type 2 diabetes, dyslipidemia, clotting dysfunction, and colon cancer. The relationship between obesity and insulin resistance is well established, and an increase in obesity in Western countries is implicated in increased incidence of diabetes and other diseases. Central, or visceral, adiposity has been particularly associated with insulin resistance; however, the mechanisms responsible for this association are unclear. Our laboratory has been studying the physiological mechanisms relating visceral adiposity and insulin resistance. Moderate fat feeding of the dog yields a model reminiscent of the metabolic syndrome, including visceral adiposity, hyperinsulinemia, and insulin resistance. We propose that insulin resistance of the liver derives from a relative increase in the delivery of free fatty acids (FFA) from the omental fat depot to the liver (via the portal vein). Increased delivery results from 1) more stored lipids in omental depot, 2) severe insulin resistance of the central fat depot, and 3) possible regulation of visceral lipolysis by the central nervous system. The significance of portal FFA delivery results from the importance of FFA in the control of liver glucose production. Insulin regulates liver glucose output primarily via control of adipocyte lipolysis. Thus, because FFA regulate the liver, it is expected that visceral adiposity will enhance delivery of FFA to the liver and make the liver relatively insulin resistant. It is of interest how the intact organism compensates for insulin resistance secondary to visceral fat deposition. While part of the compensation is enhanced B-cell sensitivity to glucose, an equally important component is reduced liver insulin clearance, which allows for a greater fraction of B-cell insulin secretion to bypass liver degradation, to enter the systemic circulation, and to result in hyperinsulinemic compensation. The signal(s) resulting in B-cell up-regulation and reduced liver insulin clearance with visceral adiposity is (are) unknown, but it appears that the glucagon-like peptide (GLP-1) hormone plays an important role. The integrated response of the organism to central adiposity is complex, involving several organs and tissue beds. An investigation into the integrated response may help to explain the features of the metabolic syndrome.

Paradoxical effect of troglitazone in normal animals: enhancement of adipocyte but reduction of liver insulin sensitivity.

Troglitazone is an antidiabetic agent that improves the ability of adipocytes to store triglycerides by enhancing their insulin sensitivity. Although potent in insulin-resistant states, the effect of troglitazone on lipid and glucose turnover in normal animals has not been assessed. Euglycemic clamps were performed as an insulin dose response in normal mongrel dogs (n = 6). Somatostatin was infused without hormone replacement (zero insulin) for 90 min. Insulin was then either portally replaced (1.8 pmol x min(-1) x kg(-1), overreplaced (5.4 pmol x min(-1) x kg(-1)), or overreplaced peripherally to match the systemic levels of the portal overreplacement dose (2.3 pmol x min(-1) x kg(-1)) for 180 min. A total of 600 mg troglitazone was then given orally each day for 3 weeks and continued throughout a second experimental phase, at which point the euglycemic clamps were repeated. In concordance with previous studies, endogenous glucose production (EGP) was similar whether insulin was delivered portally or peripherally, both before and during troglitazone treatment. Although free fatty acids (FFAs) at zero insulin were not affected, there was a leftward shift of the insulin-FFA dose response curve secondary to a suppression of FFA release into plasma. EGP was paradoxically elevated by troglitazone treatment because of an elevation of both gluconeogenesis and glycogenolysis. In conclusion, troglitazone reduced hepatic sensitivity to FFAs. Because EGP is a primary determinant of fasting blood glucose, we hypothesize that a protective mechanism exists in normal animals, preventing hypoglycemia during insulin sensitization with troglitazone.

Longitudinal compensation for fat-induced insulin resistance includes reduced insulin clearance and enhanced beta-cell response.

