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Lipid profile in men and women with different levels of sports participation and physical activity

Published online by Cambridge University Press:  01 November 2008

Tineke Scheers
Affiliation:
Department of Biomedical Kinesiology, Faculty of Kinesiology and Rehabilitation Sciences, Katholieke Universiteit Leuven, Tervuursevest 101, B-3001 Leuven, Belgium
Renaat Philippaerts
Affiliation:
Department of Movement and Sports Sciences, Ghent University, Ghent, Belgium Policy Research Centre Sport, Physical Activity and Health, Leuven, Belgium
Leen Van Langendonck
Affiliation:
Policy Research Centre Sport, Physical Activity and Health, Leuven, Belgium
William Duquet
Affiliation:
Policy Research Centre Sport, Physical Activity and Health, Leuven, Belgium Faculty of Physical Education and Physical Therapy, Vrije Universiteit Brussel, Brussels, Belgium
Nathalie Duvigneaud
Affiliation:
Policy Research Centre Sport, Physical Activity and Health, Leuven, Belgium Faculty of Physical Education and Physical Therapy, Vrije Universiteit Brussel, Brussels, Belgium
Lynn Matton
Affiliation:
Department of Biomedical Kinesiology, Faculty of Kinesiology and Rehabilitation Sciences, Katholieke Universiteit Leuven, Tervuursevest 101, B-3001 Leuven, Belgium Policy Research Centre Sport, Physical Activity and Health, Leuven, Belgium
Martine Thomis
Affiliation:
Department of Biomedical Kinesiology, Faculty of Kinesiology and Rehabilitation Sciences, Katholieke Universiteit Leuven, Tervuursevest 101, B-3001 Leuven, Belgium Policy Research Centre Sport, Physical Activity and Health, Leuven, Belgium
Katrien Wijndaele
Affiliation:
Department of Movement and Sports Sciences, Ghent University, Ghent, Belgium Policy Research Centre Sport, Physical Activity and Health, Leuven, Belgium
Johan Lefevre*
Affiliation:
Department of Biomedical Kinesiology, Faculty of Kinesiology and Rehabilitation Sciences, Katholieke Universiteit Leuven, Tervuursevest 101, B-3001 Leuven, Belgium Policy Research Centre Sport, Physical Activity and Health, Leuven, Belgium
*
*Corresponding author: Email [email protected]
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Abstract

Objective

The purpose of the present study was to analyse the lipid profile in men and women differentiated according to energy expenditure during sports participation (EESPORT), energy expenditure during active leisure time (EEALT) and overall energy expenditure (EETOTAL).

Design

The subjects were grouped by sex, age, EESPORT, EEALT and EETOTAL. Group differences were analysed using analyses of covariance with BMI and alcohol consumption as covariates.

Setting

Physical activity was assessed using the Flemish Physical Activity Computerised Questionnaire. Fasting blood samples were taken to measure total cholesterol (TC), TAG, HDL-cholesterol (HDL-C), LDL-cholesterol (LDL-C) and the ratio TC:HDL-C.

Subjects

The study sample consisted of 1170 Flemish men and women between 18 and 75 years of age.

Results

Differences in lipid profile were observed in the younger age group (<45 years), all in favour of the most active group. More specifically, when differentiating by EEALT and EETOTAL, men had a healthier lipid profile for TAG, HDL-C and TC:HDL-C. Differentiation according to EESPORT revealed the same significant results except for TAG. In women significant results for HDL-C, LDL-C and TC:HDL-C were found when differentiated by EESPORT.

Conclusions

Men and women <45 years of age with higher levels of energy expenditure due to sport show a better lipid profile than their sedentary counterparts. When differentiating subjects according to energy expenditure during active leisure time or overall energy expenditure, only in men was a healthier lipid profile observed in favour of the most active subjects.

Type
Research Paper
Copyright
Copyright © The Authors 2007

Plasma lipoproteins play a major role in the aetiology of atherosclerosis and CVDReference Heiss, Johnson, Reiland, Davis and Tyroler(1, Reference Schaefer2), which continue to be the leading cause of morbidity and mortality in the industrialised worldReference Thom, Haase and Rosamond(3).

It has been well documented that a variety of personal characteristics and environmental factors influence the composition of plasma lipids and lipoproteins, including age, gender and the associated hormonal changes in women, genetics, BMI, body weight, body composition, alcohol consumption, smoking behaviour and medication useReference Heiss, Johnson, Reiland, Davis and Tyroler(1, Reference Hall, Collins, Csemiczky and Landgren4Reference Arquer, Elosua, Covas, Molina and Marrugat10).

In addition, it has been shown that physical activity can affect the plasma lipid profile. Most studies indicate that regular exercise produces favourable changes in plasma lipids and lipoproteinsReference Ashton, Nanchahal and Wood(11Reference Pescatello, Murphy and Costanzo21).

