Advertisement
Browse Subject Areas
?

Click through the PLOS taxonomy to find articles in your field.

For more information about PLOS Subject Areas, click here.

  • Loading metrics

Open Access

Peer-reviewed

Research Article

Markers of Tissue-Specific Insulin Resistance Predict the Worsening of Hyperglycemia, Incident Type 2 Diabetes and Cardiovascular Disease

Correction

5 Dec 2014: The PLOS ONE Staff (2014) Correction: Markers of Tissue-Specific Insulin Resistance Predict the Worsening of Hyperglycemia, Incident Type 2 Diabetes and Cardiovascular Disease. PLOS ONE 9(12): e114705. https://doi.org/10.1371/journal.pone.0114705 View correction

Abstract

We investigated the ability of surrogate markers of tissue-specific insulin resistance (IR, Matsuda IR, Adipocyte IR, Liver IR) to predict deterioration of hyperglycemia, incident type 2 diabetes and cardiovascular events in the Metabolic Syndrome in Men (METSIM) Study. The METSIM Study includes 10,197 Finnish men, aged 45–73 years, and examined in 2005–2010. A total of 558 of 8,749 non-diabetic participants at baseline were diagnosed with new-onset diabetes and 239 with a new CVD event during a 5.9-year follow-up of this cohort (2010–2013). Compared to fasting plasma insulin level, Matsuda IR (IR in skeletal muscle) and Adipocyte IR were significantly better predictors of 2-hour plasma glucose and glucose area under the curve after adjustment for confounding factors. Liver IR was the strongest predictor of both incident type 2 diabetes (hazard ratio = 1.83, 95% confidence interval: 1.68–1.98) and cardiovascular events (hazard ratio = 1.31, 95% confidence interval: 1.15–1.48). Hazard ratios for fasting insulin were 1.37 (95% confidence interval: 1.32–1.42) and 1.11 (95% confidence interval: 1.00–1.24), respectively. Tissue-specific markers of IR, Matsuda IR and Adipocyte IR, were superior to fasting plasma insulin level in predicting worsening of hyperglycemia, and Liver IR was superior to fasting insulin level in predicting incident type 2 diabetes and cardiovascular events.

Citation: FízeI'ová M, Cederberg H, Stančáková A, Jauhiainen R, Vangipurapu J, Kuusisto J, et al. (2014) Markers of Tissue-Specific Insulin Resistance Predict the Worsening of Hyperglycemia, Incident Type 2 Diabetes and Cardiovascular Disease. PLoS ONE 9(10): e109772. https://doi.org/10.1371/journal.pone.0109772

Editor: Chiara Lazzeri, Azienda Ospedaliero-Universitaria Careggi, Italy

Received: June 27, 2014; Accepted: September 11, 2014; Published: October 13, 2014

Copyright: © 2014 FízeI'ová et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Data Availability: The authors confirm that all data underlying the findings are fully available without restriction. All relevant data are within the paper.

Funding: This work has been supported by the grants from the Academy of Finland, the Finnish Diabetes Research Foundation, the Finnish Cardiovascular Research Foundation, the Strategic Research Funding from the University of eastern Finland, Kuopio, Finland, and EVO Grant 5263 from the Kuopio University Hospital to M.L. The funding bodies named above had no role in the design and conduct of the study; collection management, analysis, and interpretation of the data; and preparation, review, or approval of the manuscript.

Competing interests: The authors have declared that no competing interests exist.

Introduction

Insulin resistance (IR) and impaired insulin secretion are two major pathophysiological defects in type 2 diabetes [1]. Insulin resistance, typically present for several years before the manifestation of type 2 diabetes [2], is an important predictor for the development of type 2 diabetes and contributes to an elevated risk of cardiovascular disease (CVD) events [3][6]. Insulin secretion defect has been recognized as a key determinant for the progression to type 2 diabetes [7][10].

