Review article
Nutraceuticals for geriatrics
- Open Access funded by Center for Food and Biomolecules, National Taiwan University
- Under a Creative Commons license
Abstract
Geriatrics
is a medical practice that addresses the complex needs of older
patients and emphasizes maintaining functional independence even in the
presence of chronic disease. Treatment of geriatric patients requires a
different strategy and is very complex. Geriatric medicines aim to
promote health by preventing and treating diseases and disabilities in
older adults. Development of effective dietary interventions for
promoting healthy aging is an active but challenging area of research
because aging is associated with an increased risk of chronic disease,
disability, and death. Aging populations are a global phenomenon. The
most widespread conditions affecting older people are hypertension,
congestive heart failure, dementia, osteoporosis, breathing problems,
cataract, and diabetes to name a few. Decreased immunity is also
partially responsible for the increased morbidity and mortality
resulting from infectious agents in the elderly. Nutritional status is
one of the chief variables that explains differences in both the
incidence and pathology of infection. Elderly people are at increased
risk for micronutrient deficiencies due to a variety of factors
including social, physical, economic, and emotional obstacles to eating.
Thus there is an urgent need to shift priorities to increase our
attention on ways to prevent chronic illnesses associated with aging.
Individually, people must put increased efforts into establishing
healthy lifestyle practices, including consuming a more healthful diet.
The present review thus focuses on the phytochemicals of nutraceutical
importance for the geriatric population.
Graphical abstract
Keywords
- aging;
- geriatrics;
- health;
- nutraceutical;
- nutrition;
- phytochemicals
1. Introduction
Aging
is a complex and inevitable biological process that is associated with
numerous chronically debilitating health effects. It is estimated that
there are about 50 million deaths each year worldwide.1
The top 10 leading causes of all deaths worldwide are ischemic heart
disease (6.3 million), cerebrovascular accidents (4.4 million), lower
respiratory infections (4.3 million), diarrheal disease (2.9 million),
perinatal disorders (2.4 million), chronic obstructive pulmonary disease
(2.2 million), tuberculosis (2.0 million), measles (1.1 million), and
lung cancer (0.9 million). It is evident that in both developing and
developed countries of the world, nutrition-modifiable disease is
potentially responsible for a substantial portion of global deaths.
Important areas of disease and disability in the aging populations in
which nutrition may play a role in prevention are: dyslipidemia and
heart-related problems; hypertension and stroke; cancer; reduced
mobility accompanied by excess body weight with an increased risk of
developing type 2 diabetes; Alzheimer’s disease and other cognitive
impairments including depression; physical deterioration of bones and
joints associated with osteoporosis and arthritis; vision impairment
problems including cataracts and macular degeneration; and an increased
risk of pulmonary problems and infectious diseases.
A
major challenge to health care systems around the world is how to
encourage and maintain a healthy lifespan in large and increasing
populations of elderly individuals.2
Scientists
have identified hundreds of genetic factors called longevity-related
genes that modulate lifespan and health-span in model organisms such as
yeast, worms, flies, and rodents. A number of the longevity-related
genes fall into three conserved nutrient-sensing pathways:
target-of-rapamycin, insulin/insulin-like growth factor-1-like
signaling, and sirtuin pathways.3, 4 and 5 These pathways primarily sense cellular amino acid, glucose, and nicotinamide adenine dinucleotide (NAD)+ or NAD+/NADH
levels, respectively. There are various hypotheses of aging proposed.
The most prominent is the free radical hypothesis, which states that
free radicals, such as reactive oxygen species, generated from
metabolism inflict oxidative damage to macromolecules, including
protein, DNA, and lipid. Accumulation of such oxidative damage with time
causes biological aging and eventually results in death.6
However, numerous studies have now shown that this simplified version
of the free radical hypothesis of aging is not necessarily sufficient to
explain the mechanisms underlying aging processes.
Another
suggestion is the hormesis hypothesis of aging, which has been
frequently used to interpret the prolongevity effects induced by
nutraceuticals. Hormesis theory states that mild stress-induced
stimulation of the defense response at the organism level results in
biologically beneficial effects and extends lifespan and health span.
The defense response involves many protective mechanisms and influences
on gene expression and metabolism.6 and 7
Therefore, significant efforts in developing dietary interventions for
promoting healthy aging have been devoted identifying effective ways to
modulate metabolism and stress.4
It
is believed that half of the world’s oldest populations are found in
five countries: China, India, USA, Japan, and Russia. Currently, out of
the 600 million older persons in the world, 370 million live in
developing countries. A survey indicates that by 2020, 70% of the
world's one billion elderly persons will be living in developing
countries. While in 1950 only 8% of the world’s population was over 60
years old; that proportion will be up to 21% by the year 2050. The
elderly population will make up a substantial proportion of many areas
of the globe.1
The
financial burden of caring for an aging population is substantial.
According to the Center for Disease Control and Prevention, the costs
for health care, long-term care and hospice for people with Alzheimer’s
disease and other dementias alone is expected to increase from $183
billion in 2011 to $1.1 trillion in 2050, in current dollars. Healthy
aging can be achieved by adopting healthy lifestyle practices and
consuming a healthful diet. There are three main contributions to
healthy aging: genetics and family history; lifestyle practices and
exercise; and diet and nutrition. The first of these three factors is
immutable, but the remaining two can be modified to improve health.8
Additionally,
as people grow older, they need fewer calories but more nutrients to
maintain proper health. Generally speaking, people burn fewer calories
during physical activity when they age, but even the most active aging
body gradually loses lean muscle tissue, and less muscle translates to a
lower calorie requirement. At the same time, however, their appetites
decrease while, as previously noted, their needs for several nutrients
goes up or at least remains the same in order to enable the body to run
at peak efficiency as the years pass. To fill these nutrient gaps,
fortified food or beverage products will continue to grow in popularity
and will become a mainstay with any consumer who embraces the concept of
healthy aging.8
2. Primary disease concerns in older populations
With
the advent of the developed medical facilities and technologies, the
average life span of people has increased but unfortunately longevity is
often accompanied by significant disability, despite new medications
and surgical techniques. The most widespread conditions affecting older
people are shown in Table 1.
