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Understanding age-related changes: exploring the interplay of protein intake, physical activity and appetite in the ageing population

Published online by Cambridge University Press:  01 April 2024

Dilara Dericioglu*
Affiliation:
Hugh Sinclair Unit of Human Nutrition, Department of Food and Nutritional Sciences, University of Reading, Whiteknights, Reading RG6 6DZ, UK Institute of Food, Nutrition and Health, University of Reading, Whiteknights, Reading RG6 6EU, UK
Lisa Methven
Affiliation:
Institute of Food, Nutrition and Health, University of Reading, Whiteknights, Reading RG6 6EU, UK Food Research Group, Department of Food and Nutritional Sciences, University of Reading,Whiteknights, Reading RG6 6DZ, UK
Miriam E. Clegg
Affiliation:
Hugh Sinclair Unit of Human Nutrition, Department of Food and Nutritional Sciences, University of Reading, Whiteknights, Reading RG6 6DZ, UK Institute of Food, Nutrition and Health, University of Reading, Whiteknights, Reading RG6 6EU, UK School of Food and Nutritional Sciences, University College Cork, Cork, Ireland
*
*Corresponding author: Dilara Dericioglu, email: [email protected]
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Abstract

Globally, we are currently facing a rapid demographic shift leading to an increase in the proportion of older adults within the population. This raises concerns about the potential increase in age-related diseases and their impact on our ability to provide adequate health and end-of-life care. To apply appropriate interventions, understanding the changes that happen with ageing becomes essential. Ageing is often accompanied by a decrease in appetite and physical activity, which may lead to malnutrition, resulting in decreased muscle mass, physical capabilities and independence. To preserve muscle mass, older adults are advised to increase protein intake and physical activity. However, protein’s high satiating effect may cause reduced energy intake. Physical activity is also advised to maintain or enhance older adult’s appetite. This review paper aims to discuss appetite-related changes that occur with ageing and their consequences. In particular, it will focus on investigating the relationship between protein intake and physical activity and their impact on appetite and energy intake in the ageing population. Recent studies suggest that physical activity might contribute to maintaining or enhancing appetite in older adults. Nevertheless, establishing a definitive consensus on the satiating effect of protein in ageing remains a work in progress, despite some promising results in the existing literature.

Type
Conference on ‘Nutrition at key stages of the lifecycle’
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press on behalf of The Nutrition Society

Ageing

Ageing is the lifelong process of getting older at the cellular, organ or whole-body level(Reference Timiras1). The ageing process is unique across all populations due to the differences in genetics, lifestyle and overall health(Reference Levine2). While the UN has agreed that individuals aged 60 years and above could be referred to as part of the older population(3), most developed countries globally have adopted the definition of ‘elderly’ or ‘older person’ as the chronological age of 65 years(4).

Over the last decades of the 20th century, significant advancements in society and technology, such as improved healthcare, better nutrition, public health initiatives and advancements in sanitation and hygiene, have resulted in increased life expectancy and longer lifespans(Reference Kirkwood5). The global population is experiencing an upward trend in the numbers of older people, and the majority of individuals today can expect a prolonged lifespan extending beyond their sixties(6). The WHO estimates that one in six people globally will be aged 60 years or over by 2030, and this demographic is projected to double, reaching 2·1 billion by 2050, with the number of those 80 or older tripling to 426 million(6).

The rapid growth of the ageing population has led to significant changes in the primary causes of morbidity and mortality over the past century; in particular, cases of dementia and cancer have escalated(7). By 2030, the number of cancer cases is projected to reach 27 million, while the worldwide population affected by dementia/Alzheimer’s disease is estimated to reach 115 million by 2050(Reference Suzman and Beard8). In addition, the incidence of falls, obesity, diabetes and CVD are also expected to continue to increase(9,10) . Consequently, with the continued growth of the older population, the healthcare system will encounter significant challenges presented by these diverse health conditions, leading to an increased need for resources and healthcare professionals. To reduce the pressure on the health system, promoting a healthy lifestyle is crucial(Reference Faghy, Whitsel and Arena11). Therefore, it is essential to understand the physiological and behavioural changes that occur as people age and to apply appropriate interventions. This review paper will commence by exploring age-related changes impacting nutritional status, including body composition, physical activity, nutritional requirements and appetite changes (anorexia of ageing), as well as the associated risk factors and consequences (Fig. 1). Subsequently, it will delve into the relationship between protein intake and physical activity and their impact on appetite and energy intake within the ageing population.

Fig. 1 Age-related changes impacting nutritional status.

Age-related changes in body composition

Among the various physiological changes that accompany ageing, changes in body composition are particularly noticeable(Reference JafariNasabian, Inglis and Reilly12). In general, with ageing, there is typically an increase in the percentage of body fat accompanied by a decrease in lean mass and bone density, independent of general and physiological fluctuations in weight and BMI(Reference Ponti, Santoro and Mercatelli13,Reference St-Onge and Gallagher14) . Factors contributing to this shift include decreased physical activity and secretion of growth hormones and reduced sex hormones, as well as a diminished RMR(Reference Ahmed and Haboubi15). This increase in fat mass is predominantly spread within the abdominal region, which is particularly associated with CVD and diabetes(Reference Boorsma, Snijder and Nijpels16,Reference Carr, Utzschneider and Hull17) . Reductions in fat-free mass occur due to skeletal muscle losses(Reference Ahmed and Haboubi15), and a decline in muscle mass among older adults is directly associated with reduced muscle strength, diminished maximal aerobic capacity and decreased bone density(Reference Evans18). However, these changes may not be immediately noticeable since muscle mass loss is often masked by an unchanged or even increasing BMI, due to increased fat mass(Reference Boutari and Mantzoros19). Reduced muscle mass can have significant consequences for older individuals, impacting various aspects of daily life. One notable consequence is a decrease in independence, affecting routine activities such as shopping and cooking(20). Moreover, individuals with decreased muscle mass face an increased vulnerability to falls. Muscle strength plays a crucial role in maintaining balance and stability, and a decrease in muscle mass can contribute to a higher risk of falls(20).