Euglycemia is maintained by a complex interaction between many tissues. In the fasting state the majority of glucose utilization takes place in the brain (∼50%), splanchnic organs (∼25%), and in skeletal muscle (∼25%) [11]. Postprandial increase in circulating insulin promotes the uptake of glucose into insulin-sensitive tissues. Glucose is stored principally in the form of glycogen mostly in the muscle (accounting for ∼60% of whole body uptake), liver (∼30%) and adipose tissue (∼10%) [11], [12]. Hepatic IR is characterized by enhanced gluconeogenesis in the fasting state and an impaired suppression of hepatic glucose production in response to insulin in the postprandial state [13]. Insulin resistance in skeletal muscle leads to postprandial hyperglycemia [14]. Adipose tissue IR results in elevated levels of plasma free fatty acids levels [15] and overproduction of proinflammatory cytokines (interleukin, tumor necrosis factor-α, C-reactive protein) which impair insulin sensitivity. Moreover, decreased insulin-mediated glucose uptake in different tissues leads to increased plasma insulin levels to maintain normoglycemia. Elevated fasting insulin concentrations reflect IR [16] and are associated with increased risk of CVD events [5], [17], [18].

Insulin sensitivity can be estimated with the hyperinsulinemic euglycemic glucose clamp [19], intravenous glucose tolerance test [20] or with indices calculated on the basis of insulin and glucose levels in the fasting state or after a glucose load [19], [21], [22]. Many of these surrogate markers have been validated against the hyperinsulinemic euglycemic glucose clamp [23][25]. While several tissue-specific IR indices have been developed [14], [26] it remains unknown whether they differentially predict the deterioration of hyperglycemia, progression to overt type 2 diabetes or incident CVD events, and whether they are better predictors of type 2 diabetes and CVD events than fasting insulin level. To address these questions, we investigated the ability of three validated tissue-specific IR indices to predict the deterioration of hyperglycemia, incident type 2 diabetes and CVD events in participants of the Metabolic Syndrome in Men (METSIM) Study, and compared their predictive power with that of fasting plasma insulin level.

Materials and Methods

Subjects and clinical measurement at the baseline study

The Metabolic Syndrome in Men (METSIM) Study was performed in 2005–2010 at the Clinical Research Unit at the University of Kuopio. It included 10,197 men, aged from 45 to 73 years, randomly selected from the population register of Kuopio, Eastern Finland (population 95,000). Each participant attended a 1-day outpatient visit to the Clinical Research Unit at the University of Kuopio, as described in detail previously [23]. An oral glucose tolerance test (OGTT, 75 g of glucose, glucose and insulin measurements at 0, 30 and 120 min) was performed, and glucose tolerance was classified according to the American Diabetes Association criteria [27]. Subjects with previously diagnosed type 1 diabetes (n = 25) or type 2 diabetes (n = 763) were excluded, and none of the participants included in statistical analyses were on anti-diabetic medication. A total of 9,398 men without diabetes or with newly diagnosed diabetes were included in the current analyses (age 57±7 years, body mass index (BMI) 27.0±4.0 kg m−2, mean±SD).

Subjects and clinical measurement at the follow-up study

A follow-up started in 2010, and so far 5,419 individuals have participated. The study protocol and measurements are identical to those of the baseline study.

Diagnosis of incident type 2 diabetes and CVD events

Out of 8,749 non-diabetic participants at baseline, 558 participants developed incident type 2 diabetes and 239 participants had a CVD event between the date of the baseline METSIM Study and 31 December 2013 (5.9-year follow-up). Diagnosis of new-onset type 2 diabetes was based either on an OGTT or HbA1c≥6.5% (297 cases of new diabetes) among 4,806 non-diabetic individuals who participated in the ongoing follow-up study to date in 2010–2013, or anti-diabetic medication started between the baseline and 31 December 2013 (n = 261 cases of new diabetes; information obtained from the National Drug Reimbursement registry for all 8,749 non-diabetic participants). The incident CVD event was defined as myocardial infarction, coronary heart disease death, or fatal and non-fatal cerebral infarction which occurred between the baseline study and 31 December 2013. CVD events were defined according to internationally accepted criteria [28], [29] and verified from the hospital records. Individuals with non-fatal myocardial infarction and stroke before the baseline were excluded from statistical analyses.

Ethics Statement.

The study was approved by the Ethics Committee of the University of Eastern Finland and Kuopio University Hospital and was conducted in accordance with the Helsinki Declaration. All study participants gave written informed consent.