- Table 1. Diseases common in geriatrics.
Disease/condition Disease/condition Hypertension Osteoporosis Vascular disease Diabetes Congestive heart failure Breathing problems Coronary heart disease Frequent falls/bone fractures Dementia (Alzheimer’s disease) Parkinson’s disease Depression Cancer Incontinence Cataracts Arthritis Glaucoma Macular degeneration Impaired immunity
According
to the Centers for Disease Control and Prevention, 80% of older adults
have at least one of these conditions and 50% have at least two.
3. Nutraceuticals
The term nutraceutical
encompasses a broad spectrum of commercially available products in
which a part or a part of food (nutrient) is intended to provide medical
or health benefits, including the prevention and treatment of disease
(pharmaceutical). Nutraceuticals have no formal regulatory definition
but they can be broadly defined to include functional foods, dietary
supplements, and medical foods. Like nutraceuticals, functional foods
have no legal definition but are distinguished from other types of
nutraceuticals because they are recognizable as conventional food
products. In contrast, dietary supplements are legally defined, which
expressly states, among other requirements, that a product labeled as a
dietary supplement may not be represented as a conventional foodstuff. A
final category, medical foods, is distinguishable from functional foods
and dietary supplements by the requirement that medical foods meet
distinctive nutritional requirements of a disease or condition. Medical
foods must be a food for oral or tube feeding, be labeled for dietary
management of a specific medical disorder, disease, or condition for
which there are established nutritional requirements and be intended for
use under medical supervision.
Chemically,
nutraceuticals may be classified as isoprenoid derivatives (terpenoids,
carotenoids, saponins, tocotrienols, tocopherols, terpenes), phenolic
compounds (couramines, tannins, lignins, anthocyanins, isoflavones,
flavanones, flavanoids), carbohydrate derivatives (ascorbic acid,
oligosaccharides, nonstarch polysaccharides), fatty acid and structural
lipids (n-3 polyunsaturated fatty acids, conjugated linoleic acid,
monounsaturated fatty acids, sphingolipids, lecithins), amino acid
derivatives (amino acids, allyl-S compounds, capsaicinoids,
isothiocyanates, indoles, folate, choline), microbes (probiotics,
prebiotics), and minerals (Ca, Zn, Cu, K, Se).9 and 10
They play a crucial role in maintaining optimal immune response, such
that deficient or excessive intakes can have negative impact on health.
Nutraceuticals,
including dietary supplements and functional foods, are a $152 billion
world market. The percentage of those aged 65 years and older using
nutraceutical products is higher than for any other age group and has
doubled in recent years. Aging is associated with decreased immunity,
increased morbidity and mortality resulting from infectious agents, and
poor nutritional status. Deficiencies in vitamin E, vitamin B6,
folate, zinc, and selenium are particularly common, and deficits in
these micronutrients have been reported to influence immunity
negatively. Thus, if nutraceutical products can improve micronutrient
status, the regular use of nutraceuticals by the elderly population may
provide an opportunity to enhance immunity in this at-risk population.9
Numerous
studies have demonstrated the effects of nutraceuticals from fruit or
plant extracts in reducing oxidative damage and promoting healthy aging
in invertebrate models. The active ingredients in nutraceuticals that
are generally produced by plants as secondary compounds appear
to help plants overcome stressful conditions. The beneficial properties
of nutraceuticals can be attributed to the varieties of phytochemicals,
such as flavonoids, anthocyanin glycosides, triterpenoids, and
proanthocyanidin oligomers. 9, 11 and 12 In this review, the phytochemicals with nutraceutical potential for geriatric individuals will be discussed briefly.
4. Phytochemicals for age-related disease and disability
Table 2
lists some important phytochemicals that can be potentially helpful in
the prevention of certain age-related chronic diseases and associated
disability.
- Table 2. Phytochemicals of nutraceutical importance for geriatrics.
Phytochemical/nutraceutical Target disease/condition Calcium and vitamin D Osteoporosis, cancer, diabetes Antioxidants (vitamin E, vitamin C, polyphenols) Cancer, heart disease, neurodegenerative disease B vitamins (folate, vitamin B6, vitamin B12) Heart disease, cognition Omega-3 fatty acids (fish oil, DHA, EPA) Inflammation, heart disease, stroke Plant stanols/sterols Elevated blood cholesterol, heart disease Glucosamine, chondroitin, and collagen Osteoarthritis Lutein, zeaxanthin, and lycopene Macular degeneration EGCG Cancer Fiber (soluble and insoluble) Diabetes, constipation Prebiotics and probiotics Diarrhea Potassium Hypertension Whey protein Sarcopenia Zinc Immunity, macular degeneration Coenzyme Q10 Inflammation, endothelial dysfunction - DHA = docosahexaenoic acid; EGCG = epigallocatechin-3-gallate; EPA = eicosapentaenoic acid.
