The Injurious Effects of Hyperinsulinism on Blood Vessels

Insulin resistance (IR) is a common feature of hypertension, Type II diabetes, coronary heart disease, Syndrome X, and other vascular diseases. It refers to a state in which a certain concentration of insulin produces less biologic effect than expected in human body. When IR develops, the response of human body to insulin decreases accordingly, thus inducing the compensatory hyper-secretion of insulin and consequently hyperinsulinism. Many clinical and epidemiologic studies have demonstrated that IR and iatrogenic hyperinsulinism induced consequently play an essential role in the pathogenesis of hypertension and atherosclerotic cardiovascular diseases. Therefore, more and more attention should be paid to the mechanism of IR in order to explore more therapeutic basis and prospective for the treatment of atherosclerosis and other cardiovascular diseases. In this review, we provided a general overview on the known molecular mechanisms of IR and summarized the recent findings on the injurious effects of hyperinsulinism in vitro and in vivo, which might be important for researchers and clinicians to better understand the etiology and clinical significance of IR.     

Type 2 diabetes: an atherothrombotic syndrome

Insulin resistance is found in around 80-90% of subjects with older onset (type 2) diabetes and in approximately 25% of the general population. Insulin resistance prior to the development of frank type 2 diabetes and type 2 diabetes itself is associated with a significant increase in the risk of atherothrombotic disease, which is due in part to a disruption in the balance of factors regulating coagulation and fibrinolysis. Both insulin resistance and type 2 diabetes are associated with the development of endothelial dysfunction, and enhanced platelet aggregation and activation. Whilst the plasma levels of many clotting factors including fibrinogen, FVII, FVIII, FXII, FXIII b-subunit are elevated, the fibrinolytic system is relatively inhibited as a consequence of an increase in plasminogen activator inhibitor type-1 (PAI-1) levels. These changes favour the development of a hypercoagulable pro-thrombotic state, which may in turn enhance cardiovascular risk by increasing the likelihood of developing an occlusive thrombus within a coronary/cerebral artery, and/or contributing to the development of atherosclerotic lesions. This article reviews the current published evidence of the pro-thrombotic changes that occur in association with type 2 diabetes and insulin resistance, and the putative underlying mechanisms which lead to these changes.     

Central role of the adipocyte in the insulin-sensitising and cardiovascular risk modifying actions of the thiazolidinediones

Insulin resistance is a key metabolic defect in type 2 diabetes that is exacerbated by obesity, especially if the excess adiposity is located intra-abdominally/centrally. Insulin resistance underpins many metabolic abnormalities-collectively known as the insulin resistance syndrome-that accelerate the development of cardiovascular disease. Thiazolidinedione anti-diabetic agents improve glycaemic control by activating the nuclear receptor peroxisome proliferator activated receptor-gamma (PPARgamma). This receptor is highly expressed in adipose tissues. In insulin resistant fat depots, thiazolidinediones increase pre-adipocyte differentiation and oppose the actions of pro-inflammatory cytokines such as tumour necrosis factor-alpha. The metabolic consequences are enhanced insulin signalling, resulting in increased glucose uptake and lipid storage coupled with reduced release of free fatty acids (FFA) into the circulation. Metabolic effects of PPARgamma activation are depot specific-in people with type 2 diabetes central fat mass is reduced and subcutaneous depots are increased. Thiazolidinediones increase insulin sensitivity in liver and skeletal muscle as well as in fat, but they do not express high levels of PPARgamma, suggesting that improvement in insulin action is indirect. Reduced FFA availability from adipose tissues to liver and skeletal muscle is a pivotal component of the insulin-sensitising mechanism in these latter two tissues. Adipocytes secrete multiple proteins that may both regulate insulin signalling and impact on abnormalities of the insulin resistance syndrome--this may explain the link between central obesity and cardiovascular disease. Of these proteins, low plasma adiponectin is associated with insulin resistance and atherosclerosis--thiazolidinediones increase adipocyte adiponectin production. Like FFA, adiponectin is probably an important signalling molecule regulating insulin sensitivity in muscle and liver. Adipocyte production of plasminogen activator inhibitor-1 (PAI-1), an inhibitor of fibrinolysis, and angiotensin II secretion are partially corrected by PPARgamma activation. The favourable modification of adipocyte-derived cardiovascular risk factors by thiazolidinediones suggests that these agents may reduce cardiovascular disease as well as provide durable glycaemic control in type 2 diabetes.     

