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Validation of three predictive equations for basal metabolic rate in adults

Published online by Cambridge University Press:  02 January 2007

Manuel Ramirez-Zea*
Affiliation:
Institute of Nutrition of Central America and Panama (INCAP), PO Box 1188, Calzada Roosevelt, Zona 11, Guatemala City, Guatemala
*
*Corresponding author: Email mramirez@incap.ops-oms.org
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Abstract

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Objective

To cross-validate three predictive set of equations for basal metabolic rate (BMR) developed by Schofield (Schofield database), Henry (Oxford database) and Cole (Oxford database) using mean values for age, weight, height and BMR of published studies.

Design

Literature review of studies published from 1985 to March 2002.

Setting

All studies selected used appropriate methods and followed conditions that met the criteria established for basal metabolism, were performed in healthy adults, and were not part of the Schofield or Oxford database.

Subjects

A total of 261 groups of men and women from 175 studies were selected and categorised in three age groups (18.5–29.9, 30.0–59.9, ≥60 years old) and three body mass index (BMI) groups (normal weight, overweight and obese).

Results

Linear regression and concordance correlation analysis showed that the three sets of equations had the same association and agreement with measured BMR, across gender, age, and BMI groups. The agreement of all equations was moderate for men and poor for women. The lowest mean squared prediction errors (MSPRs) were given by Henry equations in men and Cole equations in women. Henry and Cole equations gave lower values than Schofield equations, except for men over 60 years of age. Henry equations were the most accurate in men. None of the three equations performed consistently better in women.

Conclusion

These results support the use of Henry equations in men with a wide range of age and BMI. None of the proposed predictive equations seem to be appropriate to estimate BMR in women.