Age-related changes in physical activity

A sedentary lifestyle is becoming more common across all age groups(Reference Drewnowski and Evans21), and sedentary behaviour in ageing is a significant risk factor for chronic disease, morbidity and mortality. As individuals age, the frequency of engaging in high-intensity activities tends to decrease, while the reported incidence of immobility tends to rise(Reference DiPietro22). In a comprehensive survey conducted in England, involving over 92 000 individuals (the Taking Part survey, 2011), exercise participation and desire to participate have been found to decrease throughout adulthood(Reference Jones, Millward and Buraimo23). Since the majority of people aged 65 years and over spend an average of 10 h sitting each day, they are considered the most sedentary age group within the population(24).

As per the guidelines provided by WHO(6) and UK Chief Medical Officers(25), older adults are advised to do moderate-intensity aerobic physical activity for a minimum of 150 min per week or high-intensity aerobic physical activity for at least 75 min per week, or an equivalent combination of both intensities. In cases where older individuals are unable to meet the recommended levels of physical activity, the WHO advises them to be as physically active as their abilities and conditions allow(26). Moreover, older adults in the UK are advised to participate in a combination of bone and muscle strengthening exercises, such as carrying heavy bags, going to the gym or participating in yoga, twice a week. Additionally, engaging in balanced activities like dancing, playing bowls or practising Tai Chi twice a week is also advised, as it can help reduce the risk of frailty and falls(25). Despite these recommendations, the vast majority of older adults do not meet the minimum recommended activity levels for maintaining a healthy lifestyle(27).

Understanding the physical activity behaviours of older adults is essential to develop interventions for promoting health and well-being, preventing chronic diseases and improving life quality(Reference McNaughton, Crawford and Ball28). As older adults experience progressive declines in physiological function, including slower walking speed and difficulties in standing up from a seated position and maintaining balance(Reference McPhee, French and Jackson29), it becomes evident that addressing these aspects is essential. Research indicates that the great majority of older adults in their seventies had a lower physiological function compared with young adults, even without apparent difficulties in their daily activities(Reference McPhee, Hogrel and Maier30). These changes observed during the ageing process, both in physiological function and physical activity behaviours, may result from a wide variety of factors. One compelling factor contributing to these changes is that older adults commonly experience irreversible motor neurone and muscle fibre losses as part of the natural ageing process(Reference McPhee, French and Jackson29,Reference Piasecki, Ireland and Jones31) . Cross-sectional studies reveal that compared with younger adults, older adults have higher BMI, reduced muscle size and strength (particularly in the legs), lower bone mineral density and poorer performance in cognitive tests(Reference Bijlsma, Meskers and Van Den Eshof32). Furthermore, research on the relationship between muscle power and mobility in older adults suggests that the decline in mobility associated with ageing may be attributed to decreases in both muscle strength and power(Reference Sillanpää, Stenroth and Bijlsma33). Beyond the natural decline in physical activity associated with ageing, it is also important to understand, from the older individuals’ own perspective, the factors contributing to reduced activity levels with ageing. A study focused on sedentary or less active older individuals aimed to explore their motivations and barriers to physical activity(Reference Grossman and Stewart34). The findings highlight that while interest in physical activity persists with age, misconceptions and incomplete perceptions prevent engagement(Reference Grossman and Stewart34). This reveals the importance of activity counselling for this population.

Age-related changes in nutritional requirements

As people age, they often encounter challenges that make it more difficult to meet nutritional requirements effectively(Reference Leslie and Hankey35). According to the UK National Diet and Nutrition Survey (NDNS) 2014–2016 data, free-living individuals aged 75 years and over do not meet estimated average requirements (EAR)(Reference Roberts, Steer and Maplethorpe36). However, maintaining a good nutritional status is crucial for older adults, as this will not only increase well-being but also reduce the risk of disease, enabling them to maintain an independent and high quality of life(Reference Jones, Duffy and Coull37).

Age-related decreases in physical activity and metabolic changes lead to a reduction in the energy needs of older adults(Reference Ndahimana, Go and Ishikawa-Takata38). Although the energy requirement is lower due to changes in body composition and reduced physical activity in this population, it is important to note that the requirement for many nutrients remains relatively unchanged(Reference Shlisky, Bloom and Beaudreault39). Therefore, older adults need a more nutrient-dense diet with lower energy(Reference Clegg and Williams40). Dietary recommendations for macronutrients for older adults in the UK are the same as for the rest of the population(Reference Dorrington, Fallaize and Hobbs41). The Dietary Reference Values suggest that carbohydrates should contribute to 50 % of daily energy intake, while fat intake should not exceed 35 % of daily food intake for both males and females aged 65 years and over.

