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Food and Nutrition Sciences, 2012, 3, 1644-1650
http://dx.doi.org/10.4236/fns.2012.312215 Published Online December 2012 (http://www.SciRP.org/journal/fns)
Peanuts and Their Nutritional Aspects—A Review
V. S. Settaluri1,2, C. V. K. Kandala3, N. Puppala1, J. Sundaram4
1New Mexico State University, Las Cruces, USA; 2Department of Biotechnology, K. L. University, Guntur, India; 3National Peanut
Research Laboratory, United States Department of Agriculture, Agricultural Research Service, Dawson, USA; 4United States De-
partment of Agriculture, Agricultural Research Service, Athens, USA.
Email: chari.kandala@ars.usda.gov
Received September 1st, 2012; revised November 16th, 2012; accepted November 23rd, 2012
ABSTRACT
Peanut is a legume crop that belongs to the family of Fabaceae, genus Arachis, and botanically named as Arachis hy-
pogaea. Peanuts are consumed in many forms such as boiled peanuts, peanut oil, peanut butter, roasted peanuts, and
added peanut meal in snack food, energy bars and candies. Peanuts are considered as a vital source of nutrients. Nutri-
tion plays an important role in growth and energy gain of living organisms. Peanuts are rich in calories and contain
many nutrients, minerals, antioxidants, and vitamins that are essential for optimum health. All these biomolecules are
essential for pumping vital nutrients into the human body for sustaining normal health. This paper presents an overview
of the peanut composition in terms of the constituent biomolecules, and their biological functions. This paper also dis-
cusses about the relationship between consumption of peanuts and their effect on human metabolism and physiology. It
highlights the usefulness of considering peanuts as an essential component in human diet considering its nutritional
values.
Keywords: Peanuts; Nutrition; Biomolecules; Vitamins; Minerals; Plant Protein
1. Introduction
Peanuts are believed to have originated in Central Ameri-
can region from where they spread to other parts of the
world. They are widely cultivated in India, Africa, South
America, United States [1], China [2] and a few other
countries. Peanuts often are enriched with health bene-
fiting nutrients that are beneficial to human health. They
are actually legumes but are the most frequently eaten
“nut” in the United States. Studies show that peanuts,
peanut butter, and peanut oil significantly reduce the risk
of heart disease when consumed daily, similar to other
nuts. More than 300 different varieties of peanuts are
grown worldwide, which include Virginia, Valencia,
Georgia runner, Tennessee red, Tennessee white and
many others. They are usually consumed after roasting or
boiling, and also processed into different forms such as
peanut butter, candy, chocolates, cakes, and others. Pea-
nut butter and jelly sandwiches are popular in the Ame-
rican culture [3], with raw, roasted, shelled or unshelled
forms of peanuts being available in United States
throughout the year. Peanuts vary in color from red to
brown and are usually coarse in their appearance. Raw
peanuts and peanuts prepared without salt are naturally
low in sodium, having 18 mg of sodium per 100 g. This
equates to only 5.4 mg of salt in a 30 g serving. The nu-
tritional importance of peanuts is due to the energy and
growth supplementing constituents present in them. These
include carbohydrates, lipids, proteins, vitamins, miner-
als, some organic acids and purines. It is estimated that
as much as 30% of the population from many countries
in the world are suffering from malnutrition [4]. Peanuts,
which are a rich source of protein and essential amino
acids, can help in preventing malnutrition [5]. Moreover,
peanuts contain lipids and carbohydrates which are en-
ergy rich compounds, capable of complementing the ba-
sic energy demands of the human body. In this article the
chemical composition of peanuts, all types, dry-roasted,
without salt is reviewed, and their importance as a useful
source of nutrition is discussed.
2. Broad Composition of Dry-Roasted
Peanuts, without Salt
The basic composition of peanuts per 100 g of nuts [6] is
as below:
Water 1.55 g
Carbohydrates 21.51 g
Fiber 8.0 g
Lipids (Fats) 49.66 g
Proteins 23.68 g
Energy (Total Calories) 2448 kJ (585 kcal)
Table 1 given below describes the sub composition of
the above categories under every major molecule such as
Copyright © 2012 SciRes. FNS
Peanuts and Their Nutritional Aspects—A Review 1645
Table 1. Composition by weight* of biomolecules in peanuts [6].
