nutrients

Article

Ageing Is Associated with Decreases in Appetite and
Energy Intake—A Meta-Analysis in Healthy Adults

Caroline Giezenaar 1, Ian Chapman 1, Natalie Luscombe-Marsh 1,2, Christine Feinle-Bisset 1,
Michael Horowitz 1 and Stijn Soenen 1,*

Received: 9 November 2015; Accepted: 22 December 2015; Published: 7 January 2016

1 Discipline of Medicine, National Health and Medical Research Council of Australia (NHMRC) Centre of
Research Excellence in Translating Nutritional Science to Good Health, the University of Adelaide,
5000 Adelaide, Australia; caroline.giezenaar@adelaide.edu.au (C.G.); ian.chapman@adelaide.edu.au (I.C.);
natalie.luscombe-marsh@csiro.au (N.L.-M.); christine.feinle@adelaide.edu.au (C.F.-B.);
michael.horowitz@adelaide.edu.au (M.H.)

2 Commonwealth Scientific and Industrial Research Organisation (CSIRO), Food and Nutrition,
5000 Adelaide, Australia

* Correspondence: stijn.soenen@adelaide.edu.au; Tel.: +61-8-8313-3638; Fax: +61-8-8223-3870

Abstract: It is not well recognized that in the elderly weight loss is more common than weight gain.
The aim of this analysis was to determine the effect of ageing on appetite (hunger/fullness) and
energy intake, after overnight fasting and in a postprandial state, by meta-analyses of trials that
included at least two age groups (>18 years). We hypothesized that appetite and energy intake would
be less in healthy older compared with younger adults. Following a PubMed-database systematic
search up to 30 June 2015, 59 studies were included in the random-effects-model meta-analyses.
Energy intake was 16%–20% lower in older (n = 3574/~70 years/~71 kg/~25 kg/m2) than younger
(n = 4111/~26 years/~69 kg/~23 kg/m2) adults (standardized mean difference: ´0.77 (95%
confidence interval ´0.90 to ´0.64)). Hunger was 25% (after overnight fasting; weighted mean
difference (WMD):´17 (´22 to´13) mm) to 39% (in a postprandial state; WMD:´14 (´19 to ´9) mm)
lower, and fullness 37% (after overnight fasting; WMD: 6 mm (95% CI: 1 to 11 mm)) greater in older
than younger adults. In conclusion, appetite and energy intake are less in healthy older than younger
adults, suggesting that ageing per se affects food intake.

Keywords: ageing; energy intake; appetite; hunger; fullness; elderly

1. Introduction

The world population is ageing rapidly. For example, the proportion of the world’s population
over 60 years will double from 11% to 22% between 2000 and 2050. As healthcare costs are incurred
largely by older people, this will have dramatic societal impacts, so that, largely as a result of population
ageing, it is projected that government spending in Australia on health will increase tenfold per capita
by 2055 [1]. Reducing morbidity in the older population is, accordingly, a major public health goal.
A very large proportion of the increases in healthcare costs are accounted for by increasing rates
and duration of hospital admissions in older people. During hospitalisation, nutritional status often
declines in older patients, due to a lack of adequate energy intake [2].

It is often not recognized that after age ~65 years weight loss, particularly lean tissue, is more
common than weight gain—this has been well documented in cross-sectional and longitudinal
studies [3–8]. In the elderly, both low body weight and weight loss are strong predictors of poor
outcomes [7,9], including the development of pathological undernutrition and sarcopenia and reduced
functional capacity and frailty [10]. Data form animal studies suggest that caloric restriction, and
probably more importantly diet composition, play a role in longevity by reducing the risk of developing

Nutrients 2016, 8, 28; doi:10.3390/nu8010028 www.mdpi.com/journal/nutrients

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Nutrients 2016, 8, 28 2 of 22

type 2 diabetes, hypertension, cardiovascular disease and cancer, which may be related to the body
composition during life, i.e., less fat and more lean tissue [11,12]. The loss of body weight in older
people is usually associated with disproportionate loss of lean body tissue, with average decreases
of up to 3 kg of lean body mass, mainly skeletal muscle, per decade after the age of ~50 years [13].
Furthermore, the adverse effects of overweight and obesity are much less in older than young adults,
so that the body mass index (BMI) associated with maximum life expectancy increases with age;
~27–30 kg/m2 in people over 65 years compared to 20–25 kg/m2 in younger adults [14]. There is no
sound evidence that in people over 70 years a BMI > 30 kg/m2 is associated with any reduction in life
expectancy. Consistent with this, the lower end of the “optimum” BMI range is higher in older than
young adults at about 22 kg/m2 [15].

Weight loss in older people occurs because there is a decrease in daily energy intake [16],
which is greater than the decrease in energy expenditure [17]. The decrease in energy intake,
and the reduction in appetite which underlies it, has been called the “physiological anorexia of
ageing” [18,19]. The reduction in energy expenditure in the elderly is due to reduced physical
exercise, loss of energy-demanding lean tissue, and decreased metabolic cost of metabolizing the
smaller amount of consumed food [20–22]. The American National Health and Nutrition Examination
Survey (NHANES) III cross sectional studies reported a decline in energy intake, between the ages of
20–29 and 70–79 years, of 38% (1138 kcal/day) in men and 27% (522 kcal/day) in women and energy
intake measured with 24-h recall interviews [5]. We recently showed that energy intake was 16%
lower in older than younger men, when energy intake was measured with a more accurate technique:
of a single ad libitum buffet-style meal at the research facility [23].

An important strategy for maintaining good health in older people is the prevention and
management of weight loss in the elderly. It is important, therefore, to accurately characterise this
problem. Many of the studies in the area have used different methods to measure energy intake and
included relatively few subjects, so there is benefit in combining these data. The aim of this analysis
was to determine (i) the magnitude of decrease in energy intake and appetite by ageing; (ii) whether
the age-effect on energy intake is present both after overnight fasting and in the postprandial state; and
(iii) whether the age-effect on energy intake is affected by the method of energy-intake measurement,
by meta-analyses of studies which included two age groups of healthy (younger and older) adults.
We hypothesized that appetite and energy intake would be ~20%–25% less in healthy older when
compared with younger adults.

2. Experimental Section

2.1. Search Strategy, Study Selection, Data Extraction and Quality Assessment

We performed a search of English-language publications in the PubMed database for studies that
reported original data of appetite and/or energy (food) intake in “healthy” adults up to 30 June 2015.
We used “ageing/aging” in combination with “appetite”, “hunger”, “fullness”, and “food/energy
intake” as keywords (search terms: (“aging” (MeSH Terms) OR “aging” (All Fields) OR “ageing”
(All Fields)) AND (“appetite” (MeSH Terms) OR “appetite” (All Fields)); (“aging” (MeSH Terms)
OR “aging” (All Fields) OR “ageing” (All Fields)) AND (“hunger” (MeSH Terms) OR “hunger” (All
Fields)); (“aging” (MeSH Terms) OR “aging” (All Fields) OR “ageing” (All Fields)) AND fullness
(All Fields); (“aging” (MeSH Terms) OR “aging” (All Fields) OR “ageing” (All Fields)) AND “energy
intake” (All Fields); (“aging” (MeSH Terms) OR “aging” (All Fields) OR “ageing” (All Fields)) AND
“food intake” (All Fields)) with filters for animal and non-English publications. We searched for
a broad and heterogeneous range of studies, and not only intervention studies, reporting data on
appetite and energy intake in both younger and older adults. These data are often reported as
“subject characteristics” at baseline, particularly in the case of energy intake, and not as primary study
outcomes. Two researchers (CG and SS) performed screening of studies by titles and abstracts and,
subsequently, full texts. References from the retrieved publications and bibliographies of relevant



Nutrients 2016, 8, 28 3 of 22

reviews were checked to identify potential additional articles. Studies were included if they reported
mean ˘ SD/SEM energy intake (kcal) and/or appetite (i.e., hunger and/or fullness) of at least two
age groups—“younger” and “older” adults. Study subjects were required to be “healthy” and at least
18 years old, without using age restrictions in defining the “younger” and “older” age groups. Usually
the older groups were made up of people over 60–65 years. Animal studies and non-English
publications were excluded. Characteristics were extracted from the original reports using a
standardized data extraction form. When SD’s or SEM’s of appetite or energy intake were missing in
the publication or it was stated that these data were measured but not given, the investigators were
contacted by e-mail with a request to provide these data—requested and received twice regarding
data of appetite and once requested but not received regarding data of energy intake. We recorded the
study’s author(s), year of publication, study design, number and gender distribution of the participants,
and mean ˘ SD: age (years), body weight (kg), body mass index (BMI, kg/m2) for both age groups
(Table 1). The usual quality filters for randomized trials or observational epidemiologic studies did not
apply since the primary aim of this meta-analysis was to determine the magnitude of decrease in energy
intake and appetite by ageing rather than to determine the effect of an intervention. We determined
whether studies reported inclusion and exclusion criteria and data on attrition, and whether potential
confounders were considered, for example whether the younger and older groups were matched for
body weight and/or BMI. When data of interventions were used, we reported whether randomization
of study conditions was used and whether the study subjects and research personnel were blinded.
This meta-analysis is reported in accordance with the recommendations and criteria outlined in the
Preferred Reporting Items for Systematic Reviews and Meta-Analysis (PRISMA) statement [24].