Central adiposity is highly correlated with insulin resistance, which is an important risk factor for type 2 diabetes and other chronic diseases. However, in normal individuals, central adiposity can be tolerated for many years without development of impaired glucose tolerance or diabetes. Here we examine longitudinally the mechanisms by which glucose tolerance can be maintained in the face of substantial insulin resistance. Normal dogs were fed a diet enriched with moderate amounts of fat (2 g x kg(-1) x day(-1)), similar to that seen in modern "cafeteria" diets, and the time course of metabolic changes in these animals was examined over 12 weeks. Trunk adiposity as assessed by magnetic resonance imaging increased from 12 to 19%, but body weight remained unchanged. Insulin sensitivity (SI) as determined by frequently sampled intravenous glucose tolerance tests was measured over a 12-week period. SI decreased 35% by week 1 and remained impaired for the entire 12 weeks. Intravenous glucose tolerance was reduced transiently for 1 week, recovered to baseline, and then again began to decline after 8 weeks. First-phase insulin response began to increase after week 2, peaked by week 6 (190% of basal), and then declined. The increase in insulin response was due partially to enhanced beta-cell function (22%) but due also to an approximately 50% reduction in insulin clearance. This compensation by insulin clearance was also confirmed with insulin clamps performed in fat-fed versus control dogs. The present study confirms the ability of the normal individual to compensate for fat-induced insulin resistance by enhanced insulin response, such that the product of insulin sensitivity x secretion is little changed. However, the compensation is due as much to reduced insulin clearance as increased beta-cell sensitivity to glucose. Reduced hepatic extraction of insulin may be the first line of defense providing a higher proportion of secreted insulin to the periphery and sparing the beta-cells during compensation for the insulin-resistant state.

Inhibition of lipolysis causes suppression of endogenous glucose production independent of changes in insulin.

We have shown that insulin controls endogenous glucose production (EGP) indirectly, via suppression of adipocyte lipolysis. Free fatty acids (FFA) and EGP are suppressed proportionately, and when the decline in FFA is prevented during insulin infusion, suppression of EGP is also prevented. The present study tested the hypothesis that suppression of lipolysis under conditions of constant insulin would yield a suppression of EGP. N(6)-cyclohexyladenosine (CHA) was used to selectively suppress adipocyte lipolysis during euglycemic clamps in conscious male dogs. FFA suppression by CHA caused suppression of EGP. Liposyn control experiments, which maintained FFA levels above basal during CHA infusion, completely prevented the decline in EGP, whereas glycerol control experiments, which maintained glycerol levels close to basal, did not prevent a decline in EGP. These controls suggest that the EGP suppression was secondary to the suppression of FFA levels specifically. A difference in the sensitivity of FFA and EGP suppression (FFA were suppressed approximately 85% whereas EGP only declined approximately 40%) was possibly caused by confounding effects of CHA, including an increase in catecholamine and glucagons levels during CHA infusion. Thus suppression of lipolysis under constant insulin causes suppression of EGP, despite a significant rise in catecholamines.

Rapid oscillations in omental lipolysis are independent of changing insulin levels in vivo.

Abnormal fat metabolism plays an important role in the pathogenesis of obesity-related type 2 diabetes mellitus. This study examined whether free fatty acid levels (FFAs), like insulin levels, oscillate rapidly in plasma. Peripheral and portal blood samples from dogs were assayed for FFA, glycerol, glucose, and insulin. FFA and glycerol showed correlated oscillatory profiles, with about 8 pulses/hour. Omental lipolysis was also pulsatile, with about 10 pulses/hour, and insulin levels oscillated rapidly in plasma with about 7 pulses/hour. We applied an insulin clamp, beta-adrenergic blockade, or both together, to determine the driving force behind the FFA oscillation, and we analyzed our findings by approximate entropy (ApEn) for which lower values suggest regular pulses and higher values suggest disorder. Under basal conditions, ApEn was 0.3 +/- 0.2. With insulin not oscillating, FFA still cycled at about 9 pulses/hour and the ApEn was 0.2 +/- 0.1. In contrast, beta-blockade, either in the presence or absence of an insulin clamp, removed the FFA oscillation in three of nine dogs. In the other six dogs, the oscillatory profile was unchanged, but ApEn was significantly higher than basal values, suggesting that the regularity of the profile was disrupted. These results suggest that the FFA oscillation is driven by the central nervous system, not by insulin.