Amino acids Vitamins
Type Weight (g)* Type Weight (g)*
Tryptophan 0.230 Thiamin 0.438 × 10–3
Threonine 0.811 Riboflavin 0.098 × 10–3
Isoleucine 0.833 Niacin 13.525 × 10–3
Leucine 1.535 Pantothenic acid 1.395 × 10–3
Lysine 0.850 B6 0.256 × 10–3
Methioione 0.291 Folate 1450 × 10–6
Cysteine 0.304 E** 6.93 × 10–3
Phenylalanine 1.227 Choline 55.3 × 10–3
Tyrosine 0.963
Minerals
Valine 0.993 Calcium 54 × 10–3
Arginine 2.832 Iron 2.26 × 10–3
Histidine 0.599 Magnesium 176 × 10–3
Alanine 0.941 Phosphorous 358 × 10–3
Aspartic acid 2.888 Potassium 658 × 10–3
Glutamic acid 4.949 Sodium 6 × 10–3
Glycine 1.427 Zinc 3.31 × 10–3
Proline 1.045 Copper 0.671 × 10–3
Serine 1.167 Manganese 2.083 × 10–3
Lipids Selenium 7.5 × 10–6
Fatty acids (total saturated) 6.893 Others
Fatty acids (total monounsaturated) 24.640 Carbohydrates (total) 21.51
Dietary fiber 8.0
Fatty acids (total polyunsaturated) 15.694 Sugars (total) 4.18
*Quantities expressed are per 100 g of dry-roasted peanuts, all types, and without salt, throughout the paper; **This is a fat soluble vitamin and the rest are water
soluble vitamins.
different minerals, vitamins [6], amino acids present in
proteins, lipids comprising of various saturated and un-
saturated fatty acids, carbohydrates comprising of poly-
saccharides in the form of starch, organic acids, and pu-
rines, present in peanuts.
3. Peanut Nutritional Contribution in
Comparison to Other Nuts
Figures 1(a) and (b) shown below, explain the nutri-
tional contribution of peanuts in comparison to other nuts
and are found to add significantly more nutrients to the
diet each day when compared with other nuts. This data,
on the average intake of vitamins and minerals for all nut
users calculated from 2001-2004 and compiled by the
National Health and Nutrition Examination Survey (NH-
ANES) was presented at the 2007 Nuts & Health Sym-
posium at the USDA Western Human Nutrition Research
Center at the University of California, Davis. Based on a
2000 calorie intake the nutrient contribution of each nut
is shown in the figures for men and women above the age
of 19 years. (Courtesy: WWEIA, NHA-NES 2001-2004).
4. Proteins in Peanuts
It is common knowledge that all meat, chicken, turkey,
fish and dairy foods are rich in proteins. Foods from
animal sources provide all the protein needed by human
body, which means they contain all the essential amino
acids. Apart from meat, legumes such as beans, peas, and
peanuts contain notable quantities of protein, more than
any other nut. All amino acids [7] must be present evenly
in the body to supplement normal and active growth.
Among the 20 amino acids 11 are non essential, and are
continuously synthesized in the body through various
reactions interlinking carbohydrate and lipid metabolism.
The other 9 amino acids happen to be essential ones
which, ironically, cannot be synthesized by the body by
itself, and hence are needed to be supplied through diet.
So far it is known that, those proteins that contain all the
essential amino acids in the required proportions are the
complete proteins, such as casein (milk protein) and al-
Copyright © 2012 SciRes. FNS
Peanuts and Their Nutritional Aspects—A Review
1646
VitaminE
Magnesium
Folate
Niacin
Iron
Zinc
Potassium
Phosphorous
Selenium
%ContributiontoRDAinMen
0
10
20
30
40
50
60
70
Peanuts
Cashews
Almonds
Pistachios
Pecans
Walnuts
Others
(a)
VitaminE
Magnesium
Folate
Niacin
Iron
Zinc
Potassium
Phosphorous
Selenium
%ContributiontoRDAinWomen
0
10
20
30
40
50
60
70
(b)
Figure 1. Peanut, peanut butter and nut nutrient contribu-
tion to recommended dietary allowances (RDA) in men (a)
and in women (b) per 2000 Calories. Source and courtesy:
WWEIA, NHANES 2001-2004, 1 day, 19+ years.
