Portal de Periódicos da CAPES

Stiffening Our Resolve Against Adult Weight Gain

2004; Lippincott Williams & Wilkins; Volume: 45; Issue: 2 Linguagem: Alemão

10.1161/01.hyp.0000152199.18202.a9

1524-4563

Douglas R. Seals, Phillip E. Gates,

Heart Rate Variability and Autonomic Control

HomeHypertensionVol. 45, No. 2Stiffening Our Resolve Against Adult Weight Gain Free AccessEditorialPDF/EPUBAboutView PDFView EPUBSections ToolsAdd to favoritesDownload citationsTrack citationsPermissions ShareShare onFacebookTwitterLinked InMendeleyReddit Jump toFree AccessEditorialPDF/EPUBStiffening Our Resolve Against Adult Weight Gain Douglas R. Seals and Phillip E. Gates Douglas R. SealsDouglas R. Seals From the Department of Integrative Physiology, University of Colorado, Boulder. and Phillip E. GatesPhillip E. Gates From the Department of Integrative Physiology, University of Colorado, Boulder. Originally published27 Dec 2004https://doi.org/10.1161/01.HYP.0000152199.18202.a9Hypertension. 2005;45:175–177Other version(s) of this articleYou are viewing the most recent version of this article. Previous versions: December 27, 2004: Previous Version 1 Increasing adiposity with a clinical endpoint of obesity is associated with a progressive increase in risk of cardiovascular diseases (CVD). However, we are only beginning to understand the physiological and pathophysiological mechanisms by which excessive body fat storage causes CVD.In this issue of Hypertension, the findings of Wildman et al1 extend and strengthen previous observations2–5 by showing that changes in arterial stiffness, as measured by aortic pulse-wave velocity (PWV), are related to changes in body weight over a 2-year follow-up period in healthy men and women aged 20 to 40 years. Weight gain was associated with an increase, whereas weight loss was associated with a decrease in aortic PWV, independent of changes in blood pressure. The greatest increases in aortic PWV were observed in those subjects who gained the most weight (≥4.5 kg). Importantly, the changes in aortic PWV were related to changes in body mass index (BMI), indicating that the associations with body weight were mediated by changes in adiposity (rather than fat-free mass). Changes in aortic PWV over time also were related to baseline body weight, BMI, and waist circumference (an indirect measure of abdominal adiposity), providing evidence that higher initial levels of total and abdominal body fatness are associated with greater future increases in arterial stiffness. The study included subjects with a broad range of BMI, suggesting that the findings are applicable to both nonobese and obese adults in the general population. An important finding was that black adults demonstrated greater increases in weight gain-adjusted and blood pressure-adjusted aortic PWV over time, suggesting that they undergo greater increases in arterial stiffness in response to the same age-associated weight gain compared with whites.These observations provide further support for the emerging concept that adiposity-driven weight gain during adulthood contributes significantly to the adverse changes in cardiovascular function and structure that provide the essential substrate for age-associated CVD. That is, advancing age and increasing adiposity, likely amplified by worsening of other risk factors, form a dangerous partnership that accelerates the development and clinical expression of a variety of cardiovascular disorders. The effect of adiposity on arterial stiffness may begin during childhood,6 thereby increasing the duration of exposure to this stimulus and causing greater CVD risk at an earlier age in adulthood. Certain high-risk groups including individuals with a family history of CVD, pre-existing risk factors (diabetes, hypertension, dyslipidemia), and older adults may turn out to be particularly vulnerable to the negative cardiovascular effects of elevated adiposity.Increased arterial stiffness, particularly stiffening of the large elastic arteries in the cardio-thoracic circulation, is a key and, potentially, lethal trigger in the etiology of age-associated CVD.7 Arterial stiffening initiates a series of adverse cardiovascular events that include increases in central and peripheral arterial systolic blood pressure and pulse pressure, as well as increases in aortic input impedance, ie, the resistance imposed on left ventricular ejection by the systemic arterial vasculature. These changes cause or