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Nutritional issues for older adults: addressing degenerative ageing with long-term studies

Published online by Cambridge University Press:  26 February 2016

Lisette C. P. G. M. de Groot Open the ORCID record for Lisette C. P. G. M. de Groot [Opens in a new window]
Lisette C. P. G. M. de Groot*
Affiliation:
Division of Human Nutrition, Wageningen University, Bomenweg 2, 6703 HD Wageningen, The Netherlands
*
Corresponding author: L. C. P. G. M. de Groot, fax 00 31 317 48 27 82, email Lisette.deGroot@wur.nl
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Abstract

The ageing process is influenced by a variety of factors, including extrinsic, malleable lifestyle variables. The present paper deals with the epidemiological evidence for the role of dietary patterns and key nutritional concerns in relation to survival and ageing-related disorders that present themselves in later life. Healthful dietary patterns appear to be most relevant in old age. Specific nutritional concerns are related to vitamin D, vitamin B12 and protein malnutrition. An important challenge to further expand the knowledge base is currently addressed by the NuAge project, acknowledging the complexity of the ageing process and integrating different dimensions of research into human healthy ageing. In the meantime, reversing poor adherence to existing guidelines for a healthy diet remains a first challenge in public health nutritional practices.

Keywords

NutritionAgedHealthSurvival
Type
Conference on ‘Nutrition at key life stages: new findings, new approaches’
Information
Proceedings of the Nutrition Society , Volume 75 , Issue 2 , May 2016 , pp. 169 - 173
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Copyright
Copyright © The Author 2016 

Ageing and nutrition

Many industrialised countries now have ageing populations. In EU-27, the proportion of Europeans over the age of 65 is projected to increase from 17·4 % (2011) to approximately 30 % by 2060( 1 ). Even though most people reach old age in reasonable health, they are facing potential consequences of the ageing process. Ageing occurs through the lifelong accumulation of subtle faults in cells and tissues resulting in progressive loss of function, frailty and disease( Reference Kirkwood 2 ). Common features such as a mild chronic pro-inflammatory status, or inflammageing( Reference Franceschi 3 ), are implicated in several ageing-related pathologies such as osteoporosis, dementia and sarcopenia and may become major disabling conditions( Reference De Groot and van Staveren 4 ). As yet, there is substantial mechanistic evidence that it is possible to impact on the interplay between intrinsic factors and nutrition( Reference Santoro, Pini and Scurti 5 ). Moreover, in the past decades many epidemiological studies have uncovered a significant role of diet quality in the prevention of chronic disease and mortality later in life, whereby nutrition intervention studies have demonstrated benefits for dietary patterns and specific nutrients. The present paper aims to address the epidemiological evidence for the role of dietary patterns and key nutritional concerns in relation to survival and ageing-related disorders that present themselves later in life. In the meantime Nu-Age, an European Commission-funded project, is holistically interrogating the link between diet and ageing in order to define new dietary strategies addressing the specific needs of older adults( Reference Hughes 6 ).

Dietary patterns and survival

The dietary intake of foods and nutrients are related, and, as people do not eat single nutrients or foods, evaluating dietary patterns has attracted considerable interest in nutritional epidemiology. Assessing dietary quality by dietary patterns has the advantage of capturing the high inter-correlation of nutrients within a diet, as well as integrating complex interactive effects of many dietary exposures( Reference Jacques and Tucker 7 ). This follows from several systematic reviews of prospective studies relating adherence to a healthful diet to survival or increased longevity.

A recent review( Reference Jankovic, Geelen and Streppel 8 ) included eleven cohorts from Europe and the USA and comprised a total sample of 396 391 elderly participants with 84 978 deaths. Overall, a healthier diet according to WHO guidelines was associated with lower risk of death (average relative risk 0·90, for a 10 points increase on a scale of 0–70). Depending on the cohort, up to 18 % of deaths could be attributed to an unhealthy diet, and an increase in 10 healthy diet points was associated with a 2-year increase in life expectancy for a person aged 60 years. Such analyses confirm that the WHO dietary guidelines are valuable to promote overall good health.

