Nutrition is the science that interprets the interaction of nutrients and other substances in food in relation to maintenance, growth, reproduction, health and disease of an organism. It includes food intake, absorption, assimilation, biosynthesis, catabolism, and excretion.
The diet of an organism is what it eats, which is largely determined by the availability and palatability of foods. For humans, a healthy diet includes preparation of food and storage methods that preserve nutrients from oxidation, heat or leaching, and that reduces risk of foodborne illnesses.
In humans, an unhealthy diet can cause deficiency-related diseases such as blindness, anemia, scurvy, preterm birth, stillbirth and cretinism, or nutrient excess health-threatening conditions such as obesity and metabolic syndrome; and such common chronic systemic diseases as cardiovascular disease, diabetes, and osteoporosis. Undernutrition can lead to wasting in acute cases, and the stunting of marasmus in chronic cases of malnutrition.
- 1 History of human nutrition
- 2 Nutrients
- 3 Phytochemicals
- 4 Intestinal bacterial flora
- 5 Animal nutrition
- 6 Plant nutrition
- 7 Advice and guidance
- 8 Nutrition literacy
- 9 Malnutrition
- 10 Processed foods
- 11 Outline of nutrition
- 12 See also
- 13 Notes and references
- 14 Bibliography
- 15 External links
History of human nutrition
The first recorded dietary advice, carved into a Babylonian stone tablet in about 2500 BC, cautioned those with pain inside to avoid eating onions for three days. Scurvy, later found to be a vitamin C deficiency, was first described in 1500 BC in the Ebers Papyrus.
According to Walter Gratzer, the study of nutrition probably began during the 6th century BC. In China, the concept of qi developed, a spirit or “wind” similar to what Western Europeans later called pneuma. Food was classified into “hot” (for example, meats, blood, ginger, and hot spices) and “cold” (green vegetables) in China, India, Malaya, and Persia. Humours developed perhaps first in China alongside qi. Ho the Physician concluded that diseases are caused by deficiencies of elements (Wu Xing: fire, water, earth, wood, and metal), and he classified diseases as well as prescribed diets. About the same time in Italy, Alcmaeon of Croton (a Greek) wrote of the importance of equilibrium between what goes in and what goes out, and warned that imbalance would result in disease marked by obesity or emaciation.
The first recorded nutritional experiment with human subjects is found in the Bible’s Book of Daniel. Daniel and his friends were captured by the king of Babylon during an invasion of Israel. Selected as court servants, they were to share in the king’s fine foods and wine. But they objected, preferring vegetables (pulses) and water in accordance with their Jewish dietary restrictions. The king’s chief steward reluctantly agreed to a trial. Daniel and his friends received their diet for ten days and were then compared to the king’s men. Appearing healthier, they were allowed to continue with their diet.
Around 475 BC, Anaxagoras stated that food is absorbed by the human body and, therefore, contains “homeomerics” (generative components), suggesting the existence of nutrients. Around 400 BC, Hippocrates, who recognized and was concerned with obesity, which may have been common in southern Europe at the time, said, “Let food be your medicine and medicine be your food.” The works that are still attributed to him, Corpus Hippocraticum, called for moderation and emphasized exercise.
Salt, pepper and other spices were prescribed for various ailments in various preparations for example mixed with vinegar. In the 2nd century BC, Cato the Elder believed that cabbage (or the urine of cabbage-eaters) could cure digestive diseases, ulcers, warts, and intoxication. Living about the turn of the millennium, Aulus Celsus, an ancient Roman doctor, believed in “strong” and “weak” foods (bread for example was strong, as were older animals and vegetables).
Galen to Lind
One mustn’t overlook the doctrines of Galen: In use from his life in the 1st century AD until the 17th century, it was heresy to disagree with him for 1500 years. Galen was physician to gladiators in Pergamon, and in Rome, physician to Marcus Aurelius and the three emperors who succeeded him. Most of Galen’s teachings were gathered and enhanced in the late 11th century by Benedictine monks at the School of Salerno in Regimen sanitatis Salernitanum, which still had users in the 17th century. Galen believed in the bodily humours of Hippocrates, and he taught that pneuma is the source of life. Four elements (earth, air, fire and water) combine into “complexion”, which combines into states (the four temperaments: sanguine, phlegmatic, choleric, and melancholic). The states are made up of pairs of attributes (hot and moist, cold and moist, hot and dry, and cold and dry), which are made of four humours: blood, phlegm, green (or yellow) bile, and black bile (the bodily form of the elements). Galen thought that for a person to have gout, kidney stones, or arthritis was scandalous, which Gratzer likens to Samuel Butler’s Erehwon (1872) where sickness is a crime.
In the 1500s, Paracelsus was probably the first to criticize Galen publicly. Also in the 16th century, scientist and artist Leonardo da Vinci compared metabolism to a burning candle. Leonardo did not publish his works on this subject, but he was not afraid of thinking for himself and he definitely disagreed with Galen. Ultimately, 16th century works of Andreas Vesalius, sometimes called the father of modern human anatomy, overturned Galen’s ideas. He was followed by piercing thought amalgamated with the era’s mysticism and religion sometimes fueled by the mechanics of Newton and Galileo. Jan Baptist van Helmont, who discovered several gases such as carbon dioxide, performed the first quantitative experiment. Robert Boyle advanced chemistry. Sanctorius measured body weight. Physician Herman Boerhaave modeled the digestive process. Physiologist Albrecht von Haller worked out the difference between nerves and muscles.