Prolonged elevation of plasma free fatty acids impairs pancreatic beta-cell function in obese nondiabetic humans but not in individuals with type 2 diabetes.

Our recent in vivo observations in healthy nonobese humans have demonstrated that prolonged elevation of plasma free fatty acids (FFAs) results in diminished glucose-stimulated insulin secretion (GSIS) when the FFA-mediated decrease in insulin sensitivity is taken into account. In the present study, we investigated whether obese individuals and patients with type 2 diabetes are more sensitive than healthy control subjects to the inhibitory effect of prolonged elevation of plasma FFAs on GSIS. In seven patients with type 2 diabetes and seven healthy nondiabetic obese individuals, we assessed GSIS with a programmed graded intravenous glucose infusion on two occasions, 6-8 weeks apart, with and without a prior 48-h infusion of heparin and Intralipid, which was designed to raise plasma FFA concentration approximately twofold over basal. The nondiabetic obese subjects had a significant 21% decrease in GSIS (P = 0.0008) with the heparin and Intralipid infusion, associated with a decrease in whole body insulin clearance. The impairment in GSIS was evident at low (<11 mmol/l) but not at higher plasma glucose concentrations. In contrast, the patients with type 2 diabetes had a slight increase in GSIS (P = 0.027) and no change in insulin clearance, although there was marked interindividual variability in response. Plasma proinsulin concentrations measured in a subset of subjects were not altered in either group by the infusion of heparin and Intralipid. In summary, 1) obese nondiabetic individuals are susceptible to a desensitization of GSIS with heparin and Intralipid infusion, and 2) patients with type 2 diabetes do not demonstrate such susceptibility when FFAs are elevated approximately twofold above basal with heparin and Intralipid. Our results suggest that FFAs could play an important role in the development of beta-cell failure in obese individuals who are at risk for developing type 2 diabetes. They do not, however, seem to further deteriorate the beta-cell function of patients who already have established type 2 diabetes and may even result in a slight increase in GSIS in this latter group.

Acute enhancement of insulin secretion by FFA in humans is lost with prolonged FFA elevation.

The in vivo effect of elevated free fatty acids (FFA) on beta-cell function in humans remains extremely controversial. We examined, in healthy young men, the acute (90 min) and chronic (48 h) effects of an approximately twofold elevation of plasma FFA vs. control on glucose-stimulated insulin secretion (GSIS). GSIS was studied in response to a graded intravenous glucose infusion (peak plasma glucose, approximately 10 mmol/l, n = 8) and a two-step hyperglycemic clamp (10 and 20 mmol/l, n = 8). In the acute studies, GSIS was significantly higher, insulin sensitivity index (SI) was lower, and disposition index (DI = insulin sensitivity x insulin secretion) was unchanged with elevated FFA vs. control [2-step clamp: DI = 8.9 +/- 1.4 x 10(-3) l2. kg-1. min-2 in control vs. 10.0 +/- 1.9 x 10(-3) l2. kg-1. min-2 with high FFA, P = nonsignificant (NS)]. In the chronic studies, there was no difference in absolute GSIS between control and high FFA studies, but there was a reduction in SI and a loss of the expected compensatory increase in insulin secretion as assessed by the DI (2-step clamp: DI = 10.0 +/- 1.2 x 10(-3) l2. kg-1. min-2 in control vs. 6.1 +/- 0.7 x 10(-3) l2. kg-1. min-2 with high FFA, P = 0.01). In summary, 1) acute and chronic FFA elevation induces insulin resistance; 2) with acute FFA elevation, this insulin resistance is precisely countered by an FFA-induced increase in insulin secretion, such that DI does not change; and 3) chronic FFA elevation disables this beta-cell compensation.