Correspondingly adherence to a Mediterranean diet type appears to be relevant in old age. Combined analysis of eighteen prospective studies involving an overall study population of more than 4 000 000 subjects, uncovered that a 2-point increase in adherence score to the Mediterranean diet (scale 0–9/10) reduces the risk of overall mortality (8 %), and the incidence and/or mortality from cardiovascular (10 %) and neoplastic causes (4 %)( Reference Sofi, Macchi and Abbate 9 ).

Additional evidence from a recent review suggest that better adherence to a Mediterranean diet is also associated with less cognitive decline, dementia, or Alzheimer's disease as shown by four of six cross-sectional studies, six of twelve longitudinal studies, one trial and three meta-analyses( Reference van de Rest, Berendsen and Haveman-Nies 10 ).

In the European Prospective Investigation into Cancer and Nutrition, the EPIC-Elderly study, it has been questioned to what extent dietary patterns relate to health expectancy using quality-adjusted life years as outcome parameter. It turned out that two of the five studied dietary patterns, the modified Mediterranean Diet Score and the Healthy Diet Indicator, were statistically significantly associated with approximately 2 months longer healthy life, which is noteworthy from a public health perspective( Reference Fransen, Beulens and May 11 ).

There is growing evidence from intervention studies for a protective role of healthful dietary patterns. In a dietary intervention study conducted in Spanish middle-aged over a follow-up period of 4·8 years, subjects following the Mediterranean diet were reported to have a 30 % lower risk of CVD in a primary prevention setting( Reference Estruch, Ros and Salas-Salvadó 12 ), whereas the efficacy of a hybrid of Mediterranean-Dietary Approach to Systolic Hypertension diet intervention for neurodegenerative delay (MIND-diet) is yet to be demonstrated( Reference Morris, Tangney and Wang 13 ).

Much more established is the evidence for the effect of adherence to a healthful, Mediterranean type of diet along with other healthful lifestyle practices, including non-smoking, moderate alcohol consumption and physical activity. Taken together, the combinations of lifestyle practices appeared to be associated with a mortality rate of about one-third that of those with none or only one of these healthful lifestyle behaviours( Reference Knoops, de Groot and Kromhout 14 ) and with an estimated increase in life-expectancy of 2 (sd 0·3) years.

Specific nutritional concerns in old age

In general, the nutritional requirements of older adults are the same as for the rest of the adult population( Reference Doets, de Wit and Dhonukshe-Rutten 15 ) although for some nutrients, including for example vitamins D and B12, an adequate supply is hard to achieve, even with an apparently adequate food intake.

In most European countries, the percentage of the population with vitamin D insufficiency is high among the aged, though prevalences vastly depend on the set serum 25-hydroxyvitamin D  level( Reference Hilger, Friedel and Herr 16 ). The European Survey on Nutrition and the Elderly (SENECA) on community dwelling older persons showed that 40 % had serum 25-hydroxyvitamin D levels below 30 nm/l( Reference de Groot, Verheijden and de Henauw 17 ). The latter standard is much below the currently proposed level of at least 50 nm/l in e.g. the Netherlands and the USA( 18 ). Approximately one-third of the vitamin D requirements can be obtained from the diet. The rest is synthesised in the skin under the influence of sunlight. As a result of limited sunlight exposure and a fourfold reduced capacity of the skin to produce vitamin D, deficiencies may occur even in apparently healthy older people( Reference Hilger, Friedel and Herr 16 ). In most countries, dietary intakes of mostly vitamin D are far lower than recommended levels( Reference ter Borg, Verlaan and Hemsworth 19 ). As a consequence, options for optimising vitamin D status, depending largely on medical, social, cultural, legal and financial aspects, e.g. vitamin D supplements or vitamin D-enriched food products, have been implemented or are still considered across Europe( Reference Weggemans, Schaafsma and Kromhout 20 ).