Sometimes forgotten during his life, James Lind, a physician in the British navy, performed the first scientific nutrition experiment in 1747. Lind discovered that lime juice saved sailors that had been at sea for years from scurvy, a deadly and painful bleeding disorder. Between 1500 and 1800, an estimated two million sailors had died of scurvy. The discovery was ignored for forty years, after which British sailors became known as “limeys.” The essential vitamin C within citrus fruits would not be identified by scientists until 1932.
Lavoisier and modern science
Around 1770, Antoine Lavoisier discovered the details of metabolism, demonstrating that the oxidation of food is the source of body heat. Called the most fundamental chemical discovery of the 18th century, Lavoisier discovered the principle of conservation of mass. His ideas made the phlogiston theory of combustion obsolete.
In 1790, George Fordyce recognized calcium as necessary for the survival of fowl. In the early 19th century, the elements carbon, nitrogen, hydrogen, and oxygen were recognized as the primary components of food, and methods to measure their proportions were developed.
In 1816, François Magendie discovered that dogs fed only carbohydrates (sugar), fat (olive oil), and water died evidently of starvation, but dogs also fed protein survived, identifying protein as an essential dietary component. William Prout in 1827 was the first person to divide foods into carbohydrates, fat, and protein. During the 19th century, Jean-Baptiste Dumas and Justus von Liebig quarrelled over their shared belief that animals get their protein directly from plants (animal and plant protein are the same and that humans do not create organic compounds). With a reputation as the leading organic chemist of his day but with no credentials in animal physiology, Liebig grew rich making food extracts like beef bouillon and infant formula that were later found to be of questionable nutritious value. In the 1860s, Claude Bernard discovered that body fat can be synthesized from carbohydrate and protein, showing that the energy in blood glucose can be stored as fat or as glycogen.
In the early 1880s, Kanehiro Takaki observed that Japanese sailors (whose diets consisted almost entirely of white rice) developed beriberi (or endemic neuritis, a disease causing heart problems and paralysis), but British sailors and Japanese naval officers did not. Adding various types of vegetables and meats to the diets of Japanese sailors prevented the disease, (not because of the increased protein as Takaki supposed but because it introduced a few parts per million of thiamine to the diet, later understood as a cure).
In 1896, Eugen Baumann observed iodine in thyroid glands. In 1897, Christiaan Eijkman worked with natives of Java, who also suffered from beriberi. Eijkman observed that chickens fed the native diet of white rice developed the symptoms of beriberi but remained healthy when fed unprocessed brown rice with the outer bran intact. His assistant, Gerrit Grijns correctly identified and described the anti-beriberi substance in rice. Eijkman cured the natives by feeding them brown rice, discovering that food can cure disease. Over two decades later, nutritionists learned that the outer rice bran contains vitamin B1, also known as thiamine.
From 1900 to the present
In the early 20th century, Carl von Voit and Max Rubner independently measured caloric energy expenditure in different species of animals, applying principles of physics in nutrition. In 1906, Edith G. Willcock and Frederick Hopkins showed that the amino acid tryptophan aids the well-being of mice but it did not assure their growth. In the middle of twelve years of attempts to isolate them, Hopkins said in a 1906 lecture that “unsuspected dietetic factors,” other than calories, protein, and minerals, are needed to prevent deficiency diseases. In 1907, Stephen M. Babcock and Edwin B. Hart started the cow feeding, single-grain experiment, which took nearly four years to complete.
In 1912, Casimir Funk coined the term vitamin, a vital factor in the diet, from the words “vital” and “amine,” because these unknown substances preventing scurvy, beriberi, and pellagra, were thought then to be derived from ammonia. The vitamins were studied in the first half of the 20th century.
In 1913, Elmer McCollum and Marguerite Davis discovered the first vitamin, fat-soluble vitamin A, then water-soluble vitamin B (in 1915; now known to be a complex of several water-soluble vitamins) and named vitamin C as the then-unknown substance preventing scurvy. Lafayette Mendel and Thomas Osborne also performed pioneering work on vitamins A and B. In 1919, Sir Edward Mellanby incorrectly identified rickets as a vitamin A deficiency because he could cure it in dogs with cod liver oil. In 1922, McCollum destroyed the vitamin A in cod liver oil, but found that it still cured rickets. Also in 1922, H.M. Evans and L.S. Bishop discover vitamin E as essential for rat pregnancy, originally calling it “food factor X” until 1925.
In 1925, Hart discovered that trace amounts of copper are necessary for iron absorption. In 1927, Adolf Otto Reinhold Windaus synthesized vitamin D, and was awarded the Nobel Prize in Chemistry in 1928. In 1928, Albert Szent-Györgyi isolated ascorbic acid, and in 1932 proved that it is vitamin C by preventing scurvy. In 1935, he synthesized it, and in 1937, he won a Nobel Prize for his efforts. Szent-Györgyi concurrently elucidated much of the citric acid cycle.
In the 1930s, William Cumming Rose identified essential amino acids, necessary protein components that the body cannot synthesize. In 1935, Underwood and Marston independently discovered the necessity of cobalt. In 1936, Eugene Floyd DuBois showed that work and school performance are related to caloric intake. In 1938, Erhard Fernholz discovered the chemical structure of vitamin E and then he tragically disappeared. It was synthesised the same year by Paul Karrer.