Evidence from epidemiological and training studies indicates that those who are physically active exhibit higher levels of HDL-cholesterol (HDL-C)Reference Twisk, Kemper, Mellenbergh, van Mechelen and Post(6, Reference Young, Haskell, Jatulis and Fortmann7, Reference Marti, Suter, Riesen, Tschopp, Wanner and Gutzwiller18, Reference Bijnen, Feskens, Caspersen, Giampaoli, Nissinen, Menotti, Mosterd and Kromhout22Reference Barengo, Kastarinen, Lakka, Nissinen and Tuomilehto30), lower levels of TAG and a lower ratio of total cholesterol (TC) to HDL-C than those who are less activeReference Ashton, Nanchahal and Wood(11, Reference Durstine, Grandjean, Cox and Thompson12, Reference Kraus, Houmard and Duscha14Reference Ma, Liu and Ling16, Reference Wei, Macera, Hornung and Blair19, Reference Pescatello, Murphy and Costanzo21, Reference Lippi, Schena, Salvagno, Montagnana, Ballestrieri and Guidi31, Reference Kobayashi, Murase, Asano, Nohara, Kawashiri, Inazu, Yamagishi and Mabuchi32). Durstine et al.Reference Durstine, Grandjean, Davis, Ferguson, Alderson and DuBose(33) reviewed the literature and concluded that regular exercise can raise HDL-C levels by 2–8 mg/dl and lower TAG by 5–38 mg/dl in men and women.

The preceding results indicate that physical activity can positively affect the lipid profile. However, some investigators have failed to find a significant association between physical activity and favourable changes in the lipid profileReference Danielson, Cauley and Rohay(34Reference Ring-Dimitriou, von Duvillard, Paulweber, Stadlmann, Lemura, Peak and Mueller36). These discrepancies probably reflect the differences in the literature concerning intensity of the physical activity or energy expenditure due to physical activity. Many investigators agree that an exercise threshold needs to be met before favourable changes in HDL-C can occurReference Hardman(13, Reference Marrugat, Elosua, Covas, Molina and Rubies-Prat17, Reference Kokkinos and Fernhall24, Reference Kodama, Tanaka and Saito27, Reference Durstine, Grandjean, Davis, Ferguson, Alderson and DuBose33). For most individuals, this threshold is associated with a physical activity-related energy expenditure of 5·02 MJ (1200 kcal)Reference Durstine, Grandjean, Cox and Thompson(12) or 8 MJ or moreReference Hardman(13) per week, or an intensity of 29·3 kJ/min (7 kcal/min)Reference Marrugat, Elosua, Covas, Molina and Rubies-Prat(17), or 5–6 METs (metabolic energy equivalent tasks)Reference Lakka and Salonen(15).

Concerning the effect of exercise on TC and LDL-cholesterol (LDL-C) there is inconclusive evidence in both epidemiological and training studies. A careful evaluation of the literature indicates that exercise training seldom alters TC and LDL-CReference Durstine, Grandjean, Cox and Thompson(12, Reference Kraus, Houmard and Duscha14). However, there are a few exceptions. In a meta-analysis of randomised controlled trials, it was concluded that walking results in decreases in LDL-CReference Kelley, Kelley and Tran(37).

Obviously it is not completely clear whether in a normal population it should be advised to augment energy expenditure by high-intensity activities (sport) or by being more physically active in general, in order to obtain a healthier lipid profile. Moreover, relatively few studies have included women and their conclusions are less consistent than in men.

Therefore, the purpose of the current study was to investigate the lipid profile in a general population of Flemish males and females differentiated according to sports-related energy expenditure, energy expenditure during active leisure time and total energy expenditure.

Methods

Subjects

The subjects included in the present study originate from the Policy Research Centre Sport, Physical Activity and Health. This Policy Research Centre was established to investigate physical fitness, physical activity and sports participation in relation to health in the Flemish population. In order to fulfil this aim, almost 6000 subjects between 18 and 75 years of age were tested in their home town (Theme 1), of which almost 2000 subjects also completed an extensive test battery in the central laboratory of the Policy Research Centre (Theme 2).

For the present study, the data of subjects originating from Theme 2 were used. Of the total sample of almost 2000 subjects, 1632 had complete data on blood lipids, dietary intakes and physical activity habits. It was decided to exclude students, pensioners older than 75 years of age and those who took cholesterol-lowering medication. Thus, a total of 1170 subjects (672 men, mean age 46·30 (sd 10·67) years and 498 women, mean age 44·38 (sd 8·98) years) were included in the present study.

Assessment of physical activity

Participation in sport and physical activity was investigated using the Flemish Physical Activity Computerised Questionnaire (FPACQ), which is extensively described by Matton et al.(38).

In this questionnaire subjects were asked to select a maximum of three of their most important sports out of a list of 196 specific sports. To calculate the hours of health-related sports participation, the sum was made of the hours per week they spent on these three sports. This value could amount to a maximum of 30 h. Sports participation was considered as health-related sports participation if the associated MET valueReference Ainsworth, Haskell and Whitt(39) of the sport was at least 4·5, 4·0 and 3·5 respectively for subjects younger than 35, between 35 and 49 and older than 50 years of age. For each sport, the MET value was multiplied by the time spent on this sport. The sum of these three multiplications results in the total energy expenditure during health-related sports participation and was called EESPORT (MET × h/week).