Type
Research Article
Copyright
Copyright © The Author 2005

References

1Durnin, JV. Basal Metabolic Rate in Man. Working paper submitted to the Joint FAO/WHO/UNU Expert Consultation on Energy and Protein Requirements. Rome: FAO, 1981.Google Scholar
2FAO/WHO/UNU. Energy and Protein Requirements. Report of a Joint FAO/WHO/UNU Expert Consultation. Technical Report Series No.724. Geneva: World Health Organization, 1985.Google Scholar
3Schofield, C. An annotated bibliography of source material for basal metabolic rate data. Human Nutrition: Clinical Nutrition 1985; 39(Suppl. 1): 4291.Google ScholarPubMed
4Henry, CJ, Rees, DG. New predictive equations for the estimation of basal metabolic rate in tropical peoples. European Journal of Clinical Nutrition 1991; 45: 177–85.Google Scholar
5Soares, MJ, Shetty, PS. Validity of Schofield's predictive equations for basal metabolic rates of Indians. The Indian Journal of Medical Research 1988; 88: 253–60.Google ScholarPubMed
6de Boer, JO, van Es, AJ, Voorrips, LE, Blokstra, F, Vogt, JE. Energy metabolism and requirements in different ethnic groups. European Journal of Clinical Nutrition 1988; 42: 983–97.Google ScholarPubMed
7Valencia, ME, Moya, SY, McNeill, G, Haggarty, P. Basal metabolic rate and body fatness of adult men in northern Mexico. European Journal of Clinical Nutrition 1994; 48: 205–11.Google ScholarPubMed
8Cruz, CM, da Silva, AF, dos Anjos, LA. Basal metabolic rate is overestimated by predictive equation in college-age women of Rio de Janeiro, Brazil. Archivos Latinoamericanos de Nutricion 1999; 49: 232–7.Google ScholarPubMed
9Henry, CJK. Basal Metabolic Rate Studies in Humans: Measurement and Development of New Equations. Background document prepared for the Joint FAO/WHO/UNU Expert Consultation on Energy in human nutrition. Rome: FAO, 2001.Google Scholar
10Cole, TJ, Henry, CJK. The Oxford Brookes Basal Metabolic Rate Database – A Reanalysis. Report commissioned by FAO for the Joint FAO/WHO/UNU Expert Consultation on Energy in human nutrition. Rome: FAO, 2002.Google Scholar
11Tukey, J. Explanatory Data Analysis. California: Addison-Wesley, 1977.Google Scholar
12Lin, LK. A concordance correlation coefficient to evaluate reproducibility. Biometrics 1989; 45: 255–68.CrossRefGoogle ScholarPubMed
13Neter, J, Waserman, W, Kutner, MH. Applied Linear Statistical Models: Regression, Analysis of Variance, and Experimental Designs, 3rd ed. Illinois: Richard D Irwin Inc., 1990.Google Scholar
1Aleman-Mateo, H, Reza-Duran, GT, Esparza, J, Valencia, ME. Energy requirements in active elderly individuals living in a rural region of Northwest Mexico. Archivos Latinoamericanos de Nutricion 1999; 49: 121–9.Google Scholar
2Anjos, LA, Ferreira, JA. The evaluation of the physiological workload in the Brazilian legislation should be revised! The case of garbage collectors in Rio de Janeiro. Cadernos de Saude Publica: Ministerio da Saude, Fundacao Oswaldo Cruz, Escola Nacional de Saude Publica. 2000; 16: 785–90.CrossRefGoogle ScholarPubMed
3Arciero, PJ, Goran, MI, Gardner, AM, Ades, PA, Tyzbir, RS, Poehlman, ET. A practical equation to predict resting metabolic rate in older females. Journal of the American Geriatrics Society 1993; 41: 389–95.CrossRefGoogle ScholarPubMed
4Arciero, PJ, Goran, MI, Gardner, AW, Ades, PA, Tyzbir, RS, Poehlman, ET. A practical equation to predict resting metabolic rate in older men. Metabolism: Clinical and Experimental 1993; 42: 950–7.CrossRefGoogle ScholarPubMed
5Arciero, PJ, Hannibal, NS 3rd, Nindl, BC, Gentile, CL, Hamed, J, Vukovich, MD. Comparison of creatine ingestion and resistance training on energy expenditure and limb blood flow. Metabolism Clinical and Experimental 2001; 50: 1429–34.CrossRefGoogle ScholarPubMed
6Astrup, A, Buemann, B, Toubro, S, Ranneries, C, Raben, A. Low resting metabolic rate in subjects predisposed to obesity: a role for thyroid status. American Journal of Clinical Nutrition 1996; 63: 879–83.Google Scholar
7Ategbo, EA, van Raaij, JM, de Koning, FL, Hautvast, JG. Resting metabolic rate and work efficiency of rural Beninese women: a 2-y longitudinal study. American Journal of Clinical Nutrition 1995; 61: 466–72.CrossRefGoogle ScholarPubMed
8Ballor, DL, Poehlman, ET. Resting metabolic rate and coronary-heart-disease risk factors in aerobically and resistance-trained women. American Journal of Clinical Nutrition 1992; 56: 968–74.Google Scholar
9Bathalon, GP, Hays, NP, McCrory, MA, Vinken, AG, Tucker, KL, Greenberg, AS, Castaneda, C, Roberts, SB. The energy expenditure of postmenopausal women classified as restrained or unrestrained eaters. European Journal of Clinical Nutrition 2001; 55: 1059–67.CrossRefGoogle ScholarPubMed
10Beer, WH, Murray, E, Oh, SH, Pedersen, HE, Wolfe, RR, Young, VR. A long-term metabolic study to assess the nutritional value of and immunological tolerance to two soy-protein concentrates in adult humans. American Journal of Clinical Nutrition 1989; 50: 9971007.CrossRefGoogle ScholarPubMed
11Bender, PR, Martin, BJ. Ventilatory and treadmill endurance during acute semistarvation. Journal of Applied Physiology 1986; 60: 1823–7.CrossRefGoogle ScholarPubMed
12Benedek, C, Berclaz, PY, Jequier, E, Schutz, Y. Resting metabolic rate and protein turnover in apparently healthy elderly Gambian men. American Journal of Physiology 1995; 268: E10838.Google ScholarPubMed
13Black, AE, Bingham, SA, Johansson, G, Coward, WA. Validation of dietary intakes of protein and energy against 24 hour urinary N and DLW energy expenditure in middle-aged women, retired men and post-obese subjects: comparisons with validation against presumed energy requirements. European Journal of Clinical Nutrition 1997; 51: 405–13.CrossRefGoogle ScholarPubMed
14Boivin, M, Camirand, A, Carli, F, Hoffer, LJ, Silva, JE. Uncoupling protein-2 and-3 messenger ribonucleic acids in adipose tissue and skeletal muscle of healthy males: variability, factors affecting expression, and relation to measures of metabolic rate. Journal of Clinical Endocrinology and Metabolism 2000; 85: 1975–83.Google ScholarPubMed
15Bonnefoy, M, Normand, S, Pachiaudi, C, Lacour, JR, Laville, M, Kostka, T. Simultaneous validation of ten physical activity questionnaires in older men: a doubly labelled water study. Journal of the American Geriatrics Society 2001; 49: 2835.Google Scholar