Measurements

Height and weight were measured to the nearest 0.5 cm and 0.1 kg, respectively. Body mass index (BMI) was calculated as weight (kg) divided by height (m) squared. Waist circumference was measured at the midpoint between the lateral iliac crest and lowest rib. Body composition was determined by bioelectrical impedance (Bioimpedance Analyzer Madel BIA 101, Akern SrL, Florence, Italy) in subjects in the supine position after a 12-h overnight fast. Smoking status was defined as current smoking (yes vs. no). Family history of diabetes (yes vs. no) was defined as the first or second-degree relative having diabetes vs. no family history of diabetes. Physical activity (physically active vs. inactive) refers to leisure time exercise (physically active, regular exercise at least 30 min 1–2 times per week vs. physically inactive, occasional exercise or no exercise). Alcohol intake was defined as total alcohol intake in grams per week. Diagnosis of hypertension was based on the use of antihypertensive medication (information obtained from the National Drug Reimbursement registry).

Laboratory measurement

Plasma glucose was measured by enzymatic hexokinase photometric assay (Konelab Systems reagents, Thermo Fisher Scientific; Vantaa, Finland). HbA1c was analyzed with a Tosoh G7 glycohemoglobin analyser (Tosoh Bioscience, Inc. San Francisco, CA, USA). Plasma insulin concentrations were measured by a luminometric immunoassay measurement (ADVIA Centaur Insulin IRI, no 02230141, Siemens Medical Solutions Diagnostics, Tarrytown, NY, USA). LDL cholesterol (LDL-C) was measured by enzymatic colorimetric test (Konelab Systems reagents, Thermo Fisher Scientific; Vantaa, Finland).

Calculations

The trapezoidal method was used to calculate glucose area under the curve (Glucose AUC) from the OGTT using samples collected at 0, 30 and 120 min. Insulin resistance was measured by surrogate indices of tissue-specific IR. Calculation of Matsuda ISI as a measure of whole body insulin sensitivity, representing mainly skeletal muscle insulin sensitivity, has been previously described [30]. For consistency with the other indices expressed as IR, Matsuda IR (calculated as 10/Matsuda ISI) was used in all statistical analyses. The Adipocyte IR index (Adipocyte IR), was defined as the product of fasting free fatty acid levels and fasting plasma insulin [24]. We used our previously validated Liver IR index [26] as a marker of hepatic IR. Insulin secretion index (InsAUC0–30/GlucAUC0–30) was calculated as reported previously [2]. The disposition index (DI) (a measure of pancreatic β-cell function) was calculated as Matsuda ISI×InsAUC0–30/GlucAUC0–30.

Statistical analysis

Statistical analyses were conducted using IBM SPSS Statistics version 19. All traits except for age were log-transformed to correct for their skewed distribution. IR indices and fasting plasma insulin levels were compared across the fasting plasma glucose (FPG) and 2-hour plasma glucose (2hPG) categories with ANOVA. ANCOVA was used to adjust for covariates (age and BMI). Linear regression model adjusted for the follow-up time was used to evaluate the ability of IR indices and fasting plasma insulin levels to predict worsening of FPG, 2hPG and Glucose AUC. Results are presented as unstandardized effect sizes (B and SE) and standardized regression coefficient beta. Fisheŕs r-to-z transformation was performed to test the difference between the standardized beta coefficient of IR indices and fasting insulin levels. Cox regression analysis was used to evaluate the ability of IR indices and fasting insulin levels to predict incident type 2 diabetes and CVD events. Hazard ratios (HRs) are presented with the 95% confidence intervals (CI). Linear and Cox regression models were additionally adjusted for age, BMI, smoking, physical activity, alcohol consumption, family history of type 2 diabetes, DI, Glucose AUC at baseline, and linear regression model additionally for follow-up time. Cox model evaluating the risk of incident CVD events was additionally adjusted for age, BMI smoking, physical activity, alcohol consumption, family history of type 2 diabetes, hypertension, and LDL cholesterol at baseline. P<0.0125 was considered as statistically significant given the 3 IR indices and fasting insulin tested. P<0.05 was considered as nominally significant.