Furthermore, subjects were asked about time spent on active transportation (walking and cycling) in leisure time and time spent on light, moderate and vigorous household and garden activities. For each active leisure-time activity, the MET value was multiplied by the time spent on this activity. The sum of these multiplications plus the energy expenditure during health-related sports participation resulted in EEALT (MET × h/week), an indication of the overall energy expenditure of active leisure-time activities.

Finally, total energy expenditure, EETOTAL (MET × h/week), was calculated by summing the energy expenditure of all activities during a usual week.

Assessment of dietary intake

Dietary habits and energy intake were assessed by means of the 3 d (two weekdays and one weekend day) food record method. The subjects were asked to write down all the food and drinks they consumed during those three days. The detailed list of dietary products was processed with the BECEL computer program version 5·0 (Hartog-Union and Van den Bergh, Rotterdam, The Netherlands). To control for confounding factors the relationship between dietary intake and lipid profile was analysed by correlation and regression analyses (results not shown). Based on these analyses it was decided to use alcohol consumption as covariate.

Lipid analysis

Fasting blood samples (after an overnight fast) were taken for the measurement of TC, TAG, HDL-C, LDL-C and TC:HDL-C ratio. The blood lipids and lipoproteins were measured on an Olympus AU5400 analyser (Olympus Diagnostica, Hamburg, Germany). The CV between days were 2·0 % (at 7·02 mmol/l) for TC, 1·4 % (at 2·07 mmol/l) for TAG, 3·9 % (at 2·04 mmol/l) for HDL-C and 3·4 % (at 4·02 mmol/l) for LDL-C.

Statistical analysis

The subjects were grouped by sex, age (<45 years, ≥45 to <55 years and ≥55 years), EESPORT, EEALT and EETOTAL (<25th percentile v. >75th percentile). Descriptive statistics (mean, sd, P25 and P75) were calculated for the anthropometric characteristics, physical activity variables and the serum lipid and lipoprotein values. Group differences were analysed by analyses of covariance with BMI and alcohol consumption as covariates since prior analyses (correlation and regression analyses) showed the importance of these factors (results not shown).

All statistical analyses were performed using the Statistical Analysis Systems statistical software package version 9·1 (SAS Institute, Cary, NC, USA). Statistical significance was set at α = 0·05.

Results

Descriptive statistics of the anthropometric characteristics, physical activity-related variables, and the serum lipid and lipoprotein values are presented in Tables 1 and 2 for men and women respectively.

Table 1 Descriptive statistics (mean, sd, 25th percentile (P25) and 75th percentile (P75)) of the anthropometric characteristics, physical activity variables and serum lipid and lipoprotein values among men

EESPORT, energy expenditure during health-related sports participation; EEALT, energy expenditure during active leisure time; EETOTAL, total energy expenditure; TC, total cholesterol; HDL-C, HDL-cholesterol; LDL-C, LDL-cholesterol.

Table 2 Descriptive statistics (mean, sd, 25th percentile (P25) and 75th percentile (P75)) of the anthropometric characteristics, physical activity variables and serum lipid and lipoprotein values among women

EESPORT, energy expenditure during health-related sports participation; EEALT, energy expenditure during active leisure time; EETOTAL, total energy expenditure; TC, total cholesterol; HDL-C, HDL-cholesterol; LDL-C, LDL-cholesterol.

Analyses of covariance in the younger age group differentiated according to sex and level of energy expenditure (EESPORT, EEALT or EETOTAL) revealed significant differences in lipid profile, all in favour of the most active groups (Tables 3 and 4).

Table 3 Comparison of serum lipid and lipoprotein values between men being part of the lowest and highest quartile of energy spent during health-related sports participation, energy spent during active leisure time and total energy spent during a week: analyses of covariance with BMI and alcohol consumption as covariates

EESPORT, energy expenditure during health-related sports participation; EEALT, energy expenditure during active leisure time; EETOTAL, total energy expenditure; LSMean, least-squares mean; TC, total cholesterol; HDL-C, HDL-cholesterol; LDL-C, LDL-cholesterol.

Table 4 Comparison of serum lipid and lipoprotein values between women being part of the lowest and highest quartile of energy spent during health-related sports participation, energy spent during active leisure time and total energy spent during a week: analyses of covariance with BMI and alcohol consumption as covariates

EESPORT, energy expenditure during health-related sports participation; EEALT, energy expenditure during active leisure time; EETOTAL, total energy expenditure; LSMean, least-squares mean; TC, total cholesterol; HDL-C, HDL-cholesterol; LDL-C, LDL-cholesterol.

Concerning the comparison of young men with different levels of EESPORT (<P25 v. >P75), significant results were found for HDL-C (1·37 (sd 0·30) mmol/l v. 1·49 (sd 0·30) mmol/l) and TC:HDL-C (3·96 (sd 0·88) v. 3·54 (sd 0·88); Table 3). For the young women, significant results were observed for HDL-C (1·65 (sd 0·35) mmol/l v. 1·76 (sd 0·34) mmol/l), LDL-C (3·09 (sd 0·78) mmol/l v. 2·76 (sd 0·78) mmol/l) and TC:HDL-C (3·29 (sd 0·78) v. 2·95 (sd 0·71); Table 4).