Adequate protein intake is one of the key nutritional factors for maintaining independence, predominantly by preventing muscle mass loss and strength (known as sarcopenia), frailty and associated comorbidities in later life(Reference Bradlee, Mustafa and Singer42,Reference Wolfe43) . In order to avoid progressive lean body mass loss, regardless of age, the Reference Nutrient Intake for protein for all adults in the UK is 0·75 g/kg/per d(44). The Scientific Advisory Committee on Nutrition (SACN) 2021 report for older adults has also maintained this guideline(45). This recommendation is the minimum amount of protein necessary to maintain nitrogen balance in the body, regardless of physical activity level. However, individuals with low physical activity levels experience decreased nitrogen retention rates, resulting in a relative increase in protein requirement compared with those who are more physically active, in order to preserve muscle tissue(Reference Butterfield and Calloway46). Therefore, it is important to evaluate protein requirements in older adults considering their reduced physical activity(Reference Lonnie, Hooker and Brunstrom47). Furthermore, physiological changes that affect protein utilisation, including anabolic resistance (reduced response of muscle protein synthesis rates to anabolic stimuli like dietary protein and exercise), as well as insulin resistance, impaired digestion and inflammation occurring in the body with ageing, should also be considered(Reference Bauer, Biolo and Cederholm48Reference Wolfe, Miller and Miller50). Considering all these factors, the European Society for Clinical Nutrition and Metabolism (ESPEN) and the PROT-AGE study group recommend increasing protein intake to 1–1·2 g/kg per d for healthy older individuals and to 1·2–1·5 g/kg per d for older individuals who are malnourished or at risk of malnutrition(Reference Dorrington, Fallaize and Hobbs41,Reference Bauer, Biolo and Cederholm48,Reference Deutz, Bauer and Barazzoni51) . Additionally, nutritionally vulnerable adults in health and care settings in the UK are also recommended a higher intake of 1·2 g/kg body weight(52).

Age-related changes in appetite: anorexia of ageing

Appetite is a complex regulatory system involving a multitude of physiological, psychological and environmental variables(Reference Blundell, Rogers, Hill, Colms, Booth, Pangborn and Raunhardt53), controlled by hormonal and neural factors that communicate between the gut and the brain(Reference Hameed, Dhillo and Bloom54). With ageing, many people experience a decline in their appetite, and a number of studies have reported that there is a decrease in food intake in older adults(Reference Donini, Savina and Cannella55,Reference van der Meij, Wijnhoven and Lee56) . A meta-analysis has shown that compared with younger adults, older adults are less hungry, are fuller and have a lower energy intake(Reference Giezenaar, Chapman and Luscombe-Marsh57). In 1988, this reduction in appetite due to age-related changes was first named as the ‘anorexia of ageing’ by John Morley(Reference Morley and Silver58). The anorexia of ageing occurs in 15–30 % of community-dwelling individuals aged 65 years and over(Reference Donini, Poggiogalle and Piredda59,Reference Malafarina, Uriz-Otano and Gil-Guerrero60) , and this rate is higher in women, residents in nursing homes and hospitals, with a prevalence of up to 85 %(Reference Merchant, Woo and Morley61). Anorexia of ageing may be caused by physiological, pathological and social factors and can lead to dramatic consequences such as protein-energy malnutrition, sarcopenia, frailty, functional deterioration, morbidity and mortality(Reference Wysokiński, Sobów and Kłoszewska62). Each of these risk factors and consequences will now be discussed.

Physiological risk factors for anorexia of ageing

Age-related nutritional status can be affected by several changes in physiological functions, including decreased lean body mass, increased cytokine activity, changed gastric distension, delayed gastric emptying, hormonal changes and deterioration of the sense of smell and taste(Reference Ahmed and Haboubi15).

Reduction in lean body mass

As people age, there is a physiological decrease in energy needs and expenditures, leading to a reduction in energy intake. These changes may result from body composition changes, including decreased lean body mass and increased fat mass(Reference Noel and Reddy63). Over the last 20 years, cross-sectional research results strongly support the idea that muscle mass plays a vital role in influencing both energy intake and hunger(Reference Blundell, Caudwell and Gibbons64). In an initial study investigating the associations between body composition and objectively measured ad libitum food intake in adults (aged 19–67 years), a positive relationship was found between energy intake and fat-free mass(Reference Lissner, Habicht and Strupp65). Subsequent studies have further corroborated these findings, highlighting that fat-free mass exhibits a stronger association with self-selected meal size and energy intake compared with fat mass in young adults(Reference Blundell, Caudwell and Gibbons64,Reference Weise, Hohenadel and Krakoff66) . Additionally, research involving older adults also found a link between increases in muscle mass and higher ad libitum energy intake, along with increased postprandial appetite(Reference Johnson, Holliday and Mistry67). Existing evidence suggests that the impact of fat-free mass on eating behaviours may be mediated through RMR(Reference Hopkins, Finlayson and Duarte68,Reference Hopkins, Finlayson and Duarte69) . Consequently, the loss of muscle mass is believed to contribute to a reduction in RMR and energy requirements, leading older adults to naturally consume less(Reference Leslie and Hankey35).

Increase in cytokine activities

Cytokines, which are soluble peptide messengers synthesised by various cells including lymphocytes, neutrophils, macrophages and neuronal cells(Reference Morley and Baumgartner70), undergo changes in concentration as people age. The ageing process is associated with an increase in pro-inflammatory cytokines due to increased concentrations of glucocorticoids and catecholamines and decreased growth and sex hormone production(Reference Yeh and Schuster71). These age-related changes result in increased cytokine levels, which in turn can contribute to delayed gastric emptying and reduced motility in the small intestine, leading to decreased food intake(Reference Landi, Calvani and Tosato72).