Results

Tissue specific insulin resistance indices in the categories of glucose tolerance

The association of the IR indices in non-diabetic individuals and individuals with newly diagnosed type 2 diabetes across the FPG and 2hPG categories in the cross-sectional analysis of the METSIM study cohort is shown in Figure 1. Categories of FPG≤5.4 mmo/l and 2hPG≤5.9 mmol/l were set as the reference categories. The fasting plasma insulin levels increased significantly (P = 4.7×10−181 and P = 3.2×10−131, respectively) across the range of both FPG and 2hPG categories. Matsuda IR increased significantly with increasing FPG (P = 6.5×10−299) and 2hPG categories (P<6.5×10−299), adjusted for age and BMI. Compared to the reference categories, Matsuda IR increased up to +124% in the impaired fasting glucose (IFG) category and up +321% in newly diagnosed diabetes, and in the 2hPG categories up to +150% and +226% in the impaired glucose tolerance (IGT) category and in newly diagnosed diabetes respectively. Adipocyte IR also showed a significant association with the FPG (P = 1.7×10−204) and 2hPG (P<6.5×10−299) categories. Adipocyte IR increased up to +133% in individuals with IFG and up to +490% in individuals with newly diagnosed diabetes, and in the 2hPG categories up to 172% and 291% in IGT and in newly diagnosed diabetes, respectively, compared to the reference categories. Liver IR increased significantly across the entire range of FPG (P = 1.3×10−20) and 2hPG (P = 1.9×10−119). Across the FPG categories, Liver IR increased up to +4% in IFG and up to +3% in individuals with newly detected diabetes as compared to the reference category. In the 2hPG categories Liver IR increased up to +7%, and +6% in IGT and in newly diagnosed diabetes, respectively.

thumbnail
Download:
Figure 1. Mean values and standard errors of the mean (%) for tissue-specific insulin resistance (IR) indices across the fasting and 2-hour glucose categories.

All indices and fasting insulin levels across the categories were significantly different from the reference category (fasting plasma glucose ≤5.4 mmol/L, 2-hour plasma glucose ≤5.9 mmol/L, P<0.001). P values for the trends, adjusted for age and BMI, were as follows: A) 4.7×10−181 B) 3.2×10−131 C) 6.5×10−299 D) <6.5×10−299 E) 1.7×10−204 F) <6.5×10−299 G) 1.3×10−20 H) 1.9×10−119. NGT indicates normal glucose tolerance, IFG impaired fasting glucose, and IGT impaired glucose tolerance. Participants with previously diagnosed diabetes are excluded, N = 9,398. Abbreviations: IFG, impaired fasting glucose; IGT, impaired glucose tolerance; IR, insulin resistance; NGT, normal glucose tolerance; Ref, reference.

https://doi.org/10.1371/journal.pone.0109772.g001

Insulin resistance indices and fasting plasma insulin levels as predictors for the worsening of hyperglycemia

Matsuda IR, Adipocyte IR, Liver IR and fasting plasma insulin levels significantly predicted an increase in FPG, 2hPG and Glucose AUC (Table 1). Matsuda IR and Adipocyte IR were the best predictors of 2hPG and Glucose AUC. The associations were attenuated, but not abolished, after the adjustment for known risk factors of type 2 diabetes (age, BMI, smoking, physical activity, alcohol consumption and family history of type 2 diabetes). Additional adjustment for DI and Glucose AUC at baseline abolished the predictive value of Adipocyte IR and Liver IR in predicting FPG. Matsuda IR and Adipocyte IR were significantly better predictors for 2hPG and Glucose AUC than were fasting plasma insulin levels (Table 2).

thumbnail
Download:
Table 1. Tissue-specific insulin resistance indices and fasting plasma insulin as predictors of hyperglyceamia at the 5.9-years METSIM follow-up study, Kuopio, Finland.

https://doi.org/10.1371/journal.pone.0109772.t001

thumbnail
Download:
Table 2. Comparison of predictive ability of tissue-specific insulin resistance indices with fasting plasma insulin levels at baseline in predicting worsening of hyperglycemia at the 5.9-years METSIM follow-up study, Kuopio, Finland.

https://doi.org/10.1371/journal.pone.0109772.t002

Insulin resistance indices and fasting plasma insulin levels as predictors of incident diabetes and CVD events

A total of 558 of 8,749 non-diabetic men at baseline developed incident type 2 diabetes and 239 men a CVD event. In unadjusted Cox regression models all tissue-specific IR indices and fasting plasma insulin levels significantly predicted an increased risk of incident type 2 diabetes (Table 3) and incident CVD events (Table 4). Liver IR was the strongest predictor of both incident type 2 diabetes (HR = 1.83, 95% CI: 1.68–1.98, P = 3.80×10−46) and CVD events (HR = 1.31, 95% CI: 1.15–1.48, P = 4.0×10−5). Matsuda IR, Adipocyte IR and fasting plasma insulin levels had comparable ability to predict incident type 2 diabetes and CVD events.

