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Low BMI is inversely associated with arterial stiffness in Africans

Published online by Cambridge University Press:  13 April 2015

Hugo Willem Huisman*
Affiliation:
Hypertension in Africa Research Team (HART), North-West University (Potchefstroom Campus), Private Bag 6001, Potchefstroom2520, South Africa
Rudolph Schutte
Affiliation:
Hypertension in Africa Research Team (HART), North-West University (Potchefstroom Campus), Private Bag 6001, Potchefstroom2520, South Africa
Herman Louwrens Venter
Affiliation:
Hypertension in Africa Research Team (HART), North-West University (Potchefstroom Campus), Private Bag 6001, Potchefstroom2520, South Africa
Johannes Marthinus van Rooyen
Affiliation:
Hypertension in Africa Research Team (HART), North-West University (Potchefstroom Campus), Private Bag 6001, Potchefstroom2520, South Africa
*
*Corresponding author: H. W. Huisman, fax +27 18 299 2433, email hugo.huisman@nwu.ac.za
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Abstract

In low socio-economic status communities in South Africa, African men showed a low BMI. Data on the effect of low BMI on cardiovascular function are scant. The present study aimed to assess the associations between low BMI and markers of cardiovascular function such as pulse wave velocity (PWV) and blood pressure in Africans aged 35–65 years, with low socio-economic status. The study population (n 496) was stratified into a low-BMI group with BMI ≤ 20 kg/m2 and a normal-BMI group with BMI >20 kg/m2 and ≤ 25 kg/m2. Blood pressure (Omron HEM-757) and PWV (Complior SP; Artech-Medical) was determined. Africans with low BMI showed an increased arterial stiffness with significantly higher PWV compared with the normal-BMI group (men: P= 0·001; women: P= 0·026), which remained after adjustment. In men with low BMI, PWV correlated negatively with BMI before (r − 0·204; P= 0·012) and after (r − 0·200; P= 0·020) adjustment. Forward stepwise regression analyses indicated a negative association between PWV and BMI in African men. A J-curve was evident suggesting a detrimental effect of low BMI on cardiovascular function in Africans. A low BMI may contribute to the high prevalence of cardiovascular-related morbidity and mortality within a developing country.

Type
Full Papers
Copyright
Copyright © The Authors 2015 

Low socio-economic status and living in low socio-economic settlements in South Africa are related to non-communicable diseases such as CVD( Reference Sliwa, Wilkinson and Ntyintyane 1 Reference Writers Lawn and Kinney 6 ). In low socio-economic status communities, a prudent, low-energy, low-fat and micronutrient-deficient diet is followed traditionally( Reference Pisa, Behanan and Vortser 7 ). The current acculturation process in these settlements is further characterised by detrimental behavioural lifestyle factors such as unhealthy dietary habits, alcohol abuse and smoking, leading to a dramatic increase in CVD( Reference Pisa, Behanan and Vortser 7 Reference Schutte, Schutte and Huisman 12 ). This ‘new epidemic’ of CVD is disproportionally high in poor urban and rural communities( Reference Writers Lawn and Kinney 6 ).

In the low socio-economic status communities in the North West Province of South Africa, it is striking that African men showed the lowest BMI compared with African women and Caucasian men and women( Reference Kruger, Huisman and Schutte 13 , Reference Vorster, Kruger and Venter 14 ). In the Transition and Health during Urbanization of South Africans study, BMI is significantly lower in African men compared with African women (20·8 v. 26·1 kg/m2) as well as the body fat percentage (20·6 v. 47·1 %) at all levels of transition( Reference Vorster, Kruger and Venter 14 , Reference Aderibigbe, Pisa and Mamabolo 15 ). In the South African study regarding the influence of Sex, Age and Ethnicity on Insulin sensitivity and Cardiovascular function, African men have also been shown to have a significantly lower mean BMI than African women as well as Caucasian men and women( Reference Kruger, Huisman and Schutte 13 ). In another sub-study of the PURE (Prospective Urban and Rural Epidemiology) study, African men have also been shown to have the lowest BMI values compared with African women( Reference Pisa, Kruger and Vorster 9 ).