2.2. Data Analysis

Meta-analyses were performed with REVMAN software (Version 5.2; the Cochrane Collaboration
Oxford, UK) using the DerSimonian and Laird random-effects model with a 95% confidence interval,
to account for measurement variability among the included studies. For this analysis, the number of
participants’ means and SD’s of energy intake and hunger and fullness were extracted for both age
groups, i.e., younger and older adults. For all data, the SD’s were calculated, when necessary, from SE’s,
and when data were not provided in numerical form they were estimated from the figures. Cochran’s
test for heterogeneity was used to determine whether the studies included in the meta-analysis were
evaluating the same underlying sizes of effect. A threshold of p < 0.1 was used to decide whether
heterogeneity (genuine variation in effect sizes) was present. I2, an estimate of the proportion of total
observed variability that is due to genuine variation rather than random error within studies, was
used to quantify the degree of inconsistency among studies; it was considered substantial when it
was >50% [25]. Sensitivity analyses were performed on studies that may cause bias in the results.
Differences in energy intake between younger and older adults were analysed using standardized
mean differences (SMD’s). The SMD is used when it is necessary to standardize the results of several
studies to a uniform scale—when studies assess the same outcome (e.g., energy intake) but measure it
in a variety of ways (e.g., kcal/meal or kcal/day for energy intake). The SMD expresses the size of the
effect in each study relative to the variability observed in that study. The SMD is calculated by dividing
the difference in mean outcome between groups (younger and older adults) by the SD of outcome
among participants [25]. Data relating to hunger and fullness were defined as mean difference between
the younger and older adults. Percentage differences between the younger and older adults for the
outcomes were calculated for each study and averaged.



Nutrients 2016, 8, 28 4 of 22

Table 1. Studies included in the meta-analysis.

Study (No in References) N Young/Older Age (Years)
Young/Older

Mean Body Mass (kg)
Young/Older

Mean BMI (kg/m2)
Young/Older

Outcomes Used for Meta-Analysis

Alam et al. 2012 [26] 131/526 34 ˘ 9/69 ˘ 6 62.4 ˘ 13.5/63.5 ˘ 10.2 † 23.2 ˘ 2.2/22.3 ˘ 1.7 † Energy intake of 24-h food intake recalls

Apolzan et al. 2009 [27] 24/32 25 ˘ 5/71 ˘ 6 75.5 ˘ 21.1/74.1 ˘ 18.7 † 25.2 ˘ 3.9/26.0 ˘ 5.1 † Energy intake of 24-h food intake recalls

Arciero et al. 2009 [28] 0 M; 10 F/0 M; 10 F 19 ˘ 2/55 ˘ 5 62.5 ˘ 7.3/72.1 ˘ 9.4 * Energy intake of 3-day weighed food records

Bell et al. 2003 [29] 7 M; 5 F/12 M; 9 F 23 ˘ 3/68 ˘ 5 70.4 ˘ 11.8/77.2 ˘ 13.7 † 23.7 ˘ 2.4/26.6 ˘ 3.7 * Energy intake of 4-day weighed food records

Cheng et al. 1978 [30] 8 M; 0 F/7 M; 0 F 26 ˘ 3/67 ˘ 5 66.5 ˘ 7.2/61.6 ˘ 11.3 † Energy intake of weighed food records

Church et al. 1984 [31] 7 M; 8 F/6 M; 8 F 20-35/36-53 45.0-95.3/52.6-85.4 Energy intake of weighed food records

Clarkston et al. 1997 [32] 10 M; 9 F/5 M; 9 F 30 ˘ 35/76 ˘ 19 25.3 ˘ 3.4/25.2 ˘ 1.7 † Hunger/fullness during fasting and postprandial
(456 kcal oral mixed nutrient preload) conditions

Cook et al. 1997 [33],
MacIntosh et al. 1999 [34] # 7 M; 0 F/8 M; 0 F 27 (20–34)/70 (65–75) 26.8 (24.4–31.8)/25.8

(18.2–30) †

- Energy intake of 5-day weighed food records
- Energy intake during postprandial conditions ‡
(348 kcal intraduodenal lipid infusion)
- Hunger/fullness during fasting conditions

Davy et al. 2001 [35] 6 M; 0 F/5 M; 0 F 25 ˘ 2/63 ˘ 7 79.0 ˘ 7.3/82.0 ˘ 8.9 † Energy intake of 4-day weighed food records

Di Francesco et al. 2010 [36] 6 M; 6 F/5 M; 7 F 28 ˘ 2/75 ˘ 6 18.9–26.5/21.1–28.3 † Hunger during fasting and postprandial (800 kcal
oral mixed nutrient preload) conditions ˆ

Di Francesco et al. 2006 [37] 4 M; 4 F/4 M; 4 F 30 ˘ 3/78 ˘ 3 22.7–25.7/22.1–29.4 † Hunger/fullness during fasting and postprandial
(800 kcal oral mixed nutrient preload) conditions

Di Francesco et al. 2005 [38] 5 M; 4 F/5 M; 5 F 32 ˘ 8/77 ˘ 3 22.7–28.1/23.5–29.3 Hunger/fullness during fasting and postprandial
‡ (800 kcal oral mixed nutrient preload) conditions

Drewnowski et al. 1996 [39] 12 M; 12 F/12 M; 12 F 23 ˘ 1/67 ˘ 2 22.7 ˘ 1.0/24.5 ˘ 1.2 Energy intake of 14-day weighed food records

Flint et al. 2008 [40] 16 M; 14 F/16 M; 14 F 25 ˘ 4/68 ˘ 5 71.0 ˘ 10.4/73.8 ˘ 17.0 † 24.6 ˘ 2.2/24.7 ˘ 2.2 † Energy intake of 4-day weighed food records

Fukagawa et al. 1990 [20] 6 M; 0 F/6 M; 0 F 21 ˘ 2/72 ˘ 7 Energy intake of 14-day dietary recalls

Giada et al. 1995 [41] 24 M; 0 F/24 M; 0 F 24 ˘ 4/57 ˘ 6 23.7 ˘ 2.4/26.8 ˘ 2.5 † Energy intake of 7-day weighed food records

Howarth et al. 2007 [42] 1021 M; 771 F/491 M;
402 F 39 ˘ 17/71 ˘ 12 25.2 ˘ 4.2/25.4 ˘ 6.0 † Energy intake of 24-h food intake recalls

Ishikawa et al. 1999 [43] 53 M; 16 F/50 M; 32 F 30-49/50-69 69.2 ˘ 10.4/62.9 ˘ 8.6 25.2 ˘ 3.0/25.0 ˘ 2.7 Energy intake of 2-day weighed food records



Nutrients 2016, 8, 28 5 of 22

Table 1. Cont.

Study (No in References) N Young/Older Age (Years)
Young/Older

Mean Body Mass (kg)
Young/Older

Mean BMI (kg/m2)
Young/Older

Outcomes Used for Meta-Analysis

Keene et al. 1998 [44] 7 M; 5 F/4 M; 6 F 25/75 Energy intake during postprandial conditions ‡
(447 kcal oral mixed nutrient preload)

Kos et al. 1996 [45] 0 M; 38 F/0 M; 17 F 29 ˘ 3/59 ˘ 4 61.6 ˘ 9.7/57.4 ˘ 8.3 † 21.7 ˘ 3.1/21.8 ˘ 2.8 † Energy intake of 4-day weighed food records

Lieberman et al. 1989 [46] 21 M; 20 F/21 M; 24 F 26 (20–35)/73 (65–95) Energy intake of 4-day weighed food records

Macintosh et al. 2001 [47] 5 M; 7 F/5 M; 7 F 23 (20-26)/72 (65-84) 24.7 ˘ 2.4/25.0 ˘ 1.7 †
- Energy intake during fasting conditions ‡
- Energy intake of 3-day weighed food records
- Hunger/fullness during fasting conditions

Macintosh et al. 2001 [48] 6 M; 6 F/6 M; 6 F 23 ˘ 4/71 ˘ 5 23.5 ˘ 2.8/24.1 ˘ 2.4 †
- Energy intake during fasting conditions ‡
- Energy intake of 3-day weighed food records
- Hunger during fasting conditions

Macintosh et al. 2001 [49] 13 M; 0 F/13 M; 0 F 24 ˘ 5/72 ˘ 6 23.9 ˘ 2.2/23.5 ˘ 3.6 †

- Energy intake during postprandial conditions ‡
(347 kcal intraduodenal lipid infusion)
- Energy intake of 3-day weighed food records
- Hunger/fullness during postprandial conditions
‡ (347 kcal intraduodenal lipid preload)

McGandy et al. 1966 [50] 13 M; 0 F/37 M; 0 F 20-34/75-99 74.5 ˘ 1.2/70.9 ˘ 1.0 Energy intake of 7-day weighed food records

Morais et al. 2000 [51] 4 M; 3 F/3 M; 5 F 28 ˘ 5/72 ˘ 3 63.5 ˘ 10.6/64.2 ˘ 10.2 † 21.4 ˘ 2.1/24.8 ˘ 3.1 * Energy intake of 6-day weighed food records

Morais et al. 1997 [52] 8 M; 7 F/8 M; 8 F 28 ˘ 5/73 ˘ 5 62.6 ˘ 7.4/64.1 ˘ 8.7 † 21.2 ˘ 1.8/23.8 ˘ 3.2 * Energy intake of 6-day weighed food records

Moriguti et al. 2000 [53] 5 M; 6 F/9 M; 9 F 26 ˘ 3/68 ˘ 3 65.6 ˘ 9.6/80.0 ˘ 14.9 * 23.2 ˘ 1.6/27.5 ˘ 3.4 * Energy intake of provided food items (7 days)

Nagengast et al. 1988 [54] 5 M; 6 F/6 M; 5 F 22 ˘ 6/67 ˘ 5 67.6 ˘ 5.0/69.1 ˘ 12.3 † Food intake recalls

Poehlman et al. 1990 [55] 42 M; 0 F/26 M; 0 F 25 ˘ 5/67 ˘ 5 75.5 ˘ 10.7/78.4 ˘ 7.6 † Energy intake of 3-day weighed food records