Role of portal insulin delivery in the disappearance of intravenous glucose and assessment of insulin sensitivity.

The contribution of portal insulin delivery to the disappearance of glucose administered intravenously was assessed in the present study. Paired insulin-modified intravenous glucose tolerance tests (IVGTTs) were performed in dogs in which insulin was administered into the portal vein or into a peripheral vein. Peripheral insulin levels were matched in the paired IVGTTs by adjusting the portal insulin dose in proportion to first-pass hepatic insulin extraction. Two sets of IVGTTs were performed. In the first set, hepatic insulin extraction was assumed to be 50% (insulin doses of 0.03 U/kg portal and 0.015 U/kg peripheral; n = 6); in the second set, the assumed extraction rate was reduced to 33% (0.0225 U/kg portal and 0.015 U/kg peripheral; n = 8). In the second set of experiments, a control "zero" dose (no insulin injection) was also performed. For these latter three IVGTTs, the exogenous glucose bolus was labeled with 3-[3H]glucose (25 microCi) to separately assess insulin's effects on the rate of glucose disappearance (Rd) and endogenous glucose production (EGP). For the paired IVGTT based on 33% extraction, the area under the insulin curves after the portal insulin injection was within 2% of that observed with peripheral insulin injection (1,820 +/- 711 vs. 1,791 +/- 661 microU/ml min; P = 0.79). For these conditions, neither the glucose profiles nor the minimal model estimate of insulin sensitivity (S(I)) was significantly influenced by the higher portal insulin delivery (S(I): 3.69 +/- 0.56 vs. 3.35 +/- 0.60 10(-4) min(-1) per microU/ml; portal vs. peripheral; P > 0.05). Analysis of the 3-[3H]glucose tracer dynamics failed to reveal any differences in the portal versus peripheral insulin effect on glucose disappearance or production. We conclude that portal insulin delivery per se does not significantly affect insulin's ability to normalize plasma glucose during acute glucose challenges.

Central role of the adipocyte in insulin resistance.

Mechanisms of insulin resistance in subjects at risk for type 2 diabetes remain to be elucidated. Insulin acts slowly in vivo, but rapidly in vitro, suggesting that the pathway insulin traverses from B-cell to insulin sensitive tissue may be altered in diabetes. An important component of that pathway is transport of insulin across the capillary endothelium. Several groups have demonstrated that insulin resistance may result from reduced capillary permeability to insulin--it remains to be determined whether reduced permeability contributes to insulin resistance in any stage leading to type 2 diabetes. Interestingly, the transport of insulin across the endothelial barrier not only limits the rate of insulin to stimulate glucose uptake by skeletal muscle, but appears also to determine the rate at which insulin suppresses liver glucose output. Because the liver circulation is fenestrated, it is not possible that insulin transport into the liver is the rate determining step for suppression of liver glucose output. An alternative hypothesis was considered--that insulin is transported into an extrahepatic tissue. A "second signal" is generated by the extrahepatic tissue, the signal is released into the blood, and the signal in turn controls hepatic glucose output. Several lines of evidence suggest that the second signal is free fatty acids (FFA): 1) There is a strong correlation between FFA and liver glucose output under a variety of experimental conditions. 2) If FFA are maintained at basal concentrations during insulin administration, glucose output fails to decline. 3) If FFA are reduced independent of insulin administration, glucose output is reduced. These three points support the concept that insulin, by regulating adipocyte lipolysis, controls liver glucose production. Thus, the adipocyte is a critical mediator between insulin and liver glucose output. Evidence that FFA also suppress skeletal muscle glucose uptake and insulin secretion from the B-cell supports the overall central role of the adipocyte in the regulation of glycemia. Insulin resistance at the fat cell may be an important component of the overall regulation of glycemia because of the relationships between FFA and glucose production, glucose uptake, and insulin release. It is possible that insulin resistance at the adipocyte itself can be a major cause of the dysregulation of carbohydrate metabolism in the prediabetic state.