As for vitamin D, vitamin B12 deficiency is highly prevalent in the elderly. Among elderly participants of the SENECA study Europe some 25 % had plasma cobalamin levels <260 pm/l and plasma methylmalonic acid levels >0·32 µm/l( Reference de Groot, Verheijden and de Henauw 17 ). Both vitamins D and B12 are predominantly derived from animal sources. However, deficiencies can occur when vitamin B12 malabsorption is present. Atrophic gastritis reduces the absorption of several nutrients, which leads, especially for vitamin B12 to a deficiency state, which only partly could be explained by dietary intake or atrophic gastritis( Reference de Groot, Verheijden and de Henauw 17 ). As yet there is no evidence that vitamin B12 is handled differently in old age once the vitamin is absorbed. Therefore, other factors responsible for the cobalamin deficiency need to be sought( Reference Doets, In ‘t Veld and Szczecińska 21 ).

There is a large body of evidence to indicate that malnutrition is a common problem in older adults. Estimates of the prevalence are undeniably high: up to 60 % of hospitalised elderly and 70 % of those in residential care are malnourished. Among community-dwelling elderly, 44 % are considered at risk and 11–35 % are malnourished( Reference Agarwal, Miller and Yaxley 22 ). Most malnutrition risk exists in the community, where numbers will grow as recent policies aim at ageing at home in the community, not in institutions. Inadequate nutritional intake is the predominant cause of under nutrition in old age. When intakes decline to levels below requirements, foods which are nutrient-dense become particularly important( Reference Morley, van Staveren, Raats, de Groot and van Staveren 23 ).

Consequences of nutritional inadequacies

Much remains to be learned about how nutrition interacts with intrinsic and extrinsic factors in order to extend healthy life expectancy, independence and wellbeing in old age. In the meantime, observational studies continue to provide clues to healthy ageing, whilst supporting evidence from well-designed controlled trials needs to be expanded.

Vitamin D is with calcium known for its critical importance for bone health. Both seem crucial targets for preventive and treatment measures of osteoporosis. On whether or not to combine the two nutrients, not only randomised trials examining the effect of vitamin D supplementation, with or without calcium, on the incidence of fractures/falls have produced conflicting results, but also recent meta-analyses do so, even within 1 year: ‘A higher received dose of supplemental vitamin D (482–770 UI/d) should reduce fractures by at least 18 %; the addition of calcium to adequate intakes of vitamin D does not seem to enhance the effect of vitamin D’( Reference Bischoff-Ferrari, Willett and Wong 24 ); ‘Vitamin D alone appears unlikely to be effective in preventing hip fracture. Vitamin D with calcium reduces hip fractures (relative risk 0·84, 95 % CI 0·73, 0·96)’( Reference Avenell, Gillespie and Gillespie 25 ).

The latest analysis of individual patients’ data from eleven large fracture trials however indicates that only a high intake of vitamin D leads to a significant reduction in the risk of hip fracture (30 %) and any non-vertebral fracture (14 %), whereby a smaller amount of calcium supplementation (<1000 mg/d), as compared with a larger amount (⩾1000 mg/d), may be more beneficial in reducing the risk of fracture( Reference Bischoff-Ferrari, Willett and Orav 26 ).

It is currently assumed that vitamin D generates more biological responses than previously thought. As illustrated by the tissue distribution of the vitamin D receptor the biological effects of vitamin D are widening, from mediating only calcium homeostasis to functioning in other physiologic areas including the brain, muscle, the immune system, insulin secretion by the pancreatic β-cell, heart functioning and blood pressure regulation( Reference Lanham-New, Buttriss and Miles 27 ). Thus, deficiency may affect the broader spectrum of functional outcomes, involving brain, muscle, vascular and heart health.