Polito et al. 2005 [56] 48 M; 47 F/103 M; 96 F 61 ˘ 4/74 ˘ 4 71.5 ˘ 8.1/67.9 ˘ 9.0 26.1 ˘ 2.4/25.3 ˘ 2.7 Energy intake of 4-day weighed food records

Rayner et al. 2000 [57] 5 M; 0 F/5 M; 0 F 23 (22–27)/71 (68–73) 24.4 (20.7–31.2)/25.6
(22.4–30.7)

- Energy intake during fasting conditions ‡
- Hunger/fullness during fasting conditions ˆ

Roberts et al. 1996 [58] 7 M; 0 F/9 M; 0 F 24 ˘ 1/70 ˘ 7 76.2 ˘ 12.4/72.9 ˘ 9.3 † 23.9 ˘ 3.4/23.4 ˘ 3.3 † Energy intake of provided food items (10 days)

Roberts et al. 1994;
1995 [22,59] # 17 M; 0 F/18 M; 0 F 23 ˘ 2/68 ˘ 6 71.6 ˘ 11.1/78.8 ˘ 12.6 23.4 ˘ 2.6/25.2 ˘ 3.6 Energy intake of provided food items (7 days)

Rolls et al. 1995 [60] 16 M; 0 F/16 M; 0 F 24 ˘ 5/69 ˘ 6 74.0 ˘ 7.2/84.3 ˘ 12.8 * 22.7 ˘ 2.0/26.2 ˘ 3.6 *

- Energy intake during fasting and postprandial
(510 kcal oral mixed nutrient preload) conditions
- Hunger/fullness during fasting and
postprandial ‡ (510 kcal oral mixed nutrient
preload) conditions



Nutrients 2016, 8, 28 6 of 22

Table 1. Cont.

Study (No in References) N Young/Older Age (Years)
Young/Older

Mean Body Mass (kg)
Young/Older

Mean BMI (kg/m2)
Young/Older

Outcomes Used for Meta-Analysis

Rolls et al. 1991 [61] 12 M; 12 F/12 M; 12 F 26 ˘ 4/75 ˘ 5 68.9 ˘ 3.0/66.0 ˘ 3.2 23.5 ˘ 3.0/24.1 ˘ 2.8 Hunger/fullness during fasting conditions

Sawaya et al. 2001 [62] 9 M; 0 F/10 M; 0 F 23 ˘ 1/69 ˘ 1 72.9 ˘ 2.7/74.7 ˘ 3.4 † 22.7 ˘ 0.5/24.4 ˘ 0.9 † Hunger during fasting conditions

Sawaya et al. 1996 [63] 0 M; 10 F/0 M; 10 F 25 ˘ 4/74 ˘ 4 54.8 ˘ 4.1/58.7 ˘ 9.8 † 20.9 ˘ 1.9/24.1 ˘ 2.8 * Energy intake of 7-day weighed food records

Schneider et al. 2008 [64] 5 M; 5 F/3 M; 6 F 34 ˘ 8/76 ˘ 9 22.5 ˘ 2.9/23.6 ˘ 1.8 † Hunger/fullness during fasting conditions ‡

Serra-Prat et al. 2013 [65] 7 M; 12 F/13 M;7 F 38 ˘ 11/81 ˘ 8 67.3 ˘ 9.0/72.6 ˘ 16.2 23.7 ˘ 2.8/27.9 ˘ 4.9 † - Hunger during fasting and postprandial ‡
(400 kcal oral mixed nutrient preload) conditions

Serra-Prat et al. 2009 [66] 7 M; 10 F/6 M; 4 F 40 ˘ 10/80 ˘ 8 25.2 ˘ 3.3/26.7 ˘ 3.0 † - Hunger during fasting and postprandial ‡
(380 kcal oral mixed nutrient preload) conditions

Soenen et al. 2014 [23] 10 M; 0 F/10 M; 0 F 23 ˘ 4/74 ˘ 4 73 ˘ 7/79 ˘ 7 † 22 ˘ 2/26 ˘ 2 *

- Energy intake during fasting and postprandial
(180 kcal intraduodenal protein infusion)
- Hunger/fullness during fasting and postprandial
(180 kcal intraduodenal protein infusion)
conditions

Stafleu et al. 1994 [67] 0 M; 97 F/0 M; 97 F 25 ˘ 3/76 ˘ 6 64.2 ˘ 10.6/70.5 ˘ 10.7 22.5 ˘ 3.5/26.8 ˘ 4.1 Energy intake of food frequency questionnaires

Sturm et al. 2004 [68] 6 M; 6 F/6 M; 6 F 24 ˘ 1/74 ˘ 1 23.2 ˘ 2.1/24.1 ˘ 3.5 †

- Energy intake during fasting and postprandial ‡
(750 kcal oral mixed nutrient preload) conditions
- Energy intake of 3-day weighed food records
- Hunger/fullness during fasting and
postprandial ‡ (750 kcal oral mixed nutrient
preload) conditions

Sturm et al. 2003 [69] 0 M; 8 F/0 M; 8 F 22 ˘ 4/77 ˘ 3 57.5 ˘ 5.4/58.0 ˘ 5.9 † 20.5 ˘ 1.1/23.7 ˘ 2.3 *

- Energy intake during fasting and postprandial
(280 kcal oral mixed nutrient preload) conditions
- Energy intake of 3-day weighed food records
- Hunger/fullness during fasting and postprandial
(280 kcal oral mixed nutrient preload) conditions ‡

Surrao et al. 1998 [70] 0 M; 10 F/0 M; 10 F 25 ˘ 4/74 ˘ 4 54.8 ˘ 4.1/58.7 ˘ 9.8 † 20.9 ˘ 1.9/24.1 ˘ 2.5 * Energy intake of a 7-day weighed food record

Temme et al. 2010 [71] 413 M; 460 F/389 M;
355 F

Energy intakes of 24-h food intake recalls and
food frequency questionnaires

Toth et al. 1996 [72] 18 M; 0 F/30 M; 0 F 23 ˘ 4/69 ˘ 5 79 ˘ 8/75 ˘ 5 † Energy intake of 3-day weighed food records

Van Pelt et al. 2001 [73] 71 M; 0 F/66 M; 0 F 27 ˘ 8/62 ˘ 8 75.1 ˘ 16.0/77.4 ˘ 16.2 23.4 ˘ 4.7/25.1 ˘ 4.4 Energy intake of 4-day weighed food records



Nutrients 2016, 8, 28 7 of 22

Table 1. Cont.

Study (No in References) N Young/Older Age (Years)
Young/Older

Mean Body Mass (kg)
Young/Older

Mean BMI (kg/m2)
Young/Older

Outcomes Used for Meta-Analysis

Van Walleghen et al.
2007 [74] 14 M; 15 F/11 M; 10 F 25 ˘ 5/69 ˘ 9 67.9 ˘ 1.7/70.8 ˘ 2.9 23.3 ˘ 3.7/24.7 ˘ 3.2

- Energy intake during fasting conditions ‡
- Energy intake of 4-day weighed food records
- Hunger/fullness during fasting conditions

Van Walleghen et al.
2007 [75] 14 M; 15 F/13 M; 12 F 24 ˘ 5/68 ˘ 10 67.6 ˘ 15.5/71.1 ˘ 16.5 23.3 ˘ 4.3/24.6 ˘ 3.8

- Energy intake during fasting and postprandial
(476 kcal for males and 360 kcal for females oral
mixed nutrient preloads) conditions
- Energy intake of 4-day weighed food records
- Hunger/fullness during fasting and postprandial
(476 kcal for males and 360 kcal for females oral
mixed nutrient preload) conditions ‡
- Hunger/fullness during fasting conditions

Vaughan et al. 1991 [21] 33 M; 31 F/17 M; 21 F 24 ˘ 4/71 ˘ 6 84.5 ˘ 23.1/71.2 ˘ 13.5 * Energy intake of provided food items (1 day)

Winkels et al. 2010 [76] 15 M; 0 F/17 M; 0 F 24 (20–34)/68(64–85) 75.8 ˘ 11.3/75.8 ˘ 7.6 23.0 ˘ 2.3/24.5 ˘ 1.9 Energy intake of provided food items (14 days)

Wolk et al. 2004 [77] 72 M; 0 F/94 M; 0 F 42–54/65–76 25.6 ˘ 2.7/26.5 ˘ 3.7 Energy intake of 24-h food intake recalls

Wright et al. 1995 [78] 41 M; 42 F/28 M; 43 F 20–64/74–90 70.1 ˘ 10.4/64.8 ˘ 10.1 Energy intake of 7-day weighed food records

Wurtman et al. 1988 [79] 21 M; 20 F/21 M; 24 F 26 (19–35)/72 (65–94) Energy intake of provided food items (5 days)

Yukawa et al. 2006 [80] 8 M; 13 F/7 M; 11 F 25 ˘ 5/75 ˘ 4 72.9 ˘ 12.4/73.6 ˘ 12.7 † 24.7 ˘ 3.0/26.9 ˘ 3.0 * Energy intake of provided food items (14 days)

Zandstra et al. 2000 [81] 5 M; 28 F/6 M; 18 F 22 ˘ 2/76 ˘ 5 71.0 ˘ 9.6/72.4 ˘ 8.9 23.3 ˘ 2.3/26.6 ˘ 3.5
Energy intake during fasting and postprandial
(502 kcal for young subjects) or 430 kcal for older
subjects oral mixed nutrient preload) conditions ‡

Zhou et al. 2013 [82] 49 M; 10 F/15 M; 21 F 20–29/50–59 59.0 ˘ 10.8/69.0 ˘ 12.3 21.7 ˘ 3.0/24.6 ˘ 3.1 Fullness during fasting and postprandial (896 kcal
oral mixed nutrient preload) conditions

M, male; F, female; BMI, body mass index; All values are mean ˘ SD (range; when SD was not reported); # Studies reported same data; * p < 0.05, older compared with young;
† p > 0.05, older compared with young, When blank the significance of the comparison of body weight and/or BMI between older and young adults had not been reported; ‡ Data
were extracted from graphs, by creating a scale according to the y-axis, and measuring mean and SD/SEM with a ruler; ˆ Data were provided by the investigators upon request.



