New international standard definitions

Abstract

While, in adults, the body mass index (BMI) cut-offs internationally accepted as definitions of overweight and obesity (25 kg/m² and 30 kg/m², respectively) are based on increased risks of morbidity and mortality,⁵ no such outcome-based definition exists for children. Definitions for children and adolescents have generally been statistical, with percentile cut-offs based on variably representative and sized national anthropometric data sets, making it difficult to adequately monitor secular changes in body size and prevalence of obesity. Furthermore, there has been no agreement on either the most appropriate adiposity index or the cut-off points. Thus, it has not been possible to interpret and compare prevalence and intervention studies, nationally or internationally.

In 1997, the International Obesity Task Force (IOTF) Childhood Obesity Working Group accepted BMI as a consistent, pragmatic (ie, reasonable although imperfect) index of adiposity in children and adolescents.⁶ The IOTF has recently published cut-off points to define overweight and obesity in children and adolescents based on adult overweight and obesity BMI ranges.⁷ While this remains a statistical definition and can not be quantified in terms of current or future morbidity, it allows analysis of national data to determine point prevalence and identify secular trends, and enables meaningful international comparisons. For example, a secular trend in body fatness, estimated by BMI, from 1985 to 1997 was found in children aged 7-12 years in New South Wales and Victoria, but the lack of accepted standards meant that no estimates were made of the prevalence of overweight and obesity.^8,9

Using these new international definitions, we determined the prevalence of overweight and obesity in Australian children and adolescents aged 2-18 years in two nationally representative samples 10 years apart — the Australian Health and Fitness Survey of 1985 (AHFS85)¹⁰ and the National Nutrition Survey of 1995 (NNS95).¹¹ In previous estimates of the prevalence of overweight using these samples, any secular trend could not be identified because different definitions were used.^12,13

National surveys
The data collection procedures for the two surveys are described in Box 1. The original data published from the AHFS85 survey included percentiles for height and weight only. Subsequently published were BMI percentiles by age and sex, and the prevalence of overweight in the age group 12-14 years (but not in those 7-11 years of age).¹² Summary statistics of prevalence of overweight and obesity in NNS95 participants have also been published.¹³Box 2 shows the prevalence of overweight in these two surveys.

Data for analysis of the AHFS85 sample were supplied on disc by the Australian Council on Health, Physical Education and Recreation and those for the NNS95 were provided by the Australian Bureau of Statistics as a confidentialised unit record file.

New international standard definitions
The new international standard definitions for overweight and obesity published by the International Obesity Task Force were based on six large, nationally representative cross-sectional growth studies from birth to 25 years (Brazil 1989, Great Britain 1979-1993, Hong Kong 1993, the Netherlands 1980, Singapore 1993, and the United States 1963-1980).⁷ For each of these, centile curves of BMI were drawn that at age 18 years passed through the BMI cut-off points of 25 kg/m² and 30 kg/m² for adult overweight and obesity, respectively. The resulting curves were averaged to provide age- and sex-specific BMI cut-off points to define overweight (cut-off 1) and obesity (cut-off 2) in half-year intervals from 2 to 18 years.⁷

Re-estimate of overweight and obesity prevalence
We applied the new international cut-off points to each child in the two data sets to re-estimate the prevalence of overweight and obesity. For each age, the cut-off point at the mid-year value was applied (eg, for those aged 7 years, we used the cut-off at 7.5 years). For data with one-year age groups, as in these two samples, this will give an essentially unbiased estimate.⁷ We grouped children in the AHFS85 into two age bands and those in the NNS95 into five age bands to facilitate comparison between the two studies.

Statistical analysis
Analyses were performed using the Stata statistical package.¹⁴Relative risk (RR) of overweight (≥ cut-off 1) or obesity (≥ cut-off 2) within years (controlling for sex) and between years (controlling for age and sex) was determined using "Epitab - tables for epidemiologists"¹⁴ and reported as RR (95% CI).

In the AHFS85 sample:

Previous estimates of the prevalence of overweight and obesity in the AHFS85 used the 85th percentile of BMI for the age group 12-14 years in the United States National Health and Nutrition Examination Survey II (NHANES II; 1976-1980) to define overweight (Box 1).¹² In the NNS95 sample, children aged 2-8 years were classified as high weight for height if their standard deviation (Z) score of weight for height was greater than + 2, based on World Health Organization reference values.¹¹ For older subjects, the 85th and 95th BMI percentiles derived from NHANES I data of 1971-1974,¹⁵ which are lower than those from the later NHANES II data, were used to define "at risk of overweight" and overweight, respectively. The reason for the use of the older NHANES data for the later 1995 survey is not clear. These differences in reference populations and approaches to classifying participants as overweight or obese clearly limit comparison of prevalence rates and assessment of trends.