Hypertriglyceridemia secondary to obesity and diabetes

Hypertriglyceridemia is a common lipid abnormality in persons with visceral obesity, metabolic syndrome and type 2 diabetes. Hypertriglyceridemia typically occurs in conjunction with low HDL levels and atherogenic small dense LDL particles and is associated with increased cardiovascular risk. Insulin resistance is often an underlying feature and results in increased free fatty acid (FFA) delivery to the liver due to increased peripheral lipolysis. Increased hepatic VLDL production occurs due to increased substrate availability via FFAs, decreased apolipoprotein B100 degradation and increased lipogenesis. Postprandial hypertriglyceridemia also is a common feature of insulin resistance. Small dense LDL that coexist with decreased HDL particles in hypertriglyceridemic states are highly pro-atherogenic due to their enhanced endothelial permeability, proteoglycan binding abilities and susceptibility to oxidation. Hypertriglyceridemia also occurs in undertreated individuals with type 1 diabetes but intensive glucose control normalizes lipid abnormalities. However, development of visceral obesity in these patients unravels a similar metabolic profile as in patients with insulin resistance. Modest hypertriglyceridemia increases cardiovascular risk, while marked hypertriglyceridemia should be considered a risk for pancreatitis. Lifestyle modification is an important therapeutic strategy. Drug therapy is primarily focused on lowering LDL levels with statins, since efforts at triglyceride lowering and HDL raising with fibrates and/or niacin have not yet been shown to be beneficial in improving cardiovascular risk. Fibrates, however, are first-line agents when marked hypertriglyceridemia is present. This article is part of a Special Issue entitled Triglyceride Metabolism and Disease.     

Born small for gestational age: increased risk of type 2 diabetes,hypertension and hyperlipidaemia in adulthood

The metabolic and cardiovascular complications associated with reduced fetal growth have been identified in the past 10 years. These include cardiovascular disease and the insulin resistance syndrome, comprising dyslipidaemia and impaired glucose tolerance or type 2 diabetes, and they appear to result from the initial development of insulin resistance. Although the mechanism underlying the development of insulin resistance associated with reduced fetal growth remains unclear, there is some evidence that adipose tissue plays a key role. Over the past decade, several hypotheses have been proposed to explain this unexpected association. Each points to either a detrimental fetal environment, genetic susceptibility or an interaction between the two. Although yet to be confirmed, the hypothesis suggesting that the association could be the consequence of genetic-environmental interactions is at present the most attractive.     

Molecular mechanisms of chromium in alleviating insulin resistance

Type 2 diabetes is often associated with obesity, dyslipidemia and cardiovascular anomalies and is a major health problem approaching global epidemic proportions. Insulin resistance, a prediabetic condition, precedes the onset of frank type 2 diabetes and offers potential avenues for early intervention to treat the disease. Although lifestyle modifications and exercise can reduce the incidence of diabetes, compliance has proved to be difficult, warranting pharmacological interventions. However, most of the currently available drugs that improve insulin sensitivity have adverse effects. Therefore, attractive strategies to alleviate insulin resistance include dietary supplements. One such supplement is chromium, which has been shown to reduce insulin resistance in some, but not all, studies. Furthermore, the molecular mechanisms of chromium in alleviating insulin resistance remain elusive. This review examines emerging reports on the effect of chromium, as well as molecular and cellular mechanisms by which chromium may provide beneficial effects in alleviating insulin resistance.     