Nutrients 2016, 8, 28 8 of 22

3. Results

The Pubmed search identified 5044 potential articles. The review flow diagram is, following
the recommendations of the PRISMA statement [24], depicted in Figure 1. We screened 2703 titles
or abstracts following exclusion of 2341 animal studies or non-English articles. We screened
88 publications in full text of which 59 studies fulfilled the inclusion criteria. There were seven
studies that included more than two age groups [54,61,67,71,77,78,81]—we extracted the data of energy
intake and/or appetite of the youngest (ě18 years) and oldest age group for each of these studies.
There were 14 studies that presented data of multiple groups within the younger and older study
groups [31,39,41,43,46,52,55,56,73–75,78,79,83], i.e., gender, country, and/or level of physical
activity—we combined the male and female or country or level of physical activity groups by
calculating their mean energy intake/appetite score and pooling their SD’s to create a single
pair-wise comparison.

No studies were excluded based on quality of study, although many studies did not
report sufficient information for a clear bias assessment. All studies, except four [26,45,46,50],
reported inclusion and/or exclusion criteria, and stated that the participants met these
criteria. Of the studies measuring energy intake (49 studies), 18 studies matched the younger
and older participants for body weight [23,26,27,29,30,35,40,45,51,52,54,58,63,69,70,72,76,80] and
13 studies for BMI [26,27,33,40–42,45,47–49,58,68,76] and 11 studies considered gender as a
confounder [31,39,43,46,47,52,56,71,75,78,79]. No studies considered confounders for hunger
or fullness.

In crossover studies (17 studies [23,33,36,44,47–49,57,60–62,68,69,74,75,81,82]), selection bias and
performance bias were possible sources of bias. Thirteen studies [23,33,47–49,57,60,68,69,74,75,81,82]
were randomized, of which one [23] detailed a method through random numbers, in the other six,
randomization was not discussed. No studies reported the use of allocation concealment. Performance
bias scored worse, three studies were double-blind [23,47,60] and two single-blind [44,49], in the other
12 blinding was not discussed. In the studies measuring energy intake over a prolonged period of
time, all studies, except two [58,59], had a method to check compliance.

 

Records screened by title and abstract: (n = 2703): 

- Ageing and appetite (n = 427) 

- Ageing and hunger (n = 268) 

- Ageing and fullness (n = 70) 

- Ageing and “food intake” (n = 561) 

- Ageing and “energy intake” (n = 1377) 

Studies included in the meta-analysis (n = 59) 

Used for hunger (n = 20) 

Used for fullness (n = 16) 

Used for energy intake (n = 49) 

Full-text articles assessed for eligibility (n = 88) 

Records excluded (n=29) 

- Studies which did not present data for 

younger and older subjects separately 

- Studies which did not report SD/SEM 

- Studies of which the data were 

published earlier 

- Studies which did not include healthy 

subjects 

Records excluded on basis of title or 

abstract (n=2615) 

Animal studies and non-English 

publications excluded (n = 2341) 

 

 

Records identified through database searching (n = 5044): 

- Ageing and appetite (n = 663) 

- Ageing and hunger (n = 401) 

- Ageing and fullness (n = 77) 

- Ageing and “food intake” (n = 1493) 

- Ageing and “energy intake” (n = 2410) 

Id
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ca
ti

o
n

 
S

cr
ee

n
in

g
 

E
li

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ib

il
it

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Figure 1. Flow diagram for the selection of studies.



Nutrients 2016, 8, 28 9 of 22

3.1. Effect of Age on Energy Intake

Three different methods of measuring energy intake were distinguished: (i) energy intake of a
single ad libitum buffet-style meal at the research facility after overnight fasting (during a “control”
condition; e.g., no preload, water preload or saline intraduodenal infusion [23,47,48]) and in a
postprandial state after a nutrient preload (>0 kcal; range 180 [23]—729 [81] kcal), administered orally
or infused directly into the small intestine (i.e., intraduodenally [23,49])—all intervention crossover
studies; (ii) energy intake of provided food items during a prolonged period (~4 days–2 weeks); and
(iii) energy intake of weighed food records (~3–14 days), 24-h food intake recalls, or food frequency
questionnaires – we used the observational data for energy intake for the latter two categories. There
were three studies measuring energy intake of a buffet-style meal in a postprandial state which
consisted of multiple nutrient-preload conditions [23,49,60]—we extracted the energy intake data of
the condition which had the largest effect to suppress energy intake by the nutrient ingestion in the
younger-subject group (i.e., the nutrient preload with the highest energy content).

Forty-nine unique studies presented data on energy intake: (i) 10 studies (311 subjects)
reported energy intake of “a buffet-style meal” after overnight fasting [23,47,48,57,60,68,69,74,75,81]
and nine studies (266 subjects) in a postprandial state [23,33,44,49,60,68,69,75,81]—of which six
studies (203 subjects) measured energy intake both after overnight fasting and in a postprandial
state [23,60,68,69,75,81]; (ii) seven studies (339 subjects) reported energy intake “during a prolonged
period” [21,53,58,59,76,79,80]; and (iii) 37 studies (7035 subjects) reported energy intake of
weighed-food records (30 studies [20,28–31,34,35,39–41,43,45–52,55,56,63,68–70,72–75,78], 24-h food
intake recalls (six studies [26,27,42,54,71,77]), or food frequency questionnaires (one study [67])—of
which eight studies also reported energy intake of a buffet-style meal [33,47–49,68,69,74,75].

Twenty-six studies were conducted in the United States [20,21,27–29,31,35,39,40,42,46,
50,53,55,58–60,62,63,70,72–75,78–80], 10 in Europe [41,44,45,54,56,67,71,76,77,81], eight in
Australia [23,34,47–49,68,69], two in Asia [26,43], two in Canada [51,52], and one in Chile [30].
The oldest study was published in 1966 [50] and the most recent in 2014 [17]. The largest study
included 2685 subjects [42] and the smallest 10 subjects [57]. The mean age of the youngest group
within a study was 19 years (the older group in that study had a mean age of 55 years) [28] and of the
oldest group 77 years (the younger group in that study had a mean age of 22 years) [69].

3.1.1. Energy Intake in the Total Group

In the total group of 7685 subjects, energy intake after overnight fasting was less in the older
(n = 3574, ~70 years, body weight ~71 kg, BMI ~25 kg/m2) than the younger adults (n = 4111,
~26 years, ~69 kg, ~23 kg/m2), with a SMD of ´0.77 (95% CI: ´0.90 to ´0.64) (Figure 2) and significant
heterogeneity (I2 = 76%, p < 0.001). As a group, the older adults had on average 18% ˘ 9% (mean ˘
SD) lower energy intake than the younger adults.

Heterogeneity was not affected by introducing a maximum age of the younger and a minimum
age of the older age groups (I2 = 78%, n = 6620 subjects, p < 0.001); i.e., after excluding studies in
which the mean age or the maximum age, when age was reported as a range, of the younger adult
group was >40 years old (studies excluded: mean age of 61 [56]; age range of 30–49 [43], 42–54 [77],
20–64 [78]) and after excluding studies in which the mean age or the minimum age, when age was
reported as a range, of the older adult group was <65 years old (studies excluded: mean age of 55 [28],
57 [41], 59 [45], 62 [73], 63 [35] years; age range of 36–53 [31], 50–69 [43]). In the studies included in this
sensitivity analysis, energy intake was less in the older than the younger adults with a SMD of ´0.87
(95% CI: ´1.03 to ´0.72). As a group, the older adults (n = 2992) had on average 19% ˘ 9% lower
energy intake than the younger (n = 3628) adults.

Heterogeneity was not affected by excluding the “small-intestinal” studies, i.e., subjects were
intubated with a catheter to deliver the nutrients directly into the small intestine (I2 = 77%, n = 7617,
p < 0.001; three studies excluded [23,47,48]). In the studies included in this sensitivity analysis, energy
intake was less in the older than the younger adults with a SMD of ´0.77 (95% CI: ´0.90 to ´0.63). As



Nutrients 2016, 8, 28 10 of 22

a group, the older adults (n = 3540) had on average 17% ˘ 9% lower energy intake than the younger
(n = 4077) adults.