Differentiation according to EEALT and EETOTAL in young men revealed significant differences for TAG (respectively 1·20 (sd 0·49) mmol/l v. 1·04 (sd 0·49) mmol/l and 1·22 (sd 0·52) mmol/l v. 1·04 (sd 0·51) mmol/l), HDL-C (respectively 1·30 (sd 0·25) mmol/l v. 1·50 (sd 0·25) mmol/l and 1·31 (sd 0·27) mmol/l v. 1·48 (sd 0·27) mmol/l) and TC:HDL-C (respectively 4·09 (sd 0·79) v. 3·53 (sd 0·79) and 4·07 (sd 0·88) v. 3·58 (sd 0·88); Table 3). In young women no significant differences could be observed.

In the middle-aged group (≥45 to <55 years) differentiated according to sex and level of energy expenditure (EESPORT, EEALT, EETOTAL), no significant differences were observed except for HDL-C in men grouped by EESPORT (1·39 (sd 0·30) mmol/l v. 1·53 (sd 0·29) mmol/l; Table 3).

Comparison of the older age group (≥55 years) differentiated according to sex and level of energy expenditure (EESPORT, EEALT, EETOTAL) did not reveal any significant difference except for TAG in men grouped by EEALT (1·51 (sd 0·55) mmol/l v. 1·23 (sd 0·55) mmol/l; Table 3).

Discussion

There is consolidated evidence that physical activity exerts beneficial effects on lipid profiles. Former studies focused on the importance of the intensity of physical activity whereas more recently focus has shifted towards energy expenditure. Durstine et al.Reference Durstine, Grandjean, Davis, Ferguson, Alderson and DuBose(33) concluded in their review that the effects of exercise on lipid and lipoprotein levels can be initiated at low training volumes and will continue in a dose–response fashion with increasing training volume. However, results are not equivocal in different age groups. Moreover, studies focusing on women often show conflicting results and are rather sparse.

Obviously debate continues regarding the effect of physical activity. The purpose of the present study was to investigate the importance of energy expenditure on the lipid profile in a general population of Flemish males and females of different age groups. More specifically, it was investigated whether energy expenditure in general or sports-related energy expenditure contributes to a healthier lipid profile.

The results of this study indicate that young women (<45 years) of the highest quartile of energy expenditure during health-related sports participation have healthier values for HDL-C, LDL-C and TC:HDL-C than their inactive counterparts. It was expected to find differences regarding HDL-CReference Twisk, Kemper, Mellenbergh, van Mechelen and Post(6, Reference Young, Haskell, Jatulis and Fortmann7, Reference Kokkinos and Fernhall24, Reference Leon and Sanchez25, Reference Kodama, Tanaka and Saito27Reference Fransson, Alfredsson, de Faire, Knutsson and Westerholm29, Reference Durstine, Grandjean, Davis, Ferguson, Alderson and DuBose33, Reference Skoumas, Pitsavos, Panagiotakos, Chrysohoou, Zeimbekis, Papaioannou, Toutouza, Toutouzas and Stefanadis40), but finding differences in LDL-C was rather surprising since there is little support in the cross-sectional literature for significant differences in LDL-C between active and inactive groups. Even in training studies significant changes in LDL-C are generally not observed. However, there are a few exceptions: most frequently in studies with exercise training programmes in which participants expended more than 5·02 MJ/week (1200 kcal/week)Reference Durstine, Grandjean, Davis, Ferguson, Alderson and DuBose(33). Analysing the energy expenditure due to health-related sports participation of the women younger than 45 years of age, it was observed that none of the subjects of the group <P25 and seventy-six subjects of the seventy-eight subjects of the group >P75 had an EESPORT above 4·18 MJ/week (1000 kcal/week). Of these seventy-six subjects, sixty-four women had an EESPORT above 5·02 MJ/week (1200 kcal/week). It is clear that the energy expenditure due to sports participation in the most active young women of the present study is comparable with the energy expenditure in training studies in which significant effects of physical activity on the lipid profile were observed.

When the women younger than 45 years of age were differentiated according to energy spent during active leisure time or overall energy expenditure during a normal week, significant differences were no longer observed. Weller and CoreyReference Weller and Corey(41) showed that physical activity was inversely associated with risk of death in women and pointed out that the contribution of non-leisure (household chores) energy expenditure represented, on average, 82 % of women’s total activity. They argued that when studying the effect of physical activity on CVD in women non-leisure energy expenditure should be taken into account. The results of the present study suggest that sports-related energy expenditure, rather than active leisure time-related energy expenditure in which household activities are included, results in a healthy lipid profile. This conclusion is supported by the findings of O’Connor et al.Reference O’Connor, Hennekens, Willett, Goldhaber, Paffenbarger, Breslow, Lee and Buring(42), who stated that moderate to vigorous sporting activity was directly related to high HDL-C whereas total energy expenditure was uncorrelated with blood lipids. To illustrate: in the present study, less than half of the young women who belonged to the group >P75 differentiated according to energy spent during active leisure time had an EESPORT above 5·02 MJ/week (1200 kcal/week). So it seems that a minimum intensity threshold has to be met.