Oxidative stress--mediated alterations in glucose dynamics in a genetic animal model of type II diabetes

Insulin resistance, characterized by an inexorable decline in skeletal muscle glucose utilization and/or an excessive hepatic glucose production, constitutes a major pathogenic importance in a cluster of clinical disorders including diabetes mellitus, hypertension, dyslipidemia, central obesity and coronary artery disease. A novel concept suggests that heightened state of oxidative stress during diabetes contributes, at least in part, to the development of insulin resistance. Several key predictions of this premise were subjected to experimental testing using Goto-Kakizaki (GK) rats as a genetic animal model for non-obese type II diabetes. Euglycemic-hyperinsulinemic clamp studies with an insulin infusion index of 5 mU/kg bw/min were used to measure endogenous glucose production (EGP), glucose infusion rate (GIR), glucose disposal rate (GDR) and skeletal muscle glucose utilization index (GUI). Moreover, the status of oxidative stress as reflected by the urinary levels of isoprostane and protein carbonyl formation were also assessed as a function of diabetes. Post-absorptive basal EGP and circulating levels of insulin, glucose and free fatty acid (FFA) were elevated in GK rats, compared to their corresponding control values. In contrast, steady state GIR and GDR of the hyperglycemic/hyperinsulinemic animals were reduced, concomitantly with impaired insulin's ability to suppress EGP. Insulin stimulated [3H]-2-deoxyglucose (2-DG) uptake (a measure of glucose transport activity) by various types of skeletal muscle fibers both in vivo and in vitro (isolated muscle, cultured myoblasts) was diminished in diabetic GK rats. This diabetes-related suppression of skeletal muscle glucose utilization was associated with a decrease in insulin's ability to promote the phosphorylation of tyrosine residues of insulin receptor substrate-1 (IRS-1). Similarly, the translocation of GLUT-4 from intracellular compartment to plasma membrane in response to insulin was also reduced in these animals. Oxidative stress-based markers (e.g. urinary isoprostane, carbonyl-bound proteins) were elevated as a function of diabetes. Nullification of the heightened state of oxidative stress in the GK rats with alpha-lipoic acid resulted in a partial amelioration of the diabetes-related impairment of the in vivo and in vitro insulin actions. Collectively, the above data suggest that 1) insulin resistance in GK rats occurs at the hepatic and skeletal muscle levels, 2) muscle cell glucose transport exhibited a blunted response to insulin and it is associated with a major defect in key molecules of both GLUT-4 trafficking and insulin signaling pathways, 3) skeletal muscle insulin resistance in GK rats appears to be of genetic origin and not merely related to a paracrine or autocrine effect, since this phenomenon is also observed in cultured myoblasts over several passages and finally heightened state of oxidative stress may mediate the development of insulin resistance during diabetes.     

Glucocorticoids produce whole body insulin resistance with changes in cardiac metabolism

Insulin resistance is viewed as an insufficiency in insulin action, with glucocorticoids being recognized to play a key role in its pathogenesis. With insulin resistance, metabolism in multiple organ systems such as skeletal muscle, liver, and adipose tissue is altered. These metabolic alterations are widely believed to be important factors in the morbidity and mortality of cardiovascular disease. More importantly, clinical and experimental studies have established that metabolic abnormalities in the heart per se also play a crucial role in the development of heart failure. Following glucocorticoids, glucose utilization is compromised in the heart. This attenuated glucose metabolism is associated with altered fatty acid supply, composition, and utilization. In the heart, elevated fatty acid use has been implicated in a number of metabolic, morphological, and mechanical changes and, more recently, in "lipotoxicity". In the present article, we review the action of glucocorticoids, their role in insulin resistance, and their influence in modulating peripheral and cardiac metabolism and heart disease.     

Renin-angiotensin-aldosterone system and oxidative stress in cardiovascular insulin resistance

Hypertension commonly occurs in conjunction with insulin resistance and other components of the cardiometabolic syndrome. Insulin resistance plays a significant role in the relationship between hypertension, Type 2 diabetes mellitus, chronic kidney disease, and cardiovascular disease. There is accumulating evidence that insulin resistance occurs in cardiovascular and renal tissue as well as in classical metabolic tissues (i.e., skeletal muscle, liver, and adipose tissue). Activation of the renin-angiotensin-aldosterone system and subsequent elevations in angiotensin II and aldosterone, as seen in cardiometabolic syndrome, contribute to altered insulin/IGF-1 signaling pathways and reactive oxygen species formation to induce endothelial dysfunction and cardiovascular disease. This review examines currently understood mechanisms underlying the development of resistance to the metabolic actions of insulin in cardiovascular as well as skeletal muscle tissue.     