Study                    Sample size          Energy Intake 
      Mean (SD) 

  Younger/ Older        Younger/ Older 
SMD [95% CI] 

Energy Intake 
Mean (SD) SMD [95% CI] 

       Younger/ Older 

Energy Intake (kcal) of a buffet-style meal (n=13) 

Fasting (10 studies)   Postprandial (10 studies) 
MacIntosh 2001 [47]  12/ 12     1490 (450)/   934 (418)   -1.24 [-2.12, -0.35]*#

MacIntosh 2001 [48]  12/ 12       956 (367)/   645 (306)   -0.89 [-1.73, -0.04]*#

Rayner 2000 [57]  5/ 5     1026 (342)/ 1154 (402)    0.31 [-0.94,   1.56]#

Van Walleghen 2007 [74]  29/ 21       900 (193)/   664 (220)   -1.13 [-1.74, -0.53]*#

Rolls 1995 [60]  16/ 16     1110   (63)/   808   (69)   -4.46 [-5.81, -3.10]*       699 (256)/ 619 (276)  -0.29 [-0.99,  0.40] 
Van Walleghen 2007 [75]  29/ 25       884 (350)/   663 (309)   -0.66 [-1.21, -0.11]*     1099 (353)/ 984 (323)  -0.33 [-0.87,   0.21] 
Sturm 2003 [69]  8/ 8       819 (631)/   574 (331)   -0.46 [-1.46,  0.54]       697 (690)/ 429 (385)  -0.45 [-1.45,  0.54] 
Zandstra 2000 [81]  33/ 24       645 (229)/   598   (98)   -0.25 [-0.78,  0.28]#       645 (229)/ 574   (98)  -0.38 [-0.91,  0.15]# 
Soenen 2014 [23]  10/ 10     1270 (474)/ 1068 (294)   -0.49 [-1.38,  0.40]       851 (509)/ 899 (326)   0.11 [-0.77,  0.98] 
Sturm 2004 [68]  12/ 12     1274 (353)/ 1077 (419)   -0.49 [-1.31,  0.32]       741 (367)/ 812 (367)   0.19 [-0.62,  0.99]# 
Keene 1998 [44]  12/ 10       707 (288)/ 333 (131)  -1.56 [-2.54, -0.58]*# 
MacIntosh 2001 [49]  13/ 13       908 (263)/ 717 (263)  -0.70 [-1.50,  0.09]# 
Cook 1997 [33]  7/ 8       975 (423)/ 854 (453)  -0.26 [-1.28,  0.76]# 

n = 166/ 145         1037/ 819 kcal -0.89 [-1.42, -0.36]*        813/ 691  -0.37 [-0.65, -0.10]* 

     
 

Energy Intake (kcal/24h) during a prolonged period (7 studies) 

Roberts 1996 [58] 7/ 9    3363 (537)/ 2432 (236)   -2.23 [-3.56, -0.90]*
Roberts 1994 [59] 17/ 18    3363 (532)/ 2641 (236)   -1.54 [-2.46, -0.61]*
Winkels 2010 [76]   15/ 17    3418 (550)/ 2700 (430)   -1.43 [-2.22, -0.64]*
Yukawa 2006 [80] 21/ 18     2676 (436)/ 2076 (391)   -1.41 [-2.12, -0.70]*
Vaughan 1991 [21] 64/ 38    2157 (288)/ 1921 (294)   -0.81 [-1.22, -0.39]*
Wurtman 1988 [79] 41/ 45 1   1755 (475)/ 1437 (307)   -0.79 [-1.23, -0.35]*
Moriguti 2000 [53] 11/ 18    2779 (653)/ 2482 (394)   -0.57 [-1.34,  0.20] 

n =176/ 163    2787/ 2241 kcal/24h   -1.09 [-1.42,  -0.76]*

Energy Intake (kcal/24h) of weighed-food records (30 studies), 24-hour food intake recalls (6 studies)&, or food frequency questionnaires (1 study)^ 

Fukagawa 1990 [20]&   6/ 6   3059 (372)/ 1979 (372)  -2.68 [-4.41, -0.95]* 
Morais 1997 [52]   15/ 16   2492 (312)/ 1995 (267)  -1.67 [-2.50, -0.84]* 
Surrao 1998 [70]   10/ 10   2347 (417)/ 1799 (212)  -1.59 [-2.62, -0.55]* 
Morais 2000 [51]   7/ 8   2561 (423)/ 1976 (297)  -1.53 [-2.72, -0.33]* 
Alam 2012 [26]&  131/ 526   2371 (479)/ 1669 (456)  -1.52 [-1.73, -1.31]* 
Toth 1996 [72]  18/ 30   2960 (662)/ 2168 (487)  -1.40 [-2.05, -0.74]* 
Sawaya 1996 [63]  10/ 10   1902 (428)/ 1398 (306)  -1.30 [-2.28, -0.31]* 
MacIntosh 2001 [48]  12/ 12   2347 (686)/ 1700 (242)  -1.21 [-2.10, -0.33]* 
Cook 1997 [33]  7/ 8   2440 (394)/ 1764 (642)  -1.17 [-2.30, -0.05]* 
Drewnowski 1996 [39]  24/ 24   2413 (570)/ 1950 (268)  -1.02 [-1.63, -0.42]* 
Nagengast 1988 [54]&  11/ 11   2329 (564)/ 1842 (335)  -1.01 [-1.91, -0.11]* 
McGandy 1966 [50]  13/ 37   2570 (555)/ 2113 (435)  -0.96 [-1.62, -0.30]* 
Sturm 2004 [68]  12/ 12   2430 (707)/ 1860 (426)  -0.94 [-1.79, -0.09]* 
Van Pelt 2001 [73]  71/ 66   3075 (778)/ 2424 (621)  -0.92 [-1.27, -0.56]* 
MacIntosh 2001 [47]  12/ 12  2734(1035)/ 1982 (523)  -0.89 [-1.73, -0.04]* 
Lieberman 1989 [46]   41/ 45   1755 (475)/ 1437 (307)  -0.74 [-1.23, -0.35]* 
Sturm 2003 [69]   8/ 8   1868 (413)/ 1559 (373)  -0.74 [-1.77,  0.28] 
Poehlman 1991 [55]   42/ 26   2926 (699)/ 2470 (425)  -0.74 [-1.25, -0.23]* 
Temme 2010 [71]  873/ 744   2129 (734)/ 1668 (489)  -0.73 [-0.83, -0.63]* 
Davy 2001 [35]  6/ 5   2605 (387)/ 2325 (331)  -0.70 [-1.95,  0.54] 
Wright 1995 [78]   83/ 71   2127 (543)/ 1816 (484)  -0.60 [-0.92, -0.27]* 
Cheng 1978 [30]   8/ 7   2654 (478)/ 2438 (263)  -0.52 [-1.55,  0.52] 
Church 1984 [31]   15/ 14   2463 (752)/ 2118 (662)  -0.47 [-1.21,  0.27] 
Arciero 2009 [28]   10/ 10   2354 (844)/ 2020 (455)  -0.47 [-1.36,  0.42] 
Howarth 2007 [42]& 1792/ 893 2414(1015)/ 2008 (717)  -0.44 [-0.52, -0.36]* 
Wolk 2004 [77]&    72/ 94   2191 (480)/ 2004 (398)  -0.43 [-0.74, -0.12]* 
Polito 2005 [56]     95/ 199   2059 (452)/ 1902 (345)  -0.41 [-0.66, -0.16]* 
Stafleu 1994 [67]^   97/ 97   2274 (771)/ 1977 (677)  -0.41 [-0.69, -0.12]* 
Apolzan 2009 [27]&   24/ 32   2239 (835)/ 1983 (432)  -0.40 [-0.93,  0.14] 
MacIntosh 2001 [49]   13/ 13   2292 (710)/ 2075 (404)  -0.36 [-1.14,  0.41] 
Van Walleghen 2007 [74]   29/ 21   2202 (652)/ 2011 (471)  -0.32 [-0.89,  0.24] 
Bell 2003 [29]   12/ 21   2095 (613)/ 1892 (651)  -0.31 [-1.02,  0.40] 
Giada 1995 [41]   24/ 24   3014 (740)/ 2809 (615)  -0.30 [-0.87,  0.27] 
Kos 1997 [45]   38/ 17   1996 (686)/ 1825 (531)  -0.26 [-0.84,  0.31] 
Van Walleghen 2007 [75]   29/ 25   2153 (674)/ 2000 (475)  -0.26 [-0.79,  0.28] 
Flint 2008 [40]   30/ 30   2129 (641)/ 2013 (547)  -0.19 [-0.70,  0.32] 
Ishikawa 1999 [43]   69/ 82   1925 (401)/ 1892 (520)  -0.07 [-0.39,  0.25] 

n = 3769/ 3266 2376/ 1969 kcal/24h  -0.69 [-0.84, -0.55]* 

    All studies      4111/ 3574  -0.77 [-0.90, -0.64]* 

    

Higher Older compared to Younger: 

Lower Older compared to Younger: 
Fasting Energy Intake 

Lower 
Energy Intake

Postprandial Energy Intake 
Higher Higher Lower 

Older compared to Younger: Lower 
Energy Intake Higher 

Figure 2. Energy intake. Mean ˘ SD of energy intake (kcal) and a plot of the standardized mean
difference (SMD; mm) of energy intake in older compared with younger subjects with the DerSimonian
and Laird random-effect model. The horizontal lines denote the 95% confidence interval; � point
estimates (the size of the square corresponds to its weight); � the pooled estimate of age effect.
Three different methods of measuring energy intake were distinguished: (i) energy intake of a single
ad libitum buffet-style meal at the research facility after overnight fasting and in a postprandial state
after a nutrient preload, administered orally or infused directly into the small intestine; (ii) energy
intake of provided food items during a prolonged period; and (iii) energy intake of weighed food
records, 24-h food intake recalls, or food frequency questionnaires. In the total group of 7685 subjects,
energy intake was less (SMD: ´0.77 (95% CI ´0.90 to ´0.64), I2 = 76%, p < 0.001) in the older than the
younger adults. * p < 0.05 energy intake significantly less in older than younger adults within the study;
# data were derived from a figure of the original publication; food records, & 24-h food intake recalls;
or ˆ food frequency questionnaires.



Nutrients 2016, 8, 28 11 of 22

Heterogeneity was not affected by excluding the “larger” studies, i.e., with >100 subjects per age
group (I2 = 59%, n = 2432, p < 0.001; four studies excluded [36,43,44,81]). In the studies included in this
sensitivity analysis, energy intake was less in the older than the younger adults with a SMD of ´0.77
(95% CI: ´0.92 to ´0.63). As a group, the older adults (n = 1212) had on average 18% ˘ 9% lower
energy intake than the younger (n = 1220) adults.