16Broeder, CE, Burrhus, KA, Svanevik, LS, Wilmore, JH. The effects of aerobic fitness on resting metabolic rate. American Journal of Clinical Nutrition 1992; 55: 795801.Google Scholar
17Bronstein, MN, Mak, RP, King, JC. Unexpected relationship between fat mass and basal metabolic rate in pregnant women. British Journal of Nutrition 1996; 75: 659–68.Google Scholar
18Buchholz, AC, Rafii, M, Pencharz, PB. Is resting metabolic rate different between men and women? British Journal of Nutrition 2001; 86: 641–6.CrossRefGoogle ScholarPubMed
19Buchowski, MS, Simmons, LA, Chen, KY, Flakoll, PJ, Mellen, BG, Turner, EA. Plasma leptin association with body composition and energy expenditure in sickle cell disease. Journal of the American College of Nutrition 2000; 19: 228–36.CrossRefGoogle ScholarPubMed
20Butte, NF, Barbosa, L, Villalpando, S, Wong, WW, Smith, EO. Total energy expenditure and physical activity level of lactating Mesoamerindians. Journal of Nutrition 1997; 127: 299305.Google ScholarPubMed
21Butte, NF, Hopkinson, JM, Mehta, N, Moon, JK, Smith, EO. Adjustments in energy expenditure and substrate utilization during late pregnancy and lactation. American Journal of Clinical Nutrition 1999; 69: 299307.CrossRefGoogle ScholarPubMed
22Butte, NF, Wong, WW, Hopkinson, JM. Energy requirements of lactating women derived from doubly labelled water and milk energy output. Journal of Nutrition 2001; 131: 53–8.Google Scholar
23Capristo, E, Addolorato, G, Mingrone, G, De Gaetano, A, Greco, AV, Tataranni, PA, Gasbarrini, G. Changes in body composition, substrate oxidation, and resting metabolic rate in adult celiac disease patients after a 1-y gluten-free diet treatment. American Journal of Clinical Nutrition 2000; 72: 7681.CrossRefGoogle ScholarPubMed
24Carpenter, WH, Fonong, T, Toth, MJ, Ades, PA, Calles-Escandon, J, Walston, JD, Poehlman, ET. Total daily energy expenditure in free-living older African-Americans and Caucasians. American Journal of Physiology 1998; 274: E96101.Google Scholar
25Censi, L, Toti, E, Pastore, G, Ferro-Luzzi, A. The basal metabolic rate and energy cost of standardised walking of short and tall men. European Journal of Clinical Nutrition 1998; 52: 441–6.Google Scholar
26Chen, WJ, Chung, YC. Energy expenditure in patients with hepatocellular carcinoma. Cancer 1994; 73: 590–5.Google Scholar
27Chiplonkar, SA, Agte, VV, Gokhale, MK, Kulkarni, VV, Mane, ST. Energy intake and resting metabolic rate of young Indian men and women. Indian Journal of Medical Research 1992; 96: 250–4.Google Scholar
28Christin, L, O'Connell, M, Bogardus, C, Danforth, E Jr, Ravussin, E. Norepinephrine turnover and energy expenditure in Pima Indian and white men. Metabolism Clinical and Experimental 1993; 42: 723–9.Google Scholar
29Clark, D, Tomas, F, Withers, RT, et al. No major differences in energy metabolism between matched and unmatched groups of ‘large-eating’ and ‘small-eating’ men. British Journal of Nutrition 1993; 70: 393406.CrossRefGoogle ScholarPubMed
30Clark, HD, Hoffer, LJ. Reappraisal of the resting metabolic rate of normal young men. American Journal of Clinical Nutrition 1991; 53: 21–6.Google Scholar
31Cooling, J, Blundell, J. Differences in energy expenditure and substrate oxidation between habitual high fat and low fat consumers (phenotypes). International Journal of Obesity and Related Metabolic Disorders: Journal of the International Association for the Study of Obesity 1998; 22: 612–8.CrossRefGoogle ScholarPubMed
32Cordain, L, Bryan, ED, Melby, CL, Smith, MJ. Influence of moderate daily wine consumption on body weight regulation and metabolism in healthy free-living males. Journal of the American College of Nutrition 1997; 16: 134–9.Google Scholar
33Cruz, CM, da Silva, AF, dos Anjos, LA. Basal metabolic rate is overestimated by predictive equation in college-age women of Rio de Janeiro, Brazil. Archivos Latinoamericanos de Nutricion 1999; 49: 232–7.Google ScholarPubMed
34Cullinen, K, Caldwell, M. Weight training increases fat-free mass and strength in untrained young women. Journal of the American Dietetic Association 1998; 98: 414–8.Google Scholar
35De Lorenzo, A, Tagliabue, A, Andreoli, A, Testolin, G, Comelli, M, Deurenberg, P. Measured and predicted resting metabolic rate in Italian males and females, aged 18–59 y. European Journal of Clinical Nutrition 2001; 55: 208–14.Google Scholar
36Della Bianca, P, Jequier, E, Schutz, Y. Lack of metabolic and behavioral adaptations in rural Gambian men with low body mass index. American Journal of Clinical Nutrition 1994; 60: 3742.Google Scholar
37Deriaz, O, Fournier, G, Tremblay, A, Despres, JP, Bouchard, C. Lean-body-mass composition and resting energy expenditure before and after long-term overfeeding. American Journal of Clinical Nutrition 1992; 56: 840–7.CrossRefGoogle ScholarPubMed
38Detzer, MJ, Leitenberg, H, Poehlman, ET, Rosen, JC, Silberg, NT, Vara, LS. Resting metabolic rate in women with bulimia nervosa: a cross-sectional and treatment study. American Journal of Clinical Nutrition 1994; 60: 327–32.CrossRefGoogle ScholarPubMed
39Diaz, E, Goldberg, GR, Taylor, M, Savage, JM, Sellen, D, Coward, WA. Effects of dietary supplementation on work performance in Gambian laborers. American Journal of Clinical Nutrition 1991; 53: 803–11.CrossRefGoogle ScholarPubMed
40Dionne, IJ, Turner, AN, Tchernof, A, Pollin, TI, Avrithi, D, Gray, D, Shuldiner, AR, Poehlman, ET. Identification of an interactive effect of beta3-and alpha2b-adrenoceptor gene polymorphisms on fat mass in Caucasian women. Diabetes 2001;50: 91–5.CrossRefGoogle Scholar
41Doi, T, Matsuo, T, Sugawara, M, Matsumoto, K, Minehira, K, Hamada, K, Okamura, K, Suzuki, M. New approach for weight reduction by a combination of diet, light resistance exercise and the timing of ingesting a protein supplement. Asia Pacific Journal of Clinical Nutrition 2001; 10: 226–32.CrossRefGoogle ScholarPubMed
42Dolezal, BA, Potteiger, JA. Concurrent resistance and endurance training influence basal metabolic rate in nondieting individuals. Journal of Applied Physiology 1998; 85: 695700.Google Scholar
43Dufour, DL, Reina, JC, Spurr, G. Energy intake and expenditure of free-living, pregnant Colombian women in an urban setting. American Journal of Clinical Nutrition 1999; 70: 269–76.CrossRefGoogle Scholar
44Eck, LH, Bennett, AG, Egan, BM, Ray, JW, Mitchell, CO, Smith, MA, Klesges, RC. Differences in macronutrient selections in users and nonusers of an oral contraceptive. American Journal of Clinical Nutrition 1997; 65: 419–24.CrossRefGoogle ScholarPubMed