In young men differentiated according to energy expenditure during health-related sports participation significant results were observed for HDL-C and TC:HDL-C. No significant results were observed for TAG. This finding was unexpected since it was argued by Durstine et al.Reference Durstine, Grandjean, Davis, Ferguson, Alderson and DuBose(33) that both HDL-C and TAG levels can be changed by similar training volumes. They concluded that training volumes that elicit energy expenditures ≥5·02 MJ/week (≥1200 kcal/week) are associated with elevations in HDL-C levels and reduced TAG levels. When the men younger than 45 years of age were differentiated according to EEALT or EETOTAL, significant differences were observed for HDL-C, TC:HDL-C and also for TAG.

Analysing EESPORT in the group >P75 differentiated according to EESPORT, it was observed that all seventy-eight subjects had values exceeding the threshold of 5·02 MJ/week (1200 kcal/week). When differentiating according to EEALT or EETOTAL most of the subjects belonging to the group >P75 still had EESPORT values above 5·02 MJ/week (1200 kcal/week; this in contrast to the young women). However, when looking at the mean and sd of energy spent during active leisure time of the group <P25 differentiated according to EEALT, it becomes clear that these subjects were much less active [8·35 (sd 3·09) MJ/week (1996 (sd 739) kcal/week)] than the subjects belonging to the group <P25 differentiated according to EESPORT [14·69 (sd 9·47) MJ/week (3511 (sd 2263) kcal/week)]. For the group >P75, when differentiating according to EEALT higher values were observed for EEALT than for EESPORT when differentiating according to EESPORT [43·59 (sd 15·67) MJ/week (10 419 (sd 3745) kcal/week), with a minimum value of 24·33 MJ/week (5815 kcal/week) v. 39·05 (sd 17·98) MJ/week (9333 (sd 4297) kcal/week), with a minimum value of 15·89 MJ/week (3798 kcal/week)]. In contrast to the young women it seems that differentiating young men according to EEALT or EETOTAL results in more contrasting groups than when differentiating according to EESPORT.

In the middle-aged (≥45 to <55 years) and older age groups (≥55 years) no significant differences were observed except for HDL-C in middle-aged men grouped by EESPORT and TAG in men older than 55 years of age differentiated according to EEALT. However, several studies have shown the beneficial effect of physical activity on the lipid profile in middle-aged and older adultsReference Schubert, Rogers, Remsberg, Sun, Chumlea, Demerath, Czerwinski, Towne and Siervogel(8, Reference Arquer, Elosua, Covas, Molina and Marrugat10, Reference Lakka and Salonen15, Reference Pescatello, Murphy and Costanzo21, Reference Bijnen, Feskens, Caspersen, Giampaoli, Nissinen, Menotti, Mosterd and Kromhout22, Reference Sunami, Motoyama, Kinoshita, Mizooka, Sueta, Matsunaga, Sasaki, Tanaka and Shindo26, Reference Kelley, Kelley and Tran37, Reference Ainslie, Reilly, Maclaren and Campbell43). It has already been suggested that energy expenditure has to be above a certain thresholdReference Durstine, Grandjean, Davis, Ferguson, Alderson and DuBose(33). Fonong et al.Reference Fonong, Toth, Ades, Katzel, Calles-Escandon and Poehlman(35) reported that short-time exercise training, generating less than 3·77 MJ/week (900 kcal/week) in exercise energy expenditure, fails to influence HDL-C levels in healthy older men and women. In the present study, when participants of the middle-aged and older age groups were differentiated according to EESPORT, none of the subjects belonging to the group <P25 and all of the subjects belonging to the group >P75 had an EESPORT exceeding 5·02 MJ/week (1200 kcal/week). It seems that the threshold suggested by Durstine et al.Reference Durstine, Grandjean, Davis, Ferguson, Alderson and DuBose(33) does not elicit positive effects on the lipid profile in the present study sample older than 45 years of age.

It can be postulated that also an intensity threshold has to be met to expect significant effects on blood lipids. For most individuals, this threshold is associated with 5–6 METsReference Lakka and Salonen(15, Reference Marrugat, Elosua, Covas, Molina and Rubies-Prat17). Regarding this finding it can be argued that the criterion used to consider sports with an intensity of at least 3·5–4·0 METs (walking) as health-related sports participation in the older and middle-aged groups was rather low. However, former studies have shown that even walking has beneficial effects on the lipid profile and lowers the risk of coronary events, especially in older participantsReference Kelley, Kelley and Tran(37, Reference Ainslie, Reilly, Maclaren and Campbell43, Reference Manson, Hu, Rich-Edwards, Colditz, Stampfer, Willett, Speizer and Hennekens44).

It should be mentioned that also in the present study BMI and alcohol consumption were observed to be important determinants of the lipid profile. It has previously been reported that greater weekly intakes of alcohol were associated with significantly higher HDL-C in both men and womenReference Williams(45). Thus, alcohol is a potentially important confounder and studies which fail to take this factor into account may overestimate the contribution of physical activity to a healthy lipid profile. The same is true for BMI. A recent study showed that high BMI was more strongly related to adverse cardiovascular biomarker levels than physical inactivity. However, within BMI categories, physical activity was generally associated with more favourable cardiovascular biomarker levels than inactivityReference Mora, Lee, Buring and Ridker(46). It is clear that studies focusing on the effect of physical activity on the lipid profile should take these determinants into account.