bumin (egg white protein). In addition to milk and eggs
another vital source of protein is peanuts. Peanuts contain
all the essential amino acids necessary for normal body
growth and metabolism [8]. For example, lack of trypto-
phan in the diet may lead to pellagra, which is a very se-
vere skin disorder, sometimes fatal [9]. Similarly, pheny-
lalanine another essential amino acid is associated with
formation of epinephrine and norepinephrine, which are
also called flight or fight hormones produced by the ad-
renal medulla and the brain [10]. Methionine is another
essential amino acid for the synthesis of protein, and it
acts as an initiating amino acid during translation of pro-
teins. Tyrosine, another amino acid is associated with
formation of melanin and thyroid hormones. All these
amino acids are essential to prevent protein calorie mal-
nutrition disorders such as Kwashiorkor [11] and Maras-
mus [12]. Peanuts contain the above mentioned essential
amino acids that are necessary for synthesis of proteins,
and thus could be an indispensable component of human
diet [13].
In many African countries often deaths are reported as
due to malnutrition, and they could possibly be prevented
by providing a protein rich diet [14]. Peanut and peanut
added foods could provide such a nutritious diet. The
world health organization recommends [15] an “average
requirement” of 0.66 g of protein per kg of ideal body
weight, and a “safe level” of 0.86 g/kg of body weight.
According to a study peanuts contain more plant protein
than any other legumes or nuts [16]. Peanut are some-
times called a poor man’s protein as they are available at
an affordable price.
5. Carbohydrates in Peanuts
Roasted peanuts contain 21.51 g of carbohydrates per
100 g [6]. The major carbohydrate present in peanuts is
starch which is a homopolysaccharide made up of α-D
glucose residues joined together by glycosidic bonds.
When starch undergoes enzymatic degradation in the
body by the action of amylase (present in human saliva),
it is initially broken down to maltose and isomaltose [17].
These two disaccharides, when subjected to respective
digestive enzymes, are converted to glucose and liberate
energy. In countries such as India, the staple foods are
mostly starch containing foods such as rice and potatoes.
Consuming large quantities of these foods could mitigate
hunger but may not provide the vital nutrients required
for proper sustenance. Addition of a small quantity of
peanuts to the regular diet can enhance nutrition value of
a meal. The importance of the carbohydrate-amino acid
interaction in the development of roasted peanut flavor
and color is well documented. Carbohydrates are biomo-
lecules, which are differentiated based on their properties
as sugars and non-sugars, and the sugars are poly hy-
droxyl aldehyde/ketones, soluble in water, crystalline in
appearance, and can be easily digested. The most abun-
dant carbohydrate present in the human body is glucose.
All the reactions associated with the metabolism of car-
bohydrates either begins with glucose or ends up in glu-
cose. Glucose in the form of glycogen is stored in the
liver and muscle. In the muscle, carbohydrates are util-
ized for doing work and in the liver they are stored as
glycogen and released as and when necessary, when the
body demands additional glucose, to regulate vital meta-
bolic processes. Peanuts have adequate amounts of car-
bohydrates amounting to 15% of the RDA value. Carbo-
hydrates play a critical role in supplementing valuable
nutrition to the human body.
6. Lipids in Peanuts
Fatty acids that are present in peanuts belong to the cate-
gory of lipids. In addition to carbohydrates, they also are
considered as energy producing biomolecules. However,
owing to their insoluble nature in water, they are not di-
Copyright © 2012 SciRes. FNS
Peanuts and Their Nutritional Aspects—A Review 1647
rect source of energy to the body, but act as an alternate
fuel to the body. Just like carbohydrates, proteins and
amino acids, lipids must be supplemented in the diet for
vital biological functions. Saturated fatty acid is neces-
sary for storage of fat soluble vitamins like vitamin A
[18]. When 1 g of palmitic acid undergoes complete de-
gradation by beta oxidation pathway, it can produce 9
kilo calories of energy. Fatty acids are long chain or short
chain organic acids with a terminal carboxylic acid group.
