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Peripheral Adiposity and Cardiovascular Risk

2003; Lippincott Williams & Wilkins; Volume: 108; Issue: 23 Linguagem: Inglês

10.1161/01.cir.0000102950.15230.95

1524-4539

Henry S. Kahn,

Diabetes, Cardiovascular Risks, and Lipoproteins

HomeCirculationVol. 108, No. 23Peripheral Adiposity and Cardiovascular Risk Free AccessLetterPDF/EPUBAboutView PDFView EPUBSections ToolsAdd to favoritesDownload citationsTrack citationsPermissions ShareShare onFacebookTwitterLinked InMendeleyReddit Jump toFree AccessLetterPDF/EPUBPeripheral Adiposity and Cardiovascular Risk Henry S. Kahn, MD Henry S. KahnHenry S. Kahn National Center for Chronic Disease Prevention and Health Promotion, Division of Diabetes Translation, Atlanta, Ga, Originally published9 Dec 2003https://doi.org/10.1161/01.CIR.0000102950.15230.95Circulation. 2003;108:e164To the Editor:In their recent Circulation article describing a study of older Danish women, Tankó et al1 presented strong evidence that peripheral localization of fat mass is associated with reduced calcification in the aorta. This interesting finding leads one to ask whether all anatomic sites of peripheral fat contribute equally to the apparent protective effect. Several studies have previously found that increased size in the lower limbs is associated with reduced cardiovascular or metabolic risk.2–4 However, I am unaware of any studies showing tissue mass in the upper limbs to have such a protective effect.It would be useful to determine the separate contributions of lower-limb and upper-limb fat mass to the reduction in aortic calcification and other cardiovascular risk factors that Tankó et al found. If the protective effect could be attributed primarily to mass in the lower limbs, then future investigators could simplify their work by focusing studies solely on the lower-limb mass. Clinicians could benefit likewise from inexpensive, lower-limb measurements that might improve the risk stratification of patients in daily practice.1 Tankó LB, Bagger YZ, Alexandersen P, et al. Peripheral adiposity exhibits an independent dominant antiatherogenic effect in elderly women. Circulation. 2003; 107: 1626–1631.LinkGoogle Scholar2 Kahn HS, Austin H, Williamson DF, et al. Simple anthropometric indices associated with ischemic heart disease. J Clin Epidemiol. 1996; 49: 1017–1024.CrossrefMedlineGoogle Scholar3 Davey Smith G, Greenwood R, Gunnell E, et al. Leg length, insulin resistance, and coronary heart disease risk: the Caerphilly Study. J Epidemiol Community Health. 2001; 55: 867–872.CrossrefMedlineGoogle Scholar4 Lawlor DA, Ebrahim S, Davey Smith G. The association between components of adult height and Type II diabetes and insulin resistance: British Women's Heart and Health Study. Diabetologia. 2002; 45: 1097–1106.CrossrefMedlineGoogle ScholarcirculationahaCirculationCirculationCirculation0009-73221524-4539Lippincott Williams & WilkinsResponseTankó László B., , MD, PhD, Bagger Yu Z., , MD, Alexandersen Peter, , MD, Christiansen Claus, , MD, PhD, and for the Prospective Epidemiological Risk Factors (PERF) Study Group, and Larsen Philip J., , MD, PhD09122003We thank Dr Kahn for his pertinent question about our study. We have accordingly reanalyzed our cross-sectional data obtained on the same 1317 elderly women to estimate the distinct influences of peripheral fat mass as measured by dual-energy x-ray absorptiometry in the lower limbs compared with that in the upper limbs.We found a stronger inverse association of the severity score for aortic calcification with fat mass in the lower (r=−0.142, P=0.001) compared with fat mass in the upper limbs (r=−0.062, P=0.023). After adjusting for all potential cardiovascular confounders, the independent inverse correlation with fat mass in the lower limbs remained virtually unchanged (r=−0.130, P<0.001), whereas the correlation with fat mass in the upper limbs no longer was statistically significant (r=−0.042, P=0.129).Similar lower-limb versus upper-limb contrasts were found