There has been much emphasis on high BMI as a risk factor for CVD( Reference Poirier, Giles and Bray 16 Reference Kappus, Fahs and Smith 20 ); however, there has been less focus on CVD risk with low BMI( Reference Durazo-Arvizu, Cooper and Luke 21 Reference Katzmarzyk, Craig and Bouchard 23 ). A study conducted in Japan has shown that a BMI range of 21–23 kg/m2 has the lowest morbidity and mortality( Reference Higashi, Sasaki and Nakagawa 24 ). In contradiction, a low BMI has been found to be an independent predictor of cardiovascular events in elderly( Reference Wassertheil-Smoller, Fann and Allman 17 ) and in hypertensive patients( Reference Colin Bell, Adair and Popkin 25 ), and a J-curve seems evident between BMI and the risk for CVD( Reference Wassertheil-Smoller, Fann and Allman 17 , Reference Katzmarzyk, Craig and Bouchard 23 , Reference Colin Bell, Adair and Popkin 25 Reference Meenakshisundaram, Agarwal and Rajendiran 27 ). Low BMI and the association with mortality have often been explained as being due to confounders such as smoking or a pre-existing illness( Reference Wassertheil-Smoller, Fann and Allman 17 ). However, studies that controlled for these confounders have still found a J-shaped relationship( Reference Wassertheil-Smoller, Fann and Allman 17 , Reference Vikram, Pandey and Misra 22 , Reference Higashi, Sasaki and Nakagawa 24 , Reference Tokunaga, Matsuzawa and Kotani 26 ). The underlying mechanism of this relationship remains unclear. The aim of the present study was, therefore, to investigate the possible associations of low BMI with markers of vascular function in Africans.

Methods

Study design, participants and experimental protocol

The PURE study is a prospective cohort study that tracks changing lifestyles, risk factors and chronic disease using periodic standardised data collection in urban and rural areas of sixteen countries in transition( Reference Teo, Chow and Vaz 28 ).

This cross-sectional sub-study is part of the overarching PURE study and was performed in the North West Province of South Africa. The inclusion criteria were eligible residents of the households approached with an apparently low socio-economic status, older than 35 years and with no self-reported chronic diseases or medication. The present study composed of 96 % of the participants who were disposed of no formal education or only a basic primary education. The average daily income is less than 3·00 US dollar. As participants were recruited from one of the nine provinces of South Africa and only 21 % were employed, the present study may not be representative of the entire black South African population. However, a total of 2010 Africans were recruited from a sample of 6000 randomly selected households in rural and urban setting during the year 2005. All measurements were done in the morning, and subjects were informed about the objectives and procedures of the study before participation. Trained field workers assisted and were available to provide information on participants' language of preference (Setswana-speaking).

The exclusion criteria for this sub-study were participants aged 65 years and older, a history of tuberculosis or HIV infected, an ear temperature higher than 37°C, blood donors and individuals vaccinated in the past 3 months. HIV status was determined with the First Response (PMC Medical) rapid HIV card test using whole blood. If tested positive, the test was repeated with the Pareekshak (Bhat Bio-tech Private Limited) card test, and if positive the participants were referred to their local clinics.

For this sub-study, these subjects were further subdivided into two groups. The optimal BMI for longevity fell between 20·5 and 24·9 kg/m2 for men and women( Reference Calle, Thun and Petrelli 29 ). Therefore, the first group consisted of Africans with a low BMI smaller or equal to 20 kg/m2 (men n 152, women n 94) while the second group consisted of Africans with a normal BMI larger than 20 kg/m2 and smaller or equal to 25 kg/m2 (men n 100, women n 150). The remaining participants had BMI larger than 25 kg/m2 and were only used to illustrate the J-curve effect in overweight and obese subjects compared with normal- and low-BMI subjects.