Our revised estimates of prevalence of overweight in the 1985 and 1995 samples, respectively, are slightly higher and considerably higher than those previously reported.^12,13 The risks of both overweight and obesity in 1995 are significantly higher than in 1985 and the increase in prevalence is higher than previously reported.

Methodological differences between the two surveys must be taken into consideration when making these comparisons. Although the effect of sampling on the trend is unknown, the different method of determining age in the 1985 sample may result in a very few subjects being misclassified as acceptable weight and slightly fewer being misclassified as overweight. The possible net underestimate of prevalence of overweight would be extremely small and could not account for the large increase in prevalence of overweight from 1985 to 1995.

Furthermore, our prevalence rates are high by international standards. The revised prevalence figures for 1985 for both overweight and obesity fall at about the mid-point of the range of the international reference populations at age 18 years.⁷ However, prevalence figures from the 1995 sample indicate rates for both overweight and obesity that are higher than all the international reference populations and considerably higher than those of 1985. Comparison with recently published trends from 1974 to 1994 in British children aged 4-11 years¹⁶ indicates that more Australian boys aged 7-11 years were overweight in 1985 and 1995 than British boys, although the decade increase was similar. For girls, prevalence of overweight in Australia in 1985 was slightly higher than in Britain, but considerably higher in 1995 (ie, the decade increase was greater in Australian girls). Similarly, prevalence of overweight in 1994 in Australian children aged 4-6 years was considerably higher than in British children (boys, 13.4% v 6.4%; girls, 19.5% v 9.2%).

The new standard definitions for childhood overweight and obesity are not directly related to measurable outcomes in morbidity and mortality in adulthood, although dyslipidaemia, elevated blood pressure and insulin resistance are associated with these levels of adiposity in children.^2-4 Overweight and obesity in childhood and adolescence increase the risk of overweight in adulthood, but these new BMI centile curves give no information on the degree of tracking within the different levels of adiposity (ie, the extent to which individuals maintain their level of adiposity). Longitudinal studies are urgently needed to assess the change in BMI percentiles during growth, and the long term health outcomes associated with these defined levels of adiposity, so that overweight and obesity in childhood can be defined by biological endpoints.¹⁷

The secular trend towards increasing overweight and obesity in the decade from the mid-1980s and the high prevalence figures described here are of major public health concern and should stimulate urgent action: treatment of those already overweight and obese, prevention of progression of overweight to obesity, and prevention of overweight.¹⁸ The International Obesity Task Force proposes three levels at which prevention should occur:

• Universal/public health prevention directed at the whole population;

• Selective prevention directed at subgroups at increased risk of developing obesity; and

• Targeted prevention directed at high risk individuals who are overweight but not yet obese.¹

The National Health and Medical Research Council (NHMRC) report Acting on Australia's weight places particular emphasis on strategies, at the population level, to change the macroenvironment of food supply and opportunities for physical activity.¹⁸ The global epidemic of increasing overweight and obesity in both adults and children is attributed to changing lifestyle.¹ Partly because of methodological difficulties in assessment,¹⁹ no data exist in Australia on either the activity or inactivity levels of children and adolescents in the past 15 years, nor how these may have changed.

Several factors, however, suggest that the increased prevalence of overweight and obesity in Australian children may be attributed to decreasing activity, increasing inactivity and increasing food energy intake:

• a study of fitness levels in Australian children from 1985 to 1997 reported that these have declined, suggesting a decrease in physical activity;²⁰

• it is generally recognised that the time spent in sedentary activities, such as television watching and playing computer games, has increased in the past decade;

• a comparison of the dietary intakes of children aged 10-15 years from the national surveys of 1985²¹ and 1995¹³ showed that mean daily energy intake has increased by 0.5-2.0 MJ in the 10-year interval; and

• a comparison of the energy intake of children aged 4-8 years in 1995 with that of Adelaide children in the early 1980s suggested that energy intake in this age group has also increased by 0.5-1.5 MJ.²²

Health professionals have a major role to play in promoting, to all family members, the benefits of a healthy diet, an increase in habitual physical activity and a decrease in inactivity.^23-25 Such strategies have major implications for maintenance of a healthy weight, and the prevention of overweight, obesity, and future cardiovascular disease risk.