thumbnail
Download:
Table 3. Tissue-specific insulin resistance indices and fasting plasma insulin as predictors of incident type 2 diabetes in the 5.9-years METSIM prospective study, Kuopio, Finland.

https://doi.org/10.1371/journal.pone.0109772.t003

thumbnail
Download:
Table 4. Tissue-specific insulin resistance indices and fasting plasma insulin as predictors of total incident CVD events in the 5.9-Years METSIM prospective study, Kuopio, Finland.

https://doi.org/10.1371/journal.pone.0109772.t004

Discussion

Insulin resistance is an important predictor for the development of type 2 diabetes and contributes to an elevated risk of CVD events [3][5], [7][9], [17]. None of the previous studies has investigated the association of different markers of tissue level IR with the worsening of hyperglycemia, conversion to type 2 diabetes or incident CVD events. Our study showed that Matsuda IR (representing mainly IR in the skeletal muscle), Adipocyte IR (representing IR in the adipose tissue), Liver IR (representing IR in the liver) and fasting plasma insulin levels significantly predicted the worsening of hyperglycemia and the conversion to type 2 diabetes, independently of the confounding factors (age, BMI, smoking, physical activity, alcohol consumption, family history of diabetes, insulin secretion and baseline glycemia). Importantly, Matsuda IR and Adipocyte IR were superior to fasting insulin levels in predicting 2hPG and Glucose AUC. All markers of IR significantly predicted an increased risk of CVD events in unadjusted models.

Hyperinsulinemic euglycemic clamp is the gold standard for measuring whole-body insulin sensitivity [11]. Combined with radiolabelled glucose it allows to quantify individual contribution of liver and muscle insulin resistance to impaired whole-body glucose disposal [30]. These techniques are not, however, applicable to large population-based studies. Therefore, markers of IR suitable for large-scale studies have been developed. An index of muscle insulin sensitivity developed by Abdul-Ghani et al. [4] is based on the measurement of glucose and insulin during an OGTT at 8 time points. This index had a correlation of 0.78 with the M value from the clamp [4]. Because several blood samples are needed, this measure is not possible to apply in large-scale population-based studies. Instead, we calculated Matsuda IR based on three measurements (0, 30 120 min) during an OGTT. We have previously shown that Matsuda ISI, based on five measurements (0, 30, 50, 90 and 120 min), has a correlation of 0.77 with the M value from the clamp, and that Matsuda ISI based on five and three measurements gives very similar results (correlation of 0.985) [31]. Therefore, we believe that 10/Matsuda ISI reliably measures skeletal muscle IR in insulin-stimulated state. We have developed a new index of Liver IR having a correlation of 0.65 with a product of tracer measured hepatic glucose production and fasting insulin [26]. This index was used as a surrogate marker of liver IR in our statistical analyses. Insulin resistance in adipose tissue leads to an impairment of insulin’s antilipolytic effect, contributing to increased flux of free fatty acids into the circulation. We estimated Adipocyte IR with an index validated previously, calculated as the product of the fasting plasma insulin concentration and the fasting plasma FFA concentration [32].

Matsuda IR, reflecting insulin resistance mainly in the skeletal muscle, and Adipocyte IR had comparable ability to predict the worsening of hyperglycemia, measured by 2hPG and Glucose AUC in an OGTT, after adjustment for all confounding risk factors, including insulin secretion and baseline Glucose AUC. This is not surprising since skeletal muscle is responsible for >60% of glucose disposal in insulin-stimulated states. Both indices predicted better an increase in 2hPG and Glucose AUC at follow-up than fasting plasma insulin levels. Liver IR was the strongest predictor of the conversion to type 2 diabetes (HR = 1.83, 95% CI: 1.68–1.98, P = 3.80×10−46) and incident CVD events (HR = 1.31, 95% CI: 1.15–1.48, P = 4.0×10−05) in our 5.9-year follow-up study, although Matsuda IR, Adipocyte IR and fasting plasma insulin levels also significantly predicted incident type 2 diabetes and CVD events.

The strengths of our study include the examination of a large, population-based sample of men across a broad age range and standardized assessment of diabetes with an OGTT, and the measurement of tissue-level IR with validated markers. Limitations of our study are that it included only men, and one ethnic group. Although we used validated markers for IR, direct physiological measurement of insulin sensitivity at tissue level (euglycemic clamp, radiolabelled glucose etc.) are more accurate. However, direct tissue level measurements are not possible to perform in studies of several thousand participants.