Ethical considerations

An informed consent form was signed by all the participants before the commencement of measurements. Permission for the execution of the present study was obtained from the provincial Department of Health, the local authorities as well as the tribal Chief from the specific rural area. The study protocol complies with the Declaration of Helsinki as revised in 2008, and was approved by the Ethics Review Board of the North-West University, Potchefstroom, South Africa.

Questionnaires

The participants were interviewed using structured demographic, socio-economic and lifestyle questionnaires developed and standardised for the international PURE study( Reference Teo, Chow and Vaz 28 ). Lifestyle data included self-reported current smoking, alcohol consumption as well as medical history.

Anthropometric measurements

Anthropometric measurements were done in duplicate by registered biokineticists and their mean was used. Standardised procedures were used to measure the height (Invicta Stadiometer, IP 1465), weight (Precision Health Scale; A & D Company), and hip and waist circumference of each participant (Holtain unstretchable metal tape) with the guidelines as indicated by Marfell-Jones et al. ( Reference Marfell-Jones, Olds and Stewart 30 ).

Cardiovascular measurements

Systolic blood pressure (SBP) and diastolic blood pressure (DBP) measurements were obtained with the validated Omron HEM-757 device. Totally, two blood pressure measurements were performed on the right arm (brachial artery), with a 5 min rest period between the two measurements, from which the last value was used while the participants were seated upright and relaxed. The carotid-radial pulse wave velocity (PWV) as a measure of arterial stiffness was determined on the left side of each participant with the Complior SP device (Artech-Medical).

Blood and serum samples

Fasting blood samples were obtained from the antebrachial vein using a sterile winged infusion set and syringes. Serum was prepared according to appropriate methods and stored at − 80°C. In the remote areas, serum was stored under dry ice (no longer than 5 d) until it could be transported to the laboratory facility.

Biochemical analyses

Quantitative determinations of total cholesterol, HDL-cholesterol, TAG, γ-glutamyl transferase (GGT) and high-sensitivity C-reactive protein (CRP) were measured utilising the Sequential Multiple Analyzer Computer Konelab20i™ auto-analyzer (Thermo Fisher Scientific Oy).

Data analyses

Data analyses were performed using the Statistica 10 software (StatSoft, Inc.). The population effect size was calculated for PWV as the main outcome measure. The priori analysis calculated that an n value or a population of seventy-eight per group is sufficient to test the hypothesis of the present study.

Non-Gaussian distributions were normalised by logarithmic transformation. t-Tests were used to determine significant differences between groups and presented as arithmetic means with standard deviations or geometric means and 5th–95th percentile intervals. The χ2 test was used to compare the proportions. One-way ANCOVA was used to determine the differences between BMI groups while adjusting for age, smoking and alcohol consumption, and the differences were presented as mean with 95 % CI. The Pearson correlations as well as partial correlations were performed. Partial correlations were adjusted for age, smoking and alcohol consumption or age, smoking, GGT and CRP. PWV was additionally adjusted for mean arterial pressure ((SBP − DBP)0·33+DBP) and heart rate. Partial correlation analyses were also performed between cardiovascular (SBP, DBP and PWV) and biochemical (GGT and CRP) measures while adjusting for age. Multiple regression analyses using the forward stepwise method were used to determine independent associations between cardiovascular variables and BMI in each sex and BMI group. Significant values were noted as P≤ 0·05. Fig. 1 is determined by calculating the average value for each BMI value expressed as a whole number.

Fig. 1 Pulse wave velocity (PWV) and diastolic blood pressure (DBP) as a function of BMI, adjusted for age, smoking and consumption of alcohol. Dotted line on the x-axis indicates cut-off point for overweight BMI. , Men; , women.