Vitamin B12 deficiency has widely been known as pernicious anaemia, arising from an uncommon lack of intrinsic factor due to severe gastric atrophy. In old age, the main cause of deficiency is food-cobalamin absorption, characterised by the inability to release vitamin B12 from food or its binding proteins( Reference De Groot and van Staveren 4 ). Cobalamin deficiency manifests itself in a variety of ways, haematological, gastrointestinal and neurological. The efficacy studies which have been done so far, provide however no consistent evidence either way, that vitamin B12 and/or folic acid have a beneficial effect on cognitive function of unselected healthy or cognitively impaired older people( Reference Clarke, Bennett and Parish 28 ). So far, only one relatively small study demonstrated that high doses of B vitamins can be used to reduce the rate of atrophy of the brain in elderly people with mild cognitive impairment( Reference Smith, Smith and de Jager 29 ).

In the past decade, it has been shown that vitamin B is also involved in bone health. Its deficiency may lead to decreased bone mass by increased osteoclast formation due to increased methylmalonic acid and Hcy levels( Reference Vaes, Lute and van der Woning 30 ). Meta-analyses and some cross-sectional and cohort studies suggest a small but significant role of vitamin B12 status on risk of fracture but not on bone mineral density( Reference Bailey and van Wijngaarden 31 ), but these findings do not find support in a large and long-lasting homocysteine lowering trial in elderly people with mildly increased homocysteine levels( Reference van Wijngaarden, Swart and Enneman 32 ).

Undernutrition is one of the features of malnutrition, reflecting poor energy and protein intake, generally accompanied by inadequate micronutrient intakes( Reference Cederholm, Bosaeus and Barazzoni 33 ). A review on protein and energy supplementation in malnourished elderly reported evidence for weight gain, but found no evidence for positive effects on functional performance( Reference Milne, Potter and Vivanti 34 ). However, there is growing evidence that older adults can improve their muscle mass, muscle strength and functional performance by consuming an adequate amount of protein in combination with physical activity( Reference Paddon-Jones, Campbell and Jacques 35 , Reference Cermak, Res and de Groot 36 ).

Recommendations and guidelines

With basically similar nutritional requirements as the adult population at large, in old age both the quality and the quantity of the diet are important to ensure that requirements for both macronutrient and micronutrient intakes are met. However, as older people age, they may need fewer calories because they are not as physically active as when they were younger and their metabolic rate slows down. As a result nutrients and food components need to be obtained with less energy intake and nutrient and food density of the diet needs to increase( Reference De Groot and van Staveren 4 ). Generic guidance on a healthy diet for older adults is provided by national and international bodies (WHO: Keep fit for life; UK: Food Standard Agency; USDA: Dietary Guidelines for Americans). Unfortunately sustained adherence to such generic guidelines tends to be low. Effective strategies to enhance or sustain adherence to such guidance are therefore warranted, further to the development of age-specific and up-to-date guidelines or recommendations specifically for older adults( 37 ).

Still a major challenge for the future of nutrition and ageing research is to further expand the knowledge base, acknowledging the complexity of the ageing process (including its inflammatory features) and integrating different dimensions of research into human healthy ageing. Nu-Age is addressing this challenge by studying the efficacy of counteracting inflammaging through a whole-diet approach. By an integrating and holistic view of the effect of such whole-diet approach on the prevention of age-related decline, it aims at contributing to dietary standards, recommendations and guidelines and showing how diet can help European seniors to live a healthier, longer life( Reference Santoro, Pini and Scurti 5 ).

Acknowledgements

NuAge was supported by the European Union's Seventh Framework Programme under grant agreement no. 266486.

Financial Support

Meeting attendance was funded by the Nutrition Society, Irish Section.

Conflicts of Interest

None.