In 1940, rationing in the United Kingdom during and after World War II took place according to nutritional principles drawn up by Elsie Widdowson and others. In 1941, the first Recommended Dietary Allowances (RDAs) were established by the National Research Council.
The list of nutrients that people are known to require is, in the words of Marion Nestle, “almost certainly incomplete”. As of 2014, nutrients are thought to be of two types: macronutrients which are needed in relatively large amounts, and micronutrients which are needed in smaller quantities. A type of carbohydrate, dietary fiber, i.e. non-digestible material such as cellulose, is required, for both mechanical and biochemical reasons, although the exact reasons remain unclear. Some nutrients can be stored – the fat-soluble vitamins – while others are required more or less continuously. Poor health can be caused by a lack of required nutrients, or for some vitamins and minerals, too much of a required nutrient.
The macronutrients are carbohydrates, fiber, fats, protein, and water.
The macronutrients (excluding fiber and water) provide structural material (amino acids from which proteins are built, and lipids from which cell membranes and some signaling molecules are built) and energy. Some of the structural material can be used to generate energy internally, and in either case it is measured in Joules or kilocalories (often called “Calories” and written with a capital C to distinguish them from little ‘c’ calories). Carbohydrates and proteins provide 17 kJ approximately (4 kcal) of energy per gram, while fats provide 37 kJ (9 kcal) per gram, though the net energy from either depends on such factors as absorption and digestive effort, which vary substantially from instance to instance. Vitamins, minerals, fiber, and water do not provide energy, but are required for other reasons.
Molecules of carbohydrates and fats consist of carbon, hydrogen, and oxygen atoms. Carbohydrates range from simple monosaccharides (glucose, fructose and galactose) to complex polysaccharides (starch). Fats are triglycerides, made of assorted fatty acid monomers bound to a glycerol backbone. Some fatty acids, but not all, are essential in the diet: they cannot be synthesized in the body. Protein molecules contain nitrogen atoms in addition to carbon, oxygen, and hydrogen. The fundamental components of protein are nitrogen-containing amino acids, some of which are essential in the sense that humans cannot make them internally. Some of the amino acids are convertible (with the expenditure of energy) to glucose and can be used for energy production, just as ordinary glucose, in a process known as gluconeogenesis. By breaking down existing protein, the carbon skeleton of the various amino acids can be metabolized to intermediates in cellular respiration; the remaining ammonia is discarded primarily as urea in urine.
Carbohydrates may be classified as monosaccharides, disaccharides, or polysaccharides depending on the number of monomer (sugar) units they contain. They constitute a large part of foods such as rice, noodles, bread, and other grain-based products, also potatoes , yams, beans, fruits, fruit juices and vegetables.
Monosaccharides, disaccharides, and polysaccharides contain one, two, and three or more sugar units, respectively. Polysaccharides are often referred to as complex carbohydrates because they are typically long, multiple branched chains of sugar units.
Traditionally, simple carbohydrates are believed to be absorbed quickly, and therefore to raise blood-glucose levels more rapidly than complex carbohydrates. This, however, is not accurate. Some simple carbohydrates (e.g., fructose) follow different metabolic pathways (e.g., fructolysis) that result in only a partial catabolism to glucose, while, in essence, many complex carbohydrates may be digested at the same rate as simple carbohydrates. The World Health Organization (WHO) recommends that added sugars should represent no more than 10% of total energy intake.
Dietary fiber is a carbohydrate that is incompletely absorbed in humans and in some animals. Like all carbohydrates, when it is metabolized it can produce four Calories (kilocalories) of energy per gram. However, in most circumstances it accounts for less than that because of its limited absorption and digestibility. Dietary fiber consists mainly of cellulose, a large carbohydrate polymer which is indigestible as humans do not have the required enzymes to disassemble it. There are two subcategories: soluble and insoluble fiber. Whole grains, fruits (especially plums, prunes, and figs), and vegetables are good sources of dietary fiber. There are many health benefits of a high-fiber diet. Dietary fiber helps reduce the chance of gastrointestinal problems such as constipation and diarrhea by increasing the weight and size of stool and softening it. Insoluble fiber, found in whole wheat flour, nuts and vegetables, especially stimulates peristalsis – the rhythmic muscular contractions of the intestines, which move digest along the digestive tract. Soluble fiber, found in oats, peas, beans, and many fruits, dissolves in water in the intestinal tract to produce a gel that slows the movement of food through the intestines. This may help lower blood glucose levels because it can slow the absorption of sugar. Additionally, fiber, perhaps especially that from whole grains, is thought to possibly help lessen insulin spikes, and therefore reduce the risk of type 2 diabetes. The link between increased fiber consumption and a decreased risk of colorectal cancer is still uncertain.
A molecule of dietary fat typically consists of several fatty acids (containing long chains of carbon and hydrogen atoms), bonded to a glycerol. They are typically found as triglycerides (three fatty acids attached to one glycerol backbone). Fats may be classified as saturated or unsaturated depending on the detailed structure of the fatty acids involved. Saturated fats have all of the carbon atoms in their fatty acid chains bonded to hydrogen atoms, whereas unsaturated fats have some of these carbon atoms double-bonded, so their molecules have relatively fewer hydrogen atoms than a saturated fatty acid of the same length. Unsaturated fats may be further classified as monounsaturated (one double-bond) or polyunsaturated (many double-bonds). Furthermore, depending on the location of the double-bond in the fatty acid chain, unsaturated fatty acids are classified as omega-3 or omega-6 fatty acids. Trans fats are a type of unsaturated fat with trans-isomer bonds; these are rare in nature and in foods from natural sources; they are typically created in an industrial process called (partial) hydrogenation. There are nine kilocalories in each gram of fat. Fatty acids such as conjugated linoleic acid, catalpic acid, eleostearic acid and punicic acid, in addition to providing energy, represent potent immune modulatory molecules.