5. Nutraceuticals for geriatrics
5.1. Antioxidants
A prominent theory of aging and chronic disease has been the free radical theory,
in which a lifelong accumulation of cellular damage due to free
radicals leads to an increased risk of disease and disability. In living
cells, two antioxidant defense system are present against free radical
damage. The first line of defense includes antioxidant enzymes (such as
superoxide dismutase, catalase, and glutathione peroxidase) and the
second line includes low molecular weight nonenzymatic antioxidants
(thioredoxin, glutathione, vitamins A, C, E, lycopene, lutein,
polyphenols, quercetin, etc.). It is thought, therefore, that diets rich
in antioxidants, such as vitamin E and vitamin C and many bioactive
polyphenol compounds found in fruits and vegetables will help to combat
free radical damage and improve health. This theory is consistent with
strong association with better health outcomes, and may have positive
effects on cancer, heart disease, and neurodegenerative diseases. 13 and 14
These
antioxidants inhibit the formation of free radicals by breaking the
chain reaction or can reduce the concentration of free radicals by
donating hydrogen and electron. They also act as peroxide decomposers
(vitamin E), enzyme inhibitors, singlet oxygen quenchers (vitamin E),
synergists, and metal-chelating agents (transferritin). To provide
maximum intracellular protection, antioxidants are strategically
compartmentalized throughout the cell. So that free radical produced in
intracellular and extracellular during metabolism, both enzymatic and
nonenzymatic antioxidants are able to detoxify free radical.13
Certain
antioxidant enzymes (superoxide dismutase, catalase, and glutathione)
are produced within the body. Other antioxidant agents are found in
foods such as green leafy vegetables and it is believed that diets rich
in antioxidants (such as β-carotene and vitamins A, C, and E) are
beneficial to human health.15
Therefore, antioxidants naturally present in body or supplied in the
form of diet (phytonutrients) play an important role to control various
diseases resulting from oxidative stress. Raw fresh fruits and
vegetables are of more importance than cooked, because of their high
concentration and maximum absorption of antioxidants. Researchers are
trying to determine the relationship between antioxidants and prevention
of some diseases, such as cardiovascular disease and cancer.13
5.2. Plant polyphenols and catechins: turmeric (薑黃 jiāng huáng), green tea (綠茶 lǜ chá), grape seed
Polyphenols
are naturally occurring compounds found largely in fruits, vegetables,
legumes, cereals, and beverages. Legumes and chocolate also contribute
to the polyphenolic intake. These molecules are secondary metabolites of
plants and are generally involved in defense against ultraviolet
radiation or aggression by pathogens. Basic research and epidemiological
studies have shown an inverse association between risk of degenerative
diseases and intake of diet rich in polyphenols. Epidemiological studies
provide convincing evidences that diet rich in antioxidants is
associated with a lower incidence of degenerative diseases. The
curcuminoid polyphenols, which are the primary polyphenols in the
rhizome (underground stem) of the turmeric plant Curcuma longa L.
(turmeric; 薑黃 jiāng huáng) and are responsible for its yellow color,
have potent antioxidant, anti-inflammatory, and anticancer properties.
These properties have led to investigations into the impact of curcumins
in preventing cognitive decline relating to Alzheimer’s disease. 15
The
major sources of dietary polyphenols are cereals, legumes (barley,
corn, nuts, oats, rice, sorghum, wheat, beans, and pulses), oilseeds
(rapeseed, canola, flaxseed, and olive seeds), fruits, vegetables, and
beverages (fruit juices, tea, coffee, cocoa, beer, and wine).16 and 17
Fruits such as apple, grape, pear, cherry, and various berries contain
up to 200–300 mg polyphenols per 100 g fresh weight. Similarly, a glass
of red wine or a cup of coffee or tea contains about 100 mg polyphenols.
Their total dietary intake may be about 1 g/day, which is about 10
times higher than that of vitamin C and 100 times higher than those of
vitamin E and carotenoids.18
The
chief constituents of tea polyphenols are flavonols (catechin,
epicatechin, catechingallate, and epigallocatechin gallate), flavanols
(quercetin, kaempferol, and their glycosides), flavones (vitexin,
isovintexin), and phenolic acids (gallic acid, chlorogenic acid). They
constitute up to 30% of the dry weight of green leaves and 9–10% of the
dry weight of black tea leaves. Ferulic acid is associated with dietary
fiber linked with hemicellulose of the cell wall by means of ester
bonds. Caffeic acid in the form of caffeoyl esters and coumaric acids
are common in apples, pears, and grapes. Additionally, apples and pears
are rich in chlorogenic acid and grapes in gallic acid. Apples contain
the highest levels of quercetin among fruits. Grain-derived products are
especially significant in human diet as they have higher concentration
of phenolic acids in the outer layers of kernel that constitute the
bran. Most of the phenolic acid derivatives are hydrolysable tannins and
are usually esterified with glucose. Citrus fruits are major sources of
flavonones and hesperidin is found in abundance (120–250 mg/L) in
orange juice.
Green tea
polyphenols have been shown to have powerful antioxidant,
anti-inflammatory, and anticancer benefits. The most famous of these is
epigallocatechin-3-gallate (EGCG). EGCG is found in high concentrations
in green tea. As a member of the catechin family of compounds, it has
antioxidant properties, but it also has other biochemical effects in
cells. The majority of emphasis on the health promoting effects of EGCG
has been related to its potential anticancer activities, particularly
related to hormone-sensitive cancers.19 and 20 Cancer is the second leading cause of death in the elderly.
Grape
seed extract (GSE) is a concentrated source of polyphenols. These
resemble the catechins of green tea in basic molecular structure with
the exception that components in GSE reach a larger molecular size.
Although clinical research on GSE for inflammation and cancer is not as
advanced as that for the curcumins, and green tea catechins, there is
abundant animal and in vitro evidence suggesting that GSE also
has efficacy in applications aimed at protecting against oxidative
stress and aiding circulation, in addition to its general
anti-inflammatory and anticancer effects. 15
5.3. Carotenoids: lutein, zeaxanthin, and lycopene
Dietary
carotenoids are obtained from a number of fruits and vegetables, such
as green leafy vegetables, spinach, carrots, peaches, apricots, and
sweet potatoes. Carotenoids are highly pigmented, yellow, orange and
red, are present in fruits and vegetables, and when consumed by birds
are incorporated into egg yolk. Carotenoids comprise two types of
molecule: carotenes and xanthophylls. Lutein and zeaxanthin are members
of the carotenoid family of compounds and are found abundantly in green
leafy vegetables. These carotenoids have healthful properties and are
found in high concentrations in the macula of the eye, which is
responsible for central vision. Macular degeneration is a common problem
in the elderly and is among the four leading eye diseases found in this
population. Supplementation of patients with early signs of macular
degeneration with lutein and zeaxanthin has been shown to be beneficial.21
In addition, consumption of diets rich in lutein and zeaxanthin have
been found in a recent meta-analysis to be associated with a reduction
in the risk of developing late stage macular degeneration.22
Lycopene is also a member of the carotenoid family and is responsible
for the red to pink color found in tomatoes and watermelon and some
other fruits and vegetables. Epidemiologic, animal, and cell culture
evidence support a role for lycopene in cancer prevention.23
Based
on epidemiological studies a positive link is suggested between higher
dietary intake and tissue concentrations of carotenoids and lower risk
of chronic diseases.24
Human diet supplemented with carotenoids is beneficial in reducing
chronic conditions related to coronary heart diseases, certain cancers,
and macular degeneration. β-carotene and lycopene have been shown to be
inversely related to the risk of cardiovascular diseases and certain
cancers where as lutein and zeaxanthin to the disorders related to the
eye. Lutein protects against uterine, prostate, breast, colorectal, and
lung cancers. They may also protect against risk of digestive tract
cancer. The xanthophyll types of carotenoids offer protection to other
antioxidants, and they may exhibit tissue specific protection.