Changes in the gastrointestinal tract

Another physiological factor that can impact nutritional status in older adults is the occurrence of age-related changes in the gastrointestinal tract, including impaired gastric motility and decreased gastric acid secretion(Reference Ahmed and Haboubi15). Receptive relaxation impairment in the gastric fundus with ageing leads to rapid antral filling and distension, causing early satiation in older adults(Reference Morley73). Research with younger adults has revealed that stomach distension produces a satiety effect, with fullness being related to total gastric volumes for both nutrient and non-nutrient meals(Reference Marciani, Gowland and Spiller74). The stomach’s mechanosensitivity is evident through experiments utilising intragastric balloon inflation in healthy volunteers, emphasising its role in generating sensations from the stomach(Reference Marciani, Gowland and Spiller74,Reference Geliebter75) . It has also been proposed that the presence of a balloon not only directly inflates the proximal stomach but also promotes antral distension during food consumption, further increasing the feeling of fullness(Reference Janssen, Vanden Berghe and Verschueren76). Studies involving younger adults indicate that delayed gastric emptying is also linked to an increased sense of satiety and fullness, resulting in decreased food intake(Reference Halawi, Camilleri and Acosta77,Reference Wisén and Hellström78) . This prompts the belief that the ageing process plays a role in a significant delay in gastric emptying, contributing to an increased sense of early satiety(Reference Brogna, Loreno and Catalano79). Nevertheless, the intricacies of this process in older adults are still not fully understood.

Hormonal changes

Peptide hormones, believed to be one of the main regulators of appetite, are released from the gastrointestinal tract in response to nutritional stimuli(Reference Moss80). The initiation or cessation of food intake, along with the presence of food in the stomach or small bowel, prompts the secretion of hormones through mechanical and chemical stimuli from the gut(Reference Suzuki, Simpson and Minnion81). These hormones can be categorised into satiety hormones (such as peptide tyrosine tyrosine (PYY), glucagon-like peptide-1 (GLP-1), cholecystokinin (CCK), leptin and insulin) and hunger hormones (ghrelin)(Reference Moss80).

The alterations in these hormones with ageing are considered another physiological factor that may impact the nutritional status of older adults(Reference Pilgrim, Robinson and Sayer82). For example, increased concentration of circulating PYY, early production of PYY post-prandially or enhanced sensitivity to PYY with ageing may all result in increased feelings of fullness, subsequently leading to decreased food intake in older adults, and are believed to contribute to anorexia of ageing(Reference Hickson, Moss and Dhillo83,Reference Johnson, Shannon and Matu84) . Additionally, some age-related changes in CCK have also been reported, including an increased number of CCK immunoreactive cells in the duodenum(Reference Sandström and El-Salhy85), higher fasting plasma CCK levels(Reference MacIntosh, Andrews and Jones86) and a persistent elevation post-meal in older adults(Reference Johnson, Shannon and Matu84,Reference Di Francesco, Fantin and Residori87) , contributing to increased satiety and reduced food intake compared with younger adults(Reference MacIntosh, Andrews and Jones86). Most, but not all, studies have also shown that there is a reduction in ghrelin concentration in older adults compared with younger adults(Reference Di Francesco, Fantin and Residori87,Reference Giezenaar, Hutchison and Luscombe-Marsh88) . A negative correlation has been found between ghrelin concentration and proportion of body fat(Reference Parker and Chapman89). Therefore, it has been suggested that the increase in body fat with ageing causes a decrease in fasting and postprandial ghrelin concentration, resulting in a decline in appetite in older adults(Reference Di Francesco, Fantin and Residori87,Reference Giezenaar, Hutchison and Luscombe-Marsh88) . Several studies, including a meta-analysis, have reported increased circulating leptin levels linked to adipose tissue accumulation in older individuals, both in fasted and postprandial states, contributing to a decrease in appetite and energy intake(Reference Johnson, Shannon and Matu84,Reference Ruhl, Everhart and Ding90,Reference Zoico, Di Francesco and Mazzali91) . Moreover, ageing has been suggested to be associated with elevated blood insulin levels, decreased glucose tolerance and increased blood glucose levels(Reference Gutzwiller, Göke and Drewe92). A meta-analysis confirmed higher concentrations of circulating insulin in both fasted and postprandial states among older adults, correlating with a decrease in appetite and energy intake(Reference Johnson, Shannon and Matu84).

Sense of smell and taste changes

Food-related odours have a role in the stimulation of appetite, and both senses of smell and taste have a significant role in making eating and drinking enjoyable(Reference Landi, Calvani and Tosato72,Reference Yeomans93) . However, sensory sensitivity to both taste and smell can decrease with age due to factors such as a reduction in the replenishment of taste and olfactory receptor cells(Reference Wysokiński, Sobów and Kłoszewska62,Reference Methven, Allen and Withers94) . Such changes in smell and taste perception can contribute to a decline in the perception of the hedonic properties of food in older adults(Reference Schiffman and Graham95). Therefore, food can be perceived as less delicious, and this may result in changes in preference for the types and amounts of food consumed(Reference Mulligan, Moreau and Brandolini96).

Pathological risk factors for anorexia of ageing

Anorexia of ageing can be attributed to various pathological factors, including chronic diseases, depression, medications or poor dentition(Reference Ahmed and Haboubi15). Among these factors, depression is commonly associated with inadequate food intake and nutritional deficiencies in older adults(Reference German, Kahana and Rosenfeld97). Older adults with depression are more likely to experience anorexia of ageing and malnutrition than those without depression(Reference Islam, Disu and Farjana98). Additionally, dementia, particularly Alzheimer’s disease, is another pathological factor contributing to inadequate food intake(Reference Ikeda, Brown and Holland99). Individuals with dementia have nearly twice the risk of anorexia compared with people without dementia(Reference Landi, Lattanzio and Dell’Aquila100).