Certain fatty acids like palmitic and oleic can be synthe-
sized in the body, while fatty acids like the poly unsatu-
rated fatty acids (PUFA) need to be given through the
diet. The human body does not have any mechanism for
synthesizing poly unsaturated fatty acids [19,20], the es-
sential fatty acids that include, linoleic acid (18 Carbon
atoms with 2 double bonds, C17H31COOH), and linolenic
acid (18 Carbon atoms with 3 double bonds, C17H29CO-
OH). These fatty acids must therefore have to be sup-
plied from external sources through the diet. In terms of
fatty acids present, edible part of roasted peanuts have
6.893 g saturated fatty acids, 24.64 g monounsaturated
fatty acids (oleic acid) and 15.694 g polyunsaturated fatty
acids. The presence of high mono and poly unsaturated
fatty acids reduces the risk of coronary heart diseases.
Hence peanuts and peanut oil can serve as a healthy
source of nutrition [21].
7. Vitamins in Peanuts
Vitamins are a group of organic compounds that are not
synthesized in the body, but have to be supplied to the
body to maintain normal health and metabolism. They
are classified as fat soluble and water soluble vitamins.
Fat soluble vitamins are A, D, E, and K, and water solu-
ble vitamins are B-Complex and vitamin C. Fat soluble
vitamins play an important role in maintaining certain es-
sential physiological functions. For example, vitamin A
is associated with normal vision and epithelial functions,
vitamin D is associated with calcium metabolism, and
vitamin K for coagulation of blood. Water soluble vita-
mins are associated with certain biochemical reactions by
forming coenzymes that assist the enzyme in converting
a substrate into a product. For instance Riboflavin (vita-
min B2) in the form of Flavin mono nucleotide (FMN)
and Flavin adenine dinucleotide (FAD), participate in
electron transfer and hydrogen transfer reactions in the
human body. All anabolic (reactions involving synthesis
of carbohydrates, lipids and proteins), and catabolic (re-
actions involving breakdown of carbohydrates, lipids and
proteins) reactions in the human body require coenzyme
derivatives of B complex vitamins which are water solu-
ble. Peanuts are a vital source for introducing most of the
water soluble vitamins into the human body along with
vitamin E which is fat soluble (Table 1).
An important fat soluble vitamin in peanuts is vitamin
E [22] amounting to about 6.93 mg* (Table 1). Vitamin
E is known as alpha-tocopherol, and is an anti-oxidative
vitamin [23]. It is associated with obstructing the forma-
tion of free radicals by preventing the oxidation of un-
saturated fatty acids present in consumed foods, respira-
tory membranes, and mitochondrial matrix in the human
body. Vitamin E is associated with oxidative phosphory-
lation reactions in the mitochondria leading to formation
of adenosine tri phosphate, known as ATP (energy cur-
rency of the cell associated with driving the metabolism
of carbohydrates, proteins, and lipids). It also aids in
preventing the oxidation of hemoglobin and red blood
corpuscles that help intracellular respiration and adequate
exchange of gases. Peanuts, in general, and peanut oil in
particular, are efficient sources for supplementing vita-
min E to the body.
Peanuts are a good source of Thiamine (B1), a water
soluble vitamin [24], having thiamine pyrophosphate as
the coenzyme, and playing a very important role in oxi-
dative decarboxylation and co-carboxylation reactions
associated with carbohydrate and amino acid metabolism.
It is known that deficiency of thiamine leads to beri-beri,
a disease that can cause problems in the cardiovascular
and central nervous system (CNS). Peanuts contain 0.438
mg* of thiamine (Table 1).
Peanuts are also an efficient source of Vitamin B2.
Sometimes referred to as Warburg’s yellow enzyme, it
has two derivatives namely FMN and FAD [25] that act
as coenzymes playing an important role in electron
transfer reactions, and as carriers of electrons in the elec-
tron transport chain (chain of reactions converting oxy-
gen to water through a series of electron transfer agents).
They also act as coenzymes for enzymes called oxidases,
and thus participate in carbohydrate, lipid and protein
metabolism. It is now known that a deficiency of vitamin
B2 leads to Cheliosis (fissures at angles of the mouth),
angular stomatosis (throat infection) and mouth ulcers
[26,27]. These could be prevented by taking a diet [28]
rich in vitamin B2, and peanuts are a potential source of
vitamin B2, containing 0.098 mg* of riboflavin.