1. World Health Organization (WHO). Obesity: preventing and managing the global epidemic. Report of a WHO consultation on obesity, Geneva, 3-5 June, 1997. Geneva: WHO, 1998.
2. Dietz WH. Health consequences of obesity in youth: childhood predictors of adult disease. Pediatrics 1998; 101 (3 Suppl March): 518-525.
3. Power C, Lake JK, Cole TJ. Measurements of long-term health risks of child and adolescent fatness [review]. Int J Obes Relat Metab Disord 1997; 21: 507-526.
4. Guo SS, Roche AF, Chumlea WC, et al. The predicitve value of childhood body mass index values for overweight at age 35 y. Am J Clin Nutr 1994; 59: 810-819.
5. Manson JE, Willett WC, Stampfer MJ. Body weight and mortality among women. N Engl J Med 1995; 333: 677-685.
6. Bellizzi MC, Dietz WH. Workshop on childhood obesity: summary of the discussion [review]. Am J Clin Nutr 1999; 70: 173S-175S.
7. Cole TJ, Bellizzi MC, Flegal KM, Dietz WH. Establishing a standard definition for child overweight and obesity worldwide: international survey. BMJ 2000; 320: 1240-1243.
8. Lynch J, Wang XL, Wilcken DEL. Body mass index in Australian children: recent changes and relevance of ethnicity. Arch Dis Child 2000; 82: 16-20.
9. Lazarus R, Wake M, Hesketh K, Waters E. Change in body mass index in Australian primary school children, 1985-1997. Int J Obes Relat Metab Disord 2000; 24: 679-684.
10. Pyke JE. Austalian Health and Fitness Survey 1985. Parkside, SA: The Australian Council for Health, Physical Education and Recreation Inc, 1987.
11. McLennan W, Podger A. National nutrition survey user's guide 1995. Canberra: AGPS, 1998.
12. Harvey PWJ, Althaus M-M. The distribution of body mass index in Australian children aged 7-15 years. Aust J Nutr Diet 1993; 50: 151-153.
13. McLennan W, Podger A. National nutrition survey, 1995. Nutrient intakes and physical measurements. Canberra: AGPS, 1998.
14. Stata statistical software, release 7.0. College Station, Texas: Stata Corporation, 2001.
15. Must A, Dallal GE. Reference data for obesity: 85th and 95th percentiles of body mass index (wt/ht²) and triceps skinfold thickness. Am J Clin Nutr 1991; 53: 839-846.
16. Chinn S, Rona RJ. Prevalence and trends in overweight and obesity in three cross sectional studies of British children, 1974-94. BMJ 2001; 322: 24-26.
17. Dwyer T, Blizzard CI. Defining obesity in children by biological endpoint rather than population distribution. Int J Obes Relat Metab Disord 1996; 20: 472-480.
18. National Health and Medical Research Council. Acting on Australia's weight: a strategic plan for the prevention of overweight and obesity. Canberra: NHMRC, 1997.
19. Goran MI. Measurement issues related to studies of childhood obesity: assessment of body composition, body fat distribution, physical activity and food intake. Pediatrics 1998; 101 (3 Suppl March): 505-518.
20. Dollman J, Olds T, Norton K, Stuart D. The evolution of fitness and fatness in 10-11 year old Australian children: changes in distributional characteristics between 1985 and 1997. Pediatr Exer Sci 1999; 11: 108-121.
21. Department of Community Services and Health. National dietary survey of schoolchildren (aged 10-15 years), 1985: no 2 — nutrient intakes. Canberra: AGPS, 1989.
22. Magarey A, Boulton TJC. Food intake during childhood: percentiles of food energy, macronutrient and selected micronutrients from infancy to eight years of age. Med J Aust 1987; 147: 124-127.
23. National Health and Medical Research Council. Dietary Guidelines for Australians; Canberra: NHMRC, 1992.
24. National Health and Medical Research Council. Dietary guidelines for children and adolescents. Canberra: NHMRC, 1995.
25. Smith A, Kellett E, Schmerlaib Y. The Australian guide to healthy eating. Canberra: Commonwealth Department of Health and Family Services, 1998.

Authors' details

Women's and Children's Health, The Nepean Hospital, Penrith; and Western Clinical School, University of Sydney, NSW.
T John C Boulton, MD, FRACP, Clinical Professor of Paediatrics.

Reprints will not be available from the authors.
Correspondence: Dr A M Magarey, Nutrition Unit, Department of Public Health, Flinders University of South Australia, Bedford Park, SA 5034.
anthea.magareyATflinders.edu.au

©MJA 2001
Make a comment

Readers may print a single copy for personal use. No further reproduction or distribution of the articles should proceed without the permission of the publisher. For permission, contact the Australasian Medical Publishing Company.
Journalists are welcome to write news stories based on what they read here, but should acknowledge their source as "an article published on the Internet by The Medical Journal of Australia <http://www.mja.com.au>".
<URL: http://www.mja.com.au/> © 2001 Medical Journal of Australia.