Indirect effect of insulin to suppress endogenous glucose production is dominant, even with hyperglucagonemia.

Suppression of endogenous glucose production (EGP) is one of insulin's primary metabolic effects and failure of this action is a major contributor to fasting hyperglycemia of type 2 diabetes mellitus. Classically, insulin was thought to suppress the liver directly, via hyperinsulinemia in the portal vein. Recently, however, we and others have demonstrated that at least part, and possibly most of insulin's action to suppress EGP is normally mediated via an extrahepatic (i.e., indirect) mechanism. We have suggested that this mechanism involves insulin suppression of adipocyte lipolysis, leading to lowered FFA and reduced EGP ("Single Gateway Hypothesis"). Previous studies of the indirect insulin effect from this laboratory were done under conditions of lowered portal glucagon. Because of the possibility that the direct (i.e., portal) effect of insulin may have been underestimated with hypoglucagonemia, these studies examined the relative importance of portal insulin, versus peripheral insulin (administered at one-half the dose to equalize peripheral insulin levels) at four rates of portal glucagon infusion: 0, 0.65 (under-), 1.5 (basal-), and 3.0 ng/kg per min (over-replacement). Portal versus peripheral insulin suppressed steady-state EGP to the same extent (52%), confirming that the primary effect of insulin to suppress EGP is via the peripheral mechanism. This conclusion was maintained regardless of portal glucagonemia, although there was some evidence for an increase in the direct insulin effect at hyperglucagonemia. The indirect effect of insulin is the primary mechanism of steady-state EGP suppression under normal conditions. The direct effect increases with hyperglucagonemia; however, the indirect effect remains predominant even under those conditions.

Causal linkage between insulin suppression of lipolysis and suppression of liver glucose output in dogs.

Suppression of hepatic glucose output (HGO) has been shown to be primarily mediated by peripheral rather than portal insulin concentrations; however, the mechanism by which peripheral insulin suppresses HGO has not yet been determined. Previous findings by our group indicated a strong correlation between free fatty acids (FFA) and HGO, suggesting that insulin suppression of HGO is mediated via suppression of lipolysis. To directly test the hypothesis that insulin suppression of HGO is causally linked to the suppression of adipose tissue lipolysis, we performed euglycemic-hyperinsulinemic glucose clamps in conscious dogs (n = 8) in which FFA were either allowed to fall or were prevented from falling with Liposyn plus heparin infusion (LI; 0.5 ml/min 20% Liposyn plus 25 U/min heparin with a 250 U prime). Endogenous insulin and glucagon were suppressed with somatostatin (1 microgram/min/kg), and insulin was infused at a rate of either 0.125 or 0.5 mU/min/kg. Two additional experiments were performed at the 0.5 mU/min/kg insulin dose: a double Liposyn infusion (2 x LI; 1.0 ml/min 20% Liposyn, heparin as above), and a glycerol infusion (19 mg/min). With the 0.125 mU/min/kg insulin infusion, FFA fell 40% and HGO fell 33%; preventing the fall in FFA with LI entirely prevented this decline in HGO. With 0.5 mU/min/kg insulin infusion, FFA levels fell 64% while HGO declined 62%. Preventing the fall in FFA at this higher insulin dose largely prevented the fall in HGO; however, steady state HGO still declined by 18%. Doubling the LI infusion did not further affect HGO, suggesting that the effect of FFA on HGO is saturable. Elevating plasma glycerol levels did not alter insulin's ability to suppress HGO. These data directly support the concept that insulin suppression of HGO is not direct, but rather is mediated via insulin suppression of adipose tissue lipolysis. Thus, resistance to insulin control of hepatic glucose production in obesity and/or non-insulin-dependent diabetes mellitus may reflect resistance of the adipocyte to insulin suppression of lipolysis.