Another important vitamin which is supplemented in
the body by the intake of peanuts is vitamin B3 [29]
(known as Niacin or its corresponding amines, Niacina-
mide or Nicotinamide), to an extent of 13.525 mg*. This
vitamin plays an important role in the normal functioning
of the respiratory chain and participates in hydrogen
transfer, and electron transfer reactions through its coen-
zymes, Nicotinamide adenine dinucleotide (NAD) and
Nicotinamide adenine dinucleotide phosphate (NADP).
Deficiency of niacin leads to Pellagra, a disease charac-
terized by diarrhea, dementia and dermatitis [30]. Tryp-
tophan is an essential amino acid associated with the
formation of niacin and has to be supplied from dietary
Copyright © 2012 SciRes. FNS
Peanuts and Their Nutritional Aspects—A Review
1648
sources, and incidentally peanuts are a good source of
tryptophan (0.230 g*).
Vitamin B5, found in many food sources, needs a
strong presence in human diet owing to its widespread
applications in numerous biochemical reactions within
the human body. B5 is found in good amounts in peanuts.
Peanuts, mushrooms, soybeans, split peas, pecans, oat-
meal, buckwheat, sunflower seeds, lentils, rye flour, ca-
shews, and other whole grains and nuts are good sources
of pantothenic acid. Chemically Vitamin B5 is a dipep-
tide consisting of pantoic acid and beta alanine, and as a
whole known as pantothenic acid (pantothenate in Greek
means from everywhere), which is an important con-
stituent of peanuts, present to the extent of 1.395 mg*
(Table 1). Pantothenic acid in humans is responsible for
the formation of Coenzyme A, which is responsible for
many vital reactions in the body such as the kreb’s cycle,
synthesis of cholesterol [31], and synthesis of heme.
Another important water soluble vitamin, a notable
constituent of Peanuts, is Vitamin B6, Pyridoxine. Vita-
min B6 occurs in three naturally occurring forms namely
pyridoxine, pyridoxalamine, and pyridoxal. It has two
coenzyme forms, pyridoxal phosphate and pyridoxal
amine phosphate, and these two forms carry out many
significant biochemical reactions in the body especially
those associated with amino acid metabolism. It is highly
essential to supplement this vitamin through the diet into
the human body, and roasted peanuts will provide B6 to
the human body to the extent of 0.256 mg*.
Vitamin B9, more commonly known as folate or folic
acid, is a water-soluble vitamin that is part of the B vita-
min family. Folate occurs naturally in foods, while folic
acid is the synthetic form of folate. Vitamin B9 is useful
for human growth and helps the mechanism of normal
nerve and brain functioning [32]. B9 is also credited with
controlling blood-levels of the amino acid homocysteine,
thus reducing the risk of heart disease and stroke. Folate
present in peanuts to an extent of 145 µg* may also help
protect against cancers of the lung, colon, and cervix.
8. Minerals in Peanuts
Magnesium is an essential mineral for the human body
for several useful functions [33]. Magnesium is needed to
maintain normal muscle and nerve functions and a heal-
thy immune system. Magnesium promotes normal blood
pressure, keeps bones strong, and helps to regulate blood
sugar levels. People who consume peanuts have shown
higher levels of magnesium. Peanuts are a good source of
magnesium containing 176 mg* (Table 1).
A mineral that is primarily associated with strength-
ening of bones, gums and teeth is calcium. Calcium plays
an important role in the normal functioning of the visual
cycle, and in the mechanism of blood coagulation. It is
also associated with normal muscle physiology, helping
in contraction and relaxation of muscles. Though, mainly
present in milk, it is also present to a notable extent in
peanuts containing 54 mg* (Table 1).
A mineral that aids primarily in the formation of bones
and teeth along with calcium is phosphorous. Phospho-
rous helps to synthesize protein for the growth, mainte-
nance and repair of cells, and tissues. With 358 mg* (Ta-
ble 1) of phosphorous, peanuts are a good source of pho-
sphorous providing about 50% of our daily needs.
One has to eat the right amount of foods that contain
potassium to keep the blood levels in a healthy range.
