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5. ENERGY REQUIREMENTS OF ADULTS

The principles followed by the 1985 FAO/WHO/UNU expert consultation (WHO, 1985) were adhered to, and energy requirements of adults were calculated from factorial estimates of habitual TEE. The use of techniques such as DLW and HRM confirmed the large diversity of TEE - and hence of energy requirements - among adult societies, which were previously reported by time-motion studies. Growth is no longer an energy-demanding factor in adulthood, and BMR is relatively constant among population groups of a given age and gender. Consequently, habitual physical activity and body weight are the main determinants for the diversity in energy requirements of adult populations with different lifestyles (James and Schofield, 1990).

5.1 Factorial estimation of total energy expenditure and physical activity level

The diversity in body size, body composition and habitual physical activity among adult populations with different geographic, cultural and economic backgrounds does not allow a universal application of energy requirements based on TEE measured with DLW (or HRM) in groups with a specific lifestyle. Hence, to account for the differences in physical activity, TEE was estimated through factorial calculations that combined the time allocated to habitual activities and the energy cost of those activities. Table 5.1 shows examples of these calculations. To account for differences in body size and composition, the energy cost of activities was calculated as a multiple of BMR per minute, also referred to as the physical activity ratio (PAR), and the 24-hour energy requirement was expressed as a multiple of BMR per 24 hours by using the PAL value (James and Schofield, 1990). Together with BMR of the population, PAL when known or when derived using BMR estimated from age and gender-specific predictive equations based on the average body weight of the population provides an estimate of TEE and hence the mean energy requirement for that population.

To simplify calculations, the previous expert consultation classified the PAL of adult population groups as light, moderate or heavy, depending on their occupational or other work, and multiplied it by the corresponding BMR to arrive at requirements (WHO, 1985). The present consultation considered that the 24-hour PAL should not be based only on the physical effort demanded by occupational work, as there are people with light occupations who perform vigorous physical activity in their spare time, and people with heavy work who are quite sedentary the rest of the day. As discussed in section 5.3, it was decided to base the factorial estimates of energy requirements on the energy expenditure associated with lifestyles that combine occupational and discretionary physical activities.

This consultation also agreed that the average energy cost of activities expressed as a multiple of BMR, or PAR, should be similar for men and women. The effect of gender comes out when the PAR value is converted into energy units, because men have higher BMR for their body weight than women, and this difference is accentuated by the heavier weight of men. Consequently, the energy cost of most activities listed in Table 5.1 as a function of BMR is applicable to both men and women. Notable exceptions are vigorous activities that demand a level of effort proportional to muscle mass and strength, which tend to be greater among men (for example, lifting and carrying heavy loads, cutting wood or working with a sledgehammer).

5.2 Estimation of basal metabolic rate

BMR constitutes about 45 to 70 percent of TEE in adults, and is determined principally by gender, body size, body composition and age. It can be measured accurately with small intra-individual variation by direct or indirect calorimetry under standard conditions, which include being awake in the supine position, ten to 12 hours after a meal, following eight hours of physical rest and no strenuous exercise in the preceding day, and being in a state of mental relaxation and an ambient environmental temperature that does not evoke shivering or sweating. BMR can be measured only under laboratory conditions and in small groups of representative individuals. There is a need to estimate BMR at the population level when using the factorial approach to estimate TEE from the average BMR and PAL value attributable to that population. Hence, the alternative has been to estimate a group’s mean BMR using predictive equations based on measurements that are easier to obtain, such as body weight and/or height.

TABLE 5.1
Factorial calculations of total energy expenditure for a population group

Main daily activities

Time allocation
hours

Energy costa
PAR

Time × energy cost

Mean PALb
multiple of 24-hour BMR

Sedentary or light activity lifestyle





Sleeping

8

1

8.0


Personal care (dressing, showering)

1

2.3

2.3


Eating

1

1.5

1.5


Cooking

1

2.1

2.1


Sitting (office work, selling produce, tending shop)

8

1.5

12.0


General household work

1

2.8

2.8


Driving car to/from work

1

2.0

2.0


Walking at varying paces without a load

1

3.2

3.2


Light leisure activities (watching TV, chatting)