Saturated fats (typically from animal sources) have been a staple in many world cultures for millennia. Unsaturated fats (e. g., vegetable oil) are considered healthier, while trans fats are to be avoided. Saturated and some trans fats are typically solid at room temperature (such as butter or lard), while unsaturated fats are typically liquids (such as olive oil or flaxseed oil). Trans fats are very rare in nature, and have been shown to be highly detrimental to human health, but have properties useful in the food processing industry, such as rancidity resistance.
Essential fatty acids
Most fatty acids are non-essential, meaning the body can produce them as needed, generally from other fatty acids and always by expending energy to do so. However, in humans, at least two fatty acids are essential and must be included in the diet. An appropriate balance of essential fatty acids—omega-3 and omega-6 fatty acids—seems also important for health, although definitive experimental demonstration has been elusive. Both of these “omega” long-chain polyunsaturated fatty acids are substrates for a class of eicosanoids known as prostaglandins, which have roles throughout the human body. They are hormones, in some respects. The omega-3 eicosapentaenoic acid (EPA), which can be made in the human body from the omega-3 essential fatty acid alpha-linolenic acid (ALA), or taken in through marine food sources, serves as a building block for series 3 prostaglandins (e.g., weakly inflammatory PGE3). The omega-6 dihomo-gamma-linolenic acid (DGLA) serves as a building block for series 1 prostaglandins (e.g. anti-inflammatory PGE1), whereas arachidonic acid (AA) serves as a building block for series 2 prostaglandins (e.g. pro-inflammatory PGE 2). Both DGLA and AA can be made from the omega-6 linoleic acid (LA) in the human body, or can be taken in directly through food. An appropriately balanced intake of omega-3 and omega-6 partly determines the relative production of different prostaglandins, which is one reason why a balance between omega-3 and omega-6 is believed important for cardiovascular health. In industrialized societies, people typically consume large amounts of processed vegetable oils, which have reduced amounts of the essential fatty acids along with too much of omega-6 fatty acids relative to omega-3 fatty acids.
The conversion rate of omega-6 DGLA to AA largely determines the production of the prostaglandins PGE1 and PGE2. Omega-3 EPA prevents AA from being released from membranes, thereby skewing prostaglandin balance away from pro-inflammatory PGE2 (made from AA) toward anti-inflammatory PGE1 (made from DGLA). Moreover, the conversion (desaturation) of DGLA to AA is controlled by the enzyme delta-5-desaturase, which in turn is controlled by hormones such as insulin (up-regulation) and glucagon (down-regulation). The amount and type of carbohydrates consumed, along with some types of amino acid, can influence processes involving insulin, glucagon, and other hormones; therefore, the ratio of omega-3 versus omega-6 has wide effects on general health, and specific effects on immune function and inflammation, and mitosis (i.e., cell division).
Proteins are structural materials in much of the animal body (e.g. muscles, skin, and hair). They also form the enzymes that control chemical reactions throughout the body. Each protein molecule is composed of amino acids, which are characterized by inclusion of nitrogen and sometimes sulphur (these components are responsible for the distinctive smell of burning protein, such as the keratin in hair). The body requires amino acids to produce new proteins (protein retention) and to replace damaged proteins (maintenance). As there is no protein or amino acid storage provision, amino acids must be present in the diet. Excess amino acids are discarded, typically in the urine. For all animals, some amino acids are essential (an animal cannot produce them internally) and some are non-essential (the animal can produce them from other nitrogen-containing compounds). About twenty amino acids are found in the human body, and about ten of these are essential and, therefore, must be included in the diet. A diet that contains adequate amounts of amino acids (especially those that are essential) is particularly important in some situations: during early development and maturation, pregnancy, lactation, or injury (a burn, for instance). A complete protein source contains all the essential amino acids; an incomplete protein source lacks one or more of the essential amino acids.
It is possible with protein combinations of two incomplete protein sources (e.g., rice and beans) to make a complete protein source, and characteristic combinations are the basis of distinct cultural cooking traditions. However, complementary sources of protein do not need to be eaten at the same meal to be used together by the body. Excess amino acids from protein can be converted into glucose and used for fuel through a process called gluconeogenesis.
Water is excreted from the body in multiple forms; including urine and feces, sweating, and by water vapour in the exhaled breath. Therefore, it is necessary to adequately rehydrate to replace lost fluids.
Early recommendations for the quantity of water required for maintenance of good health suggested that 6–8 glasses of water daily is the minimum to maintain proper hydration. However the notion that a person should consume eight glasses of water per day cannot be traced to a credible scientific source. The original water intake recommendation in 1945 by the Food and Nutrition Board of the National Research Council read: “An ordinary standard for diverse persons is 1 milliliter for each calorie of food. Most of this quantity is contained in prepared foods.” More recent comparisons of well-known recommendations on fluid intake have revealed large discrepancies in the volumes of water we need to consume for good health. Therefore, to help standardize guidelines, recommendations for water consumption are included in two recent European Food Safety Authority (EFSA) documents (2010): (i) Food-based dietary guidelines and (ii) Dietary reference values for water or adequate daily intakes (ADI). These specifications were provided by calculating adequate intakes from measured intakes in populations of individuals with “desirable osmolarity values of urine and desirable water volumes per energy unit consumed.”