Many chronic diseases, including cardiac failure, chronic pulmonary obstructive disease, kidney failure, chronic liver disease, chronic constipation, cancer and Parkinson’s disease, can contribute to a decrease in appetite(Reference Donini, Poggiogalle and Piredda59,Reference Pilgrim, Robinson and Sayer82) , which leads to anorexia of ageing(Reference Wysokiński, Sobów and Kłoszewska62). Along with diseases, medications can also play an important role in reducing food intake in older adults(Reference Visvanathan and Chapman101). A large number of prescribed drugs can cause side effects such as dry mouth, metallic taste, nausea, vomiting, constipation and diarrhoea, all of which can negatively affect food intake in older adults(Reference Akamine, Michel Filho and Peres102).

Poor oral health is another pathological factor which contributes to decreased taste sense, and loss of appetite is frequently observed among older adults(Reference Solemdal, Sandvik and Willumsen103). The weakening of teeth and dry mouth can cause older adults to limit their choice of food(Reference Watson, Leslie and Hankey104). Chewing problems, resulting from poor dentition and inappropriate dentures, can further restrict the type and quantity of food consumed by older adults(Reference Donini, Poggiogalle and Piredda59). Additionally, swallowing problems (dysphagia), often associated with conditions such as stroke and other neurological diseases, can limit the amount and type of food intake(Reference Wysokiński, Sobów and Kłoszewska62).

Social risk factors for anorexia of ageing

In addition to physiological and pathological factors, various social factors such as loneliness, widowhood, poverty and low education can affect eating behaviour in older adults(Reference Ramic, Pranjic and Batic-Mujanovic105). Among these social factors, socioeconomic inequality emerges as an important contributor to reduced appetite and food intake in older adults(Reference Landi, Calvani and Tosato72). In many countries, poverty plays a crucial role in reducing food diversity and often leads to inadequate dietary patterns among older adults(Reference Purdam, Esmail and Garratt106). Additionally, low education levels and common misconceptions about dietary restrictions can contribute to poor food choices in this population(Reference Wysokiński, Sobów and Kłoszewska62).

Numerous studies have demonstrated that older adults who live alone have a higher nutritional risk compared with those who live with family members or others(Reference Ramic, Pranjic and Batic-Mujanovic105). Widowhood, among the prevalent conditions faced by older adults, has been recognised as a significant factor influencing their food intake(Reference Wham, Teh and Robinson107). Studies indicate that widows and widowers are at a higher risk of nutritional issues compared with those who are married, partnered, divorced, separated or have never married(Reference Wham, Teh and Robinson107).

The shift from an independent living setting to a nursing home or hospital represents another social factor that notably influences the eating behaviour of older adults(Reference Donini, Savina and Cannella55,Reference de Boer, Ter Horst and Lorist108) . This alteration in the social environment has been linked to an increase in the prevalence of anorexia among older adults living in institutions, such as hospitals (26·7 % men, 33·3 % women), compared with those living independently (11·3 % men, 3·3 % women)(Reference Donini, Dominguez and Barbagallo109). Additionally, the nutrition intake of older adults can be adversely affected by difficulties in shopping and preparing food, particularly in the presence of illnesses and disabilities(Reference Watson, Leslie and Hankey104). A study investigating the home food environment, and the shopping and meal preparation abilities of older adults, showed that individuals struggling with these activities were more likely to have difficulty consuming food, leading to inadequate food intake(Reference Anyanwu, Sharkey and Jackson110).

Consequences of anorexia of ageing: malnutrition

Anorexia of ageing is considered one of the main risk factors for malnutrition among older individuals(Reference Visvanathan111). Although there is no consensus on the definition of malnutrition(Reference Laur, McNicholl and Valaitis112), according to ESPEN, it can be defined as ‘a state resulting from lack of uptake or intake of nutrition leading to altered body composition (decreased fat-free mass) and body cell mass leading to diminished physical and mental function and impaired clinical outcome from disease’(Reference Sobotka and Forbes113). Recent studies focusing on malnutrition in older adults, as indicated by a systematic review, emphasise the link between nutritional deficits and functional disorders(Reference Visser, Volkert and Corish114). Inadequate energy intake causes unintentional weight loss and loss of muscle mass and physical function(Reference Ritchie, Locher and Roth115), contributing significantly to the development of sarcopenia and frailty(Reference Mezuk, Lohman and Rock116). This, in turn, aggravates nutritional problems and can worsen malnutrition(Reference Visser, Volkert and Corish114).

Malnutrition risk increases after the age of 65 years(Reference Margetts, Thompson and Elia117), with higher prevalence observed in older adults (≥ 65 years) compared with younger individuals according to the British Association of Parenteral and Enteral Nutrition’s (BAPEN) Nutrition Screening Survey in the UK (28 % v. 21 %)(Reference Russell and Elia118). Data from the NDNS for the combined period of 2014/2015–2015/2016 showed that individuals aged 65 years and older had a mean daily energy intake below (65–74 years; males 17 %, females 22 %, 75+ years; males 18 %, females 27 %) the EAR and the total energy intake of women aged 75 years and older was significantly lower compared with previous years(Reference Roberts, Steer and Maplethorpe36). Recent NDNS datasets have shown similar findings(Reference Beverley, David and Kerry119). This higher risk of malnutrition is not limited to older individuals experiencing weight loss; it also includes overweight and obese older adults, with a notable prevalence of 18 % among the overweight and 29 % among the obese(Reference Sulmont-Rossé, Wymelbeke-Delannoy and Maître120).

