Harris–Benedict equation

The Harris–Benedict equation (also called the Harris-Benedict principle) is a method used to estimate an individual's basal metabolic rate (BMR).

The estimated BMR value may be multiplied by a number that corresponds to the individual's activity level; the resulting number is the approximate daily kilocalorie intake to maintain current body weight.

The Harris-Benedict equation may be used to assist weight loss — by reducing the kilocalorie intake number below the estimated maintenance intake of the equation.[citation needed]

Calculating the Harris-Benedict BMR

edit

The original Harris–Benedict equations were published in 1918 and 1919.[1][2]

Sex Units Calculations of BMR, resulting in kcal/day
Men Metric BMR = ( 13.7516 × weight in kg ) + ( 5.0033 × height in cm ) – ( 6.755 × age in years ) + 66.473
Imperial BMR = ( 6.23762 × weight in pounds ) + ( 12.7084 × height in inches ) – ( 6.755 × age in years ) + 66.473
Women Metric BMR = ( 9.5634 × weight in kg ) + ( 1.8496 × height in cm ) – ( 4.6756 × age in years ) + 655.0955
Imperial BMR = ( 4.33789 × weight in pounds ) + ( 4.69798 × height in inches ) – ( 4.6756 × age in years ) + 655.0955

The Harris–Benedict equations revised by Roza and Shizgal in 1984.[3]

Men BMR = (13.397 × weight in kg) + (4.799 × height in cm) – (5.677 × age in years) + 88.362
Women BMR = (9.247 × weight in kg) + (3.098 × height in cm) – (4.330 × age in years) + 447.593

The 95% confidence range for men is ±213.0 kcal/day, and ±201.0 kcal/day for women.

The Harris–Benedict equations revised by Mifflin and St Jeor in 1990:[4]

Men BMR = (10 × weight in kg) + (6.25 × height in cm) – (5 × age in years) + 5
Women BMR = (10 × weight in kg) + (6.25 × height in cm) – (5 × age in years) – 161

History

edit

The Harris-Benedict equation sprang from a study by James Arthur Harris and Francis Gano Benedict, which was published in 1919 by the Carnegie Institution of Washington in the monograph A Biometric Study Of Basal Metabolism In Man. A 1984 revision improved its accuracy. Mifflin et al. published an equation more predictive for modern lifestyles in 1990.[4] Later work produced BMR estimators that accounted for lean body mass.

Issues in dietary use

edit

As the BMR equations do not attempt to take into account body composition, identical results can be calculated for a very muscular person, and an overweight person, who are both the same height, weight, age and gender. As muscle and fat require differing amounts of calories to maintain, the TEE estimates will not be accurate for such cases.

The paper behind the latest update (Mifflin et al) to the BMR formula states all participants in their study fall within the 'normal' and 'overweight' body mass index (BMI) categories, and so the results also do not necessarily apply to those in the 'underweight' or 'obese' BMI categories.

See also

edit

Cited sources

edit
  1. ^ Harris JA, Benedict FG (1918). "A Biometric Study of Human Basal Metabolism". Proceedings of the National Academy of Sciences of the United States of America. 4 (12): 370–3. Bibcode:1918PNAS....4..370H. doi:10.1073/pnas.4.12.370. PMC 1091498. PMID 16576330.
  2. ^ A Biometric Study of Basal Metabolism in Man. J. Arthur Harris and Francis G. Benedict. Washington, DC: Carnegie Institution, 1919.
  3. ^ Roza AM, Shizgal HM (1984). "The Harris Benedict equation reevaluated: resting energy requirements and the body cell mass". The American Journal of Clinical Nutrition. 40 (1): 168–82. doi:10.1093/ajcn/40.1.168. PMID 6741850.
  4. ^ a b Mifflin MD, St Jeor ST, Hill LA, Scott BJ, Daugherty SA, Koh YO (1990). "A new predictive equation for resting energy expenditure in healthy individuals". The American Journal of Clinical Nutrition. 51 (2): 241–7. doi:10.1093/ajcn/51.2.241. PMID 2305711.
edit