For healthful hydration, the current EFSA guidelines recommend total water intakes of 2.0 L/day for adult females and 2.5 L/day for adult males. These reference values include water from drinking water, other beverages, and from food. About 80% of our daily water requirement comes from the beverages we drink, with the remaining 20% coming from food. Water content varies depending on the type of food consumed, with fruit and vegetables containing more than cereals, for example. These values are estimated using country-specific food balance sheets published by the Food and Agriculture Organisation of the United Nations.
The EFSA panel also determined intakes for different populations. Recommended intake volumes in the elderly are the same as for adults as despite lower energy consumption, the water requirement of this group is increased due to a reduction in renal concentrating capacity. Pregnant and breastfeeding women require additional fluids to stay hydrated. The EFSA panel proposes that pregnant women should consume the same volume of water as non-pregnant women, plus an increase in proportion to the higher energy requirement, equal to 300 mL/day. To compensate for additional fluid output, breastfeeding women require an additional 700 mL/day above the recommended intake values for non-lactating women. Dehydration and over-hydration – too little and too much water, respectively – can have harmful consequences. Drinking too much water is one of the possible causes of hyponatremia, i.e., low serum sodium.
Pure ethanol provides 7 calories per gram. For distilled spirits, a standard serving in the United States is 1.5 fluid ounces, which at 40% ethanol (80 proof), would be 14 grams and 98 calories. Wine and beer contain a similar range of ethanol for servings of 5 ounces and 12 ounces, respectively, but these beverages also contain non-ethanol calories. A 5 ounce serving of wine contains 100 to 130 calories. A 12 ounce serving of beer contains 95 to 200 calories. According to the U.S. Department of Agriculture, based on NHANES 2013-2014 surveys, women ages 20 and up consume on average 6.8 grams/day and men consume on average 15.5 grams/day. Ignoring the non-alcohol contribution of those beverages, the average ethanol calorie contributions are 48 and 108 cal/day. Alcoholic beverages are considered empty calorie foods because other than calories, these contribute no essential nutrients.
Dietary minerals are inorganic chemical elements required by living organisms, other than the four elements carbon, hydrogen, nitrogen, and oxygen that are present in nearly all organic molecules. The term “mineral” is archaic, since the intent is to describe simply the less common elements in the diet. Some are heavier than the four just mentioned, including several metals, which often occur as ions in the body. Some dietitians recommend that these be supplied from foods in which they occur naturally, or at least as complex compounds, or sometimes even from natural inorganic sources (such as calcium carbonate from ground oyster shells). Some minerals are absorbed much more readily in the ionic forms found in such sources. On the other hand, minerals are often artificially added to the diet as supplements; the most famous is likely iodine in iodized salt which prevents goiter.
Many elements are essential nutrients called dietary minerals. Some have roles as cofactors, while others are electrolytes. Elements with recommended dietary allowance (RDA) greater than 150 mg/day are, in alphabetical order:
- Calcium, a common electrolyte, but also needed structurally (for muscle and digestive system health, bone strength, some forms neutralize acidity, provides signaling ions for nerve and membrane functions)
- Chloride; electrolyte; see sodium, below
- Magnesium, required for processing ATP and related reactions (builds bone, facilitates peristalsis)
- Phosphorus, required component of bones; essential for energy processing
- Potassium, an electrolyte (heart and nerve functions)
- Sodium, an electrolyte; common in food and manufactured beverages, typically as sodium chloride. Excessive sodium consumption can deplete calcium and magnesium, leading to high blood pressure.
- Cobalt required for biosynthesis of vitamin B12 family of coenzymes. Animals cannot biosynthesize B12, and must obtain this cobalt-containing vitamin in their diet.
- Copper required component of many redox enzymes, including cytochrome c oxidase
- Chromium required for sugar metabolism
- Iodine required not only for the biosynthesis of thyroxine but also — it is presumed — for other important organs as breast, stomach, salivary glands, thymus, etc. (see Extrathyroidal iodine); for this reason iodine is needed in larger quantities than others in this list, and sometimes classified with the macrominerals
- Iron required for many enzymes, and for hemoglobin and some other proteins
- Manganese (processing of oxygen)
- Molybdenum required for xanthine oxidase and related oxidases
- Selenium required for peroxidase (antioxidant proteins)
- Zinc required for several enzymes such as carboxypeptidase, liver alcohol dehydrogenase, and carbonic anhydrase
Vitamins are essential nutrients, necessary in the diet for good health. (Vitamin D is an exception, as it can be synthesized in the skin in the presence of UVB radiation, and many animal species can synthesize vitamin C.) Vitamin deficiencies may result in disease conditions, including goitre, scurvy, osteoporosis, impaired immune system, disorders of cell metabolism, certain forms of cancer, symptoms of premature aging, and poor psychological health, among many others. Excess levels of some vitamins are also dangerous to health. The Food and Nutrition Board of the Institute of Medicine has established Tolerable Upper Intake Levels (ULs) for seven vitamins.