In 1555 females (17 studies [28,31,39,43,45–47,52,56,63,67,69–71,74,78,79]), energy intake after
overnight fasting was less in older (n = 763) than younger participants (n = 792), with a SMD of
´0.70 (95% CI: ´0.95 to ´0.45) and significant heterogeneity (I2 = 73%, p < 0.001). As a group, the
older females (1559 kcal) had on average 16% ˘ 9% lower energy intake than the younger females
(1844 kcal).

In 2030 males (28 studies [20,23,30,31,33,35,39,41,43,46,47,49,50,52,55–60,71–74,76–79]), energy
intake after overnight fasting was less in older (n = 1045) than younger participants (n = 985), with a
SMD of ´0.95 (95% CI: ´1.20 to ´0.75) and significant heterogeneity (I2 = 73%, p < 0.001). As a group,
the older males (2033 kcal) had on average 18% ˘ 10% lower energy intake than the younger males
(2486 kcal).

Within an individual study, energy intake was significantly less in older than younger adults
in five of ten studies that determined energy intake of a single ad libitum buffet-style meal after
overnight fasting at the research facility [47,48,60,74,75], six of seven studies which determined energy
intake by provided food items during a prolonged period [21,58,59,76,79,80], and 24 of 37 studies
which determined energy intake by weighed-food records, 24-h food intake recalls, or food frequency
questionnaires [20,26,33,39,42,46–48,50–52,54–56,63,67–73,77,78] (Figure 2). There were no studies in
which energy intake after overnight fasting was significantly higher in older than younger adults.

3.1.2. Energy Intake of a Buffet-Style Meal

In the subgroup of 311 subjects in which energy intake was measured of a single ad libitum
buffet-style meal at the research facility after overnight fasting [23,47,48,57,60,68,69,74,75,81], energy
intake was less in the older than the younger adults, with a SMD of ´0.89 (95% CI: ´1.42 to ´0.36)
(Figure 2) and significant heterogeneity (I2 = 77%, p < 0.001). As a group, the older adults (n = 145,
energy intake of 819 kcal/meal) had on average 20% ˘ 15% (~218 kcal/meal) lower energy intake
of a buffet-style meal after overnight fasting than the younger adults (n = 166, energy intake of
1037 kcal/meal).

In the subgroup of 266 subjects in which energy intake was measured of a buffet-style meal
during postprandial conditions [23,33,44,49,60,68,69,75,81], energy intake was less in the older than
the younger adults, with a SMD of ´0.37 (95% CI: ´0.65 to ´0.10) (Figure 2) and no significant
heterogeneity (I2 = 15%, p = 0.31). As a group the older adults (n = 126, energy intake of 691 kcal/meal)
had on average 16%˘ 20% (~122 kcal/meal) lower energy intake of a buffet-style meal in a postprandial
state than the younger adults (n = 140, energy intake of 814 kcal/meal).

In the subgroup of 203 subjects in which energy intake was measured of a buffet-style meal both
after overnight fasting and in a postprandial state [23,60,68,69,75,81], energy intake decreased less in
the older adults (decrease in energy intake of on average 10% or ~79 kcal from 798 kcal after overnight
fasting to 719 kcal in the postprandial state) than in the younger adults (decrease in energy intake of on
average 21% or ~212 kcal from 1000 kcal after overnight fasting to 788 kcal in the postprandial state).

3.1.3. Energy Intake during a Prolonged Period

In the subgroup of 339 subjects in which energy intake from provided food items was measured
during a prolonged period (~4 days–2 weeks) [21,53,58,59,76,79,80], energy intake was less in the older
than the younger adults, with a SMD of ´1.09 (95% CI: ´1.42 to ´0.76) (Figure 2) and non-significant
heterogeneity (I2 = 42%, p = 0.11). As a group, the older adults (n = 163, energy intake of 2241 kcal/24 h)
had on average 19% ˘ 6% (~546 kcal/24 h) lower energy intake during a prolonged period than the
younger adults (n = 176, energy intake of 2787 kcal/24 h).



Nutrients 2016, 8, 28 12 of 22

3.1.4. Energy Intake of Weighed-Food Records, 24-h Food Intake Recalls, or Food
Frequency Questionnaires

In the subgroup of 7035 subjects in which energy intake was measured using
weighed food records [20,28–31,34,35,39–41,43,45–52,55,56,63,68–70,72–75,78], 24-h food intake
recall [26,27,42,54,71,77], or food frequency questionnaires [67], energy intake was less in the older
than the younger adults with a SMD of ´0.69 (95% CI: ´0.84 to ´0.55) (Figure 2) and significant
heterogeneity (I2 = 77%, p < 0.001). As a group the older adults (n = 3266, energy intake of
1969 kcal/24 h) had on average 17% ˘ 8% (~407 kcal/24 h) lower energy intake than the younger
adults (n = 3769, energy intake of 2376 kcal/24 h).

In the subgroup of 4311 subjects, in which energy intake was measured using weighed food
records energy intake was less in the older than the younger adults with a SMD of ´0.63 (95% CI:
´0.77 to ´0.49) and significant heterogeneity (I2 = 49%, p = 0.001).

In the subgroup of 2530 subjects, in which energy intake was measured using 24-h food intake
recalls energy intake was less in the older than the younger adults with a SMD of ´0.63 (95% CI:
´0.77 to ´0.49) and significant heterogeneity (I2 = 92%, p = 0.001).

3.2. Effect of Age on Appetite

3.2.1. Hunger

Twenty studies (561 subjects) reported hunger after overnight fasting [23,32,33,36–38,47–49,57,
60–62,64–66,68,69,74,75]. Twelve of these studies (344 subjects) evaluated hunger also after nutrient
ingestion (60 min after oral nutrient consumption/start of the small intestinal nutrient infusion;
i.e., a time point which was reported in the majority of the studies [23,32,36–38,49,65,66,68,69] (two
studies did not measure appetite up to 60 min and, therefore, the data of 30 min [75] and 15 min [60]
were included); 10 studies (98 subjects) after oral mixed macronutrient (protein, carbohydrate and
fat) consumption [32,36–38,60,65,66,68,69,75] and two studies (46 subjects) during intraduodenal
infusion of protein [23] or fat [49]. All studies reporting hunger were intervention studies,
14 crossover [23,33,36,47–49,57,60–62,68,69,74,75] and six non-controlled studies [32,37,38,64–66],

Nine studies were conducted in Australia [23,32,33,47–49,57,68,69], six in Europe [36–38,64–66],
and five in the United States [60–62,74,75]. The largest study included 54 subjects [75] and the smallest
10 subjects [57]. The mean age of the youngest group within a study was 22 years (the older group in
that study had a mean age of 77 years) and the oldest group 81 years (the young group in that study
had a mean age of 38 years) [65].

Hunger, measured after overnight fasting [23,32,33,36–38,47–49,57,60–62,64–66,68,69,74,75], was
less in the older (n = 285, 74 years, 72 kg, 25 kg/m2) than the younger adults (n = 276, 27 years,
69 kg, 24 kg/m2), with a weighted mean difference (WMD) of ´17 mm (95% CI: ´22 to ´13 mm)
(Figure 3) and significant heterogeneity (I2 = 52%, p = 0.004). Heterogeneity was not significant when
the “small-intestinal” studies were excluded [23,33,47–49] (I2 =51%, n = 444 subjects, p = 0.01). As
a group, the older adults (43 mm) had on average 25% ˘ 24% (~16 ˘ 13 mm) lower hunger after
overnight fasting than the younger adults (59 mm).

Hunger, measured in a postprandial state [23,32,36–38,49,60,65,66,68,69,75], was less in the
older than the younger adults, with a WMD of ´14 mm (95% CI: ´19 to ´9 mm) (Figure 3) and
significant heterogeneity (I2 = 53%, p = 0.01). As a group, the older adults had on average 39% ˘ 30%
(~15 ˘ 11 mm) lower hunger in a postprandial state than the younger adults. In the group of
344 subjects, hunger was decreased by 26 mm from 66 mm after overnight fasting to 40 mm in a
postprandial state in the younger adults and by 20 mm from 45 mm after overnight fasting to 25 mm
in a postprandial state in the older adults.

Within an individual study, hunger was significantly less in older than younger
adults in 12 [33,37,38,47–49,57,60,65,66,74,75] of 20 studies after overnight fasting and



Nutrients 2016, 8, 28 13 of 22

eight [32,37,38,49,65,66,68,69] of 12 studies in a postprandial state. There were no studies in which
hunger was significantly higher in older than younger adults.