contribute to vascular endothelial injury, aneurysms, left ventricular hypertrophy, altered diastolic filling, decreased left ventricular systolic reserve, and reduced baroreflex sensitivity, resulting in increased risk of vascular occlusive diseases, hemorrhagic stroke, exercise intolerance, heart failure, and cardiac arrhythmias.The mechanisms by which increasing adiposity and obesity cause arterial stiffening are not well understood. Currently, we have only fragments of insight, discrete physiological links among a likely myriad of players involved, but no integrated picture. Arterial stiffness is determined by a number of factors that influence vascular structure and function. Among the primary factors influencing arterial structure are the key extracellular matrix proteins, elastin and collagen. Increased fragmentation/reduced density of elastin, along with an increased concentration and cross-linking of collagen molecules, leads to increased arterial stiffness, and vice versa. The production of advanced glycation end-products (which act to increase collagen cross-linking), the bioactivity of matrix metalloproteinases (important effectors of vascular remodeling), vascular smooth muscle cell (VSMC) hypertrophy, and a variety of growth factors also modulate the structural and functional properties of the arterial wall. In addition, several factors influence arterial stiffness by changing VSMC tone, including sympathetic nerve activity and norepinephrine release, circulating vasoactive hormones, local (endothelium-derived) vasodilators (nitric oxide, prostacyclins) and vasoconstrictors (endothelin-1, angiotensin II), pro-/anti-inflammatory molecules, and reactive oxygen species, as well as myogenic tone. Body fatness likely modulates arterial stiffness by affecting several of these intermediary influences.The physiological/pathophysiological coupling between body fat and arterial stiffness may be mediated in part via stimulation of a pro-inflammatory state, resulting in activation of oxidant enzyme systems, increased production of reactive oxygen species such as superoxide anions, and the development of oxidative stress (Figure 1). Both pro-inflammatory molecules and increased superoxide activity can alter expression of extracellular matrix proteins by influencing matrix metalloproteinase activity or through other mechanisms. This pro-inflammatory/high-oxidant state also produces a vascular endothelial phenotype characterized by reduced nitric oxide bioavailability and VSMC relaxation and augmented production of endothelin-1 and angiotensin II-associated VSMC contraction, with resulting arterial stiffening. Elevated adiposity also is associated with elevated sympathetic nerve activity and norepinephrine-evoked VSMC contraction, which also likely contributes to obesity-related arterial stiffness. Moreover, increased body fatness results in elevated circulating leptin concentrations, which are linked to increased arterial stiffness by as yet unknown mechanisms.8 It remains to be determined if the modulation of arterial stiffness by these mechanisms is more tightly linked to changes in abdominal visceral or subcutaneous fat, or to total adiposity. Download figureDownload PowerPointHypothetical model of the integrative pathophysiological mechanisms by which increased adiposity may combine with advancing age and other risk factors to increase arterial stiffness and its cardiovascular sequelae. MMPs indicates matrix metalloproteinases; TIMPs, tissue inhibitor of metalloproteinases; NO, nitric oxide; PGI2, prostacyclin; ET-1, endothelin 1; Ang II, angiotensin II; SNA, sympathetic nervous activity; NE, norepinephrine; AGES, advanced glycation end products; VSMC, vascular smooth muscle cell; BP, blood pressure; LV, left ventricle.Although changes in aortic PWV were not significantly related to changes in arterial blood pressure in the study of Wildman et al,1 we should not overlook the normally close association between the 2 events. Whereas arterial stiffening will increase arterial blood pressure, an intervention that increases or decreases arterial blood pressure will result in a corresponding increase or decrease in arterial stiffness. It is often difficult to tease out whether the change in arterial stiffness leads to the change in arterial blood pressure or vice versa (or if both occur). Moreover, subtle interactions between arterial stiffness and blood pressure, eg, expressed as blood pressure