Authorship

References

1. European Commission: Eurostat: Population Structure and Ageing (2015). http://eurostat.ec.europa.eu/statistics_explained/index.php/population_structure_and_ageing#future_trends_in_population_ageing.Google Scholar
2. Kirkwood, TB (2008) A systematic look at an old problem. Nature 451, 644647.CrossRefGoogle Scholar
3. Franceschi, C (2007) Inflammaging as a major characteristic of old people: can it be prevented or cured? Nutr Rev 65, S173S176.CrossRefGoogle ScholarPubMed
4. De Groot, CPGM & van Staveren, WA (2010) Nutritional concerns, health and survival in old age. Biogerontology 11, 597602.Google Scholar
5. Santoro, A, Pini, E, Scurti, M et al. (2014) Combating inflammaging through a Mediterranean whole diet approach: the NU-AGE project's conceptual framework and design. Mech Ageing Dev 136–137, 313.Google Scholar
6. Hughes, V (2012) Cultural differences. Studies of gut bacteria are beginning to untangle how diet affects health in old age – but determining cause and effect is tricky. Nature 492, S14S16.CrossRefGoogle Scholar
7. Jacques, PF & Tucker, KL (2001) Are dietary patterns useful for understanding the role of diet in chronic disease? Am J Clin Nutr 73, 12.Google Scholar
8. Jankovic, N, Geelen, A, Streppel, MT et al. (2014) Adherence to a healthy diet according to the World Health Organization guidelines and all-cause mortality in elderly adults from Europe and the United States. Am J Epidemiol 180, 978988.Google Scholar
9. Sofi, F, Macchi, C, Abbate, R et al. (2014) Mediterranean diet and health status: an updated meta-analysis and a proposal for a literature-based adherence score. Public Health Nutr 17, 27692782.Google Scholar
10. van de Rest, O, Berendsen, AA, Haveman-Nies, A et al. (2015) Dietary patterns, cognitive decline, and dementia: a systematic review. Adv Nutr 6, 154168.Google Scholar
11. Fransen, HP, Beulens, JW, May, AM et al. (2015) Dietary patterns in relation to quality-adjusted life years in the EPIC-NL cohort. Prev Med 77, 119124.Google Scholar
12. Estruch, R, Ros, E, Salas-Salvadó, J et al. (2013) PREDIMED study investigators primary prevention of cardiovascular disease with a Mediterranean diet. N Engl J Med 368, 12791290.CrossRefGoogle Scholar
13. Morris, MC, Tangney, CC, Wang, Y et al. (2015) MIND diet slows cognitive decline with aging. Alzheimers Dement. pii: S1552-5260(15)00194-6. doi: 10.1016/j.jalz.2015.04.011. [Epublication ahead of printing]Google Scholar
14. Knoops, KT, de Groot, LC, Kromhout, D et al. (2004) Mediterranean diet, lifestyle factors, and 10-year mortality in elderly European men and women: the HALE project. JAMA 292, 14331439.CrossRefGoogle ScholarPubMed
15. Doets, EL, de Wit, LS, Dhonukshe-Rutten, RA et al. (2008) Current micronutrient recommendations in Europe: towards understanding their differences and similarities. Eur J Nutr 47, Suppl. 1, 1740.CrossRefGoogle ScholarPubMed
16. Hilger, J, Friedel, A, Herr, R et al. (2014) A systematic review of vitamin D status in populations worldwide. Br J Nutr 111, 2345.CrossRefGoogle ScholarPubMed
17. de Groot, LC, Verheijden, MW, de Henauw, S et al. (2004) Lifestyle, nutritional status, health, and mortality in elderly people across Europe: a review of the longitudinal results of the SENECA study. J Gerontol A Biol Sci Med Sci 59, 12771284.Google Scholar
18. Institute of Medicine (2011) Dietary Reference Intakes for Calcium and Vitamin D. Washington, DC: The National Academies Press.Google Scholar
19. ter Borg, S, Verlaan, S, Hemsworth, J et al. (2015) Micronutrient intakes and potential inadequacies of community-dwelling older adults: a systematic review. Br J Nutr 113, 11951206.CrossRefGoogle ScholarPubMed