when we examined the correlations with metabolic risk factors independent of age, body mass index, central fat mass, level of education, coffee and alcohol consumption, weekly fitness activity, current and previous smoking, diabetes, and current use of hormone replacement therapy. Under these conditions, the lower-limb and upper-limb partial correlations for fasting glucose were −0.137 (P<0.001) and −0.023 (P=0.422), the correlations for white blood cell count were −0.082 (P=0.004) and −0.030 (P=0.281), and those for total cholesterol were −0.079 (P=0.005) and −0.052 (P=0.067). Both compartments appeared to exhibit a favorable effect on serum triglyceride (r=−0.239 [P<0.001] and r=−0.112 [P<0.001], respectively).In the subpopulation of 290 women with a more thorough analysis of metabolic risk profile, the lower-limb and upper-limb partial correlations for the homeostasis assessment of insulin resistance index were −0.140 (P=0.023) and 0.048 (P=0.437), the correlations for HDL cholesterol were 0.176 (P=0.004) and 0.105 (P=0.087), and those for lipoprotein (a) were −0.146 (P=0.017) and −0.056 (P=0.366). None of the compartments was associated with apolipoprotein A1 or LDL cholesterol, whereas both compartments were significantly associated with apolipoprotein B (r=−0.261 [P<0.001] and r=−0.144 [P=0.019], respectively).These results confirm Dr Kahn's implication that the antidiabetic and antiatherogenic influence of peripheral fat mass is attributable primarily to fat mass on the lower limbs. Our findings suggest a need for thorough assessment of the diagnostic and prognostic value of simple anthropometric measures of lower-body fat depots. Studies to clarify the determinants of lower-body fat mass might also contribute to the prevention of cardiovascular disease.Dr Christiansen is the CEO of the Center of Clinical and Basic Research, which besides its interest in epidemiological research related to women's health (osteoporosis, cardiovascular disease, obesity, type 2 diabetes, osteoarthritis) performs clinical phase II and III and postmarketing trials on novel drugs, mainly in the field of osteoporosis and osteoarthritis in postmenopausal women. Previous Back to top Next FiguresReferencesRelatedDetailsCited By Tankó L and Christiansen C (2009) Adipose tissue, insulin resistance and low-grade inflammation: implications for atherogenesis and the cardiovascular harm of estrogen plus progestogen therapy, Climacteric, 10.1080/13697130600738765, 9:3, (169-180), Online publication date: 1-Jan-2006. Tankó L, Bagger Y, Qin G, Alexandersen P, Larsen P and Christiansen C (2005) Enlarged Waist Combined With Elevated Triglycerides Is a Strong Predictor of Accelerated Atherogenesis and Related Cardiovascular Mortality in Postmenopausal Women, Circulation, 111:15, (1883-1890), Online publication date: 19-Apr-2005. Kahn H, Imperatore G and Cheng Y (2005) A population-based comparison of BMI percentiles and waist-to-height ratio for identifying cardiovascular risk in youth, The Journal of Pediatrics, 10.1016/j.jpeds.2004.12.028, 146:4, (482-488), Online publication date: 1-Apr-2005. Kahn H (2005) The "lipid accumulation product" performs better than the body mass index for recognizing cardiovascular risk: a population-based comparison, BMC Cardiovascular Disorders, 10.1186/1471-2261-5-26, 5:1, Online publication date: 1-Dec-2005. Granger D, Vowinkel T and Petnehazy T (2004) Modulation of the Inflammatory Response in Cardiovascular Disease, Hypertension, 43:5, (924-931), Online publication date: 1-May-2004. Zhao H, Yakar S, Gavrilova O, Sun H, Zhang Y, Kim H, Setser J, Jou W and LeRoith D (2004) Phloridzin Improves Hyperglycemia But Not Hepatic Insulin Resistance in a Transgenic Mouse Model of Type 2 Diabetes, Diabetes, 10.2337/diabetes.53.11.2901, 53:11, (2901-2909), Online publication date: 1-Nov-2004. December 9, 2003Vol 108, Issue 23 Advertisement Article InformationMetrics https://doi.org/10.1161/01.CIR.0000102950.15230.95PMID: 14662699 Originally publishedDecember 9, 2003 PDF download Advertisement