In conclusion, tissue-specific markers of IR predicted the worsening of hyperglycemia, incident type 2 diabetes and CVD events, independently of confounding risk factors. Matsuda IR and Adipocyte IR were stronger predictors of the worsening of 2hPG and Glucose AUC than fasting plasma insulin levels. Liver IR was the best predictor for incident type 2 diabetes and CVD events. Our study shows that tissue-specific markers of IR offer a new approach to evaluate the role of insulin resistance beyond and above fasting insulin level in the prediction of incident type 2 diabetes and cardiovascular disease.

Author Contributions

Conceived and designed the experiments: ML JK. Performed the experiments: MF HC AS RJ JV. Analyzed the data: MF HC AS RJ JV. Contributed reagents/materials/analysis tools: ML JK. Contributed to the writing of the manuscript: MF ML HC AS.

References

  1. 1. Defronzo RA (2009) Banting Lecture. From the triumvirate to the ominous octet: a new paradigm for the treatment of type 2 diabetes mellitus. Diabetes 58: 773–795.
  2. 2. Tripathy D, Almgren P, Tuomi T, Groop L (2004) Contribution of insulin-stimulated glucose uptake and basal hepatic insulin sensitivity to surrogate measures of insulin sensitivity. Diabetes Care 27: 2204–2210.
  3. 3. Lillioja S, Mott DM, Spraul M, Ferraro R, Foley JE, et al. (1993) Insulin resistance and insulin secretory dysfunction as precursors of non-insulin-dependent diabetes mellitus. Prospective studies of Pima Indians. N Engl J Med 329: 1988–1992.
  4. 4. Abdul-Ghani MA, Matsuda M, Balas B, DeFronzo RA (2007) Muscle and liver insulin resistance indexes derived from the oral glucose tolerance test. Diabetes Care 30: 89–94.
  5. 5. Laakso M, Sarlund H, Salonen R, Suhonen M, Pyorala K, et al. (1991) Asymptomatic atherosclerosis and insulin resistance. Arterioscler Thromb 11: 1068–1076.
  6. 6. Bressler P, Bailey SR, Matsuda M, DeFronzo RA (1996) Insulin resistance and coronary artery disease. Diabetologia 39: 1345–1350.
  7. 7. Ferrannini E, Natali A, Camastra S, Nannipieri M, Mari A, et al. (2013) Early metabolic markers of the development of dysglycemia and type 2 diabetes and their physiological significance. Diabetes 62: 1730–1737.
  8. 8. Lorenzo C, Wagenknecht LE, D’Agostino RB Jr, Rewers MJ, Karter AJ, et al. (2010) Insulin resistance, beta-cell dysfunction, and conversion to type 2 diabetes in a multiethnic population: the Insulin Resistance Atherosclerosis Study. Diabetes Care 33: 67–72.
  9. 9. Walker M, Mari A, Jayapaul MK, Bennett SM, Ferrannini E (2005) Impaired beta cell glucose sensitivity and whole-body insulin sensitivity as predictors of hyperglycaemia in non-diabetic subjects. Diabetologia 48: 2470–2476.
  10. 10. Lyssenko V, Almgren P, Anevski D, Perfekt R, Lahti K, et al. (2005) Predictors of and longitudinal changes in insulin sensitivity and secretion preceding onset of type 2 diabetes. Diabetes 54: 166–174.
  11. 11. DeFronzo RA (2004) Pathogenesis of type 2 diabetes mellitus. Medical Clinics of North America 88: 787–835.
  12. 12. Zierath JR, Kawano Y (2003) The effect of hyperglycaemia on glucose disposal and insulin signal transduction in skeletal muscle. Best Practice & Research Clinical Endocrinology & Metabolism 17: 385–398.
  13. 13. Cherrington AD (1999) Banting Lecture 1997. Control of glucose uptake and release by the liver in vivo. Diabetes 48: 1198–1214.
  14. 14. Abdul-Ghani MA, Matsuda M, DeFronzo RA (2008) Strong association between insulin resistance in liver and skeletal muscle in non-diabetic subjects. 25: 1289–1294.