45Ferro-Luzzi, A, Petracchi, C, Kuriyan, R, Kurpad, AV. Basal metabolism of weight-stable chronically undernourished men and women: lack of metabolic adaptation and ethnic differences. American Journal of Clinical Nutrition 1997; 66: 1086–93.Google Scholar
46Fontaine, E, Savard, R, Tremblay, A, Despres, JP, Poehlman, E, Bouchard, C. Resting metabolic rate in monozygotic and dizygotic twins. Acta Geneticae Medicae et Gemellologiae 1985; 34: 41–7.Google Scholar
47Fontvieille, AM, Ferraro, RT, Rising, R, Larson, DE, Ravussin, E. Energy cost of arousal: effect of sex, race and obesity. International Journal of Obesity and Related Metabolic Disorders: Journal of the International Association for the Study of Obesity 1993; 17: 705–9.Google Scholar
48Forsum, E, Sadurskis, A, Wager, J. Resting metabolic rate and body composition of healthy Swedish women during pregnancy. American Journal of Clinical Nutrition 1988; 47: 942–7.CrossRefGoogle ScholarPubMed
49Fox, CS, Esparza, J, Nicolson, M, Bennett, PH, Schulz, LO, Valencia, ME, Ravussin, E. Is a low leptin concentration, a low resting metabolic rate, or both the expression of the “thrifty genotype”? Results from Mexican Pima Indians. American Journal of Clinical Nutrition 1998; 68: 1053–7.CrossRefGoogle ScholarPubMed
50Frigerio, C, Schutz, Y, Whitehead, R, Jequier, E. A new procedure to assess the energy requirements of lactation in Gambian women. American Journal of Clinical Nutrition 1991; 54: 526–33.CrossRefGoogle ScholarPubMed
51Frigerio, C, Schutz, Y, Whitehead, R, Jequier, E. Postprandial thermogenesis in lactating and non-lactating women from The Gambia. European Journal of Clinical Nutrition 1992; 46: 713.Google Scholar
52Fukagawa, NK, Bandini, LG, Young, JB. Effect of age on body composition and resting metabolic rate. The American Journal of Physiology 1990; 259: E2338.Google ScholarPubMed
53Fuller, NJ, Sawyer, MB, Coward, WA, Paxton, P, Elia, M. Components of total energy expenditure in free-living elderly men (over 75 years of age): measurement, predictability and relationship to quality-of-life indices. British Journal of Nutrition 1996; 75: 161–73.Google Scholar
54Garrow, JS, Webster, JD. Effects on weight and metabolic rate of obese women of a 3.4 MJ (800 kcal) diet. Lancet 1989; 1: 1429–31.Google Scholar
55Gilliat-Wimberly, M, Manore, MM, Woolf, K, Swan, PD, Carroll, SS. Effects of habitual physical activity on the resting metabolic rates and body compositions of women aged 35 to 50 years. Journal of the American Dietetic Association 2001; 101: 1181–8.Google Scholar
56Goldberg, GR, Prentice, AM, Coward, WA, Davies, HL, Murgatroyd, PR, Sawyer, MB, Ashford, J, Black, AE. Longitudinal assessment of the components of energy balance in well-nourished lactating women. American Journal of Clinical Nutrition 1991; 54: 788–98.CrossRefGoogle ScholarPubMed
57Goldberg, GR, Prentice, AM, Coward, WA, Davies, HL, Murgatroyd, PR, Wensing, C, Black, AE, Harding, M, Sawyer, M. Longitudinal assessment of energy expenditure in pregnancy by the doubly labelled water method. American Journal of Clinical Nutrition 1993; 57: 494505.Google Scholar
58Goldberg, GR, Prentice, AM, Murgatroyd, PR, Haines, W, Tuersley, MD. Effects on metabolic rate and fuel selection of a selective beta-3 agonist (ICI D7114) in healthy lean men. International Journal of Obesity and Related Metabolic Disorders: Journal of the International Association for the Study of Obesity 1995; 19: 625–31.Google ScholarPubMed
59Goldstone, AP, Brynes, AE, Thomas, EL, Bell, JD, Frost, G, Holland, A, Ghatei, MA, Bloom, SR. Resting metabolic rate, plasma leptin concentrations, leptin receptor expression, and adipose tissue measured by whole-body magnetic resonance imaging in women with Prader-Willi syndrome. American Journal of Clinical Nutrition 2002; 75: 468–75.Google Scholar
60Goran, MI, Beer, WH, Wolfe, RR, Poehlman, ET, Young, VR. Variation in total energy expenditure in young healthy free-living men. Metabolism Clinical and Experimental 1993; 42: 487–96.Google Scholar
61Goran, MI, Calles-Escandon, J, Poehlman, ET, O'Connell, M, Danforth, E Jr. Effects of increased energy intake and/or physical activity on energy expenditure in young healthy men. Journal of Applied Physiology 1994; 77: 366–72.Google Scholar
62Goris, AH, Westerterp, KR. Underreporting of habitual food intake is explained by under eating in highly motivated lean women. Journal of Nutrition 1999; 129: 878–82.Google Scholar
63Gower, BA, Nagy, TR, Goran, MI, Smith, A, Kent, E. Leptin in postmenopausal women: influence of hormone therapy, insulin, and fat distribution. Journal of Clinical Endocrinology and Metabolism 2000; 85: 1770–5.Google ScholarPubMed
64Grinspoon, S, Corcoran, C, Miller, K, Wang, E, Hubbard, J, Schoenfeld, D, Anderson, E, Basgoz, N, Klibanski, A. Determinants of increased energy expenditure in HIV-infected women. American Journal of Clinical Nutrition 1998; 68: 720–5.Google Scholar
65Guillermo-Tuazon, MA, Barba, CV, van Raaij, JM, Hautvast, JG. Energy intake, energy expenditure, and body composition of poor rural Philippine women throughout the first 6 mo of lactation. American Journal of Clinical Nutrition 1992; 56: 874–80.Google Scholar
66Hill, JO, Peters, JC, Yang, D, Sharp, T, Kaler, M, Abumrad, NN, Greene, HL. Thermogenesis in humans during overfeeding with medium-chain triglycerides. Metabolism Clinical and Experimental 1989; 38: 641–8.Google Scholar
67Horner, NK, Lampe, JW, Patterson, RE, Neuhouser, ML, Beresford, SA, Prentice, RL. Indirect calorimetry protocol development for measuring resting metabolic rate as a component of total energy expenditure in free-living postmenopausal women. Journal of Nutrition 2001; 131: 2215–8.Google Scholar
68Hunter, GR, Weinsier, RL, Gower, BA, Wetzstein, C. Age-related decrease in resting energy expenditure in sedentary white women: effects of regional differences in lean and fat mass. American Journal of Clinical Nutrition 2001; 73: 333–7.Google Scholar
69Illner, K, Brinkmann, G, Heller, M, Bosy-Westphal, A, Muller, MJ. Metabolically active components of fat free mass and resting energy expenditure in nonobese adults. American Journal of Physiology. Endocrinology and Metabolism 2000; 278: E30815.Google Scholar