Results

Characteristics of the participants

The group was stratified into low- and normal-BMI groups. The age distributions of the groups were similar. As expected, the low-BMI men and women showed lower BMI and waist circumference values (Table 1). Men with low BMI, compared with those with normal BMI, showed significantly higher DBP (P= 0·022) and higher PWV (P= 0·001). In women, the low-BMI group had a higher PWV compared with the normal-BMI group (P= 0·026). Men with low BMI had lower total cholesterol (P= 0·036) as well as TAG (P= 0·002) and higher CRP (P= 0·016) values compared with the normal-BMI group. The low-BMI group smoked more and consumed more alcohol (men 74·3, 70·4 % and women 67, 46·8 %, respectively).

Table 1 Characteristics of study population with low and normal BMI (kg/m2) (Arithmetic mean values and standard deviations; geometric mean values and 5th–95th percentiles; number of participants and percentages)

WC, waist circumference; SBP, systolic blood pressure; DBP, diastolic blood pressure; MAP, mean arterial blood pressure; PWV, pulse wave velocity; HR, heart rate; GGT, γ-glutamyl transferase; CRP, C-reactive protein; TC, total cholesterol.

After adjusting for age, smoking and alcohol consumption and PWV additionally adjusted for mean arterial blood pressure and heart rate, DBP and PWV remained significantly higher in men with low BMI compared with the normal-BMI men (Table 2). Women with low BMI also sustained a significantly higher value for PWV compared with the normal-BMI group.

Table 2 Adjusted variables (ANCOVA) with low and normal BMI (kg/m2)* (Mean values and 95 % confidence intervals)

SBP, systolic blood pressure; DBP, diastolic blood pressure; PWV, pulse wave velocity; CRP, C-reactive protein; TC, total cholesterol.

* Adjusted for age, smoking and alcohol consumption.

PWV was additionally adjusted for mean arterial pressure and heart rate.

Single and partial regression analyses

In men with low BMI, PWV correlated negatively with BMI before (r − 0·204; P= 0·012) and after (r − 0·200; P= 0·020) adjusting for age, smoking, alcohol consumption, mean arterial pressure and heart rate (Table 3) . A negative association was also evident in men with normal BMI after adjusting for the above-mentioned covariates (r − 0·228; P= 0·041). When alcohol consumption was substituted with GGT and CRP in the adjustment, the negative correlation between PWV and BMI was still evident (r − 0·199; P< 0·001) in the low-BMI men, but disappeared in the normal-BMI men. Correlations for SBP (r 0·14; P= 0·037) and DBP (r 0·14; P= 0·044) with BMI emerged in the normal-BMI men (data not shown). No correlation was found between the cardiovascular (SBP, DBP and PWV) and biochemical variables (GGT and CRP) for both BMI groups, except for DBP and GGT in the normal-BMI men (r 0·170; P= 0·012). In men with low BMI, GGT also showed a negative correlation with BMI before (r − 0·182; P= 0·031) and after adjustments (r − 0·181; P= 0·034) were made.

Table 3 Adjusted regression analyses of low and normal BMI (kg/m2) as independent variable with cardiovascular and biochemical variables in African men and women*

SBP, systolic blood pressure; DBP, diastolic blood pressure; PWV, pulse wave velocity; GGT, γ-glutamyl transferase; CRP, C-reactive protein.

* Partial correlations were adjusted for age, smoking and alcohol consumption.

PWV was additionally adjusted for mean arterial pressure and heart rate.

For women, no correlations were found between PWV and BMI in the low- and normal-BMI groups. In women with low BMI, CRP correlated negatively with BMI before (r − 0·381; P= 0·001) and after (r − 0·344; P= 0·001) adjusting for age, smoking and alcohol consumption. There were also correlations between blood pressure and GGT (P< 0·01) in the low- and normal-BMI groups.

In Fig. 1, the variables PWV and DBP expressed as a function of BMI, and tend to reveal a typical J-curve pattern, particularly in African men.

Linear multiple stepwise regression analyses of African men confirmed the negative association between PWV and BMI (adjusted R 2 0·113, β = − 0·246, 95 % CI − 0·351, − 0·141; P≤ 0·001) in the low-BMI group and (adjusted R 2 0·106, β = − 0·146, 95 % CI − 0·279, − 0·013; P= 0·034) in the normal-BMI group.