It can be concluded that young men and women with higher levels of energy expenditure due to sports activities show a better lipid profile than their sedentary counterparts. When differentiating subjects according to EEALT or EETOTAL only for the men could a healthier lipid profile be observed in favour of the most active subjects. It seems that, in the present study, taking household and garden activities into account to differentiate groups obscures differences in lipid profiles in women and amplifies differences in lipid profiles in men. For men and women younger than 45 years of age the conclusion of Durstine et al.Reference Durstine, Grandjean, Davis, Ferguson, Alderson and DuBose(33), that training volumes eliciting energy expenditures ≥5·02 MJ/week (≥1200 kcal/week) contribute to a healthy lipid profile, can be confirmed.

In the middle-aged and older age groups differentiated according to energy expenditure (EESPORT, EEALT or EETOTAL), no differences could be observed in lipid profile except for HDL-C in middle-aged men grouped by EESPORT and TAG in older men grouped by EEALT.

Acknowledgements

The Policy Research Centre Sport, Physical Activity and Health was supported by the Flemish government.

T.S. was involved in development and design of the study and wrote the manuscript. L.V.L. performed the statistical analyses and interpretation and was a significant manuscript reviewer. R.P., W.D. and M.T. contributed to the concept and design of the study. N.D., L.M. and K.W. participated in the data acquisition. J.L. was involved in development and design of the study and provided statistical expertise. All authors assisted in revising the manuscript. None of the authors have any interests that might be interpreted as influencing the research.