Liver attenuation, pericardial adipose tissue, obesity, and insulin resistance: the Multi-Ethnic Study of Atherosclerosis (MESA)

Insulin resistance is linked to general and abdominal obesity, but its relation to hepatic lipid content and pericardial adipose tissue is less clear. The purpose of this study was to examine cross‐sectional associations of liver attenuation, pericardial adipose tissue, BMI, and waist circumference with insulin resistance. We measured liver attenuation and pericardial adipose tissue using the existing cardiac computed tomography scans in 5,291 individuals free of clinical cardiovascular disease and diabetes in the Multi‐Ethnic Study of Atherosclerosis (MESA) during the study's baseline visit (2000–2002). Low liver attenuation was defined as the lowest quartile and high pericardial adipose tissue as the upper quartile of volume (cm³). We used standard clinical definitions for obesity and abdominal obesity. Insulin resistance was assessed by the homeostasis model assessment of insulin resistance (HOMA_IR) index. In multivariate linear regression with all adiposity measures in the model simultaneously, all adiposity measures were significantly (P < 0.0001) associated with insulin resistance: regression coefficients (±s.e.) were 0.31 (±0.02) for low liver attenuation, 0.27 (±0.02) for high pericardial adipose tissue, 0.27 (±0.02) for obesity, and 0.32 (±0.02) for abdominal obesity. We found significant differences (P = 0.003) between standardized liver attenuation and insulin resistance by ethnicity: regression coefficients per 1 s.d. increment were 0.10 ± 0.01 for whites, 0.11 ± 0.02 for Chinese, 0.08 ± 0.2 for blacks, and 0.14 ± 0.01 for Hispanics. Liver attenuation and pericardial adipose tissue were associated with insulin resistance, independent of BMI and waist circumference.     

Current approaches for assessing insulin sensitivity and resistance in vivo: advantages, limitations, and appropriate usage

Insulin resistance contributes to the pathophysiology of diabetes and is a hallmark of obesity, metabolic syndrome, and many cardiovascular diseases. Therefore, quantifying insulin sensitivity/resistance in humans and animal models is of great importance for epidemiological studies, clinical and basic science investigations, and eventual use in clinical practice. Direct and indirect methods of varying complexity are currently employed for these purposes. Some methods rely on steady-state analysis of glucose and insulin, whereas others rely on dynamic testing. Each of these methods has distinct advantages and limitations. Thus, optimal choice and employment of a specific method depends on the nature of the studies being performed. Established direct methods for measuring insulin sensitivity in vivo are relatively complex. The hyperinsulinemic euglycemic glucose clamp and the insulin suppression test directly assess insulin-mediated glucose utilization under steady-state conditions that are both labor and time intensive. A slightly less complex indirect method relies on minimal model analysis of a frequently sampled intravenous glucose tolerance test. Finally, simple surrogate indexes for insulin sensitivity/resistance are available (e.g., QUICKI, HOMA, 1/insulin, Matusda index) that are derived from blood insulin and glucose concentrations under fasting conditions (steady state) or after an oral glucose load (dynamic). In particular, the quantitative insulin sensitivity check index (QUICKI) has been validated extensively against the reference standard glucose clamp method. QUICKI is a simple, robust, accurate, reproducible method that appropriately predicts changes in insulin sensitivity after therapeutic interventions as well as the onset of diabetes. In this Frontiers article, we highlight merits, limitations, and appropriate use of current in vivo measures of insulin sensitivity/resistance.     

Peroxisome proliferator-activated receptor-gamma agonists in atherosclerosis: current evidence and future directions