  15. 15. Gastaldelli A, Natali A, Vettor R, Corradini SG (2010) Insulin resistance, adipose depots and gut: interactions and pathological implications. Dig Liver Dis 42: 310–319.
  16. 16. Laakso M (1993) How good a marker is insulin level for insulin resistance? Am J Epidemiol 137: 959–965.
  17. 17. Gast KB, Tjeerdema N, Stijnen T, Smit JW, Dekkers OM (2012) Insulin resistance and risk of incident cardiovascular events in adults without diabetes: meta-analysis. PLoS One 7: e52036.
  18. 18. Kuusisto J, Lempiainen P, Mykkanen L, Laakso M (2001) Insulin resistance syndrome predicts coronary heart disease events in elderly type 2 diabetic men. Diabetes Care 24: 1629–1633.
  19. 19. Matsuda M, DeFronzo RA (1999) Insulin sensitivity indices obtained from oral glucose tolerance testing: comparison with the euglycemic insulin clamp. Diabetes Care 22: 1462–1470.
  20. 20. Bergman RN, Ider YZ, Bowden CR, Cobelli C (1979) Quantitative estimation of insulin sensitivity. Am J Physiol 236: E667–677.
  21. 21. Stumvoll M, Mitrakou A, Pimenta W, Jenssen T, Yki-Jarvinen H, et al. (2000) Assessment of insulin secretion from the oral glucose tolerance test in white patients with type 2 diabetes. Diabetes Care 23: 1440–1441.
  22. 22. Katz A, Nambi SS, Mather K, Baron AD, Follmann DA, et al. (2000) Quantitative insulin sensitivity check index: a simple, accurate method for assessing insulin sensitivity in humans. J Clin Endocrinol Metab 85: 2402–2410.
  23. 23. Stancakova A, Javorsky M, Kuulasmaa T, Haffner SM, Kuusisto J, et al. (2009) Changes in insulin sensitivity and insulin release in relation to glycemia and glucose tolerance in 6,414 Finnish men. Diabetes 58: 1212–1221.
  24. 24. Abdul-Ghani MA, Molina-Carrion M, Jani R, Jenkinson C, Defronzo RA (2008) Adipocytes in subjects with impaired fasting glucose and impaired glucose tolerance are resistant to the anti-lipolytic effect of insulin. Acta Diabetol 45: 147–150.
  25. 25. Matthews DR, Hosker JP, Rudenski AS, Naylor BA, Treacher DF, et al. (1985) Homeostasis model assessment: insulin resistance and beta-cell function from fasting plasma glucose and insulin concentrations in man. Diabetologia 28: 412–419.
  26. 26. Vangipurapu J, Stancakova A, Kuulasmaa T, Paananen J, Kuusisto J, et al. (2011) A novel surrogate index for hepatic insulin resistance. Diabetologia 54: 540–543.
  27. 27. American Diabetes A (2006) Diagnosis and classification of diabetes mellitus. Diabetes Care 29 Suppl 1: S43–48.
  28. 28. Thygesen K, Alpert JS, Jaffe AS, Simoons ML, Chaitman BR, et al. (2012) Third universal definition of myocardial infarction. Eur Heart J 33: 2551–2567.
  29. 29. European Stroke Initiative Executive C, Committee EW, Olsen TS, Langhorne P, Diener HC, et al. (2003) European Stroke Initiative Recommendations for Stroke Management-update 2003. Cerebrovasc Dis 16: 311–337.
  30. 30. Defronzo RA, Simonson D, Ferrannini E (1982) Hepatic and Peripheral Insulin Resistance - a Common Feature of Non-Insulin-Dependent (Nidd) and Insulin-Dependent Diabetes (Idd). Clinical Research 30: A523–A523.
  31. 31. Lorenzo C, Haffner SM, Stancakova A, Laakso M (2010) Relation of Direct and Surrogate Measures of Insulin Resistance to Cardiovascular Risk Factors in Nondiabetic Finnish Offspring of Type 2 Diabetic Individuals. Journal of Clinical Endocrinology & Metabolism 95: 5082–5090.
  32. 32. Groop LC, Bonadonna RC, Delprato S, Ratheiser K, Zyck K, et al. (1989) Glucose and Free Fatty-Acid Metabolism in Non-Insulin-Dependent Diabetes-Mellitus - Evidence for Multiple Sites of Insulin Resistance Journal of Clinical Investigation. 84: 205–213.