Consequences of anorexia of ageing: frailty

While it has also been difficult to reach a consensus on the definition of frailty, it is considered a progressive age-related reduction in physiological systems, resulting in decreased internal capacity reserves, creating extreme weakness against stress factors and increasing the risk of negative health consequences(Reference Cesari, Prince and Thiyagarajan121). The causes of frailty, a multidimensional condition influenced by genetic, psychological, physiological and environmental factors, are complex(Reference Walston, Hadley and Ferrucci122). There is abundant evidence supporting the notion that the prevalence of frailty increases with advancing age(Reference Collard, Boter and Schoevers123,Reference Rockwood, Song and Mitnitski124) . According to a large European-based cross-sectional study, the estimated prevalence of frailty was found to be 4·1 % among individuals aged 50–64 years, and this percentage increased to 17 % in those aged 65 years and over(Reference Santos-Eggimann, Cuénoud and Spagnoli125).

Frailty is a strong determinant of important adverse health consequences in older adults, and its adverse effects on health-related outcomes, including physical impairment, reduced muscle strength and impaired functional status, have been demonstrated across studies worldwide(Reference Cesari, Prince and Thiyagarajan121,Reference Landi, Russo and Liperoti126) . Additionally, many reviews consistently highlight the role of reduced food intake associated with anorexia of ageing in frailty development(Reference Martone, Onder and Vetrano127Reference Tsutsumimoto, Doi and Makizako129). It has also been linked to an increased risk of falls, prolonged hospital stays and higher mortality rates(Reference Blodgett, Theou and Howlett130Reference Zaslavsky, Zelber-Sagi and Gray132).

Consequences of anorexia of ageing: sarcopenia

Sarcopenia is an age-related loss of muscle and function(Reference Marzetti, Calvani and Tosato133), despite no consensus on the definition(Reference Malafarina, Úriz-Otano and Iniesta134). In 2010, the European Working Group on Sarcopenia in Older People (EWGSOP) developed a practical clinical definition of sarcopenia, and they defined it as a geriatric syndrome characterised by the presence of both low muscle mass and low muscle function, causing increased negative outcomes such as physical disability, poor life quality and increased mortality rates(Reference Cruz-Jentoft, Baeyens and Bauer135). In 2018, the same group updated the definition, emphasising that muscle strength serves as a superior determinant compared with muscle mass in predicting the adverse outcomes associated with sarcopenia(Reference Cruz-Jentoft, Bahat and Bauer136).

Sarcopenia, while potentially observed at any age due to factors like inflammatory diseases, malnutrition, cachexia, disuse atrophy or endocrine disorders(Reference Muscaritoli, Anker and Argiles137), is primarily considered a disease of older adults(Reference Baumgartner, Koehler and Gallagher138). Linked to various adverse health outcomes, sarcopenia is associated with falls, physical frailty, disability and mortality(Reference Marzetti, Calvani and Tosato133). The estimated worldwide prevalence of sarcopenia among individuals aged 60 years and over was found to be 10 % for both males and females(Reference Shafiee, Keshtkar and Soltani139). Additionally, a recent systematic review of individuals aged 60 years or over showed that the prevalence of sarcopenia ranged widely between 17·7 and 73·3 % in older adults living in nursing homes and between 22 and 87 % in those living in assisted-living facilities(Reference Rodríguez-Rejón, Ruiz-López and Wanden-Berghe140).

The pathophysiology of sarcopenia in older adults is complex, involving a number of internal and external factors that contribute to its development(Reference Muscaritoli, Anker and Argiles137). Internal factors include age-related declines in anabolic hormones such as testosterone and growth hormone, oxidative stress caused by free radicals accumulation and changes in the functioning of muscle cells(Reference Joseph, Kenny and Taxel141). Insufficient energy and particularly protein intake(Reference Muscaritoli, Anker and Argiles137,Reference Calvani, Martone and Marzetti142) , along with a sedentary lifestyle and decreased physical activity(Reference Cruz-Jentoft, Landi and Topinková143), alcohol and tobacco use and long-term bed rest(Reference Kortebein, Ferrando and Lombeida144), are external factors that contribute to the loss of muscle mass and function(Reference Muscaritoli, Anker and Argiles137).

Abundant evidence indicates that anorexia of ageing poses a significant risk for physical and mental disruption and is a major factor in the development of sarcopenia in older adults(Reference Morley145). Inadequate food intake associated with anorexia causes a decrease in exercise capacity, muscle mass and strength(Reference Muscaritoli, Anker and Argiles137). Community studies highlight the prevalence of anorexia in free-living older adults (21 %) and its independent association with sarcopenia(Reference Landi, Liperoti and Russo146). In addition to inadequate energy and protein intake, another contributing factor to sarcopenia in older adults is overnutrition, which can lead to sarcopenic obesity and further accelerate the loss of muscle mass(Reference Koster, Ding and Stenholm147). Increasing body fat due to ageing complicates the effects on skeletal muscle, reducing protein synthesis stimulation and contributing to muscle mass loss(Reference Chevalier, Gougeon and Choong148). Furthermore, the secretion of adipocytokines, such as leptin, by increased adipose tissue can have a catabolic effect on muscle mass, ultimately reducing both muscle mass and strength(Reference Roubenoff149).