PURPOSE OF REVIEW: The prevalence of type 2 diabetes globally is reaching epidemic proportions. Type 2 diabetes is strongly associated with increased risk of cardiovascular disease. Atherosclerosis is thought to arise as a result of a chronic inflammatory process within the arterial wall. Insulin resistance is central to the pathogenesis of type 2 diabetes and may contribute to atherogenesis, either directly or through associated risk factors. The peroxisome proliferator-activated receptor-gamma agonists, the thiazolidinediones, pioglitazone and rosiglitazone, are insulin sensitizing agents, that are licensed for the management of hyperglycaemia. Growing evidence supports an array of additional effects of thiazolidinedione therapy, both immunomodulatory and antiinflammatory, which may attenuate atherogenesis in type 2 diabetes. RECENT FINDINGS: Studies have shown that thiazolidinedione therapy may lead to risk factor modulation in type 2 diabetes. Thiazolidinediones treatment has been shown to reduce blood pressure, modify the atherogenic lipid profile associated with type 2 diabetes, reduce microalbuminuria and ameliorate the prothrombotic diathesis. Further evidence suggests that thiazolidinediones therapy inhibits the inflammatory processes which may be involved in atherosclerotic plaque initiation, propagation and destabilization. SUMMARY: Modification of insulin resistance by thiazolidinedione therapy in type 2 diabetes and the range of pleiotropic effects may not only impact on incident type 2 diabetes, but also on associated cardiovascular disease. Numerous large clinical endpoint studies are under way to investigate these issues.     

Gender differences in the relationship between leptin, insulin resistance and the autonomic nervous system

OBJECTIVES: Leptin, an important hormonal regulator of body weight, has been shown to stimulate the sympathetic nervous system (SNS) in vitro although the physiological relevance remains unclear. Increased SNS activity has been implicated in the pathogenesis of insulin resistance and an increased cardiovascular risk. We have therefore investigated the relationship between leptin, insulin resistance and cardiac autonomic activity in healthy young adults. 130 healthy men and women age 20.9 years were studied. Insulin sensitivity was assessed using the IVGTT and minimal model with simultaneous measures of leptin. Cardiac autonomic activity was assessed using spectral analysis of heart rate variability. RESULTS: Women showed significantly higher fasting leptin, heart rate and cardiac sympathetic activity, and lower insulin sensitivity. Men showed inverse correlations between insulin resistance and heart rate, and between insulin resistance and cardiac sympatho-vagal ratio. Women, in contrast, showed no SNS relationship with insulin resistance, but rather an inverse correlation between leptin and the sympatho-vagal ratio, suggesting that leptin in women is associated with SNS activity. The correlation remained significant after adjustment for BMI and waist-to-hip ratio (beta=-0.33 and p=0.008). CONCLUSION: Insulin resistance and SNS activity appear to be linked, although the relationship showed marked gender differences, and the direction of causality was unclear from this cross-sectional study. Leptin appears to exert a greater effect on the SNS in women, possibly because of their greater fat mass.     

Role of NYGGF4 in insulin resistance

Insulin resistance is a clinical condition that is characterized by reducing glucose uptake in response to insulin. A major factor in the development of insulin resistance syndrome is obesity. NYGGF4 is a novel gene that is abundantly expressed in the adipose tissue of obese subjects. NYGGF4 induced the secretion of FFAs and TNF-α and caused mitochondrial dysfunction, which may cause insulin resistance. This review will summarize the effect of NYGGF4 on the adipogenesis, glucose uptake and mitochondrial dysfunction in vitro, and the possible mechanism and signal pathway of NYGGF4 for insulin resistance.     

Dietary fat,fatty acid composition in plasma and the metabolic syndrome

PURPOSE OF REVIEW: The metabolic syndrome, a cluster of disorders often including abdominal obesity, is associated with a high risk of cardiovascular disease and premature death. Insulin resistance is a key feature of the metabolic syndrome. Observational studies have indicated that the type of fat in the diet may be related to the development of insulin resistance and the metabolic syndrome, also independent of possible effects on body weight. Dietary surveys are often imprecise. One way to monitor the type of fat in the diet is to record the fatty acid composition in plasma. This review summarizes recent data on the relationships between fatty acid composition in plasma and insulin resistance, diabetes and other disorders related to the metabolic syndrome. RECENT FINDINGS: Insulin resistance and insulin resistant states are often associated with the fatty acid pattern in plasma, characterized by an increased proportion of palmitic (16 : 0) and a low proportion of linoleic (18 : 2 n-6) acids, with a distribution of other fatty acids indicating an increased activity of delta-9 and delta-6 desaturase. This shows that there may be a causal relationship between the type of fat in the diet and insulin action, an assumption supported by recent dietary intervention studies. SUMMARY: In a public health perspective these results, from both observational and intervention studies, underline the importance of fat quality in the diet for the development of a number of prevalent diseases. Taken together with several earlier studies and recent epidemiological findings, they give strong support to present dietary guidelines.     