Maintaining fluid and electrolyte balance is a critical
function in the human body and this function is taken
care of by potassium. In association with sodium ions,
potassium plays an important role in the brain and nerve
functions, and for muscle development. Peanuts contain-
ing 658 mg* of potassium are a good source of this vital
mineral (Table 1).
Zinc is a cofactor for most of the dehydrogenases that
require the coenzymes NAD and NADP. This mineral
also supports our immune systems, helps in wound heal-
ing, and is involved in building proteins. Zinc is an es-
sential mineral for normal growth and development dur-
ing pregnancy, childhood, and adolescence. Zinc also
helps the cells in human body communicate by function-
ing as a neurotransmitter. Deficiency of zinc can lead to
stunted growth, diarrhea, impotence, hair loss, eye and
skin lesions, impaired appetite, and depressed immunity.
Peanuts are a great source of zinc. One hundred grams of
roasted peanuts will provide 3.31 mg* of zinc (Table 1).
Peanuts contain 2.26 mg* of iron (Table 1). Iron is an
essential metal ion that acts as the chelating agent, and
chelates with heme to form hemoglobin. It is an integral
part of many enzymes that participate in biochemical re-
actions such as peroxidase, catalase and ferro chelatase.
It is involved in oxygen transport and helps regulate cell
growth and differentiation. It is known that the defici-
ency of iron leads to anemia which is prevalent in many
parts of the world [34].
Copper plays a role in the production of key proteins
in our body such as collagen and hemoglobin, which
trans- port oxygen. A serving of one hundred grams of
roasted peanuts provide 0.671 mg* (Table 1), and thus
peanuts are an excellent source of copper providing over
70% of our daily needs [35].
Selenium is an essential mineral but needed in small
amounts for the human body. Selenium is naturally found
in plants, seafood, meat and meat products. Selenium is a
micronutrient and antioxidant, and a component of se-
veral essential enzymes. Selenium is believed to delay or
prevent the onset of cancer and also has anti-aging ef-
fects [36]. Selenium is found in peanuts to the extent of
7.5 µg* (Table 1) giving about 14% of our daily needs.
Copyright © 2012 SciRes. FNS
Peanuts and Their Nutritional Aspects—A Review 1649
9. Raw and Roasted Peanuts
Though unroasted peanuts are fit for consumption, they
do not have the same flavor as the roasted ones. However,
a significant risk in eating raw peanuts is the possible
presence of aflatoxin [37], a poison produced by a fungus,
though it may occur rarely. Roasting peanuts usually re-
moves this fungus. Eating contaminated peanuts can
cause liver diseases.
It was found in 0.4% to 0.6% of persons, particularly
in children, consumption of peanuts in any form lead to
allergic reactions, some severe. These may develop in the
childhood or could be due to a family history of peanut
allergy [38]. The symptoms associated with peanut al-
lergy may range from oozing and skin rashes, to short-
ness of breath or wheezing.
Consumption of nuts has a positive effect on coronary
heart diseases. It has been observed that the risk of coro-
nary heart diseases and related cardiovascular diseases
[39] is 37% lower for those consuming nuts more than 4
times per week, than in those people who don’t consume
nuts at all.
Peanuts play a crucial role in weight management [40].
Epidemiological studies have provided useful informa-
tion on beneficial effects of nuts which also includes pea-
nuts. Even though peanuts are rich in fats, they can still
be included in diet for weight loss.
10. Conclusion
Peanuts are an excellent and affordable source of nutria-
tion, supplementing vital nutrients to the human body
such as proteins, carbohydrates, lipids, vitamins, miner-
als and fiber. Peanuts are often referred as poor man’s
protein but, when taken in adequate amounts in any form,
will supplement rich nutrients to the body that can pro-
vide growth and energy, and play a vital role in the pre-
vention of diseases. Metal ions which are cofactors for
many enzymes, vitamins that are not synthesized in the
body, poly unsaturated and monounsaturated fatty acids,
whose consumption can increase the levels of HDL cho-
lesterol which is good for the heart, are present in pea-
nuts. Essential amino acids that are not synthesized in the
body, but are essential as building blocks of proteins and
carbohydrates, which are the principle source of energy
in the body, can be provided by peanuts. A diet including
peanuts could provide all these vital nutrients, and play a
critical role in preventing disease and promoting good
health.
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