2

1.4

2.8


Total

24


36.7

36.7/24 = 1.53






Active or moderately active lifestyle





Sleeping

8

1

8.0


Personal care (dressing, showering)

1

2.3

2.3


Eating

1

1.5

1.5


Standing, carrying light loads
(waiting on tables, arranging merchandise)c

8

2.2

17.6


Commuting to/from work on the bus

1

1.2

1.2


Walking at varying paces without a load

1

3.2

3.2


Low intensity aerobic exercise

1

4.2

4.2


Light leisure activities (watching TV, chatting)

3

1.4

4.2


Total

24


42.2

42.2/24 = 1.76






Vigorous or vigorously active lifestyle





Sleeping

8

1

8.0


Personal care (dressing, bathing)

1

2.3

2.3


Eating

1

1.4

1.4


Cooking

1

2.1

2.1


Non-mechanized agricultural work (planting, weeding, gathering)

6

4.1

24.6


Collecting water/wood

1

4.4

4.4


Non-mechanized domestic chores (sweeping, washing clothes and dishes by hand)

1

2.3

2.3


Walking at varying paces without a load

1

3.2

3.2


Miscellaneous light leisure activities

4

1.4

5.6


Total

24


53.9

53.9/24 = 2.25

a Energy costs of activities, expressed as multiples of basal metabolic rate, or PAR, are based on Annex 5 of the previous consultation’s report (WHO, 1985) (see also Annex 5 of this report).
b PAL = physical activity level, or energy requirement expressed as a multiple of 24-hour BMR.
c Composite of the energy cost of standing, walking slowly and serving meals or carrying a light load.

Examples:

Sedentary or light activity: If this PAL was from a female population, 30 to 50 years old, with mean weight of 55 kg and mean BMR of 5.40 MJ/day (1 290 kcal/day), TEE = 1.53 × 5.40 = 8.26 MJ (1 975 kcal), or 150 kJ (36 kcal)/kg/d.

Active or moderately active: If this PAL was from a female population, 20 to 25 years old, with mean weight of 57 kg and mean BMR of 5.60 MJ/day (1 338 kcal/day), TEE = 1.76 × 5.60 = 9.86 MJ (2 355 kcal), or 173 kJ (41 kcal)/kg/d.

Vigorous or vigorously active: If this PAL was from a male population, 20 to 25 years old, with mean weight of 70 kg and mean BMR of 7.30 MJ/day (1 745 kcal/day), TEE = 2.25 × 7.30 = 16.42 MJ (3 925 kcal), or 235 kJ (56 kcal)/kg/d.

The report from the 1985 FAO/WHO/UNU expert consultation used a set of equations derived mostly from studies in Western Europe and North America (Schofield, 1985). Almost half of the data used to generate the equations for adults were from studies carried out in the late 1930s and early 1940s on Italian men with relatively high BMR values, and questions have been raised about the universal applicability of those equations (Soares and Shetty, 1988; de Boer et al., 1988; Henry and Rees, 1991; Arciero et al., 1993; Piers and Shetty, 1993; Soares, Francis and Shetty, 1993; Hayter and Henry, 1993 and 1994; Valencia et al., 1994; Cruz, da Silva and dos Anjos, 1999; Henry, 2001; Ismail et al., 1998). The use of closed-circuit indirect calorimetry in most studies has also been questioned, as this technique might overestimate oxygen consumption and energy expenditure. For the present consultation, predictive equations derived from a database with broader geographical and ethnic representation were evaluated (Henry, 2001; Cole, 2002). The predictive accuracies of the new equations and of those from 1985 were compared with published measurements of BMR in adults from different parts of the world, which were not part of the databases used to generate the predictive equations (Ramirez-Zea, 2002). Although the new equations had some merits, such as small reductions in the error of prediction and the overestimation bias among men, this consultation concluded that these were not robust enough to justify their adoption at present. For the time being, it was decided to retain the equations proposed in 1985 by Schofield (Table 5.2), and to pursue a more thorough analysis of existing information, or to promote a prospective study with broad global geographic and ethnic representation.

TABLE 5.2
Equations for estimating BMR from body weight*

Age
Years

No.