The impact of dietary protein on appetite and food intake in older adults

Preserving muscle mass is crucial for older adults to maintain independence and overall health(Reference Cruz-Jentoft, Hughes and Scott150). As highlighted above, dietary protein plays a crucial role in ageing, contributing to the preservation of muscle mass and the prevention of conditions such as sarcopenia, frailty, osteoporosis, impaired immune response and associated comorbidities later in life(Reference Bradlee, Mustafa and Singer42,Reference Wolfe43,Reference Bonjour151,Reference Chernoff152) . To achieve this, there is a growing emphasis on the importance of maintenance of appetite and increased protein intake for older adults(Reference Deutz, Bauer and Barazzoni51). Although older adults are advised to maintain or increase their protein intake to preserve their muscle mass(Reference Dorrington, Fallaize and Hobbs41,Reference Bauer, Biolo and Cederholm48,Reference Deutz, Bauer and Barazzoni51) , it is worth noting that studies conducted on younger individuals have consistently demonstrated that protein is the most satiating macronutrient(Reference Blundell and MacDiarmid153Reference Paddon-Jones, Westman and Mattes156). Considering that older adults often experience decreased appetite and food intake, the possibility of increasing protein intake may potentially exacerbate appetite suppression and result in further reductions in overall energy intake. Contrary to this concern, a recent meta-analysis highlighted a positive effect of protein supplementation on energy intake in older adults(Reference Ben-Harchache, Roche and Corish157). However, it is important to acknowledge that most of the included studies comparing protein and other nutrients were not isovolumetric and equienergetic. Consequently, the satiety effect of protein in ageing and its comparability to younger adults remain uncertain.

From this perspective, the authors of this review conducted a randomised controlled trial focused on examining changes in appetite and food intake in response to isoenergetic (∼300 kcal) and isovolumetric (250 ml) preloads containing varying macronutrient compositions (high in protein (48 g v. 5 g), carbohydrate (71 g v. 20 g) and fat (26 g v. 2 g)) in both 20 younger and 20 older adults(Reference Dericioglu, Oldham and Methven158). The findings of the study indicated that the consumption of preloads with different macronutrient content had no significant impact on subsequent energy intake and appetite in either younger or older adults(Reference Dericioglu, Oldham and Methven158). In addition to the primary objective of this study, it has also aimed to investigate the effect of different macronutrients on the gastric emptying rate. The study’s findings revealed that, in older adults, protein consumption resulted in a decrease in the ascension time, one of the parameters, representing a period of high 13CO2-excretion rates. However, it was also observed that the latency phase, representing an initial delay in the excretion curve, accelerated, indicating that protein had no overall effect on the total gastric emptying half-time(Reference Dericioglu, Oldham and Methven158). While this outcome contradicts some, but not all, of the previous studies on protein and appetite in young individuals, it is a promising result for the ageing population(Reference Blundell and MacDiarmid153,Reference Nickols-Richardson, Coleman and Volpe155,Reference Paddon-Jones, Westman and Mattes156) . Notably, the findings suggest that increasing protein intake in older adults can be achieved without adversely affecting subsequent energy intake(Reference Dericioglu, Oldham and Methven158). Contrary to the many studies in the literature, the lack of significant changes in appetite and food intake in young adults following protein consumption compared with other macronutrients may be attributed to alterations in appetite hormones. The macronutrient content of the diet may influence the secretion of appetite hormones, potentially modulating appetite and energy intake(Reference Nguo, Bonham and Truby159). For example, protein has been found to increase GLP-1 and PYY stimulation more so than carbohydrate or fat(Reference van der Klaauw, Keogh and Henning160). In contrast, another study within the authors’ research group, exploring the effect of protein and physical activity on appetite and energy intake in older adults(Reference Dericioglu, Methven and Shafat161), revealed different results(Reference Dericioglu, Oldham and Methven158). This study showed that in a home environment, the consumption of a higher protein preload suppressed the subsequent energy intake and prolonged gastric emptying in older adults without having any effect on perceived appetite(Reference Dericioglu, Methven and Shafat161). The fact that such a difference occurred between these two studies(Reference Dericioglu, Oldham and Methven158,Reference Dericioglu, Methven and Shafat161) , even though the protein amounts and preload volume and energies were equal, showed how important the environmental factor is in the measurement of appetite and energy intake studies and that this should also be taken into account in future studies.

The impact of physical activity on appetite and food intake in older adults

Physical activity is widely encouraged as a health-promoting behaviour for the management of body composition and the prevention of overweight and obesity, among many other benefits for general health(Reference Donnelly, Blair and Jakicic162,163) . Physical activity is believed to have the potential to regulate appetite control by influencing the satiety signal system, additionally influencing food choices and macronutrient preferences by altering the hedonic response to foods in younger individuals(Reference Blundell, Stubbs and Hughes164). Studies investigating the impact of physical activity on appetite and food intake are divided into two broad categories: those examining the acute responses to single bouts of exercise and those exploring the chronic responses to exercise training conducted over weeks or months(Reference Stensel, King and Thackray165). Compared with a single bout of exercise, it is more difficult to examine whether physical activity or regular exercise training increases energy intake over the long term due to the difficulty of objectively measuring energy intake in free-living conditions(Reference Stensel, King and Thackray165).