Zeaxanthin, cryptoxanthin, and astaxanthin are members of the
xanthophyll group. The antioxidant properties of carotenoids have been
suggested as being the main mechanism by which they afford their
beneficial effects. Recent studies are also showing that carotenoids may
mediate their effects via other mechanisms such as gap junction
communication, cell growth regulation, modulating gene expression,
immune response, and as modulators of Phase I and II drug metabolizing
enzymes.24
The
nutraceutical industry synthetically manufactures five major
carotenoids on an industrial scale (lycopene, β-carotene, canthaxanthin,
zeaxanthin, and astaxanthin) for use in a range of food products and
cosmetics, such as vitamin supplements and health products and as feed
additives for poultry, livestock, fish, and crustaceans.25
One of the most commercially valuable pigments, astaxanthin, is
primarily synthesized by marine microorganisms, such as the green alga Haematococcus pluvialis
and accumulates in fish such as salmon, coloring their flesh red.
Astaxanthin has been implicated as a potential therapeutic agent
treating cardiovascular disease and prostatic cancer. 24, 20 and 26
5.4. Plant stanols/sterols (phytosterols)
Plant
sterols and stanols, an important terpene subclass, are naturally found
in small amounts in many plant-based foods. The primary sources of
phytosterols are vegetables, nuts, fruits, and seeds. Seeds contain an
average of 120 mg of plant sterols/100 g wet weight; vegetables contain
20 mg/100 g of wet weight; and fruit about 15 mg/100 g wet weight.
Sitosterol, campesterol, and stigmasterol are most abundant in nature
comprising 65%, 30%, and 3% of dietary phytosterol intake, respectively.27
The primary phytosterols in the diet are sitosterol, stigmasterol, and
campesterol and typical consumption of plant sterols is approximately
160–400 mg/day. The enrichment of foods with phytosterols is one of the
recent developments in functional foods to enhance the
cholesterol-lowering ability of traditional food products.28
Two sterol molecules that are synthesized by plants are β-sitosterol
and its glycoside. These compounds have cholesterol-lowering properties
resulting from the inhibition of cholesterol absorption.29
They are now widely used as food fortificants to help lower blood
cholesterol and reduce the risk of heart disease. Since dyslipidemia is
an important risk factor for heart disease and a common condition in
older people, it would be prudent for this population to consider using
plant stanol/sterol-enriched food products as part of a healthy diet.20
In
recent studies, these two molecules have been shown to exhibit
anti-inflammatory, antineoplastic, antipyretic, and immunomodulating
activity in experimental animals. Phytosterols have been reported to
block inflammatory enzymes, for example by modifying the prostaglandin
pathways in a way that protected platelets. Phytosterols compete with
cholesterol in the intestine for uptake, and aid in the elimination of
cholesterol from the body. In the intestine, plant sterols are initially
solubilized into a micelle form. These micelles interact with brush
border cells and are transferred into enterocytes. Plant sterols are
esterified within the enterocyte, assembled into chylomicrons and
secreted into the lymphatics. They are excreted via the biliary system.
5.5. B vitamins
The
status of B-group vitamins is frequently inadequate in the elderly and
recent studies have shown associations between loss of cognitive
function or Alzheimer disease and inadequate B vitamin status. Evidence
of the importance of the B vitamins folic acid, vitamin B-12, and
vitamin B-6 for the well-being and normal function of the brain derives
from data showing neurological and psychological dysfunction in vitamin
deficiency states and in cases of congenital defects of one-carbon
metabolism. These inadequacies could give rise to impairment of
methylation reactions that are crucial to the health of brain tissue. In
addition, these inadequacies could result in hyperhomocysteinemia, a
recently identified risk factor for occlusive vascular disease, stroke,
and thrombosis, any of which may result in brain ischemia. Advances in
the understanding of this putative relation between inadequate vitamin
status and loss of cognitive function in the elderly are likely to be
slow and may depend on the outcomes of both prospective studies and
longitudinal studies in which nutritional intervention is provided
before cognitive decline occurs.30 and 31
Scientific studies have shown that B-vitamins have possible roles in heart disease and cognitive impairment.30 Vitamin B6, Vitamin B12,
and folate are three important B-vitamins that are involved in
metabolic cycles that supply the body with methyl groups (1-carbon
metabolites) that are important to many functions in the body, including
homocysteine metabolism, a potential risk factor for heart disease.31
5.6. Calcium and vitamin D
A
recent study suggested that vitamin D when taken with calcium can
reduce the rate of mortality in seniors, thereby providing a possible
means of increasing life expectancy.32
The
role of calcium and vitamin D has been associated with its important
function in bone metabolism and the prevention of osteoporosis. However,
in recent years, there has been increased research attention placed on
the nonskeletal roles of these nutrients. For example, high calcium
diets have been shown to have some efficacy in reducing the risk of
colon cancer and the recurrence of colonic polyps, while vitamin D has
been implicated in a variety of diseases including diabetes and various
cancers.31
5.7. Omega-3 fatty acids
Omega-3
(n-3) fatty acids are found in fish oil and in some plants, such as
flaxseed. N-3 fatty acids are known to have anti-inflammatory effects
and to lower blood triglycerides33 and 34
and have also been suggested to have a positive effect in patients
suffering from recent myocardial infarction (heart attack) or heart
failure. The Japan EPA Lipid Intervention Study (JELIS) found a 19%
reduction in the risk of coronary heart disease and a significant
reduction in recurrent stroke after long-term use of pure
eicosapentaenoic acid (EPA) in Japanese patients with
hypercholesterolemia.35 and 36
Higher circulating long-chain omega-3 fatty acids have also been shown
to be associated with a lower risk of congestive heart failure in a
prospective cohort study.37
Omega-3 intake may also play a role in cancer development; for example,