BMR: MJ/day

see

BMR: kcal/day

see

Males






< 3

162

0.249kg - 0.127

0.292

59.512kg - 30.4

70

3-10

338

0.095kg + 2.110

0.280

22.706kg + 504.3

67

10-18

734

0.074kg + 2.754

0.441

17.686kg + 658.2

105

18-30

2879

0.063kg + 2.896

0.641

15.057kg + 692.2

153

30-60

646

0.048kg + 3.653

0.700

11.472kg + 873.1

167

³ 60

50

0.049kg + 2.459

0.686

11.711kg + 587.7

164

Females






< 3

137

0.244kg - 0.130

0.246

58.317kg - 31.1

59

3-10

413

0.085kg + 2.033

0.292

20.315kg + 485.9

70

10-18

575

0.056kg + 2.898

0.466

13.384kg + 692.6

111

18-30

829

0.062kg + 2.036

0.497

14.818kg + 486.6

119

30-60

372

0.034kg + 3.538

0.465

8.126kg + 845.6

111

³ 60

38

0.038kg + 2.755

0.451

9.082kg + 658.5

108

* Weight is expressed in kg. Predictive equations for children and adolescents are presented for the sake of completeness.
Source: Schofield, 1985.

5.3 Physical activity level

The average PAL of healthy, well-nourished adults is a major determinant of their total energy requirement. As growth does not contribute to energy needs in adulthood, PAL can be measured or estimated from the average 24-hour TEE and BMR (i.e. PAL = TEE/BMR). Multiplying the PAL by the BMR gives the actual energy requirements. For example, a male with a PAL of 1.75 and a mean BMR of 7.10 MJ/day (1 697 kcal/day) would have a mean energy requirement of 1.75 × 7.10 = 12.42 MJ/day (2 970 kcal/day).[4] Other examples of these calculations are shown at the bottom of each panel in Table 5.1.

PAL has been calculated in several studies from measurements of TEE and measurements or estimates of BMR. Most of the existing data on the TEE of adults are from studies in industrialized societies, although some investigations have been done in developing countries where many people have lifestyles associated with levels of physical activity that differ from those in industrialized countries (Coward, 1998). A meta-analysis of studies that involved a total of 411 men and women from 18 to 64 years of age showed a modal value for PAL of 1.60 (range 1.55 to 1.65) for both men and women (Black et al., 1996). For the most part, subjects were from affluent societies in developed countries. All were healthy, but 13 percent of the women and 9 percent of the men were overweight or obese, with BMI > 30. Typical sub-populations included students, housewives, white-collar or professional workers, and unemployed or retired individuals; only three persons were specifically identified as manual workers. Hence, the authors of the meta-analysis defined the study participants as people with a "predominantly sedentary Western lifestyle". An expert panel of the International Obesity Task Force (IOTF) suggested a somewhat lower PAL range of 1.50 to 1.55 as being representative of sedentary individuals (Erlichman, Kerbey and James, 2001).

The PAL values that can be sustained for a long period of time by free-living adult populations range from about 1.40 to 2.40. This consultation agreed that a desirable PAL includes the regular practice of physical activity at work or in spare time with an intensity and duration that will reduce the risk of becoming overweight and developing a variety of non-communicable chronic diseases usually associated as co-morbidities with obesity. As discussed in section 5.6, this corresponds to PAL values of 1.75 and higher. On the other hand, a minimum "maintenance" energy requirement was not defined, reaffirming the position of the previous expert consultation which stated that "any figure chosen would reflect a value judgement on what levels of activity above the minimum for survival could be appropriately included in the term "maintenance" (WHO, 1985).

5.3.1 Classification of physical activity levels

Energy requirements are highly dependent on habitual physical activity. This consultation classified the intensity of a population’s habitual physical activity into three categories, as was done by the 1981 FAO/WHO/UNU expert consultation (WHO, 1985). However, in contrast with the 1981 consultation, a range of PAL values, rather than a mean PAL value, was established for each category. Furthermore, the same PAL values were used to assign men and women to a PAL category, for the reasons discussed in section 5.1.