References

1.Heiss, G, Johnson, NJ, Reiland, S, Davis, CE & Tyroler, HA (1980) The epidemiology of plasma high-density lipoprotein cholesterol levels. The Lipid Research Clinics Program Prevalence Study. Summary. Circulation 62, IV116IV136.Google ScholarPubMed
2.Schaefer, EJ (2002) Lipoproteins, nutrition, and heart disease. Am J Clin Nutr 75, 191212.CrossRefGoogle ScholarPubMed
3.Thom, T, Haase, N, Rosamond, W et al. (2006) Heart disease and stroke statistics – 2006 update: a report from the American Heart Association Statistics Committee and Stroke Statistics Subcommittee. Circulation 113, e85e151.Google ScholarPubMed
4.Hall, G, Collins, A, Csemiczky, G & Landgren, BM (2002) Lipoproteins and BMI: a comparison between women during transition to menopause and regularly menstruating healthy women. Maturitas 41, 177185.CrossRefGoogle ScholarPubMed
5.Martinez-Gonzalez, MA, Fernandez-Garcia, J, Sanchez-Izquierdo, F, Lardelli-Claret, P, Jimenez, MJ & Galvez-Vargas, R (1998) Lifestyle factors associated with changes in serum lipids in a follow-up study of cardiovascular risk factors. Eur J Epidemiol 14, 525533.CrossRefGoogle Scholar
6.Twisk, JW, Kemper, HC, Mellenbergh, GJ, van Mechelen, W & Post, GB (1996) Relation between the longitudinal development of lipoprotein levels and lifestyle parameters during adolescence and young adulthood. Ann Epidemiol 6, 246256.CrossRefGoogle Scholar
7.Young, DR, Haskell, WL, Jatulis, DE & Fortmann, SP (1993) Associations between changes in physical activity and risk factors for coronary heart disease in a community-based sample of men and women: the Stanford Five-City Project. Am J Epidemiol 138, 205216.CrossRefGoogle Scholar
8.Schubert, CM, Rogers, NL, Remsberg, KE, Sun, SS, Chumlea, WC, Demerath, EW, Czerwinski, SA, Towne, B & Siervogel, RM (2006) Lipids, lipoproteins, lifestyle, adiposity and fat-free mass during middle age: the Fels Longitudinal Study. Int J Obes (Lond) 30, 251260.CrossRefGoogle ScholarPubMed
9.Shakir, YA, Samsioe, G, Nyberg, P, Lidfeldt, J & Nerbrand, C (2006) Does the hormonal situation modify lipid effects by lifestyle factors in middle-aged women? Results from a population-based study of Swedish women: the women’s health in the Lund area study. Metabolism 55, 10601066.CrossRefGoogle ScholarPubMed
10.Arquer, A, Elosua, R, Covas, MI, Molina, L & Marrugat, J (2006) Amount and intensity of physical activity, fitness, and serum lipids in pre-menopausal women. Int J Sports Med 27, 911918.CrossRefGoogle ScholarPubMed
11.Ashton, WD, Nanchahal, K & Wood, DA (2000) Leisure-time physical activity and coronary risk factors in women. J Cardiovasc Risk 7, 259266.CrossRefGoogle ScholarPubMed
12.Durstine, JL, Grandjean, PW, Cox, CA & Thompson, PD (2002) Lipids, lipoproteins, and exercise. J Cardiopulm Rehabil 22, 385398.CrossRefGoogle ScholarPubMed
13.Hardman, AE (1999) Interaction of physical activity and diet: implications for lipoprotein metabolism. Public Health Nutr 2, 369376.CrossRefGoogle ScholarPubMed
14.Kraus, WE, Houmard, JA, Duscha, BD et al. (2002) Effects of the amount and intensity of exercise on plasma lipoproteins. N Engl J Med 347, 14831492.CrossRefGoogle ScholarPubMed
15.Lakka, TA & Salonen, JT (1992) Physical activity and serum lipids: a cross-sectional population study in eastern Finnish men. Am J Epidemiol 136, 806818.CrossRefGoogle ScholarPubMed
16.Ma, J, Liu, Z & Ling, W (2003) Physical activity, diet and cardiovascular disease risks in Chinese women. Public Health Nutr 6, 139146.CrossRefGoogle ScholarPubMed
17.Marrugat, J, Elosua, R, Covas, MI, Molina, L & Rubies-Prat, J (1996) Amount and intensity of physical activity, physical fitness, and serum lipids in men. The MARATHOM Investigators. Am J Epidemiol 143, 562569.CrossRefGoogle ScholarPubMed
18.Marti, B, Suter, E, Riesen, WF, Tschopp, A, Wanner, HU & Gutzwiller, F (1980) Effects of long-term, self-monitored exercise on the serum lipoprotein and apolipoprotein profile in middle-aged men. Atherosclerosis 81, 1931.CrossRefGoogle Scholar
19.Wei, M, Macera, CA, Hornung, CA & Blair, SN (1997) Changes in lipids associated with change in regular exercise in free-living men. J Clin Epidemiol 50, 11371142.CrossRefGoogle ScholarPubMed
20.Kelley, GA, Kelley, KS & Tran, ZV (2004) Aerobic exercise and lipids and lipoproteins in women: a meta-analysis of randomized controlled trials. J Womens Health 13, 11481164.CrossRefGoogle ScholarPubMed
21.Pescatello, LS, Murphy, D & Costanzo, D (2000) Low-intensity physical activity benefits blood lipids and lipoproteins in older adults living at home. Age Ageing 29, 433439.CrossRefGoogle ScholarPubMed
22.Bijnen, FC, Feskens, EJ, Caspersen, CJ, Giampaoli, S, Nissinen, AM, Menotti, A, Mosterd, WL & Kromhout, D (1996) Physical activity and cardiovascular risk factors among elderly men in Finland, Italy, and the Netherlands. Am J Epidemiol 143, 553561.CrossRefGoogle ScholarPubMed
23.Fung, TT, Hu, FB, Yu, J, Chu, NF, Spiegelman, D, Tofler, GH, Willett, WC & Rimm, EB (2000) Leisure-time physical activity, television watching, and plasma biomarkers of obesity and cardiovascular disease risk. Am J Epidemiol 152, 11711178.CrossRefGoogle ScholarPubMed
24.Kokkinos, PF & Fernhall, B (1999) Physical activity and high density lipoprotein cholesterol levels: what is the relationship? Sports Med 28, 307314.CrossRefGoogle ScholarPubMed
25.Leon, AS & Sanchez, OA (2001) Response of blood lipids to exercise training alone or combined with dietary intervention. Med Sci Sports Exerc 33, S502S515.CrossRefGoogle ScholarPubMed
26.Sunami, Y, Motoyama, M, Kinoshita, F, Mizooka, Y, Sueta, K, Matsunaga, A, Sasaki, J, Tanaka, H & Shindo, M (1999) Effects of low-intensity aerobic training on the high-density lipoprotein cholesterol concentration in healthy elderly subjects. Metabolism 48, 984988.CrossRefGoogle ScholarPubMed