a recent study found that higher omega-3 intake was associated with a
decrease in breast cancer risk in obese Mexican women.38
Currently, an ongoing study, called VITAL (Vitamin D and Omega-3
Trial), is investigating the effects of these compounds in a large
randomized, double-blind, placebo-controlled study of primary cancer and
cardiovascular disease prevention.39
Another interesting finding concerning omega-3 fatty acids is that
female health professionals consuming higher intakes of EPA and
docosahexaenoic acid had a lower incidence of age-related macular
degeneration.20 and 40
A publication from the Food Agriculture Organization in 201041 contains dietary recommendations for total fat, saturated, trans,
and polyunsaturated fatty acids, lipoic acid, α-lipoic acid, and their
metabolites EPA and docosahexaenoic acid, for adults, pregnant and
lactating women, infants aged 0–2 years, and children aged 2–18 years
old. The recommendations are expressed as energy percentage. For adults,
total fat intake is 20–35%, 42
minimum intake for lipoic acid and α-lipoic acid to prevent deficiency
is 2.5% plus 0.5% respectively; minimum total polyunsaturated fatty
acids for reducing cardiovascular risk is 6%. 34
5.8. Glucosamine, chondroitin, collagen, and quercetin
Glucosamine
and chondroitin are part of normal cartilage. Cartilage acts as a
cushion between the bones in a joint. During movement, the cartilage
that surrounds the ends of bones in joints is subject to breaking down
and must be repaired. Cartilage is composed of type II collagen. Studies
have shown that oral consumption of these building blocks of cartilage
is believed to be beneficial in reducing pain and protecting bone
cartilage. A recent randomized, double-blind clinical trial in 40
Japanese patients with symptomatic knee osteoarthritis found an
improvement in symptoms in those receiving a combination of glucosamine
hydrochloride, chondroitin sulfate and quercetin glycosides compared to
the receiving placebo.43
Likewise, a study in Spain in 250 patients with knee osteoarthritis
found that treatment with collagen hydrolysates resulted in a
significant improvement in knee joint comfort.44
Moreover, a study in Belgium found in a follow-up of individuals who
had previously been enrolled in clinical trials of glucosamine sulfate
for knee osteoarthritis and had received treatment for at least 12
months that the glucosamine treatment group were 57% less likely to
require total joint replacement surgery compared to the placebo group.45
Glucosamine,
also called chitosamine, is a natural substance that is found in the
covering of shellfish. It is available in different forms, including
glucosamine hydrochloride, N-acetyl-glucosamine, and glucosamine
sulfate, which is a combination of glucosamine and mineral salt.
Quercetin,
a potent antioxidant, is found in red wine, onions, green tea, apples,
berries and cruciferous vegetables and is a popular component in the
herbal and supplemental marketplace due to its value in treating and
preventing many illnesses. Studies have shown that
quercetin-incorporated collagen matrix could be a novel dressing
material for dermal wound healing. Quercetin, a flavonoid present in the
human diet has been shown to inhibit platelet aggregation and signaling in vitro. Consequently, it has been proposed that quercetin may contribute to the protective effects against cardiovascular disease. 46
The study showed relatively high systemic availability of quercetin in
the form of quercetin-4′-O-b-D-glucoside by supplementation, and
implicates quercetin as a dietary inhibitor of platelet cell signaling
and thrombus formation. 46
5.9. Dietary fiber
Dietary
fiber intake is important from a metabolic viewpoint (lipid and glucose
metabolism), acting as prebiotics on microbiota health, in preventing
colonic cancer, in treating bowel diseases and symptoms, on mineral
absorption. Fiber intake seems to be important in particular in the
elderly to the point that all national dietary guidelines and food guide
pyramids for elderly people underline the necessity to increase dietary
fiber intake, and therefore fruits and vegetables.47
Dietary fiber can be classified into either soluble fiber or insoluble
fiber. These two types of fiber have different effects metabolically due
to their different chemical properties. Soluble dietary fiber, such as
found in peas and soybeans, are soluble in water and have a gelling
effect in the intestine and can thereby slow down the digestion of
carbohydrates and flatten out the postprandial blood glucose curve. This
metabolic effect of soluble fiber can be of benefit to help control
blood glucose levels in diabetes. Insoluble dietary fiber is not water
soluble and relatively indigestible, tending to increase the dry matter
content of the stool and aiding in the prevention of constipation.48
5.10. Prebiotics and probiotics
Probiotics (particularly belonging to genera Lactobacillus and Bifidobacterium)
and prebiotics (nondigestible oligosaccharides) have been shown to be
useful in preventing certain disease conditions and promoting specific
aspects of health particularly in the elderly population. Both
probiotics and prebiotics are helpful in malnutrition, lactose
intolerance, and calcium absorption and in constipation. Probiotics have
also been shown to boost immunity in elderly people. 49
It is believed that large populations of friendly bacteria aid in
keeping the growth of unfriendly pathogenic bacteria and yeast at bay.
An imbalance (dysbiosis) of intestinal bacteria can be caused by
antibiotic treatment and result in disease, including antibiotic-induced
diarrheal disease. Thus, it is believed that supplying the body with
good bacteria (probiotics), such as those from the Lactobacillus and Bifidobacterium
genera can help restore the correct bacterial balance. Prebiotics are
nondigestible food carbohydrates that can enter the large intestine and
act as nutritional supplements to stimulate the growth of certain
intestinal bacteria. At present, a synbiotic formulation, consisting of a
mixture of the above selected strains, oligosaccharides as prebiotic
ingredients, glutamin, vitamin B6 and zinc, has been
developed. The most used and already marketed synbiotics regard mixtures
of oligofructose, fructo-oligosaccharides, galacto-oligosaccharides,
with probiotic bacterial strains of Lactobacillus plantarum, Lactobacillus paracasei, Lactobacillus rhamnosus, Bifidobacterium bifidum, or Bifidobacterium lactis.