70Jobin, N, de Jonge, L, Garrel, DR. Effects of RU 486 on energy expenditure and meal tolerance in normal men. Journal of the American College of Nutrition 1996; 15: 283–8.Google Scholar
71Jorgensen, JO, Vahl, N, Dall, R, Christiansen, JS. Resting metabolic rate in healthy adults: relation to growth hormone status and leptin levels. Metabolism Clinical and Experimental 1998; 47: 1134–9.Google Scholar
72Kanade, AN, Gokhale, MK, Rao, S. Energy costs of standard activities among Indian adults. European Journal of Clinical Nutrition 2001; 55: 708–13.Google Scholar
73Karlsson, C, Stenlof, K, Johannsson, G, Marin, P, Bjorntorp, P, Bengtsson, BA, Carlsson, B, Carlsson, LM, Sjostrom, L. Effects of growth hormone treatment on the leptin system and on energy expenditure in abdominally obese men. European Journal of Endocrinology: European Federation of Endocrine Societies 1998; 138: 408–14.Google Scholar
74Kashiwazaki, H, Dejima, Y, Suzuki, T. Influence of upper and lower thermoneutral room temperatures (20 degrees C and 25 degrees C) on fasting and post-prandial resting metabolism under different outdoor temperatures. European Journal of Clinical Nutrition 1990; 44: 405–13.Google Scholar
75Katzmarzyk, PT, Perusse, L, Tremblay, A, Bouchard, C. No association between resting metabolic rate or respiratory exchange ratio and subsequent changes in body mass and fatness: 5–1/2 year follow-up of the Quebec family study. European Journal of Clinical Nutrition 2000; 54: 610–4.Google Scholar
76Katzmarzyk, PT, Rankinen, T, Perusse, L, Deriaz, O, Tremblay, A, Borecki, I, Rao, DC, Bouchard, C. Linkage and association of the sodium potassium-adenosine triphosphatase alpha2 and beta1 genes with respiratory quotient and resting metabolic rate in the Quebec Family Study. Journal of Clinical Endocrinology and Metabolism 1999; 84: 2093–7.Google Scholar
77Kerckhoffs, DA, Blaak, EE, Van Baak, MA, Saris, WH. Effect of aging on beta-adrenergically mediated thermogenesis in men. American Journal of Physiology 1998; 274: E10759.Google Scholar
78Kinabo, JL, Durnin, JV. Thermic effect of food in man: effect of meal composition, and energy content. British Journal of Nutrition 1990; 64: 3744.Google Scholar
79Klausen, B, Toubro, S, Astrup, A. Age and sex effects on energy expenditure. American Journal of Clinical Nutrition 1997; 65: 895907.Google Scholar
80Kriketos, AD, Sharp, TA, Seagle, HM, Peters, JC, Hill, JO. Effects of aerobic fitness on fat oxidation and body fatness. Medicine and Science in Sports and Exercise 2000; 32: 805–11.Google Scholar
81Lawrence, M, Thongprasert, K, Durnin, JV. Between-group differences in basal metabolic rates: an analysis of data collected in Scotland, the Gambia and Thailand. European Journal of Clinical Nutrition 1988; 42: 877–91.Google Scholar
82Lemmer, JT, Ivey, FM, Ryan, AS, Martel, GF, Hurlbut, DE, Metter, JE, Fozard, JL, Fleg, JL, Hurley, BF. Effect of strength training on resting metabolic rate and physical activity: age and gender comparisons. Medicine and Science in Sports and Exercise 2001; 33: 532–41.Google Scholar
83Li, ET, Tsang, LB, Lui, SS. Resting metabolic rate and thermic effects of a sucrose-sweetened soft drink during the menstrual cycle in young Chinese women. Canadian Journal of Physiology and Pharmacology 1999; 77: 544–50.Google Scholar
84Liuzzi, A, Savia, G, Tagliaferri, M, et al. Serum leptin concentration in moderate and severe obesity: relationship with clinical, anthropometric and metabolic factors. International Journal of Obesity and Related Metabolic Disorders: Journal of the International Association for the Study of Obesity 1999; 23: 1066–73.CrossRefGoogle ScholarPubMed
85Livingstone, MB, Strain, JJ, Prentice, AM, Coward, WA, Nevin, GB, Barker, ME, Hickey, R, McKenna, PG, Whitehead, RG. Potential contribution of leisure activity to the energy expenditure patterns of sedentary populations. British Journal of Nutrition 1991; 65: 145–55.Google Scholar
86Lovelady, CA, Nommsen-Rivers, LA, McCrory, MA, Dewey, KG. Effects of exercise on plasma lipids and metabolism of lactating women. Medicine and Science in Sports and Exercise 1995; 27: 22–8.Google Scholar
87Luhrmann, PM, Herbert, BM, Gaster, C, Neuhauser-Berthold, M. Validation of a self-administered 3-day estimated dietary record for use in the elderly. European Journal of Nutrition 1999; 38: 235–40.Google Scholar
88Luke, A, Rotimi, CN, Adeyemo, AA, Durazo-Arvizu, RA, Prewitt, TE, Moragne-Kayser, L, Harders, R, Cooper, RS. Comparability of resting energy expenditure in Nigerians and US blacks. Obesity Research 2000; 8: 351–9.CrossRefGoogle Scholar
89Lundholm, K, Holm, G, Lindmark, L, Larsson, B, Sjostrom, L, Bjorntorp, P. Thermogenic effect of food in physically well-trained elderly men. European Journal of Applied Physiology and Occupational Physiology 1986; 55: 486–92.Google Scholar
90Manore, MM, Berry, TE, Skinner, JS, Carroll, SS. Energy expenditure at rest and during exercise in nonobese female cyclical dieters and in nondieting control subjects. American Journal of Clinical Nutrition 1991; 54: 41–6.Google Scholar
91Marra, M, Scalfi, L, Covino, A, Esposito-Del Puente, A, Contaldo, F. Fasting respiratory quotient as a predictor of weight changes in non-obese women. International Journal of Obesity and Related Metabolic Disorders: Journal of the International Association for the Study of Obesity 1998; 22: 601–3.Google Scholar
92Mawson, JT, Braun, B, Rock, PB, Moore, LG, Mazzeo, R, Butterfield, GE. Women at altitude: energy requirement at 4,300m. Journal of Applied Physiology 2000; 88: 272–81.Google Scholar
93McCrory, MA, Kim, HR, Wright, NC, Lovelady, CA, Aitkens, S, Kilmer, DD. Energy expenditure, physical activity, and body composition of ambulatory adults with hereditary neuromuscular disease. American Journal of Clinical Nutrition 1998; 67: 1162–9.CrossRefGoogle ScholarPubMed
94McNeill, G, Rivers, JP, Payne, PR, de Britto, JJ, Abel, R. Basal metabolic rate of Indian men: no evidence of metabolic adaptation to a low plane of nutrition. Human Nutrition: Clinical Nutrition 1987; 41: 473–83.Google Scholar
95Minghelli, G, Schutz, Y, Charbonnier, A, Whitehead, R, Jequier, E. Twenty-four-hour energy expenditure and basal metabolic rate measured in a whole-body indirect calorimeter in Gambian men. American Journal of Clinical Nutrition 1990; 51: 563–70.Google Scholar