Discussion

The present study showed a higher PWV in the low-BMI group compared with the normal-BMI group in both men and women and an inverse relationship between PWV and BMI in men with low BMI. In women, the inverse association between PWV and BMI was absent in the low-BMI group but a tendency existed in the normal-BMI group. This relationship, particularly in African men, is illustrated by a typical J-curve pattern when PWV and DBP are expressed as a function of BMI. Increased arterial stiffness is reflected by an increase in PWV, and arterial stiffness is an independent predictor of adverse cardiovascular events, including mortality( Reference Nichols 31 , Reference Schutte, Huisman and Schutte 32 ).

Opposing studies have criticised that some studies have found an increased risk associated with a low BMI but failed to exclude smokers and people with coexisting illness( Reference Calle, Thun and Petrelli 29 ). After adjusting for smoking and alcohol consumption and the exclusion criteria of the present study, which included participants infected with tuberculosis and HIV, or suffering from other self-reported chronic diseases, the negative association between PWV with low BMI still existed, most prominently in African men. The lipid profile is also favourable in Africans, in general, as well as in the present study population.

In support of this, a significant negative association has also been found between GGT and BMI in African men. Although lifestyle factors alone could not explain the present results, because we did not find a direct link between lifestyle or inflammation and arterial stiffness in men, these detrimental lifestyle factors could have a long-term harmful effect on the cardiovascular system and overall health. In women, a link between GGT and blood pressure existed, but although the level of PWV was higher in the low-BMI group, negative correlations between PWV and BMI were not found. As shown previously, behavioural lifestyle and environmental factors such as unhealthy dietary habits, smoking and alcohol consumption have been associated with hypertension and vascular dysfunction in Africans living in low socio-economic conditions( Reference Panagiotakos, Pitsavos and Chrysohoou 3 , Reference Pisa, Behanan and Vortser 7 , Reference Pisa, Kruger and Vorster 9 , Reference Zatu, Van Rooyen and Loots 11 ).

This higher level of arterial stiffness was accompanied with increased levels of DBP and CRP in men with low BMI. Increased vascular resistance could at least partly contribute to the increased DBP, while inflammation can be associated with CRP( Reference Huisman, Schutte and Schutte 33 ). This suggests detrimental changes in vascular and endothelial functions in men with low BMI. Low BMI in African people may be the result of environmental factors, which, in turn, may have had a detrimental effect on vascular function. The increased arterial stiffness in low-BMI group may be due to several changes in the vascular wall occurring simultaneously over a long period, including changes in extracellular matrix and endocrine or paracrine factors( Reference Schutte, Huisman and Schutte 32 , Reference Huisman, Schutte and Schutte 33 ). The relationship between body weight and mortality supports the hypothesis of a curvilinear relation, in which the CVD risk is increased among low- and high-BMI subjects( Reference Wassertheil-Smoller, Fann and Allman 17 , Reference Vikram, Pandey and Misra 22 , Reference Colin Bell, Adair and Popkin 25 , Reference Meenakshisundaram, Agarwal and Rajendiran 27 , Reference Calle, Thun and Petrelli 29 ).

In accordance with these findings, it is also evident from the literature that serum GGT has conventionally been used as a marker of alcohol consumption and as a non-specific marker of liver function. Furthermore, it is increasingly regarded as a marker of CVD and the conditions associated with CVD such as oxidative stress, leading to a reduced bioavailability of NO( Reference Pisa, Behanan and Vortser 7 , Reference Thadhani, Camargo and Stampher 34 Reference Wannamethee, Lennon and Shaper 36 ). Wannamethee et al. ( Reference Wannamethee, Lennon and Shaper 36 ) indicated that GGT associates with PWV in a prospective study of 6997 men aged 40–59 years with no history of CVD or diabetes. Whether high alcohol consumption or oxidative stress is responsible for this harmful effects in African men remains uncertain; however, both could have an added negative influence on vascular stiffness and vascular damage contributing to CVD( Reference Wannamethee, Lennon and Shaper 36 , Reference Rimm, Williams and Fosher 37 ). These associations suggest that PWV (arterial stiffness), DBP (pre-hypertension) and GGT (oxidative stress) in African men and in a lesser extent in African women play a possible role in predicting impeded cardiovascular function with low BMI, supporting the J-curve theory.