Prebiotics
and lactic acid bacteria (probiotics) have demonstrated beneficial
effects with respect to the function of innate immunity, intestinal
barrier function, and increased resistance to disease. The gut mucosa
and microbiota are intimately linked in the maintenance of a functional
interface between the host and the external environment. The hope is
that a combined supply of prebiotics and probiotics (synbiotics) shall
have synergistic effects in enhancing immunity and facilitating
intestinal barrier function.50 and 20
5.11. Potassium
When
blood potassium levels exceed the normal range of 3.6–5.2 mmol/L, a
condition called hyperkalemia develops. A high potassium level can lead
to widespread muscle fatigue and weakness. If left untreated, it can
cause muscle paralysis and potentially fatal problems with heart rhythm.
The elderly are particularly at risk for hyperkalemia. High-potassium
foods are often common components of an elderly person’s regular diet.
Milk is a main source of calcium, but also provides plenty of potassium.
For elderly patients with dental problems, high-potassium yogurt,
boiled potatoes, tomatoes, and bananas are soft and easy to eat. Many
older people also favor prunes or raisins, which are also very high in
potassium. Additional dietary sources of potassium include meat, fish,
broccoli, lima beans, citrus fruits, and apricots.51
However,
potassium is an essential mineral nutrient that plays a number of
critical roles in the body. Research has shown that diets high in fruits
and vegetables are associated with a reduced risk of hypertension (high
blood pressure), which may be due to the beneficial effects of dietary
potassium on blood pressure.52
Low potassium levels produce an increased risk of death or
hospitalization in patients with heart failure and chronic kidney
disease.
5.12. Whey protein
Whey
protein is an important protein constituent of milk that may have
health promoting properties. A recent study in elderly men found that
consumption of a test meal that contained higher amounts of whey protein
(35 g vs. 10 g) was associated with increased amino acid absorption and
an increase in muscle protein synthesis.53
The same group had previously observed that feeding whey protein to
elderly men had a more positive impact on muscle synthesis rates than
feeding casein, the other major milk protein, as a protein source.54
These findings suggest that feeding whey protein may have a beneficial
effect on building muscle mass in the elderly, which would be important
because aging is associated with a loss of lean body mass (sarcopenia),
which is an important cause of frailty and disability.55
Whey
proteins are considered to have the highest nutritional values of all
food proteins. They contain all the amino acids required by humans, in
the right proportions. Whey proteins are rich in branched chain amino
acids, components that provide energy for people undergoing intense or
prolonged periods of exercise and help prevent loss of body mass and
muscle. They are also readily digestible and completely bioavailable.
Whey proteins supply additional nutritional benefits; for example,
α-lactalbumin, the second most abundant whey protein, has a high content
of the amino acid tryptophan, a precursor of the vitamin niacin.56 and 57
The
health and nutritional value of the components of whey include: high
quality nutritional source of amino acids; antimicrobial action; growth
enhancement of beneficial gut microflora, such as bifidobacteria;
immunoenhancing properties; control of specific diseases, including
cancer; and antitoxin activity.58 and 57
5.13. Zinc
Zinc
is an essential trace element that is biochemically involved in a wide
variety of reactions and has important effects on DNA synthesis, cell
proliferation, and differentiation. The trace element zinc is essential
for the immune system, and zinc deficiency affects multiple aspects of
innate and adaptive immunity. There are remarkable parallels in the
immunological changes during aging and zinc deficiency, including a
reduction in the activity of the thymus and thymic hormones, a shift of
the T helper cell balance toward T helper type 2 cells, decreased
response to vaccination, and impaired functions of innate immune cells.
Many studies confirm a decline of zinc levels with age. Most of these
studies do not classify the majority of elderly as zinc deficient, but
even marginal zinc deprivation can affect immune function. Immune
function is compromised in zinc deficiency59 and zinc supplementation along with antioxidants may play a role in protecting people from macular degeneration.60
Studies have shown that normal serum zinc concentrations in nursing
home elderly were associated with decreased incidence and duration of
pneumonia, and decreased use and duration of antimicrobial therapy. Zinc
supplementation to maintain normal serum zinc concentrations in the
elderly may help reduce pneumonia incidence and associated morbidity.61
Consequently, oral zinc supplementation demonstrates the potential to
improve immunity and efficiently downregulates chronic inflammatory
responses in the elderly. These data indicate that a wide prevalence of
marginal zinc deficiency in elderly people may contribute to
immuno-senescence.62
5.14. Coenzyme Q10
Coenzyme Q10
is a vitamin-like compound that plays an important role in aerobic
respiration in the mitochondria of the cell and is involved in the
generation of ATP, which is used as an energy source by the cell.