variability or nighttime dipping of blood pressure, could have been missed in the absence of 24-hour blood pressure recordings.Regardless of the mechanisms involved, the implications of body fatness-related arterial stiffening for maintaining physiological function and health during adult aging are clear. Total body and abdominal fat are strong independent correlates of 24-hour systolic blood pressure and pulse pressure,9 both of which are determined primarily by the stiffness of the large elastic arteries and represent a major CVD risk factor for adults 50 years of age and older. Age-associated increases in 24-hour systolic blood pressure and pulse pressure do not occur in the absence of increases in total and abdominal adiposity and arterial stiffness,10 and correcting for abdominal fat and arterial stiffness abolishes the significance of age-related elevations in 24-hour systolic blood pressure and pulse pressure.10 Increasing total and abdominal fat also contributes to left ventricular remodeling and reduced diastolic function with adult aging, driven in part by arterial stiffness-mediated increases in aortic input impedance.11Wildman et al1 emphasize the importance of their findings in supporting the need for weight-loss interventions, especially in blacks. The fact that weight reductions were associated with decreases in aortic PWV in their study certainly is consistent with this idea, at least in young to early middle-aged men and women. However, sustained weight-loss without regain, particularly in obese adults, is difficult and currently has a very poor long-term success rate. Moreover, some individuals or groups (eg, patients with long-standing obesity–hypertension) may with time develop an arterial stiffness phenotype that is resistant to weight loss. As such, a key focus of our future efforts in this area must be directed toward the primary prevention of adult weight gain. Because the association between weight gain and arterial stiffness was observed even in nonobese adults in this study, one aim of the overall strategy should be to prevent the development of overweight and obesity in presently lean individuals. However, increases in arterial stiffness over the follow-up period were greater in those subjects with higher initial BMI and waist girth. Thus, preventing additional abdominal and total fat storage appears to be important for minimizing future increases in arterial stiffness in both nonobese and obese adults. Given new evidence that childhood obesity predicts arterial stiffness during adulthood,6 this strategy likely needs to be extended to adolescence.Recently it was emphasized that for 20- to 40-year-old adults, the average weight gain is only ≈2 pounds/year, and that reducing energy accumulation by 50 to 100 kcal/d would offset this weight gain in 90% of the population.12 It also was emphasized that only small behavioral changes involving some combination of increased physical activity-related energy expenditure and reduced energy intake would be required to maintain energy balance.12 Habitual aerobic exercise may be a particularly effective element of body weight management in this context given its favorable independent modulatory influence on age-associated arterial stiffening.10 Thus, maintaining healthy arterial compliance and the associated reduced risk of CVD by limiting adult weight gain appear to be attainable goals with relatively modest and palatable adjustments to our modern lifestyle. The importance of making these adjustments is becoming increasingly apparent as we recognize that uncoupling the deadly combination of aging and obesity is a critical battleground in the fight against CVD.The opinions expressed in this editorial are not necessarily those of the editors or of the American Heart Association.FootnotesCorrespondence to Douglas R. Seals, PhD, Department of Integrative Physiology, University of Colorado at Boulder, UCB 354, Boulder, CO 80309. E-mail [email protected] References 1 Wildman RP, Farhat GN, Patel AS, Mackey RH, Brockwell S, Thompson T, Sutton-Tyrrell K. Weight change is associated with change in arterial stiffness among healthy young adults. Hypertension. 2005; 45: 187–192.LinkGoogle Scholar2 Amar J, Ruidavets JB, Chamontin B, Drouet L, Ferrieres J. Arterial stiffness and cardiovascular risk factors in a population-based study. J Hypertens. 