The present study must be further interpreted within the context of its limitations. In the present study, causality could not be inferred. There is a need to compare data obtained from Africans with data from Caucasians. This was a cross-sectional study and because of the focus of the PURE study, participants were selected from specific rural and urban environments from the North West Province of South Africa only, and the present results may not necessarily be representative of the general South African population. We could also not exclude selection biases in this low socio-economic environment. Contextual variables of sociological interest were not measured. Furthermore, there may be measurement errors, even though all variables were obtained under controlled conditions. For the present study the carotid-radialis PWV was measured instead of the carotid-femoralis PWV, the gold standard for measurements of stiffness. Finally, although the present results were consistent after multiple adjustments, we cannot exclude residual confounding.

In conclusion, a detrimental effect of low BMI is evident on cardiovascular function in Africans even after excluding participants with known chronic disease and adjusted for age, smoking and alcohol consumption. When BMI decreases from the optimum value to lower values, a J-curve is evident( Reference Katzmarzyk, Craig and Bouchard 23 ). PWV, DBP and GGT increased significantly in African men with low BMI, whereas the key J-curve was indicated for the PWV, thus supporting the theory that stiffening of the arteries is evident in Africans with a low BMI. Low BMI may contribute to the high prevalence of CVD mortality within low-income countries such as South Africa and therefore increased the risk for CVD.

Acknowledgements

The authors acknowledged the contributions of the team members and participants of the PURE study. The authors also thank Dr S. Yusuf and the PURE project office staff at the Population Health Research Institute, Hamilton Health Sciences and McMaster University, ON, Canada. The present study was financially supported by the National Research Foundation South Africa, North-West University, Potchefstroom and the Metabolic Syndrome Institute. All authors were involved in the design of the study as well as the acquisition, analysis and interpretation of the data for the analyses. H. W. H. drafted the manuscript, while other authors revised the manuscript critically for important intellectual content.

All authors declared no conflict of interest.