Coenzyme Q10 is also a powerful antioxidant that can reduce oxidative stress. Supplementation with coenzyme Q10
has also been found to have an anti-inflammatory effect by reducing the
inflammatory marker IL-6 in patients with coronary artery disease.63 Another study has found that coenzyme Q10 supplementation improves endothelial function in patients with heart disease.64 Coenzyme Q10 may also be implicated in cancer because a recent study in Chinese women observed that low plasma coenzyme Q10 levels are associated with an increased risk of breast cancer.65 It has also been shown that coenzyme Q10 affects creatine kinase activity and mood in geriatric bipolar depression.66
6. Supplementary dietary botanicals for geriatrics
6.1. Ginkgo biloba for neuroprotection
Ginkgo is widely known for its health benefits for the elderly population in Chinese medicine.67 Extract of Ginkgo biloba is well known to prevent Alzheimer’s disease (AD). The herbal extract EGb761 prepared from G. biloba
is rich in phytochemicals such as flavonoids and terpenoids. These
phytonutrients improve the functions of platelets and nerve cells and
the blood flow to the nervous system and brain, due to their antioxidant
properties. 68
6.2. Vaccinium corymbosum (blueberry) for lifespan extension
Blueberries (Vaccinium corymbosum)
are one of the richest sources of antioxidants. They contain a wide
array of polyphenols that offer a variety of health benefits. 69
Antioxidants optimize health by helping to combat the free radicals
that can damage cellular structures as well as DNA. Animal studies have
shown that supplementation of blueberry preserves learning and memory in
experimental animals by improving neuronal function. Studies in Caenorhabditis elegans
have also shown that polyphenols present in blueberries significantly
increased the lifespan by decreasing age-related accumulation of the
intracellular level of lipofuscin, a biomarker for age-related cellular
damage, and reduces the level of 4-hydroxynonenal, a biomarker for lipid
peroxidation. 70
In addition, blueberry polyphenols improve the pharyngeal pumping rates
of aged worms and increase thermo-tolerance, thereby improving the
worms’ health span. A recent study has demonstrated that blueberry
extract extends mean lifespan by approximately 10% in Drosophila. 71 These research findings in invertebrates suggest the pivotal role of blueberries in mediating lifespan extension.
6.3. Cranberry and oregano for longevity promotion
Cranberry (Vaccinium oxycoccos) and oregano (Origanum vulgare)
possess multiple medicinal properties, such as antimicrobial,
antiviral, antimutagenic, antiangiogenic, and antioxidative functions. 72
Scientists have shown that a mixture of oregano and cranberry (OC)
extract increased lifespan in Mexican fruit flies (mexfly) in a diet
composition dependent manner. 73 In addition, OC supplementation in middle age was sufficient to promote longevity. 74
However, lifespan was not increased when OC was supplemented only in
young age or old age. These findings point out the importance of
considering diet composition and implementing time in developing an
efficacious aging intervention.
Scientists have also assessed the effect of cranberry extract alone on lifespan and health-span in C. elegans. The data indicate that the cranberry extract alone is sufficient to prolong lifespan in C. elegans. 75
Cranberries are high in antioxidants and phytochemicals, including
proanthocyanidins and vitamin C, which may neutralize free radicals and
reduce oxidative damage, and, more importantly, modulate signaling
transduction pathways. 69 and 76
6.4. Nectarine and acai for life span extension
Nectarine (Prunus persica) is a globally consumed fruit 77 and acai (Euterpe oleracea) is a fruit indigenous to the Amazon River area. 78 Both fruits contain various kinds of bioactive phytochemicals. 79 and 80 Studies have shown that nectarine supplementation can extend lifespan in flies.
There
are several scientific studies carried out on experimental animals that
show the role of nectarine and acai in extension of longevity of life.
Research has shown that the lifespan extension induced by nectarine is
associated with increased lifetime reproductive output and reduced lipid
oxidation.81 In contrast, supplementation of acai pulp promotes survival in Drosophila fed with a high-fat but not a standard diet. 82
The diet composition dependent effect of acai is also evident in the
mexfly. Acai supplementation promotes the survival of the mexfly fed a
high-fat and high sugar diet but not other nonfat diets. 83
Along with the OC study described above, the importance of diet
composition is also evident in aging intervention studies using
pharmacological agents, such as resveratrol. Studies in Drosophila, mexfly, and mice have shown that the prolongevity effects of resveratrol depend on diet composition. 84
These studies again stress the importance of diet composition in
modulating the health benefits of nutraceuticals. Moreover, both
nectarine and acai can promote the survival of flies with sod1 deficiency. Flies deficient in sod1
have a short lifespan and experience high levels of oxidative damage.
These findings suggest that nectarine and acai possess antioxidant
activities at the organism level. 83 and 85
6.5. Rosa damascena for life span extension
A hybrid rose species, Rosa damascena, is well known for its use as rose oil and water in cosmetic and food industries. 86 It is well documented that the extracts from R. damascene
contains numerous volatile organic compounds including various terpenes
such as citronellol, heneicosane, and disiloxane, and polyphenols, such
as quercetin, myricetin, kaempferol, and gallic acid. 87R. damascena
extracts have been shown to possess biological properties that are
protective against microbial infection, seizures in rats, and toxicity
of amyloid beta in neurons, a biomarker of AD. 88 and 89 An R. damascena extract has been found to increase both mean and maximum lifespan in Drosophila. This extract also enhances flies’ resistance to oxidative stress and low iron stress. It has been proposed that R. damascena extract extends lifespan by protecting flies against iron-induced stress.
6.6. Cocoa polyphenols and longevity effect
Numerous
polyphenols with high antioxidant activities, such as flavonoids, have
been isolated from cocoa. Research has shown that flavonoid-enriched
cocoa powder reduces oxidative stress in C. elegans. 90 Cocoa polyphenols may promote longevity by reducing oxidative stress, influencing metabolism, and altering chromatin structure.
6.7. Green tea as health supplement
Green
tea contains polyphenolic catechins that have been reported to have a
number of health benefits, including prevention of AD, Parkinson’s
disease, and heart disease.91 Green tea can protect against angiogenesis and tumor formation.92
The health benefits of green tea are due to bioactive properties of its
phytochemical constituents. Green tea contains a number of polyphenolic
catechins, such as epicatechin, epicatechin-3-gallate,
epigallocatechin, EGCG, catechin, and gallocatechin.91
Among these, EGCG is perhaps the most abundant catechin in green tea,
and has been reported to induce antioxidant enzymes, including
glutathione peroxidase, catalase, and glutathione S-transferase,
in mice. In addition, a recent study demonstrated that l-theanine, a
unique amino acid particularly present in green tea promotes the
survival of C. elegans in the presence of paraquat. 93
It has been reported that l-theanine provides broad health benefits,
such as antitumor, AD prevention, and blood pressure reduction. 94 and 95 These findings suggest that green tea increases lifespan and stress resistance partially through its antioxidant properties.