2001; 19: 381–387.CrossrefMedlineGoogle Scholar3 Wildman RP, Mackey RH, Bostom A, Thompson T, Sutton-Tyrrell K. Measures of obesity are associated with vascular stiffness in young and older adults. Hypertension. 2003; 42: 468–473.LinkGoogle Scholar4 Sutton-Tyrrell K, Newman A, Simonsick EM, Havlik R, Pahor M, Lakatta E, Spurgeon H, Vaitkevicius P. Aortic stiffness is associated with visceral adiposity in older adults enrolled in the study of health, aging, and body composition. Hypertension. 2001; 38: 429–433.CrossrefMedlineGoogle Scholar5 Taquet A, Bonithon-Kopp C, Simon A, Levenson J, Scarabin Y, Malmejac A, Ducimetiere P, Guize L. Relations of cardiovascular risk factors to aortic pulse wave velocity in asymptomatic middle-aged women. Eur J Epidemiol. 1993; 9: 298–306.CrossrefMedlineGoogle Scholar6 Ferreira I, Twisk JW, van Mechelen W, Kemper HC, Seidell JC, Stehouwer CD. Current and adolescent body fatness and fat distribution: relationships with carotid intima-media thickness and large artery stiffness at the age of 36 years. J Hypertens. 2004; 22: 145–155.CrossrefMedlineGoogle Scholar7 Lakatta EG, Levy D. Arterial and cardiac aging: major shareholders in cardiovascular disease enterprises: Part I: aging arteries: a "set up" for vascular disease. Circulation. 2003; 107: 139–146.LinkGoogle Scholar8 Singhal A, Farooqi IS, Cole TJ, O'Rahilly S, Fewtrell M, Kattenhorn M, Lucas A, Deanfield J. Influence of leptin on arterial distensibility: a novel link between obesity and cardiovascular disease? Circulation. 2002; 106: 1919–1924.LinkGoogle Scholar9 Stevenson ET, Davy KP, Jones PP, Desouza CA, Seals DR. Blood pressure risks factors in healthy postmenopausal women: physical activity and hormone replacement. J Appl Physiol. 1997; 82: 652–660.CrossrefMedlineGoogle Scholar10 Seals DR, Stevenson ET, Jones PP, DeSouza CA, Tanaka H. Lack of age-associated elevations in 24-h systolic and pulse pressures in women who exercise regularly. Am J Physiol. 1999; 277: H947–H955.MedlineGoogle Scholar11 Gates PE, Gentile CL, Seals DR, Christou DD. Adiposity contributes to differences in left ventricular structure and diastolic function with age in healthy men. J Clin Endocrinol Metab. 2003; 88: 4884–4890.CrossrefMedlineGoogle Scholar12 Hill JO, Wyatt HR, Reed GW, Peters JC. Obesity and the environment: where do we go from here? Science. 2003; 299: 853–855.CrossrefMedlineGoogle Scholar Previous Back to top Next FiguresReferencesRelatedDetailsCited By Cox E, Brown W, Gajanand T, Bailey T, Gomersall S, Chachay V, Burton N, Fassett R, Cox S, Coombes J and Keating S (2022) Effects of fitness and fatness on age‐related arterial stiffening in people with type 2 diabetes, Clinical Obesity, 10.1111/cob.12519, 12:3, Online publication date: 1-Jun-2022. Gul M, Inci S, Aktas H, Yildirim O, Alsancak Y and Ozkan N (2021) Dynamic changes in aortic stiffness after substantial weight loss by laparoscopic sleeve gastrectomy in patients with obesity: a 1-year follow-up study, Journal of Investigative Medicine, 10.1136/jim-2021-001778, 69:6, (1168-1174), Online publication date: 1-Aug-2021. Aizawa K, Ramalli A, Sbragi S, Tortoli P, Casanova F, Morizzo C, Thorn C, Shore A, Gates P and Palombo C (2019) Arterial wall shear rate response to reactive hyperaemia is markedly different between young and older humans, The Journal of Physiology, 10.1113/JP278310, 597:16, (4151-4163), Online publication date: 1-Aug-2019. Königstein K, Infanger D, Klenk C, Hinrichs T, Rossmeissl A, Baumann S, Hafner B, Hanssen H and Schmidt-Trucksäss A (2018) Does obesity attenuate the beneficial cardiovascular effects of cardiorespiratory fitness?, Atherosclerosis, 10.1016/j.atherosclerosis.2018.03.014, 272, (21-26), Online publication date: 1-May-2018. Strasser B, Arvandi M, Pasha E, Haley A, Stanforth P and Tanaka H (2015) Abdominal obesity is associated with arterial stiffness in middle-aged adults, Nutrition, Metabolism and Cardiovascular Diseases, 10.1016/j.numecd.2015.01.002, 25:5, (495-502), Online publication date: 1-May-2015. Grizelj I, Cavka A, Bian J, Szczurek M, Robinson A, Shinde S, Nguyen V, Braunschweig C, Wang E, Drenjancevic I and Phillips S (2015) Reduced Flow-and Acetylcholine-Induced Dilations in Visceral Compared to Subcutaneous Adipose Arterioles in Human Morbid Obesity, Microcirculation, 10.1111/micc.12164, 22:1, (44-53), Online publication date: 1-Jan-2015. Ferreira I (2015) Obesity and Metabolic Syndrome Arterial Disorders, 10.1007/978-3-319-14556-3_17, (237-248), . Ferreira I, van de Laar R and Stehouwer C (2014) Obesity, Metabolic