Study  Sample size 

 Younger/ Older  

Hunger/ Fullness VAS 
Mean (SD) 

Younger/  Older 
WMD [95% CI]

Hunger/ Fullness VAS 
Mean (SD) 

Younger/  Older 
WMD [95% CI] 

Hunger (mm) 
 Fasting (20 studies)     Postprandial (12 studies)

Cook 1997 [33]    7/ 8   52 (21)/ 19 (17)  -33 [-53, -13]*
MacIntosh 2001[48]   16/ 16   61 (14)/ 40 (16)  -21 [-29, -13]*
Van Walleghen 2007 [74]  29/ 21   40 (16)/ 24 (18)  -16 [-26,   -6]*
MacIntosh 2001 [47]   12/ 12   70 (14)/ 55 (12)  -15 [-26,   -4]*
Rolls 1991 [61]    24/ 24   70 (15)/ 61 (24)    -9 [-19,    1]* 
Rayner 2000 [57]^    5/ 5   38 (22)/ 37   (5)    -1 [-26,  24]* 
Schneider 2008 [64]     10/ 9   35 (16)/ 40   (9)     5 [-19 , 29]#*
Sawaya 2001 [62]     10/ 9   29 (26)/ 41   (9)   10 [-12,  32]* 
Serra-Prat 2009 [66]    17/ 10   73 (16)/ 30 (25)  -43 [-60, -26]*    22 (25)/ 4     (9)  -18 [-31,   -5]*#

Van Walleghen 2007 [75]  29/ 25   64 (32)/ 37 (30)  -27 [-44, -10]*#    38 (27)/ 29 (31)    -9 [-25,    7]#

MacIntosh 2001 [49]    13/ 13   60   (7)/ 34 (11)  -26 [-33, -19]*   64 (11)/ 48 (18)  -16 [-27,   -5]*#

   8/ 8   73 (11)/ 48 (31)  -25 [-48,   -2]*   32 (20)/ 8   (11)  -24 [-40,   -8]*
  9/ 10   73 (18)/ 48 (35)  -25 [-50,   -1]*#   32 (21)/ 9   (16)  -23 [-40,   -6]*#

    8/ 8   65 (28)/ 45 (31)  -22 [-51,    7]*    67 (17)/ 31 (20)  -36 [-54, -18]*#

   12/ 12   69 (14)/ 47 (17)  -22 [-34, -10]*   59 (31)/ 33 (21)  -26 [-47,   -5]*#

  19/ 34   51   (8)/ 35   (5)  -16 [-20, -12]*    28   (5)/ 20   (4)    -8 [-11,   -5]*#

  19/ 14   57 (18)/ 42 (36)  -15 [-36,    6]*    22 (17)/ 9   (19)  -13 [-26,   -1]*
  16/ 16   75 (12)/ 60 (20)  -15 [-26,   -4]*    53 (12)/ 44 (16)    -9 [-19,    1]#

   10/ 10   64 (21)/ 54 (29)  -10 [-32,  12]*   55 (28)/ 56 (31)   1 [-25,  27] 

Di Francesco 2006 [37] 
Di Francesco 2005 [38] 
Sturm 2003 [69] 
Sturm 2004 [68] 
Serra-Prat 2013 [65] 
Clarkston 1997 [32] 
Rolls 1995 [60] 
Soenen 2014 [23] 
Di Francesco 2010 [36]^   12/ 12   65 (21)/ 63 (17)    -2 [-17,  13]*    13 (21)/ 14 (10)     1 [-12,  14] 

All studies   n = 285/ 276 59/ 43 mm   -17 [-22, -13]* 41/ 25 mm   -14 [-19,  -9]* 

     
        

Fullness (mm) 
Fasting (16 studies)   Postprandial (10 studies)

Cook 1997 [33]     7/ 8     7 (11)/ 6     (8)    -1 [-11,   9]* 
Rayner 2000[57]^     5/ 5   21 (16)/ 21 (19)     0 [-22, 22]* 
Rolls 1991 [61]    24/ 24   29 (20)/ 32 (20)     3 [-8,   14]* 
MacIntosh 2001[47]    12/ 12   23   (7)/ 33 (14)   10 [1,    19]*
Van Walleghen 2007[74] 29/ 21   23 (23)/ 46 (24)   23 [10,  36]*
Schneider 2008 [64]   10/ 9   25 (19)/ 63 (32)   38 [14,  62]*#  
Sturm 2003 [69]   8/ 8   25 (21)/ 17 (13)   -8 [-25,  9]#*   27 (14)/ 41 (23) 14 [-5,   33]#*
Soenen 2014 [23]    10/ 10   10   (8)/ 3     (4)    -7 [-13, -1]*   23 (23)/ 11 (27)  -12 [-34, 10]* 
Clarkston 1997 [32]    19/ 14     9 (17)/ 2     (4)    -7 [-15,  1]*    30 (31)/ 46 (45) 16 [-11, 43]* 
MacIntosh 2001[49]    13/ 13   36   (2)/ 37   (7)     1 [-3,    5]*    35 (18)/ 43 (18)   8 [-6,   22]#

Sturm 2004 [68]    12/ 12   15   (7)/ 17 (10)     2 [-5,    9]*    33 (17)/ 34 (21)   1 [-14, 16]#

Di Francesco 2006 [37]   8/ 8   11   (8)/ 18 (20)     7 [-8,  22]#*   56 (22)/ 76 (24) 20 [-3,   43]#

Di Francesco 2005 [38]     9/ 10   11 (15)/ 19 (22)     8 [-9,  25]*    55 (21)/ 75 (23) 20 [0,    40] 
Zhou 2013 [82]    36/ 59   29 (17)/ 44 (22)   15 [7,   23]*   70 (17)/ 61 (22)  -9 [-17, -1]*
Rolls 1995 [60]    16/ 16   10   (8)/ 28 (16)   18 [9,   27]*   39 (20)/ 49 (20) 10 [-4,   24]#

Van Walleghen 2007[75] 29/ 25   22 (59)/ 44 (55)   22 [-8,  52]#   44 (36)/ 51 (28)   7 [-10, 24]#

All studies  n = 247/ 254 19/ 27 mm  6 [1,   11]* 41/ 49 mm   6 [-2,   14] 

       
       

Less Less More 
Postprandial Hunger 

Older compared to Younger: 
Fasting Hunger 

More 

Postprandial Fullness More Less 
Fasting Fullness 

Older compared to Younger: Less More 

Figure 3. Appetite. Mean ˘ SD of appetite (hunger and fullness; Visual Analogue Scale (VAS;
mm)) after overnight fasting and in a postprandial state and a plot of the weighted mean difference
(WMD; mm) of appetite in older compared with younger subjects with the DerSimonian and Laird
random-effect model. The horizontal lines denote the 95% confidence interval; � point estimates (the
size of the square corresponds to its weight); � the pooled estimate of the age effect. Older compared
to younger adults were less hungry (WMD: ´17 mm (95% CI ´22 to ´13 mm), I2 = 52%, p = 0.004)
and more full (WMD: 6 mm 95% CI 1 to 11 mm, I2 = 76%, p < 0.001) after overnight fasting and less
hungry (WMD: ´14 mm (95% CI ´19 to ´9 mm), I2 = 53%, p = 0.01) in a postprandial state, whereas
fullness was comparable (WMD: 6 mm (95% CI ´2 to 14 mm), I2 = 54%, p = 0.02). * p < 0.05 appetite
(hunger/fullness) significantly different in older than younger adults within the study; # data were
derived from a figure of the original publication; ˆ data were provided by the investigators by e-mail
upon request.

3.2.2. Fullness

Sixteen studies (501 subjects) reported fullness after overnight fasting [23,32,33,37,38,47,49,57,
60,61,64,68,69,74,75,82]. Ten of these studies (335 subjects) evaluated fullness also after nutrient
ingestion; eight studies after oral mixed macronutrient consumption [32,37,38,60,68,69,75,82]; and
two studies during intraduodenal infusion of protein [23] or fat [49]. All studies reporting fullness
were intervention studies, 12 crossover [23,33,47,49,57,60,61,68,69,74,75,82] and four non-controlled
studies [32,37,38,64].



Nutrients 2016, 8, 28 14 of 22

Eight studies were conducted in Australia [23,32,33,47,49,57,68,69], four in the United
States [60,61,74,75], three in Europe [37,38,64], and one in Asia [82]. The largest study included
95 subjects [82] and the smallest 10 subjects [57]. The mean age of the youngest group was 22 years
and 77 years of the oldest group [69].

Fullness, measured after overnight fasting, was greater in the older (n = 254, 73 years, 71 kg,
25 kg/m2) than the younger adults (n = 247, 26 years, 67 kg, 23 kg/m2), with a WMD of 6 mm (95%
CI: 1 to 11 mm) and significant heterogeneity (I2 = 76%, p < 0.001; Figure 3). Heterogeneity was not
affected by excluding the “small-intestinal” studies (I2 = 73%, n = 416 subjects, p < 0.001; four studies
excluded [23,33,47,49]). As a group the older adults (27 mm) had on average 37% ˘ 73% (~8 ˘ 13 mm)
higher fullness after overnight fasting than the younger adults (19 mm) adults.

Fullness, measured in a postprandial state, was not significantly different between the
older and the younger subjects with a WMD of 6 mm (95% CI: ´2 to 14 mm) and significant
heterogeneity (I2 = 54%, p = 0.02). In the group of 335 subjects, fullness was increased by 23 mm
from 18 mm after overnight fasting to 41 mm in a postprandial state in the younger adults and by
26 mm from 23 mm after overnight fasting to 49 mm in a postprandial state in the older adults.

Heterogeneity decreased by introducing a maximum age of the younger and a minimum age of
the older age groups (I2 = 0%, n = 240 subjects, p = 0.51); i.e., after excluding studies in which the mean
age or the minimum age, when age was reported as a range, of the older adult group was <65 years
old (one study excluded: range of 50–59 years [82])—there were no studies in which the mean age
or the maximum age, when age was reported as a range, of the younger adult group was >40 years
old. In the studies included in this sensitivity analysis, fullness was significantly different between the
older and the younger adults with a WMD of 9 mm (95% CI: 2 to 14). As a group, the older adults had
on average 21% ˘ 32% (~9 ˘ 10 mm) higher fullness in a postprandial state than the younger adults.

Within an individual study, fullness was greater in older than younger adults in
six [23,47,60,64,74,82] of 16 studies after overnight fasting. In contrast, fullness was less in older
than younger adults in one [23] of 16 studies after overnight fasting and one [82] of 10 studies in a
postprandial state.