96Moffatt, RJ, Owens, SG. Cessation from cigarette smoking: changes in body weight, body composition, resting metabolism, and energy consumption. Metabolism Clinical and Experimental 1991; 40: 465–70.Google Scholar
97Morales, AJ, Haubrich, RH, Hwang, JY, Asakura, H, Yen, SS. The effect of six months treatment with a 100 mg daily dose of dehydroepiandrosterone (DHEA) on circulating sex steroids, body composition and muscle strength in age-advanced men and women. Clinical Endocrinology 1998; 49: 421–32.CrossRefGoogle ScholarPubMed
98Murray, LA, Reilly, JJ, Choudhry, M, Durnin, JV. A longitudinal study of changes in body composition and basal metabolism in physically active elderly men. European Journal of Applied Physiology and Occupational Physiology 1996; 72: 215–18.Google Scholar
99Myerson, M, Gutin, B, Warren, MP, May, MT, Contento, I, Lee, M, Pi-Sunyer, FX, Pierson, RN Jr, Brooks-Gunn, J. Resting metabolic rate and energy balance in amenorrheic and eumenorrheic runners. Medicine and Science in Sports and Exercise 1991; 23: 1522.Google Scholar
100Nicklas, BJ, van Rossum, EF, Berman, DM, Ryan, AS, Dennis, KE, Shuldiner, AR. Genetic variation in the peroxisome proliferator-activated receptor-gamma2 gene (Pro12Ala) affects metabolic responses to weight loss and subsequent weight regain. Diabetes 2001; 50: 2172–6.CrossRefGoogle ScholarPubMed
101Nielsen, S, Hensrud, DD, Romanski, S, Levine, JA, Burguera, B, Jensen, MD. Body composition and resting energy expenditure in humans: role of fat, fat-free mass and extracellular fluid. International Journal of Obesity and Related Metabolic Disorders: Journal of the International Association for the Study of Obesity 2000; 24: 1153–7.Google Scholar
102Nixon, DW, Kutner, M, Heymsfield, S, et al. Resting energy expenditure in lung and colon cancer. Metabolism Clinical and Experimental 1988; 37: 1059–64.Google Scholar
103Owen, OE, Holup, JL, D'Alessio, DA, Craig, ES, Polansky, M, Smalley, KJ, Kavle, EC, Bushman, MC, Owen, LR, Mozzoli, MA. A reappraisal of the caloric requirements of men. American Journal of Clinical Nutrition 1987; 46: 875–85.CrossRefGoogle ScholarPubMed
104Owen, OE, Kavle, E, Owen, RS, Polansky, M, Caprio, S, Mozzoli, MA, Kendrick, ZV, Bushman, MC, Boden, G. A reappraisal of caloric requirements in healthy women. American Journal of Clinical Nutrition 1986; 44: 119.Google Scholar
105Ozeki, O, Ebisawa, L, Ichikawa, M, Nagasawa, N, Sato, F, Fujita, Y. Physical activities and energy expenditures of institutionalized Japanese elderly women. Journal of Nutritional Science and Vitaminology 2000; 46: 188–92.Google Scholar
106Pelkman, CL, Chow, M, Heinbach, RA, Rolls, BJ. Short-term effects of a progestational contraceptive drug on food intake, resting energy expenditure, and body weight in young women. American Journal of Clinical Nutrition 2001; 73: 1926.Google Scholar
107Piers, LS, Diffey, B, Soares, MJ, Frandsen, SL, McCormack, LM, Lutschini, MJ, O'Dea, K. The validity of predicting the basal metabolic rate of young Australian men and women. European Journal of Clinical Nutrition 1997; 51: 333–7.Google Scholar
108Piers, LS, Diggavi, SN, Rijskamp, J, van Raaij, JM, Shetty, PS, Hautvast, JG. Resting metabolic rate and thermic effect of a meal in the follicular and luteal phases of the menstrual cycle in well-nourished Indian women. American Journal of Clinical Nutrition 1995; 61: 296302.Google Scholar
109Piers, LS, Diggavi, SN, Thangam, S, van Raaij, JM, Shetty, PS, Hautvast, JG. Changes in energy expenditure, anthropometry, and energy intake during the course of pregnancy and lactation in well-nourished Indian women. American Journal of Clinical Nutrition 1995; 61: 501–13.Google Scholar
110Piers, LS, Shetty, PS. Basal metabolic rates of Indian women. European Journal of Clinical Nutrition 1993; 47: 586–91.Google Scholar
111Poehlman, ET, Arciero, PJ, Melby, CL, Badylak, SF. Resting metabolic rate and postprandial thermogenesis in vegetarians and nonvegetarians. American Journal of Clinical Nutrition 1988; 48: 209–13.Google Scholar
112Poehlman, ET, Gardner, AW, Ades, PA, Katzman-Rooks, SM, Montgomery, SM, Atlas, OK, Ballor, DL, Tyzbir, RS. Resting energy metabolism and cardiovascular disease risk in resistance-trained and aerobically trained males. Metabolism: Clinical and Experimental 1992; 41: 1351–60.Google Scholar
113Poehlman, ET, Melby, CL, Badylak, SF. Relation of age and physical exercise status on metabolic rate in younger and older healthy men. Journal of Gerontology 1991; 46: E548.Google Scholar
114Poehlman, ET, Scheffers, J, Gottlieb, SS, Fisher, ML, Vaitekevicius, P. Increased resting metabolic rate in patients with congestive heart failure. Annals of Internal Medicine 1994; 121: 860–2.Google Scholar
115Poehlman, ET, Toth, MJ. Mathematical ratios lead to spurious conclusions regarding age-and sex-related differences in resting metabolic rate. American Journal of Clinical Nutrition 1995; 61: 482–5.Google Scholar
116Poehlman, ET, Toth, MJ, Gardner, AW. Changes in energy balance and body composition at menopause: a controlled longitudinal study. Annals of Internal Medicine 1995; 123: 673–5.Google Scholar
117Poehlman, ET, Toth, MJ, Webb, GD. Sodium-potassium pump activity contributes to the age-related decline in resting metabolic rate. Journal of Clinical Endocrinology and Metabolism 1993; 76: 1054–7.Google Scholar
118Poehlman, ET, Tremblay, A, Fontaine, E, Despres, JP, Nadeau, A, Dussault, J, Bouchard, C. Genotype dependency of the thermic effect of a meal and associated hormonal changes following short-term overfeeding. Metabolism Clinical and Experimental 1986; 35: 30–6.Google Scholar
119Poehlman, ET, Tremblay, A, Nadeau, A, Dussault, J, Theriault, G, Bouchard, C. Heredity and changes in hormones and metabolic rates with short-term training. American Journal of Physiology 1986; 250: E7117.Google ScholarPubMed
120Polito, A, Fabbri, A, Ferro-Luzzi, A, Cuzzolaro, M, Censi, L, Ciarapica, D, Fabbrini, E, Giannini, D. Basal metabolic rate in anorexia nervosa: relation to body composition and leptin concentrations. American Journal of Clinical Nutrition 2000; 71: 1495–502.Google Scholar
121Poppitt, SD, Livesey, G, Elia, M. Energy expenditure and net substrate utilization in men ingesting usual and high amounts of nonstarch polysaccharide. American Journal of Clinical Nutrition 1998; 68: 820–6.Google Scholar