Phytochemicals such as polyphenols are compounds produced naturally in plants (phyto means “plant” in Greek). In general, the term identifies compounds that are prevalent in plant foods, but are not proven to be essential for human nutrition, as of 2018. There is no conclusive evidence in humans that polyphenols or other non-nutrient compounds from plants confer health benefits, mainly because these compounds have poor bioavailability, i,e., following ingestion, they are digested into smaller metabolites with unknown functions, then are rapidly eliminated from the body.
While initial studies sought to reveal if dietary supplements might promote health, one meta-analysis concluded that supplementation with antioxidant vitamins A and E and beta-carotene did not convey any benefits, and may increase risk of death. Vitamin C and selenium supplements did not impact mortality rate. Health effects of non-nutrient phytochemicals such as polyphenols were not assessed in this review.
Intestinal bacterial flora
Animal intestines contain a large population of gut flora. In humans, the four dominant phyla are Firmicutes, Bacteroidetes, Actinobacteria, and Proteobacteria. They are essential to digestion and are also affected by food that is consumed. Bacteria in the large intestine perform many important functions for humans, including breaking down and aiding in the absorption of fermentable fiber, stimulating cell growth, repressing the growth of harmful bacteria, training the immune system to respond only to pathogens, producing vitamin B12, and defending against some infectious diseases. “Probiotics” refers to the idea of deliberately consuming live bacteria in an attempt to change the bacterial population in the large intestine, to the health benefit of the host human or animal. “Prebiotic (nutrition)” refers to the idea that consuming a bacterial energy source such as soluble fiber could support the population of health-beneficial bacteria in the large intestine. There is not yet a scientific consensus as to health benefits accruing from probiotics or prebiotics.
Carnivore and herbivore diets are contrasting, with basic nitrogen and carbon proportions vary for their particular foods. Many herbivores rely on bacterial fermentation to create digestible nutrients from indigestible plant cellulose, while obligate carnivores must eat animal meats to obtain certain vitamins or nutrients their bodies cannot otherwise synthesize.
Plant nutrition is the study of the chemical elements that are necessary for plant growth. There are several principles that apply to plant nutrition. Some elements are directly involved in plant metabolism. However, this principle does not account for the so-called beneficial elements, whose presence, while not required, has clear positive effects on plant growth.
A nutrient that is able to limit plant growth according to Liebig’s law of the minimum is considered an essential plant nutrient if the plant cannot complete its full life cycle without it. There are 16 essential plant soil nutrients, besides the three major elemental nutrients carbon and oxygen that are obtained by photosynthetic plants from carbon dioxide in air, and hydrogen, which is obtained from water.
Plants uptake essential elements from the soil through their roots and from the air (consisting of mainly nitrogen and oxygen) through their leaves. Green plants obtain their carbohydrate supply from the carbon dioxide in the air by the process of photosynthesis. Carbon and oxygen are absorbed from the air, while other nutrients are absorbed from the soil. Nutrient uptake in the soil is achieved by cation exchange, wherein root hairs pump hydrogen ions (H+) into the soil through proton pumps. These hydrogen ions displace cations attached to negatively charged soil particles so that the cations are available for uptake by the root. In the leaves, stomata open to take in carbon dioxide and expel oxygen. The carbon dioxide molecules are used as the carbon source in photosynthesis.
Although nitrogen is plentiful in the Earth’s atmosphere, very few plants can use this directly. Most plants, therefore, require nitrogen compounds to be present in the soil in which they grow. This is made possible by the fact that largely inert atmospheric nitrogen is changed in a nitrogen fixation process to biologically usable forms in the soil by bacteria.
Plant nutrition is a difficult subject to understand completely, partially because of the variation between different plants and even between different species or individuals of a given clone. Elements present at low levels may cause deficiency symptoms, and toxicity is possible at levels that are too high. Furthermore, deficiency of one element may present as symptoms of toxicity from another element, and vice versa.
Advice and guidance
Canada’s Food Guide is an example of a government-run nutrition program. Produced by Health Canada, the guide advises food quantities, provides education on balanced nutrition, and promotes physical activity in accordance with government-mandated nutrient needs. Like other nutrition programs around the world, Canada’s Food Guide divides nutrition into four main food groups: vegetables and fruit, grain products, milk and alternatives, and meat and alternatives. Unlike its American counterpart, the Canadian guide references and provides alternative to meat and dairy, which can be attributed to the growing vegan and vegetarian movements.
In the US, nutritional standards and recommendations are established jointly by the US Department of Agriculture and US Department of Health and Human Services and these recommendations are published as the Dietary Guidelines for Americans. Dietary and physical activity guidelines from the USDA are presented in the concept of MyPlate, which superseded the food pyramid, which replaced the Four Food Groups. The Senate committee currently responsible for oversight of the USDA is the Agriculture, Nutrition and Forestry Committee. Committee hearings are often televised on C-SPAN. The U.S. Department of Health and Human Services provides a sample week-long menu that fulfills the nutritional recommendations of the government.
Governmental organisations have been working on nutrition literacy interventions in non-primary health care settings to address the nutrition information problem in the U.S. Some programs include:
The Family Nutrition Program (FNP) is a free nutrition education program serving low-income adults around the U.S. This program is funded by the Food Nutrition Service’s (FNS) branch of the United States Department of Agriculture (USDA) usually through a local state academic institution that runs the program. The FNP has developed a series of tools to help families participating in the Food Stamp Program stretch their food dollar and form healthful eating habits including nutrition education.