6.8. Olive oil as a phenolics supplement
Scientific studies have shown that consumption of olive oil has beneficial effects on health and longevity in humans.96 and 97
This is due to the abundance of phenolic compounds present in olive
oil. Preclinical studies have revealed that the tyrosol, one of the most
abundant phenols in olive oil,98 significantly promotes the longevity of C. elegans, and also resistance to thermal and oxidative stress. 99
6.9. HSP-12.6 for protein homeostasis
It
has been reported that small heat shock proteins, including HSP-12.6,
can extend lifespan and delay polyglutamine protein aggregation in C. elegans. 100
Heat shock factor protein 1 is critical for maintaining protein
homeostasis. Experimental studies suggest that tyrosol in olive oil
extends lifespan by increasing oxidative stress resistance and
thermo-tolerance as well as improves protein homeostasis. 99
6.10. Quercetin and tannic acid as health supplement
Quercetin
(3,3′,4′,5,7-pentahydroxyflavone) is one of the most important dietary
flavonoids present in a wide array of foods such as fruits and
vegetables and has numerous health benefits.101 Preclinical studies have shown that quercetin increases the lifespan of C. elegans. 102 and 103
However, studies on the molecular basis have yielded conflicting
results and the mechanisms underlying the prolongevity effect of
quercetin are still unknown.
Tannic
acid (TA) belongs to tannins, which are secondary metabolites of plants
with many health benefits. TA possesses many phytochemicals that
prevent neurodegeneration,104 pathogen infection,105 carcinogenesis, and oxidative damage.106 In an experimental study, it was found that TA significantly increases the lifespan of worms.102
Transcriptome
studies indicate that quercetin affects expression of genes in the
TGF-β signaling, insulin-like signaling, and p38 MAPK pathways, while TA
changes expressions of genes in the TGF-β and the p38 MAPK pathways as
well as the amino acid metabolism. Together, these studies suggest that
TGF-β and p38 MAPK pathways play crucial roles in mediating the
prolongevity effects of quercetin and TA.107
6.11. Caffeic acid and rosmarinic acid for lifespan extension
Caffeic
acid [3-(3,4-dihydroxyphenyl)-2-propenoic acid; CA] and rosmarinic acid
(α-o-caffeoyl-3, 4-dihydroxyphenyl lactic acid; RA) are abundantly
present in a variety of fruits, vegetables, and herbs. CA and RA have
anticarcinogenesis, antioxidant, antimicrobial, anti-inflammatory, and
antirheumatic properties. CA and RA can prolong the healthy lifespan of C. elegans. 108
Similar results have been obtained for CA mediated lifespan extension.
The research findings suggest that CA and RA promote lifespan extension
through overlapping pathways involved in metabolism and stress response.
6.12. Spermidine for prolonging lifespan
Spermidine
is a type of polyamine present in citrus fruits and soybean, and has
effects on epigenetic modifications, autophagy and necrosis.109 and 110 Polyamine concentrations and autophagy have been shown to decline in various organisms, including humans.111 Preclinical studies have shown that supplementation of spermidine prolongs the lifespan of C. elegans and Drosophila by 15% and 30%, respectively. 109
More research is needed to see if spermidine and its derivatives can
confer lifespan extension in humans by, at least in part, enhancing
autophagy.
6.13. Curcumin and thioflavin T as health supplements
Curcumin (diferuloylmethane) is the pharmacologically active substance in turmeric (Curcuma longa),
and has been widely used as an herbal medicine in Asia. It is well
documented that curcumin possesses many biological activities, such as
antioxidative, anti-inflammatory, anticancer, chemopreventive, and
antineurodegenerative properties. 112 and 113 With its pleiotropic activities, curcumin has been considered as a potential aging intervention compound. Studies in Drosophila and C. elegans have demonstrated that curcumin can delay aging and prolong the lifespan. 114 and 115
Curcumin-treated flies exhibited enhanced resistance against oxidative
stress, improved locomotor activity, and higher tolerance to
chemotherapy drugs.
6.14. Formulation challenges
There
are several formulation challenges while attempting to design fortified
functional foods for geriatric individuals. Some of the issues include
possible chemical interactions between nutrient ingredients, issues
related to final product acceptance, product stability, taste and
texture concerns, and product shelf-life.116
In
the development of nutraceuticals for geriatrics, manufacturers should
take into consideration that aging is associated with some notable
physiological changes, including the loss of taste. Therefore, the
incorporation of flavor enhancers and textual considerations should be
carefully addressed in premix development for these products. As the
taste of the product is of paramount importance for a product to be
successful, it is important to pay close attention to flavor intensity,
masking any off notes, and addition of colorants. Products can be
flavored with herbs and spices, and a number of other ingredients can be
included in a premix or finished product to intensify product color or
enhance texture to increase product appeal. Additionally, as consumers
age healthfully, many are more likely to be taking medications to
address certain health conditions, so formulators need to consider
potential interactions with common medicines. For example, within the
juice category, the interaction between grapefruit juice and some
immunosuppressant drugs (statins) used to lower blood cholesterol, and
calcium-channel blockers used to treat high blood pressure would suggest
that more attention should be placed on fortifying other types of juice
applications for this population.116
7. Conclusion
From
the above review it is evident that nutraceuticals made from
widely-consumed plant products promote longevity, improve health-span,
and protect against aging and stress. The diet composition-dependent
effects will have a significant impact on the increasing demand for
personalized nutritional intervention. However, the individual and
synergistic effects of nutraceuticals as a component of dietary
composition will require further study and scientific scrutiny. Some
nutraceuticals and their synthetic derivatives are being tested for
their therapeutic potential. Numerous promising results have been
obtained in model organisms that suggest evolutionarily conserved
mechanisms are involved in their beneficial effects. Much progress has
been made to decipher the molecular mechanisms of aging shared among
multiple species, which provide valuable guidance for aging
interventions. However, further extensive studies will be required to
demonstrate whether any nutraceuticals or pharmaceuticals can
effectively delay aging or age-related disease in humans.
Conflicts of interest
All contributing authors declare no conflicts of interest.
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