122Prentice, AM, Black, AE, Coward, WA, Davies, HL, Goldberg, GR, Murgatroyd, PR, Ashford, J, Sawyer, M, Whitehead, RG. High levels of energy expenditure in obese women. British Medical Journal 1986; 292: 983–7.Google Scholar
123Pullicino, E, Copperstone, C, Luzi, L, McNeill, G, Elia, M. Relationship between anthropometric indices of body fat distribution and basal energy metabolism in healthy Maltese women. Acta Diabetologica 1996; 33: 198204.Google Scholar
124Ratheiser, KM, Brillon, DJ, Campbell, RG, Matthews, DE. Epinephrine produces a prolonged elevation in metabolic rate in humans. American Journal of Clinical Nutrition 1998; 68: 1046–52.Google Scholar
125Reeves, SL, Henry, CJ. Dietary change, energy balance and body weight regulation among migrating students. International Journal of Food Sciences and Nutrition 2000; 51: 429–38.Google Scholar
126Rising, R, Harper, IT, Fontvielle, AM, Ferraro, RT, Spraul, M, Ravussin, E. Determinants of total daily energy expenditure: variability in physical activity. American Journal of Clinical Nutrition 1994; 59: 800–4.Google Scholar
127Rothenberg, EM, Bosaeus, IG, Westerterp, KR, Steen, BC. Resting energy expenditure, activity energy expenditure and total energy expenditure at age 91–96 years. British Journal of Nutrition 2000; 84: 319–24.Google Scholar
128Rush, EC, Plank, LD, Coward, WA. Energy expenditure of young Polynesian and European women in New Zealand and relations to body composition. American Journal of Clinical Nutrition 1999; 69: 43–8.Google Scholar
129Saad, MF, Alger, SA, Zurlo, F, Young, JB, Bogardus, C, Ravussin, E. Ethnic differences in sympathetic nervous system-mediated energy expenditure. American Journal of Physiology 1991; 261: E78994.Google ScholarPubMed
130Sanchez-Castillo, CP, Franklin, M, McNeill, G, Solano, MD, Bonner, S, Lopez, N, Davidson, L, James, WPT. Are the proposed limits of energy intake: basal metabolic rate and dietary nitrogen:urinary nitrogen ratios suitable for validation of food intake? British Journal of Nutrition 2001; 85: 725–31.Google Scholar
131Sathyaprabha, TN. Basal metabolic rate and body composition in elderly Indian males. Indian Journal of Physiology and Pharmacology 2000; 44: 179–84.Google Scholar
132Schmidt, WD, O'Connor, PJ, Cochrane, JB, Cantwell, M. Resting metabolic rate is influenced by anxiety in college men. Journal of Applied Physiology 1996; 80: 638–42.Google Scholar
133Schultink, JW, Van Raaij, JM, Hautvast, JG. Seasonal weight loss and metabolic adaptation in rural Beninese women: the relationship with body mass index. British Journal of Nutrition 1993; 70: 689700.Google Scholar
134Schulz, LO, Nyomba, BL, Alger, S, Anderson, TE, Ravussin, E. Effect of endurance training on sedentary energy expenditure measured in a respiratory chamber. American Journal of Physiology 1991; 260: E25761.Google Scholar
135Seale, JL, Conway, JM. Relationship between overnight energy expenditure and BMR measured in a room-sized calorimeter. European Journal of Clinical Nutrition 1999; 53: 107–11.Google Scholar
136Segal, KR, Chun, A, Coronel, P, Cruz-Noori, A, Santos, R. Reliability of the measurement of postprandial thermogenesis in men of three levels of body fatness. Metabolism Clinical and Experimental 1992; 41: 754–62.Google Scholar
137Segal, KR, Dunaif, A. Resting metabolic rate and postprandial thermogenesis in polycystic ovarian syndrome. International Journal of Obesity 1990; 14: 559–67.Google Scholar
138Seidell, JC, Muller, DC, Sorkin, JD, Andres, R. Fasting respiratory exchange ratio and resting metabolic rate as predictors of weight gain: the Baltimore Longitudinal Study on Aging. International Journal of Obesity and Related Metabolic Disorders: Journal of the International Association for the Study of Obesity 1992; 16: 667–74.Google Scholar
139Singh, J, Prentice, AM, Diaz, E, Coward, WA, Ashford, J, Sawyer, M, Whitehead, RG. Energy expenditure of Gambian women during peak agricultural activity measured by the doubly labelled water method. British Journal of Nutrition 1989; 62: 315–29.Google Scholar
140Singhal, A, Davies, P, Wierenga, KJ, Thomas, P, Serjeant, G. Is there an energy deficiency in homozygous sickle cell disease? American Journal of Clinical Nutrition 1997; 66: 386–90.Google Scholar
141Smith, DA, Dollman, J, Withers, RT, Brinkman, M, Keeves, JP, Clark, DG. Relationship between maximum aerobic power and resting metabolic rate in young adult women. Journal of Applied Physiology 1997; 82: 156–63.CrossRefGoogle ScholarPubMed
142Smith, DA, Withers, RT, Brinkman, M, Tucker, RC, Chatterton, BE, Schultz, CG, Clark, DG. Resting metabolic rate, body composition and aerobic fitness comparisons between active and sedentary 54–71 year old males. European Journal of Clinical Nutrition 1999; 53: 434–40.Google Scholar
143Soares, MJ, Piers, LS, O'Dea, K, Shetty, PS. No evidence for an ethnic influence on basal metabolism: an examination of data from India and Australia. British Journal of Nutrition 1998; 79: 333–41.Google Scholar
144Soares, MJ, Shetty, PS. Long-term stability of metabolic rates in young adult males. Human Nutrition Clinical Nutrition 1987; 41: 287–90.Google Scholar
145Spaaij, CJ, van Raaij, JM, Van der Heijden, LJ, Schouten, FJM, Drijvers, JJMM, de Groot, LCPGM, Boekholt, HA, Hautvast, JGAJ. No substantial reduction of the thermic effect of a meal during pregnancy in well-nourished Dutch women. British Journal of Nutrition 1994; 71: 335–44.Google Scholar
146Spaanderman, ME, Meertens, M, van Bussel, M, Ekhart, TH, Peeters, LL. Cardiac output increases independently of basal metabolic rate in early human pregnancy. American Journal of Physiology. Heart and Circulatory Physiology 2000; 278: E15858.Google Scholar
147Spurr, GB, Dufour, DL, Reina, JC, Hoffmann, RG, Waslien, CI, Staten, LK. Variation of the basal metabolic rate and dietary energy intake of Colombian women during 1 y. American Journal of Clinical Nutrition 1994; 59: 20–7.Google Scholar
148Stenlof, K, Sjostrom, L, Fagerberg, B, Nystrom, E, Lindstedt, G. Thyroid hormones, procollagen III peptide, body composition and basal metabolic rate in euthyroid individuals. Scandinavian Journal of Clinical and Laboratory Investigation 1993; 53: 793803.Google Scholar
149Strickland, SS, Duffield, AE. Anthropometric status and resting metabolic rate in users of the areca nut and smokers of tobacco in rural Sarawak. Annals of Human Biology 1997; 24: 453–74.Google Scholar