Expanded Food and Nutrition Education Program (ENFEP) is a unique program that currently operates in all 50 states and in American Samoa, Guam, Micronesia, Northern Marianas, Puerto Rico, and the Virgin Islands. It is designed to assist limited-resource audiences in acquiring the knowledge, skills, attitudes, and changed behavior necessary for nutritionally sound diets, and to contribute to their personal development and the improvement of the total family diet and nutritional well-being.
An example of a state initiative to promote nutrition literacy is Smart Bodies, a public-private partnership between the state’s largest university system and largest health insurer, Louisiana State Agricultural Center and Blue Cross and Blue Shield of Louisiana Foundation. Launched in 2005, this program promotes lifelong healthful eating patterns and physically active lifestyles for children and their families. It is an interactive educational program designed to help prevent childhood obesity through classroom activities that teach children healthful eating habits and physical exercise.
Nutrition is taught in schools in many countries. In England and Wales, the Personal and Social Education and Food Technology curricula include nutrition, stressing the importance of a balanced diet and teaching how to read nutrition labels on packaging. In many schools, a Nutrition class will fall within the Family and Consumer Science or Health departments. In some American schools, students are required to take a certain number of FCS or Health related classes. Nutrition is offered at many schools, and, if it is not a class of its own, nutrition is included in other FCS or Health classes such as: Life Skills, Independent Living, Single Survival, Freshmen Connection, Health etc. In many Nutrition classes, students learn about the food groups, the food pyramid, Daily Recommended Allowances, calories, vitamins, minerals, malnutrition, physical activity, healthful food choices, portion sizes, and how to live a healthy life.
A 1985, US National Research Council report entitled Nutrition Education in US Medical Schools concluded that nutrition education in medical schools was inadequate. Only 20% of the schools surveyed taught nutrition as a separate, required course. A 2006 survey found that this number had risen to 30%. Membership by physicians in leading professional nutrition societies such as the American Society for Nutrition has generally declined from the 1990s.
In the US, Registered dietitian nutritionists (RDs or RDNs) are health professionals qualified to provide safe, evidence-based dietary advice which includes a review of what is eaten, a thorough review of nutritional health, and a personalized nutritional treatment plan through dieting. They also provide preventive and therapeutic programs at work places, schools and similar institutions. Certified Clinical Nutritionists or CCNs, are trained health professionals who also offer dietary advice on the role of nutrition in chronic disease, including possible prevention or remediation by addressing nutritional deficiencies before resorting to drugs. Government regulation especially in terms of licensing, is currently less universal for the CCN than that of RD or RDN. Another advanced Nutrition Professional is a Certified Nutrition Specialist or CNS. These Board Certified Nutritionists typically specialize in obesity and chronic disease. In order to become board certified, potential CNS candidate must pass an examination, much like Registered Dieticians. This exam covers specific domains within the health sphere including; Clinical Intervention and Human Health.
The findings of the 2003 National Assessment of Adult Literacy (NAAL) provide a basis upon which to frame the nutrition literacy problem in the U.S. NAAL introduced the first ever measure of “the degree to which individuals have the capacity to obtain, process and understand basic health information and services needed to make appropriate health decisions” – an objective of Healthy People 2010 and of which nutrition literacy might be considered an important subset. On a scale of below basic, basic, intermediate and proficient, NAAL found 13 percent of adult Americans have proficient health literacy, 44% have intermediate literacy, 29 percent have basic literacy and 14 percent have below basic health literacy. The study found that health literacy increases with education and people living below the level of poverty have lower health literacy than those above it.
Another study examining the health and nutrition literacy status of residents of the lower Mississippi Delta found that 52 percent of participants had a high likelihood of limited literacy skills. While a precise comparison between the NAAL and Delta studies is difficult, primarily because of methodological differences, Zoellner et al. suggest that health literacy rates in the Mississippi Delta region are different from the U.S. general population and that they help establish the scope of the problem of health literacy among adults in the Delta region. For example, only 12 percent of study participants identified the My Pyramid graphic two years after it had been launched by the USDA. The study also found significant relationships between nutrition literacy and income level and nutrition literacy and educational attainment further delineating priorities for the region.
These statistics point to the complexities surrounding the lack of health/nutrition literacy and reveal the degree to which they are embedded in the social structure and interconnected with other problems. Among these problems are the lack of information about food choices, a lack of understanding of nutritional information and its application to individual circumstances, limited or difficult access to healthful foods, and a range of cultural influences and socioeconomic constraints such as low levels of education and high levels of poverty that decrease opportunities for healthful eating and living.
The links between low health literacy and poor health outcomes has been widely documented and there is evidence that some interventions to improve health literacy have produced successful results in the primary care setting. More must be done to further our understanding of nutrition literacy specific interventions in non-primary care settings in order to achieve better health outcomes.
According to WHO, malnutrition refers to deficiencies, excesses, or imbalances in a person’s intake of energy and/or nutrients. The term malnutrition addresses 3 broad groups of conditions: undernutrition, which includes wasting (low weight-for-height), stunting (low height-for-age) and underweight (low weight-for-age); micronutrient-related malnutrition, which includes micronutrient deficiencies or insuficiencies (a lack of important vitamins and minerals) or micronutrient excess; and overweight, obesity and diet-related noncommunicable diseases (such as heart disease, stroke, diabetes and some cancers). In Mali, the International Crops Research Institute for the Semi-Arid Tropics (ICRISAT) and the Aga Khan Foundation trained women’s groups to make equinut, a healthy and nutritional version of the traditional recipe di-dèguè (comprising peanut paste, honey and millet or rice flour). The aim was to boost nutrition and livelihoods by producing a product that women could make and sell, and which would be accepted by the local community because of its local heritage.