27.Kodama, S, Tanaka, S, Saito, K et al. (2007) Effect of aerobic exercise training on serum levels of high-density lipoprotein cholesterol: a meta-analysis. Arch Intern Med 167, 9991008.CrossRefGoogle ScholarPubMed
28.Panagiotakos, DB, Pitsavos, C, Chrysohoou, C, Skoumas, J, Zeimbekis, A, Papaioannou, I & Stefanadis, C (2003) Effect of leisure time physical activity on blood lipid levels: the ATTICA study. Coron Artery Dis 14, 533539.CrossRefGoogle ScholarPubMed
29.Fransson, EI, Alfredsson, LS, de Faire, UH, Knutsson, A & Westerholm, PJ (2003) Leisure time, occupational and household physical activity, and risk factors for cardiovascular disease in working men and women: the WOLF study. Scand J Public Health 31, 324333.CrossRefGoogle ScholarPubMed
30.Barengo, NC, Kastarinen, M, Lakka, T, Nissinen, A & Tuomilehto, J (2006) Different forms of physical activity and cardiovascular risk factors among 24–64-year-old men and women in Finland. Eur J Cardiovasc Prev Rehabil 13, 5159.Google ScholarPubMed
31.Lippi, G, Schena, F, Salvagno, GL, Montagnana, M, Ballestrieri, F & Guidi, GC (2006) Comparison of the lipid profile and lipoprotein(a) between sedentary and highly trained subjects. Clin Chem Lab Med 44, 322326.CrossRefGoogle ScholarPubMed
32.Kobayashi, J, Murase, Y, Asano, A, Nohara, A, Kawashiri, MA, Inazu, A, Yamagishi, M & Mabuchi, H (2006) Effect of walking with a pedometer on serum lipid and adiponectin levels in Japanese middle-aged men. J Atheroscler Thromb 13, 197201.CrossRefGoogle ScholarPubMed
33.Durstine, JL, Grandjean, PW, Davis, PG, Ferguson, MA, Alderson, NL & DuBose, KD (2001) Blood lipid and lipoprotein adaptations to exercise: a quantitative analysis. Sports Med 31, 10331062.CrossRefGoogle ScholarPubMed
34.Danielson, ME, Cauley, JA & Rohay, JM (1993) Physical activity and its association with plasma lipids and lipoproteins in elderly women. Ann Epidemiol 3, 351357.CrossRefGoogle ScholarPubMed
35.Fonong, T, Toth, MJ, Ades, PA, Katzel, LI, Calles-Escandon, J & Poehlman, ET (1996) Relationship between physical activity and HDL-cholesterol in healthy older men and women: a cross-sectional and exercise intervention study. Atherosclerosis 127, 177183.CrossRefGoogle ScholarPubMed
36.Ring-Dimitriou, S, von Duvillard, SP, Paulweber, B, Stadlmann, M, Lemura, LM, Peak, K & Mueller, E (2007) Nine months aerobic fitness induced changes on blood lipids and lipoproteins in untrained subjects versus controls. Eur J Appl Physiol 99, 291299.CrossRefGoogle ScholarPubMed
37.Kelley, GA, Kelley, KS & Tran, ZV (2004) Walking, lipids, and lipoproteins: a meta-analysis of randomized controlled trials. Prev Med 38, 651661.CrossRefGoogle ScholarPubMed
38. Matton L, Wijndaele K, Duvigneaud N, Duquet W, Philippaerts RM, Thomis M & Lefevre J (2007) Reliability and validity of the Flemish Physical Activity Computerized Questionnaire (FPACQ) in adults. Res Q Exerc Sport (In the Press).CrossRefGoogle Scholar
39.Ainsworth, BE, Haskell, WL, Whitt, MC et al. (2000) Compendium of physical activities: an update of activity codes and MET intensities. Med Sci Sports Exerc 32, S498S516.CrossRefGoogle ScholarPubMed
40.Skoumas, J, Pitsavos, C, Panagiotakos, DB, Chrysohoou, C, Zeimbekis, A, Papaioannou, I, Toutouza, M, Toutouzas, P & Stefanadis, C (2003) Physical activity, high density lipoprotein cholesterol and other lipids levels, in men and women from the ATTICA study. Lipids Health Dis 2, 3.CrossRefGoogle ScholarPubMed
41.Weller, I & Corey, P (1998) The impact of excluding non-leisure energy expenditure on the relation between physical activity and mortality in women. Epidemiology 9, 632635.CrossRefGoogle ScholarPubMed
42.O’Connor, GT, Hennekens, CH, Willett, WC, Goldhaber, SZ, JrPaffenbarger, RS, Breslow, JL, Lee, IM & Buring, JE (1995) Physical exercise and reduced risk of nonfatal myocardial infarction. Am J Epidemiol 142, 11471156.CrossRefGoogle ScholarPubMed
43.Ainslie, PN, Reilly, T, Maclaren, DP & Campbell, IT (2005) Changes in plasma lipids and lipoproteins following 10-days of prolonged walking: influence of age and relationship to physical activity level. Ergonomics 48, 13521364.CrossRefGoogle ScholarPubMed
44.Manson, JE, Hu, FB, Rich-Edwards, JW, Colditz, GA, Stampfer, MJ, Willett, WC, Speizer, FE & Hennekens, CH (1999) A prospective study of walking as compared with vigorous exercise in the prevention of coronary heart disease in women. N Engl J Med 341, 650658.CrossRefGoogle Scholar
45.Williams, PT (2004) The relationships of vigorous exercise, alcohol, and adiposity to low and high high-density lipoprotein-cholesterol levels. Metabolism 53, 700709.CrossRefGoogle ScholarPubMed
46.Mora, S, Lee, IM, Buring, JE & Ridker, PM (2006) Association of physical activity and body mass index with novel and traditional cardiovascular biomarkers in women. JAMA 295, 14121419.CrossRefGoogle ScholarPubMed
Figure 0

Table 1 Descriptive statistics (mean, sd, 25th percentile (P25) and 75th percentile (P75)) of the anthropometric characteristics, physical activity variables and serum lipid and lipoprotein values among men

Figure 1

Table 2 Descriptive statistics (mean, sd, 25th percentile (P25) and 75th percentile (P75)) of the anthropometric characteristics, physical activity variables and serum lipid and lipoprotein values among women

Figure 2

Table 3 Comparison of serum lipid and lipoprotein values between men being part of the lowest and highest quartile of energy spent during health-related sports participation, energy spent during active leisure time and total energy spent during a week: analyses of covariance with BMI and alcohol consumption as covariates

Figure 3

Table 4 Comparison of serum lipid and lipoprotein values between women being part of the lowest and highest quartile of energy spent during health-related sports participation, energy spent during active leisure time and total energy spent during a week: analyses of covariance with BMI and alcohol consumption as covariates