20. Weggemans, RM, Schaafsma, G & Kromhout, D (2009) Towards an adequate intake of vitamin D. An advisory report of the Health Council of the Netherlands. Eur J Clin Nutr 63, 14551457.CrossRefGoogle ScholarPubMed
21. Doets, EL, In ‘t Veld, PH, Szczecińska, A et al. (2013) Systematic review on daily vitamin B12 losses and bioavailability for deriving recommendations on vitamin B12 intake with the factorial approach. Ann Nutr Metab 62, 311322.CrossRefGoogle ScholarPubMed
22. Agarwal, E, Miller, M, Yaxley, A et al. (2013) Malnutrition in the elderly: a narrative review. Maturitas 76, 296302.Google Scholar
23. Morley, JE & van Staveren, WA (2009) Undernutrition: diagnosis, causes, consequences and treatment. In Food for the Ageing Population, 1st ed., pp. 153166 [Raats, M, de Groot, L & van Staveren, W, editors]. Woodhead Publishing Limited, Cambridge.Google Scholar
24. Bischoff-Ferrari, HA, Willett, WC, Wong, JB et al. (2009) Prevention of nonvertebral fractures with oral vitamin D and dose dependency: a meta-analysis of randomized controlled trials. Arch Intern Med 169, 551561.Google Scholar
25. Avenell, A, Gillespie, WJ, Gillespie, LD et al. (2009) Vitamin D and vitamin D analogues for preventing fractures associated with involutional and post-menopausal osteoporosis. Cochrane Database Syst Rev 15, CD000227.Google Scholar
26. Bischoff-Ferrari, HA, Willett, WC, Orav, EJ et al. (2012) A pooled analysis of vitamin D dose requirements for fracture prevention. N Engl J Med 367, 4049.Google Scholar
27. Lanham-New, SA, Buttriss, JL, Miles, LM et al. (2011) Proceedings of the rank forum on vitamin D. Br J Nutr 105, 144156.Google Scholar
28. Clarke, R, Bennett, D, Parish, S et al. (2014) B-Vitamin Treatment Trialists’ Collaboration. Effects of homocysteine lowering with B vitamins on cognitive aging: meta-analysis of 11 trials with cognitive data on 22,000 individuals. Am J Clin Nutr 100, 657666.Google Scholar
29. Smith, AD, Smith, SM, de Jager, CA et al. (2010) Homocysteine-lowering by B vitamins slows the rate of accelerated brain atrophy in mild cognitive impairment: a randomized controlled trial. PLoS ONE 5, e12244.CrossRefGoogle Scholar
30. Vaes, BL, Lute, C, van der Woning, SP et al. (2010) Inhibition of methylation decreases osteoblast differentiation via a non-DNA-dependent methylation mechanism. Bone 46, 514523.Google Scholar
31. Bailey, RL & van Wijngaarden, JP (2015) The role of B-Vitamins in bone health and disease in older adults. Curr Osteoporos Rep 13, 256261.Google Scholar
32. van Wijngaarden, JP, Swart, KM, Enneman, AW et al. (2014) Effect of daily vitamin B-12 and folic acid supplementation on fracture incidence in elderly individuals with an elevated plasma homocysteine concentration: B-PROOF, a randomized controlled trial. Am J Clin Nutr 100, 15781586.Google Scholar
33. Cederholm, T, Bosaeus, I, Barazzoni, R et al. (2015) Diagnostic criteria for malnutrition – an ESPEN consensus statement. Clin Nutr 34, 335340.Google Scholar
34. Milne, AC, Potter, J, Vivanti, A et al. (2009) Protein and energy supplementation in elderly people at risk from malnutrition. Cochrane Database Syst Rev CD003288.Google Scholar
35. Paddon-Jones, D, Campbell, WW, Jacques, P et al. (2015) Protein and healthy ageing. Am J Clin Nutr 101 (supplememt), S1339–1345.Google Scholar
36. Cermak, NM, Res, PT, de Groot, LC et al. (2012) Protein supplementation augments the adaptive response of skeletal muscle to resistance-type exercise training: a meta-analysis. Am J Clin Nutr 96, 14541464.Google Scholar
37. European Commission, Joint Research Centre (2014) The Role of Nutrition in Active and Healthy Ageing. For Prevention and Treatment of Age-related Diseases so Far. Luxembourg: Publications Office of the European Union.Google Scholar