References

1 Sliwa, K, Wilkinson, D, Ntyintyane, L, et al. (2008) Spectrum of heart disease and risk factors in a black urban population in South Africa (the Heart of Soweto Study): a cohort study. Lancet 371, 915922.Google Scholar
2 Tarasiuk, A, Greenberg-Dotan, S, Simon, T, et al. (2006) Low socio-economic status is a risk factor for cardiovascular disease among adult obstructive sleep apnea syndrome patients requiring treatment. Chest 130, 766773.CrossRefGoogle ScholarPubMed
3 Panagiotakos, DB, Pitsavos, C, Chrysohoou, C, et al. (2008) Dietary habits mediate the relationship between socio-economic status and CVD factors among healthy adults: the ATTICA study. Public Health Nutr 11, 13421349.CrossRefGoogle ScholarPubMed
4 Van Rooyen, JM, Kruger, HS, Huisman, HW, et al. (2000) An epidemiological study of hypertension and its determinants in a population in transition: the THUSA study. J Hum Hypertens 14, 779787.Google Scholar
5 Reddy, KS & Yusuf, S (1998) Emerging epidemic of cardiovascular disease in developing countries. Circulation 97, 596601.CrossRefGoogle ScholarPubMed
6 The Lancet South Africa Series Executive Summary Core Group, Writers Lawn, JE & Kinney, MV. The Lancet Health in South Africa: Executive Summary for the Series (August 2009).Google Scholar
7 Pisa, PT, Behanan, R, Vortser, HH, et al. (2012) Social drift of cardiovascular disease risk factors in Africans from the North West Province of South Africa: the PURE study. Cardiovasc J Afr 23, 371378.CrossRefGoogle ScholarPubMed
8 Ambrose, JA & Barua, RS (2004) The pathophysiology of cigarette smoking and cardiovascular disease. J Am Coll Cardiol 43, 17311737.CrossRefGoogle ScholarPubMed
9 Pisa, PT, Kruger, A, Vorster, HH, et al. (2010) Alcohol consumption and cardiovascular disease risk in an African population in transition: the Prospective Urban and Rural Epidemiology (PURE) study. S Afr J Clin Nutr 23, S29S37.Google Scholar
10 Twagirumukiza, M, De Bacquer, D, Kips, JG, et al. (2011) Current and projected prevalence of arterial hypertension in sub-Sahara Africa by sex, age and habitat: an estimation from population studies. J Hypertens 29, 12431252.Google Scholar
11 Zatu, MC, Van Rooyen, JM, Loots, D-T, et al. (2014) Self-reported alcohol intake is a better estimate of 5-year change in blood pressure than biochemical markers in low resource settings: the PURE study. J Hypertens 32, 749755.CrossRefGoogle ScholarPubMed
12 Schutte, AE, Schutte, R, Huisman, HW, et al. (2012) Are behavioural risk factors to be blamed for the conversion from optimal blood pressure to hypertensive status in Black South Africans? A 5-year prospective study. Int J Epidemiol 14, 11141123.Google Scholar
13 Kruger, IM, Huisman, HW & Schutte, AE (2011) The relationship between adiponectin, ageing and renal function in a bi-ethnic sample. Regul Pept 169, 5863.Google Scholar
14 Vorster, HH, Kruger, A, Venter, CS, et al. (2007) Cardiovascular disease risk factors and socio-economic position of Africans in transition: the THUSA study. Cardiovasc J Afr 18, 282289.Google Scholar
15 Aderibigbe, OR, Pisa, PT, Mamabolo, RL, et al. (2011) The relationship between indices of iron status and selected anthropometric cardiovascular risk markers in an African population: the THUSA study. Cardiovasc J Afr 22, 249256.Google Scholar
16 Poirier, P, Giles, TD, Bray, GA, et al. (2006) Obesity and cardiovascular disease: pathophysiology, evaluation, and effect of weight loss. Circulation 113, 898918.Google Scholar
17 Wassertheil-Smoller, S, Fann, C, Allman, RM, et al. (2000) Relation of low body mass to death and stroke in the systolic hypertension in the elderly program. The SHEP Cooperative Research Group. Ann Intern Med 160, 494500.Google Scholar
18 Wang, Y, Mi, J, Shan, XY, et al. (2007) Is China facing an obesity epidemic and the consequences? The trends in obesity and chronic disease in China. Int J Obes 31, 177188.Google Scholar
19 Pischon, T, Boeing, H, Hoffmann, K, et al. (2008) General and abdominal adiposity and risk of death in Europe. N Engl J Med 359, 21052120.CrossRefGoogle ScholarPubMed
20 Kappus, RM, Fahs, CA, Smith, D, et al. (2014) Obesity and overweight associated with increased carotid diameter and decreased arterial function in young otherwise healthy men. Am J Hypertens 27, 628634.Google Scholar