Syndrome, Diabetes and Smoking Blood Pressure and Arterial Wall Mechanics in Cardiovascular Diseases, 10.1007/978-1-4471-5198-2_33, (409-422), . Gohlke H, Albus C, Bönner G, Darius H, Eckert S, Gohlke-Bärwolf C, Gysan D, Hahmann H, Halle M, Hambrecht R, Mathes P, Predel H, Sauer † G, von Schacky C, Schuler G, Siegrist J, Thiery J, Tschöpe D, Völler H and Wirth A (2012) Empfehlungen der Projektgruppe Prävention der DGK zur risikoadjustierten Prävention von Herz- und KreislauferkrankungenRecommendations of the project group of the German Society for Cardiology for risk-adjusted prevention of cardiovascular diseases, Der Kardiologe, 10.1007/s12181-012-0430-y, 6:3, (249-262), Online publication date: 1-Jun-2012. Kaats G and Preuss H (2012) Challenges to the Conduct and Interpretation of Weight Loss Research Obesity, 10.1201/b12261-63, (833-850), Online publication date: 13-Jul-2012. Schouten F, Twisk J, de Boer M, Stehouwer C, Serné E, Smulders Y and Ferreira I (2011) Increases in central fat mass and decreases in peripheral fat mass are associated with accelerated arterial stiffening in healthy adults: the Amsterdam Growth and Health Longitudinal Study, The American Journal of Clinical Nutrition, 10.3945/ajcn.111.013532, 94:1, (40-48), Online publication date: 1-Jul-2011. LARSON-MEYER D, REDMAN L, HEILBRONN L, MARTIN C and RAVUSSIN E (2010) Caloric Restriction with or without Exercise, Medicine & Science in Sports & Exercise, 10.1249/MSS.0b013e3181ad7f17, 42:1, (152-159), Online publication date: 1-Jan-2010. Strain W, Elyas S, Gates P and Shore A (2010) Age-related change in endothelial and microvessel function and therapeutic consequences, Reviews in Clinical Gerontology, 10.1017/S0959259810000158, 20:3, (161-170), Online publication date: 1-Aug-2010. Gates P, Strain W and Shore A (2009) Human endothelial function and microvascular ageing, Experimental Physiology, 10.1113/expphysiol.2008.043349, 94:3, (311-316), Online publication date: 1-Mar-2009. Gohlke H, Albus C, Gysan D, Hahmann H and Mathes P (2009) Cardiovascular Prevention in Clinical Practice (ESC and German Guidelines 2007)Kardiovaskuläre Prävention im klinischen Alltag, Herz, 10.1007/s00059-009-3196-7, 34:1, (4-14), Online publication date: 1-Feb-2009. Orr J, Gentile C, Davy B and Davy K (2008) Large Artery Stiffening With Weight Gain in Humans, Hypertension, 51:6, (1519-1524), Online publication date: 1-Jun-2008. Zhu H, Yan W, Ge D, Treiber F, Harshfield G, Kapuku G, Snieder H and Dong Y (2008) Relationships of Cardiovascular Phenotypes With Healthy Weight, at Risk of Overweight, and Overweight in US Youths, Pediatrics, 10.1542/peds.2006-3720, 121:1, (115-122), Online publication date: 1-Jan-2008. YAMADA J, TOMIYAMA H, MATSUMOTO C, YOSHIDA M, KOJI Y, SHIINA K, NAGATA M and YAMASHINA A (2008) Overweight Body Mass Index Classification Modifies Arterial Stiffening Associated with Weight Gain in Healthy Middle-Aged Japanese Men, Hypertension Research, 10.1291/hypres.31.1087, 31:6, (1087-1092), . Gohlke H (2007) Moderne Risikoanalyse bei intermediärem Risiko für kardiovaskuläre EreignisseModern risk analysis in the intermediate risk range for myocardial infarction or cardiovascular death, Clinical Research in Cardiology Supplements, 10.1007/s11789-007-0021-9, 2:5, (V10-V17), Online publication date: 1-Dec-2007. Gohlke H, Winter M, Karoff M and Held K (2016) CARRISMA: a new tool to improve risk stratification and guidance of patients in cardiovascular risk management in primary prevention, European Journal of Cardiovascular Prevention & Rehabilitation, 10.1097/01.hjr.0000244581.30421.69, 14:1, (141-148), Online publication date: 1-Feb-2007. Cruickshank J (2007) Are we misunderstanding beta-blockers, International Journal of Cardiology, 10.1016/j.ijcard.2007.01.069, 120:1, (10-27), Online publication date: 1-Aug-2007. Christou D, Gentile C, DeSouza C, Seals D and Gates P (2005) Fatness Is a Better Predictor of Cardiovascular Disease Risk Factor Profile Than Aerobic Fitness in Healthy Men, Circulation, 111:15, (1904-1914), Online publication date: 19-Apr-2005.Mazzaro L, Almasi S, Shandas R, Seals D and Gates P (2005) Aortic Input Impedance Increases With Age in Healthy Men and Women, Hypertension, 45:6, (1101-1106), Online publication date: 1-Jun-2005. February 2005Vol 45, Issue 2 Advertisement Article InformationMetrics https://doi.org/10.1161/01.HYP.0000152199.18202.a9PMID: 15623541 Originally publishedDecember 27, 2004 PDF download Advertisement