Effects of Hyperinsulinemia on vascular blood flows in experimental obesity

Human obesity, which is very common in Polycystic Ovaries Syndrome and in “X Syndrome”, constitutes an insulin-resistance state in which multiple clinical, biochemical and hemodynamic alterations coexist. Insulin resistance in the obese has been recently associated with an endothelial dysfunction. To investigate the possibility that clinical and metabolic derangements related to insulin resistance could induce changes in vascular blood flows, we have studied the levels of mesenteric (MBF), renal (RBF) and femoral (FBF) blood flows in Beagle dogs kept for 2 years on a normal (control group) or high fat diet (obese group). This experimental model exhibits many of the abnormalities with the human syndrome. In addition, we have tested the effects of chronic treatment with captopril (capto group) in monotherapy or in association with pravastatin (prava+capto group) on the hemodynamic changes associated with this diet. After the two year follow-up, Transonic flow probes were placed around the three arteries to measure basal blood flows and their response to a hyperinsulinemic-normoglycemic test in anesthetized animals. During this test the degree of insulin sensitivity was estimated. In association with higher body weight, blood pressure, insulin resistance, and fasting levels of insulin and total cholesterol, the obese group exhibited decreased basal levels of FBF and a greater femoral vasoconstriction during hyperinsulinism (P<0.05 vs control). Combined therapy with captopril and pravastatin ameliorated the reduction in basal FBF and hyperinsulinism-induced vasoconstriction (P<0.05), in addition to the beneficial effects on insulin sensitivity, and clinical and metabolic parameters. Synergistic beneficial effects of both drugs on lipid and carbohydrate profiles may account for this positive outcome, by attenuating the atherogenic process associated with this model.     

高血压患者胰岛素抵抗与代谢综合征及心血管事件的发生情况的相关性分析

目的:分析高血压患者胰岛素抵抗与代谢综合征及心血管事件的发生情况及其影响因素。方法:选择2014年6月至2017年9月解放军113医院及河南大学附属医院收治的382例高血压患者,根据是否存在胰岛素抵抗将其分为单纯高血压(对照组,n=212)和高血压伴胰岛素抵抗(实验组,n=170)。根据国际糖尿病联盟代谢综合征的相关定义将患者分为A组(代谢综合征,n=202)和B组(非代谢综合征,n=180)。比较患者的身高、体质量并计算其体质量指数(BMI)、收缩压(SBP)、舒张压(DBP),检测两组受试者空腹血糖(FPG)、三酰甘油(TG)、总胆固醇(TC)、肌酐(SCr)、血尿素氮(BUN)、高密度脂蛋白胆固醇(HDL-C)、低密度脂蛋白胆固醇(LDL-C)、采用酶联免疫法测定高敏C反应蛋白(hs-CRP)、脂联素(APN)、空腹胰岛素(FINS)水平。随访1年并记录患者心血管事件发生情况。结果:实验组血清APN、FPG、FINS、HOMA-IR、hs-CRP水平与对照组比较,差异具有统计学意义(P0.05)。A组患者SBP、DBP、BUN、APN、FPG、HOMA-IR、hs-CRP水平明显高于B组,HDL-C水平明显低于B组,差异具有统计学意义(P0.05)。BUN、HDL-C、HOMA-IR、hs-CRP水平升高为高血压患者发生代谢综合征独立危险因素(P0.05)。随访1年后,对照组患者发生心血管事件72例,实验组144例。进一步采用多因素Logistic回归分析显示,血清TG、HDL-C、HOMA-IR、hs-CRP水平升高为高血压患者发生心血管事件的危险因素(P0.05)。结论:高血压伴胰岛素抵抗患者其胰岛素抵抗程度高于单纯高血压患者;胰岛素抵抗与代谢综合征显著相关,为高血压患者发生心血管事件的危险因素。     

Regulation of insulin sensitivity by adipose tissue-derived hormones and inflammatory cytokines