21 Durazo-Arvizu, R, Cooper, R, Luke, A, et al. (1997) Relative weight and mortality in U.S. blacks and whites: findings from representative national population samples. Ann Epidemiol 7, 383395.Google Scholar
22 Vikram, NK, Pandey, RM, Misra, A, et al. (2003) Non-obese (body mass index < 25 kg/m2) Asian Indians with normal waist circumference have high cardiovascular risk. Nutrition 19, 503509.Google Scholar
23 Katzmarzyk, PT, Craig, CL & Bouchard, C (2001) Original article underweight, overweight and obesity: relationships with mortality in the 13-year follow-up of the Canada Fitness Survey. J Clin Epidemiol 54, 916920.CrossRefGoogle ScholarPubMed
24 Higashi, Y, Sasaki, S, Nakagawa, K, et al. (2003) Low body mass index is a risk factor for impaired endothelium-dependent vasodilation in humans: role of nitric oxide and oxidative stress. J Am Coll Cardiol 42, 256263.Google Scholar
25 Colin Bell, A, Adair, LS & Popkin, BM (2002) Ethnic differences in the association between body mass index and hypertension. Am J Epidemiol 155, 346353.Google Scholar
26 Tokunaga, K, Matsuzawa, Y, Kotani, K, et al. (1991) Ideal body weight estimated from the body mass index with lowest morbidity. Int J Obes 15, 15.Google ScholarPubMed
27 Meenakshisundaram, R, Agarwal, D, Rajendiran, C, et al. (2010) Risk factors for myocardial infarction among low socio-economic status South Indian population. Diabetol Metab Syndr 2, 32.Google Scholar
28 Teo, K, Chow, CK, Vaz, M, et al. (2009) The Prospective Urban Rural Epidemiology (PURE) study: examining the impact of societal influences on chronic non-communicable diseases in low-, middle-and high-income countries. Am Heart J 58, 17.e1.Google Scholar
29 Calle, EE, Thun, MJ, Petrelli, JM, et al. (1999) Body mass index and mortality in a prospective cohort of U.S. adults. N Engl J Med 341, 10971105.Google Scholar
30 Marfell-Jones, M, Olds, T, Stewart, A, et al. (2006) International Standards for Anthropometric Assessment. Potchefstroom: ISAK.Google Scholar
31 Nichols, WW (2007) Clinical measurement of arterial stiffness obtained from noninvasive pressure waveforms. Am J Hypertens 18, 3S10S.Google Scholar
32 Schutte, AE, Huisman, HW, Schutte, R, et al. (2011) Arterial stiffness profiles: investigating various sections of the arterial tree of African and Caucasian people. Clin Exp Hypertens 33, 511517.CrossRefGoogle ScholarPubMed
33 Huisman, HW, Schutte, AE, Schutte, R, et al. (2013) Exploring the link between cardiovascular reactivity and end-organ damage in African and Caucasian men: the SABPA study. Am J Hypertens 26, 6875.Google Scholar
34 Thadhani, R, Camargo, CA Jr & Stampher, MJ (2002) Prospective study of moderate alcohol consumption and risk of hypertension in young women. Arch Intern Med 162, 569574.Google Scholar
35 Turgut, O, Yilmaz, MB, Yalta, K, et al. (2009) Gamma-glutamyltransferase as a useful predictor for cardiovascular risk: clinical and epidemiological perspectives. Atherosclerosis 202, 348349.Google Scholar
36 Wannamethee, SG, Lennon, L & Shaper, AG (2008) The value of gamma-glutamyltransferase in cardiovascular risk prediction in men without diagnosed cardiovascular disease or diabetes. Atherosclerosis 201, 168175.Google Scholar
37 Rimm, EB, Williams, P & Fosher, K (1999) Moderate alcohol intake and lower risk of coronary heart disease: meta-analysis of effects on lipids and haemostatic factors. BMJ 319, 15231528.Google Scholar
Figure 0

Fig. 1 Pulse wave velocity (PWV) and diastolic blood pressure (DBP) as a function of BMI, adjusted for age, smoking and consumption of alcohol. Dotted line on the x-axis indicates cut-off point for overweight BMI. , Men; , women.

Figure 1

Table 1 Characteristics of study population with low and normal BMI (kg/m2) (Arithmetic mean values and standard deviations; geometric mean values and 5th–95th percentiles; number of participants and percentages)

Figure 2

Table 2 Adjusted variables (ANCOVA) with low and normal BMI (kg/m2)* (Mean values and 95 % confidence intervals)

Figure 3

Table 3 Adjusted regression analyses of low and normal BMI (kg/m2) as independent variable with cardiovascular and biochemical variables in African men and women*