150Strickland, SS, Ulijaszek, SJ. Energetic cost of standard activities in Gurkha and British soldiers. Annals of Human Biology 1990; 17: 133–44.Google Scholar
151Sujatha, T, Shatrugna, V, Venkataramana, Y, Begum, N. Energy expenditure on household, childcare and occupational activities of women from urban poor households. British Journal of Nutrition 2000; 83: 497503.Google Scholar
152Svensson, J, Lonn, L, Jansson, JO, Murphy, G, Wyss, D, Krupa, D, Cerchio, K, Polvino, W, Gertz, B, Boseaus, I, Sjöström, L, Bengtsson, BA. Two-month treatment of obese subjects with the oral growth hormone (GH) secretagogue MK-677 increases GH secretion, fat-free mass, and energy expenditure. Journal of Clinical Endocrinology and Metabolism 1998; 83: 362–9.Google Scholar
153Tataranni, PA, Larson, DE, Ravussin, E. Body fat distribution and energy metabolism in obese men and women. Journal of the American College of Nutrition 1994; 13: 569–74.Google Scholar
154Thompson, JL, Gylfadottir, UK, Moynihan, S, Jensen, CD, Butterfield, GE. Effects of diet and exercise on energy expenditure in postmenopausal women. American Journal of Clinical Nutrition 1997; 66: 867–73.Google Scholar
155Toth, MJ, Gardner, AW, Poehlman, ET. Training status, resting metabolic rate, and cardiovascular disease risk in middle-aged men. Metabolism Clinical and Experimental 1995; 44: 340–7.CrossRefGoogle ScholarPubMed
156Toth, MJ, Poehlman, ET. Resting metabolic rate and cardiovascular disease risk in resistance-and aerobic-trained middle-aged women. International Journal of Obesity and Related Metabolic Disorders: Journal of the International Association for the Study of Obesity 1995; 19: 691–8.Google Scholar
157Toth, MJ, Poehlman, ET. Sympathetic nervous system activity and resting metabolic rate in vegetarians. Metabolism Clinical and Experimental 1994; 43: 621–5.Google Scholar
158van der Ploeg, GE, Gunn, SM, Withers, RT, Modra, AC, Keeves, JP, Chatterton, BE. Predicting the resting metabolic rate of young Australian males. European Journal of Clinical Nutrition 2001; 55: 145–52.Google Scholar
159van Pelt, RE, Dinneno, FA, Seals, DR, Jones, PP. Age-related decline in RMR in physically active men: relation to exercise volume and energy intake. American Journal of Physiology. Endocrinology and Metabolism 2001; 281: E6339.Google Scholar
160van Raaij, JM, Schonk, CM, Vermaat-Miedema, SH, Peek, ME, Hautvast, JG. Body fat mass and basal metabolic rate in Dutch women before, during, and after pregnancy: a reappraisal of energy cost of pregnancy. American Journal of Clinical Nutrition 1989; 49: 765–72.Google Scholar
161van Raaij, JM, Schonk, CM, Vermaat-Miedema, SH, Peek, ME, Hautvast, JG. Energy cost of physical activity throughout pregnancy and the first year postpartum in Dutch women with sedentary lifestyles. American Journal of Clinical Nutrition 1990; 52: 234–9.Google Scholar
162Velthuis-te Wierik, EJ, Westerterp, KR, van den Berg, H. Impact of a moderately energy-restricted diet on energy metabolism and body composition in non-obese men. International Journal of Obesity and Related Metabolic Disorders: Journal of the International Association for the Study of Obesity 1995; 19: 318–24.Google Scholar
163Visser, M, Deurenberg, P, van Staveren, WA, Hautvast, JG. Resting metabolic rate and diet-induced thermogenesis in young and elderly subjects: relationship with body composition, fat distribution, and physical activity level. American Journal of Clinical Nutrition 1995; 61: 772–8.Google Scholar
164Volpe, SL, Huang, HW, Larpadisorn, K, Lesser, II. Effect of chromium supplementation and exercise on body composition, resting metabolic rate and selected biochemical parameters in moderately obese women following an exercise program. Journal of the American College of Nutrition 2001; 20: 293306.Google Scholar
165Voorrips, LE, van Acker, TM, Deurenberg, P, van Staveren, WA. Energy expenditure at rest and during standardized activities: a comparison between elderly and middle-aged women. American Journal of Clinical Nutrition 1993; 58: 1520.CrossRefGoogle ScholarPubMed
166Wahrlich, V, Anjos, LA. Validation of predictive equations of basal metabolic rate of women living in Southern Brazil. Revista de Saude Publica 2001; 35: 3945.Google Scholar
167Webb, GD, Poehlman, ET, Tonino, RP. Dissociation of changes in metabolic rate and blood pressure with erythrocyte Na–K pump activity in older men after endurance training. Journal of Gerontology 1993; 48: M47–M52.Google Scholar
168Welle, S, Forbes, GB, Statt, M, Barnard, RR, Amatruda, JM. Energy expenditure under free-living conditions in normal-weight and overweight women. American Journal of Clinical Nutrition 1992; 55: 1421.Google Scholar
169Welle, S, Nair, KS. Relationship of resting metabolic rate to body composition and protein turnover. American Journal of Physiology 1990; 258: E9908.Google Scholar
170Welle, S, Thornton, C, Totterman, S, Forbes, G. Utility of creatinine excretion in body-composition studies of healthy men and women older than 60 y. American Journal of Clinical Nutrition 1996; 63: 151–6.Google Scholar
171Weststrate, JA, Weys, PJ, Poortvliet, EJ, Deurenberg, P, Hautvast, JG. Diurnal variation in postabsorptive resting metabolic rate and diet-induced thermogenesis. American Journal of Clinical Nutrition 1989; 50: 908–14.Google Scholar
172Williamson, DL, Kirwan, JP. A single bout of concentric resistance exercise increases basal metabolic rate 48 hours after exercise in healthy 59–77-year-old men. Journals of Gerontology. Series A, Biological Sciences and Medical Sciences 1997; 52: E3525.Google Scholar
173Wilmore, JH, Stanforth, PR, Hudspeth, LA, Gagnon, J, Daw, EW, Leon, AS, Rao, DC, Skinner, JS, Bouchard, C. Alterations in resting metabolic rate as a consequence of 20 wk of endurance training: the HERITAGE Family Study. American Journal of Clinical Nutrition 1998; 68: 6671.Google Scholar
174Withers, RT, Smith, DA, Tucker, RC, Brinkman, M, Clark, DG. Energy metabolism in sedentary and active 49- to 70-yr-old women. Journal of Applied Physiology 1998; 84: 1333–40.Google Scholar
175Yamauchi, T, Umezaki, M, Ohtsuka, R. Influence of urbanisation on physical activity and dietary changes in Huli-speaking population: a comparative study of village dwellers and migrants in urban settlements. British Journal of Nutrition 2001; 85: 6573.Google Scholar