4. Discussion

This meta-analysis examined the effect of ageing on appetite and energy intake in adults, including
data from >7500 subjects on energy intake and >500 subjects on appetite derived from 59 studies.
Energy intake was less in healthy older (~70 years) than younger (~26 years) adults. The calculated
reduction fell into quite a narrow range at 16%–20%, despite studies being done in the fasting and
fed state, and energy intake being calculated by a variety of methods, including intake at an acute
study meal, during prolonged periods or using weighed food records, 24-h food intake recalls, and
food frequency questionnaires, i.e., a robust finding regardless of the method of intake evaluation.
The results of this analysis show that older people (~73 years) feel less hungry than younger adults
(~26 years), both fasting (25%) and after they have consumed some food (39%), and also feel more full
in the fasting state (37%). These age-related differences are substantial, and likely to be a major cause
of the reduced energy intake by older people.

Our results indicate a reduction in energy intake of approximately 20% between the ages of 26
and 70 years, i.e., about 0.5% per year. This is consistent with previous reports of reduced energy
intake of approximately 30% between the ages of 20 and 80 years [5,79], and with the results of
individual prospective studies. For example, a seven-year New Mexico longitudinal study of 156
persons aged 64–91 years, reported a decrease of 19 kcal/day/year in women and 25 kcal/day/year
in men [3], while a Swedish longitudinal study of 98 people found an even greater decline of energy
intake of 610 kcal/day in men and 440 kcal/day in women, between the ages of 70 and 76 years [4].
A population-based study indicated that older people aged 60–74 years consume ~500–700 kcal/day
less than their younger counterparts aged 20–39 years [5]. Our gender analyses indicated that energy



Nutrients 2016, 8, 28 15 of 22

intake was less in both older than younger males (18%) and females (16%), to a similar extent in
both sexes.

The regulation of energy intake may be diminished in the elderly. Older subjects have a reduced
suppression of energy intake after oral [60], or small intestinal nutrient [23], ingestion. In this
meta-analysis in the subgroup of 203 subjects (six studies [23,60,68,69,75,81]), in which energy intake
was measured during a single ad libitum buffet-style meal at the research facility both after overnight
fasting and in the postprandial state, energy intake decreased on average 11% less in the older than
young adults. Older people do not show the ability to regulate food intake after prolonged over- or
under-feeding as young individuals [53,59]. This indicates that after an anorectic insult (for example,
major surgery), older people are likely to take longer than young adults to regain the weight lost,
remain undernourished longer, and be more susceptible to subsequent superimposed illnesses, such
as infections.

Our results indicate a reduction in hunger of approximately 25% and increase in fullness of
approximately 35% between the ages of 27 and 74 years, i.e., changes of about 0.5% per year for hunger
and about 0.7% per year for fullness, respectively. Scores for appetite are predictive of energy intake in
both healthy young and older subjects [84]. Appetite and energy intake are dependent on the precise
co-ordination of interrelated “intragastric” (i.e., gastric emptying [85], antral area and motility (the distal
stomach) [68,85], and plasma ghrelin concentrations [69,86–88]) and “small intestinal” mechanisms
(pyloric motility [89] and gut hormone secretion including cholecystokinin (CCK) [86], glucagon-like
polypeptide-1 (GLP-1) [90], peptide tyrosine tyrosine (PYY) and gastric inhibitory polypeptide
(GIP)). These gastrointestinal mechanisms affecting appetite and energy intake are modulated by
ageing [91]. Healthy older people, as a group, have slightly slower gastric emptying [32] mediated
by increased pyloric motility [33,34,68,69], greater gastric antral area [68], decreased perception of
gastric distension [57], lower plasma ghrelin [92] and higher CCK concentrations than young adults,
differences that all favour reductions in appetite and energy intake. Ageing is associated with insulin
resistance and impaired glucose tolerance [93] which may be influenced by changes in small intestinal
hormone (GLP-1, GIP) secretion [94]. In addition, thyroid hormone concentrations are known to change
with ageing which may be regarded as a physiologic process that can affect appetite [95,96]. There may
be a decrease in appetite-stimulating free thyroid hormones with increasing age in men [97]. Serum
thyroid stimulating hormone (TSH) concentrations may be higher and free thyroid hormones lower
in older, when compared to younger, men [98]. Older people have an increased prevalence of both
hypo- (up to 5%) and hyperthyroidism (0.5%–3%) than younger patients. In the elderly the symptoms
of both conditions can overlap with other age-related diseases (e.g., unexplained, weight loss, anorexia,
weakness, fatigue, depression, constipation) [98]. The senses of smell and taste deteriorate with
age [99], leading to a reduced capacity to enjoy food and develop sensory-specific satiety, [61] the
normal decline in pleasantness of the taste of a particular food after it has been consumed, leading to a
decrease in its consumption and a tendency to shift consumption to other food choices during a meal.
Age-related reduction in sensory-specific satiety favours a less varied, more monotonous diet, and the
development of micronutrient deficiencies.

Physiological anorexia and seemingly minor weight loss predisposes to the development of
pathological under-nutrition, cachexia and adverse effects [100] and is, accordingly, associated with
increased morbidity and mortality. For example, in a large study of community-dwelling Americans
aged 65 years or older, weight loss in excess of 5% body weight over three years occurred in 17%
and was associated with a 70% increase in mortality, irrespective of the initial weight, whereas
weight stability and weight gain were not associated with increased mortality [7]. Not uncommonly,
pathological anorexia and weight loss are superimposed on the “physiological anorexia of ageing” [19].
This can be the result of a variety of conditions that become more frequent with age, including
acute and chronic medical conditions (gastrointestinal disease, malabsorption syndromes, infection,
hypermetabolism, micronutrient deficiencies, increased energy requirements), medications (which
may cause malabsorption of nutrients, gastrointestinal symptoms, and loss of appetite), psychological



Nutrients 2016, 8, 28 16 of 22

factors (depression, dementia and Alzheimer’s disease, and bereavement), social factors (poverty,
difficulties with shopping, meal preparation and self-feeding, living alone, social isolation and
loneliness) and physical factors (poor dentition leading to problems with chewing, immobility
(stroke), Parkinson disease, and impaired vision). Because the majority of these factors are at least
partly responsive to treatment, their recognition is important. For example, increased cytokine
levels, due to the stress of ageing per se, or the amplified stressful effects of other pathologies, may
provide an explanation for some of the decline in appetite and energy intake in older people [101].
Increased cortisol and catecholamines stimulate the release of interleukin 6 and tumour necrosis factor
alpha [102].

Although only a limited number of studies have examined the effects of undernutrition on
appetite and energy intake, there is evidence of substantial differences between undernourished
and well-nourished older people, which may potentially result from being undernourished and/or
contribute to the undernourished state [65,66,69]. Undernourished older adults had significantly
reduced hunger in the fasted state and in the postprandial state’ and significant greater fullness in the
fasted state when compared to healthy older [65] and young adults [65,69]. In undernourished older
women energy intake was not suppressed by a mixed-nutrient preload, unlike in well-nourished older
and young women [69]. In another study of undernourished older subjects, concentrations of CCK
were higher than in well-nourished older subjects [103], suggesting that increased CCK activity may
be a cause of undernutrition in older people, and/or act to perpetuate it.

Limitations of the meta-analysis are that we used a single database and that there is variability in
study design and characteristics indicated by high heterogeneity—we performed a-priori determined
meta-analyses depending on the method used to determine energy intake and sensitivity analyses
when possible, i.e., effect of sex and age, and observed that the effects of ageing on appetite and energy
intake were comparable in these analyses.

5. Conclusions

In summary, this meta-analysis of 59 studies supports previous reports that appetite and
energy intake are reduced in healthy older compared with younger adults, with a 16%–20% lower
energy intake, 25%–39% lower hunger and 37% more fullness in those aged on average 70–74 years
compared to 26–27 years, a robust finding regardless of the method of intake evaluation. These
age-related differences in healthy adults are consistent with a reduction of food intake with ageing,
i.e., a physiological anorexia of ageing. The reduction in energy intake in this analysis equates to
approximately 0.5% per year of increasing age, and is likely to contribute to loss of weight in older
people and the development of pathological under-nutrition in predisposed older people.

Acknowledgments: We thank Kylie Lange, National Health and Medical Research Council of Australia Centre of
Clinical Research Excellence in Translating Nutritional Research to Good Health, Discipline of Medicine, Royal
Adelaide Hospital, The University of Adelaide, for statistical support. Stijn Soenen was supported by a Royal
Adelaide Hospital (RAH) Mary Overton Early Career Research Fellowship, a RAH Clinical Project Grant, and a
Geriatrics Training & Research with Aged Care Centre (G-TRAC) Resthaven Grant. Christine Feinle-Bisset was
supported by a National Health and Medical Research Council of Australia (NHMRC) Senior Research Fellowship
(627002). The Royal Adelaide Hospital Research Foundation and G-TRAC Resthaven did not have any input in
the design, implementation, analysis or interpretation of the data.

Author Contributions: S.S. designed research; C.G. and S.S. conducted research; C.G. and S.S. analysed data and
performed statistical analysis; C.G., S.S., I.C., N.L.-M., C.F.-B. and M.H. contributed to data interpretation; and
S.S., C.G., I.C., N.L.-M., C.F.-B. and M.H. contributed to writing the manuscript. S.S. had primary responsibility
for the final content.

Conflicts of Interest: The authors declare no conflict of interest.



Nutrients 2016, 8, 28 17 of 22

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	Introduction 
	Experimental Section 
	Search Strategy, Study Selection, Data Extraction and Quality Assessment 
	Data Analysis 

	Results 
	Effect of Age on Energy Intake 
	Energy Intake in the Total Group 
	Energy Intake of a Buffet-Style Meal 
	Energy Intake during a Prolonged Period 
	Energy Intake of Weighed-Food Records, 24-h Food Intake Recalls, or Food Frequency Questionnaires 

	Effect of Age on Appetite 
	Hunger 
	Fullness 


	Discussion 
	Conclusions