PURPOSE OF REVIEW: The aim of this review is to assess the role of adipose tissue-derived hormones and inflammatory cytokines in the pathogenesis of obesity-linked type II diabetes, with a special focus on articles published between December 2002 and December 2003. RECENT FINDINGS: Insulin resistance is widely recognized as a fundamental defect seen in obesity and type II diabetes. Although the molecular mechanisms triggering the development of insulin resistance remain elusive, recent studies have suggested that adipose tissue and adipose tissue-derived hormones and inflammatory cytokines play essential roles in the overall insulin sensitivity in vivo. Dysfunctions of adipose tissue can lead to systemic insulin resistance. SUMMARY: Understanding the regulation of the metabolic and secretory functions of adipose tissue, as well as its subsequent impact on overall insulin sensitivity, is becoming increasingly important given the therapeutic potential of targeting the root causes of insulin resistance in the treatment of type 2 diabetes and its associated complications, such as cardiovascular and cerebrovascular diseases.     

The Clinical Significance of PPAR Gamma Agonism

Insulin resistance is a principal underlying defect in type 2 DM along with beta-cell dysfunction, and this insulin resistance underpins many of the abnormalities associated with the metabolic syndrome. Peroxisome-proliferator-activated receptor gamma agonists (PPARgamma agonists), also known as glitazones or thiazolidinediones (TZDs) are powerful insulin sensitisers with recent evidence suggesting that they also have a potential to improve pancreatic beta-cell function. TZDs cause a major redistribution of body fat with a decrease in visceral and hepatic fat content with a resultant increase in insulin sensitivity. The glucose lowering effects of TZDs are similar to those seen with the well-established sulphonylureas and metformin. TZDs have a small reducing effect on blood pressure and have been shown to reduce microalbuminuria independent of their blood glucose lowering effect. Both TZDs in clinical practice, pioglitazone and rosiglitazone, reduce small dense LDL-cholesterol and increase HDL-cholesterol levels but pioglitazone would appear to have a more pronounced benefit on these two parameters with a greater reduction in plasma triglycerides. TZDs improved the pro-coagulant state and show benefits in improving endothelial dysfunction and reducing 'non-traditional' inflammatory cytokines and increasing adiponectin levels. The greatest benefit for the TZDs is to directly influence atherogenesis itself and the potential that these so-called pleiotrophic effects of TZDs to reduce cardiovascular events in type 2 DM will be tested when the results of outcome trials are published in the next few years. If the results are positive for the reduction in vascular end-points, then TZDs will represent a major advance in improving the prognosis of type 2 DM subjects with the metabolic syndrome.     

Correlations of insulin resistance and neoplasms

Insulin resistance is a worldwide risk factor for the two most dangerous human disease groups; namely, for cardiovascular lesions and malignancies. The insulin resistance syndrome have five basic criteria: hyperglycemia, visceral obesity, elevated serum triglyceride level, low HDL-cholesterol level (dyslipidemia) and hypertension. Each of these criteria alone are risk factors for cancer, and they mean together a multiple risk. Insulin resistance of the liver, skeletal muscles, and fatty tissue leads to a reactive hyperinsulinemia by the increased secretory activity of the beta-cells. Insulin has diverse metabolic effects, and at the same time is a growth factor. It enhances the production and mitogenic activity of other, insulin-like growth factors, and leads to pathological cell proliferation. In the uncompensated phase of insulin resistance hyperglycemia appears, which promotes tumor genesis by several pathways. The elevated serum glucose level is advantageous for the increased DNA synthesis of the tumor cells. It provokes deliberation of free radicals, which will cause derangement of both the DNA and the enzymes having a role in the repair mechanisms. Hyperglycemia leads to a nonenzymatic glycation of protein structures, and the glycated products enhance the deliberation of free radicals, cytokines and growth factors. Insulin resistance means an enhanced risk for breast, pancreas, liver, colon, bladder, prostate and oral cavity cancers. The moderately increased fasting glucose level is also a risk factor for breast, stomach and colon cancers, even without manifestation of type 2 diabetes. Insulin resistance promotes tumor progression as well. In cancer patients with hyperglycemia or type 2 diabetes, the rate of tumor recurrence, metastatic spread and fatal outcome is higher as compared with the tumor patients without metabolic disease. The correlation between insulin resistance and tumor promotion reveals new possibilities in the prevention and treatment of cancer. The healthy diet, physical activity and weight loss increase insulin sensitivity, and decrease the risk for both cardiovascular diseases and malignancies.