The categories shown in Table 5.3 represent the different levels of activity associated with a population’s lifestyle. These categories indicate the physical activity most often performed by most individuals in the population, over a period of time. Although there is no physiological basis for establishing the duration of that period, it may be defined as one month or longer.

The term "lifestyle" was preferred to "occupational work", as was used in the 1985 report, because there are groups of people with light or sedentary occupations who perform vigorous discretionary activities regularly, and therefore have a lifestyle that falls more appropriately within the "active" or "vigorously active" categories. It should also be borne in mind that some populations undergo cyclic changes in lifestyle, such as those related to the agricultural cycle among traditional rural societies, or those related to the seasons of the year where hot or mild summers alternate with cold winters. Energy requirements of such populations will change with the energy demands of their cyclical lifestyles.

TABLE 5.3
Classification of lifestyles in relation to the intensity of habitual physical activity, or PAL

Category

PAL value

Sedentary or light activity lifestyle

1.40-1.69

Active or moderately active lifestyle

1.70-1.99

Vigorous or vigorously active lifestyle

2.00-2.40*

* PAL values > 2.40 are difficult to maintain over a long period of time.

5.3.2 Examples of lifestyles with different levels of energy demands

Sedentary or light activity lifestyles. These people have occupations that do not demand much physical effort, are not required to walk long distances, generally use motor vehicles for transportation, do not exercise or participate in sports regularly, and spend most of their leisure time sitting or standing, with little body displacement (e.g. talking, reading, watching television, listening to the radio, using computers). One example is male office workers in urban areas, who only occasionally engage in physically demanding activities during or outside working hours. Another example are rural women living in villages that have electricity, piped water and nearby paved roads, who spend most of the time selling produce at home or in the marketplace, or doing light household chores and caring for children in or around their houses.

Active or moderately active lifestyles. These people have occupations that are not strenuous in terms of energy demands, but involve more energy expenditure than that described for sedentary lifestyles. Alternatively, they can be people with sedentary occupations who regularly spend a certain amount of time in moderate to vigorous physical activities, during either the obligatory or the discretionary part of their daily routine. For example, the daily performance of one hour (either continuous or in several bouts during the day) of moderate to vigorous exercise, such as jogging/running, cycling, aerobic dancing or various sports activities, can raise a person’s average PAL from 1.55 (corresponding to the sedentary category) to 1.75 (the moderately active category). Other examples of moderately active lifestyles are associated with occupations such as masons and construction workers, or rural women in less developed traditional villages who participate in agricultural chores or walk long distances to fetch water and fuelwood.

Vigorous or vigorously active lifestyles. These people engage regularly in strenuous work or in strenuous leisure activities for several hours. Examples are women with non-sedentary occupations who swim or dance an average of two hours each day, or non-mechanized agricultural labourers who work with a machete, hoe or axe for several hours daily and walk long distances over rugged terrains, often carrying heavy loads.

Extremes of low and high PALs. Extremely low levels of energy expenditure allow for survival, but they are not compatible with long-term health, moving around freely, or earning a living. Such levels have been reported, for example, in elderly mental patients (Prentice et al., 1989), adolescents with cerebral palsy or myelodysplasia (Bandini et al., 1991) and resting adults confined to a whole body calorimeter (Ravussin et al., 1991; Schulz et al., 1992). The mean PAL of 1.21, which is similar to the baseline energy need of 1.27 estimated in the 1985 report, is suggested for short-term survival of totally inactive dependent people in conditions of crisis (WHO, 1985). The present consultation felt that such a value is too low and should not be used in emergency relief programmes, as people are not completely inactive in situations of crisis and the various stresses that impinge on them may increase their energy demands. The consultation hence suggests that food supplies to satisfy a PAL of 1.40, which represents the lower limit of the sedentary lifestyle range shown in Table 5.3, would be more appropriate for short-term relief interventions.

At the other end of the scale, studies have shown PAL values as high as 4.5 to 4.7 during three weeks of competitive cycling (Westerterp et al., 1986), or hauling sleds across the Arctic (Stroud, Coward and Sawyer, 1993). However, such levels of energy expenditure are not sustainable in the long term.


[4] When the averages of the PAL and of the BMR of a population are known, the average energy requirement of the population can be estimated.

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