Evidence on the effect of physical activity on appetite and energy intake varies between different age groups. It is commonly believed that being more physically active results in increased energy intake and better appetite control, and some cross-sectional studies on younger adults have suggested significantly higher energy intake among physically active individuals compared with inactive groups(Reference Beaulieu, Hopkins and Blundell166Reference Rintala, Lyytikäinen and Leskinen170). Additionally, it has been indicated that young individuals who engage in habitual exercise tend to compensate better for energy deficits by increasing their energy intake. Notably, findings reveal that young men involved in regular physical activity (> 120 min/week) demonstrate better energy intake regulation compared with sedentary controls(Reference Long, Hart and Morgan171). Similarly, in another study involving both older and younger adults, it was found that energy intake compensation was more accurate in active individuals compared with sedentary subjects. However, no age-specific interaction with physical activity was identified(Reference Van Walleghen, Orr and Gentile172). As a result, the extent to which this phenomenon applies to older adults remains not fully understood. If older adults can compensate for the energy deficit by becoming more active and maintaining their energy balances, there may be potential for physical activity to play a role in preventing the ‘anorexia of ageing’(Reference Apolzan, Flynn and McFarlin173). Therefore, the relationship between energy balance and appetite needs to be better understood in older adults. The current guidelines of organisations such as the National Health Service (NHS) and Age UK recommend increasing physical activity levels to increase appetite in older adults(24,174) . However, a systematic review has raised concerns regarding the limited evidence supporting the recommendation of increasing habitual physical activity as a means to improve appetite in older adults, without specific knowledge on the types and limits of physical activity to recommend(Reference Clegg and Godfrey175).

In the literature, conflicting results emerge regarding the impact of physical activity on appetite and energy intake in older adults. For example, in a cross-sectional study, habitual physical activity in older adults was linked to increased energy intake with no significant changes in appetite ratings(Reference Shahar, Yu and Houston176). Conversely, insights from a recent randomised controlled trial examining the effects of an acute resistance exercise bout on appetite and energy intake in healthy older adults revealed a slight decrease in perceived appetite, yet no subsequent impact on energy intake(Reference Johnson, Mistry and Holliday177). Adding to the complexity, a systematic review with meta-analysis proposed that exercise and physical activity might modulate resting hunger and satiety in older adults through reductions in fasting glucose and serum leptin levels(Reference Hubner, Boron and Koehler178). To address the confusion in the existing literature, a cross-sectional study was conducted by the authors of this review examining the relationship between physical activity levels, appetite and energy intake in older adults(Reference Dericioglu, Methven and Clegg179). While the findings did not reveal a difference in energy intake, the group with high physical activity levels demonstrated a higher desire to eat(Reference Dericioglu, Methven and Clegg179). This aligns with existing literature, supporting the notion that higher physical activity levels are associated with higher desire to eat among older adults. This also provides strong support for previously unconfirmed recommendations advocating increased physical activity to maintain appetite in this population. Beyond assessing physical activity levels, participants in this study were also categorised into tertiles (low, medium, high) based on both activity and total energy expenditure. The findings revealed a trend towards increased energy intake in the high total energy expenditure group compared with the low group(Reference Dericioglu, Methven and Clegg179). Additionally, significantly higher protein intake was observed in the high activity and total energy expenditure groups compared with the low groups, while the high physical activity group showed a significant increase in fibre intake compared with the low group(Reference Dericioglu, Methven and Clegg179).

To strengthen this finding, the authors of this review also conducted a randomised intervention focusing on both protein intake and physical activity(Reference Dericioglu, Methven and Shafat161). The effects of isoenergetic (∼300 kcal) and isovolumetric (250 ml) preloads with varying protein levels (57 % (∼50 g) v. 17 % (∼13 g) energy as protein) on appetite, food intake and gastric emptying were compared in older adults with either high or low physical activity levels. Contrary to their cross-sectional study(Reference Dericioglu, Methven and Clegg179), the results of their intervention study revealed that having more physical activity exerted a suppressive effect on perceived appetite by delaying gastric emptying(Reference Dericioglu, Methven and Shafat161). Interestingly, despite this influence on gastric emptying, being more physically active did not have a significant impact on subsequent energy intake(Reference Dericioglu, Methven and Shafat161). Hence, it is crucial to note the complexity of appetite, involving hormones and the nervous system, as discussed earlier. Looking ahead, future studies should include the analysis of appetite hormones such as ghrelin, PYY and leptin, which play vital roles in satiety, incorporating blood samples for a more comprehensive understanding of the impact of protein intake and physical activity in older adults.

Conclusion

This review paper discusses appetite-related changes with ageing and their consequences, with a specific focus on exploring the association of protein intake and physical activity with appetite and energy intake in the ageing population. As individuals age, preserving muscle mass becomes crucial, and both protein intake and physical activity play significant roles in this context. Recent studies indicate promising findings that physical activity may play a role in maintaining or increasing appetite among older adults. However, there is still no clear consensus regarding the satiating effect of protein in this population. Therefore, to deepen our understanding of the association of protein and physical activity with appetite, future research should incorporate more intervention studies that include examination of appetite-related hormones and investigations in natural settings.

Acknowledgements

The authors thank the Nutrition Society for the invitation to contribute to the Proceedings of the Nutrition Society after the Nutrition Society Summer Conference 2023.

Financial support

This research was conducted with the financial assistance of the Ministry of National Education of Turkey. The funder had no role in the study design, data collection and analysis, decision to publish or manuscript preparation.

Author contributions

DD drafted the manuscript, with LM and MEC providing intellectual contributions and revisions. All authors approved the final version of the manuscript.

Conflicts of interest

There are no conflicts of interest.

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Figure 0

Fig. 1 Age-related changes impacting nutritional status.