The U.S. Food and Nutrition Board sets Estimated Average Requirements (EARs) and Recommended Dietary Allowances (RDAs) for vitamins and minerals. EARs and RDAs are part of Dietary Reference Intakes. The DRI documents describe nutrient deficiency signs and symptoms.
The U.S. Food and Nutrition Board sets Tolerable Upper Intake Levels (known as ULs) for vitamins and minerals when evidence is sufficient. ULs are set a safe fraction below amounts shown to cause health problems. ULs are part of Dietary Reference Intakes. The European Food Safety Authority also reviews the same safety questions and set its own ULs.
When too much of one or more nutrients is present in the diet to the exclusion of the proper amount of other nutrients, the diet is said to be unbalanced. High calorie food ingredients such as vegetable oils, sugar and alcohol are referred to as “empty calories” because they displace from the diet foods that also contain protein, vitamins, minerals and fiber.
Illnesses caused by deficient nutrient consumption
Health and nutrition appear to have close links with overall educational success.
Nutritional supplement treatment may be appropriate for major depression, bipolar disorder, schizophrenia, and obsessive compulsive disorder, the four most common mental disorders in developed countries. Supplements under study for possible effects on mood elevation and stabilization include eicosapentaenoic acid and docosahexaenoic acid, which are omega-3 fatty acids in fish oil.
Since the Industrial Revolution some two hundred years ago, the food processing industry has invented many technologies that both help keep foods fresh longer and alter the fresh state of food as they appear in nature. Cooling is the primary technology used to maintain freshness, whereas many more technologies have been invented to allow foods to last longer without becoming spoiled. These latter technologies include pasteurisation, autoclavation, drying, salting, and separation of various components, all of which appearing to alter the original nutritional contents of food. Pasteurisation and autoclavation (heating techniques) have no doubt improved the safety of many common foods, preventing epidemics of bacterial infection. But some of the (new) food processing technologies have downfalls as well.
Modern separation techniques such as milling, centrifugation, and pressing have enabled concentration of particular components of food, yielding flour, oils, juices, and so on, and even separate fatty acids, amino acids, vitamins, and minerals. Inevitably, such large-scale concentration changes the nutritional content of food, saving certain nutrients while removing others. Heating techniques may also reduce food’s content of many heat-labile nutrients such as certain vitamins and phytochemicals, and possibly other yet-to-be-discovered substances. Because of reduced nutritional value, processed foods are often ‘enriched’ or ‘fortified’ with some of the most critical nutrients (usually certain vitamins) that were lost during processing. Nonetheless, processed foods tend to have an inferior nutritional profile compared to whole, fresh foods, regarding content of both sugar and high GI starches, potassium/sodium, vitamins, fiber, and of intact, unoxidized (essential) fatty acids. In addition,
processed foods often contain potentially harmful substances such as oxidized fats and trans fatty acids.
A dramatic example of the effect of food processing on a population’s health is the history of epidemics of beri-beri in people subsisting on polished rice. Removing the outer layer of rice by polishing it removes with it the essential vitamin thiamine, causing beri-beri. Another example is the development of scurvy among infants in the late 19th century in the United States. It turned out that the vast majority of sufferers were being fed milk that had been heat-treated (as suggested by Pasteur) to control bacterial disease. Pasteurisation was effective against bacteria, but it destroyed the vitamin C.
As mentioned, lifestyle- and obesity-related diseases are becoming increasingly prevalent all around the world. There is little doubt that the increasingly widespread application of some modern food processing technologies has contributed to this development. The food processing industry is a major part of modern economy, and as such it is influential in political decisions (e.g., nutritional recommendations, agricultural subsidising). In any known profit-driven economy, health considerations are hardly a priority; effective production of cheap foods with a long shelf-life is more the trend. In general, whole, fresh foods have a relatively short shelf-life and are less profitable to produce and sell than are more processed foods. Thus, the consumer is left with the choice between more expensive, but nutritionally superior, whole, fresh foods, and cheap, usually nutritionally inferior, processed foods. Because processed foods are often cheaper, more convenient (in both purchasing, storage, and preparation), and more available, the consumption of nutritionally inferior foods has been increasing throughout the world along with many nutrition-related health complications.
Outline of nutrition
Dangers of poor nutrition
- Dietary minerals
- Dietary supplements
- Evolution of dietary antioxidants
- Essential nutrients
- Food fortification
- Table of food nutrients
Standard amino acids
- Aspartic acid (aspartate)
- Glutamic acid (glutamate)
- Isoleucine (branched chain amino acid)
- Leucine (branched chain amino acid)
- Valine (branched chain amino acid)
Other amino acids
- Food preferences in older adults and seniors
- Nutrition psychology
- Physical fitness
Notes and references
- “Joint Collection Development Policy: Human Nutrition and Food”. US National Library of Medicine, National Institutes of Health. 14 October 2014. Retrieved 13 December 2014.
- Whitney, Ellie; Rolfes, Sharon Rady (2013). Understanding Nutrition (13 ed.). Wadsworth, Cengage Learning. pp. 667, 670. ISBN 978-1-133-58752-1.
- Obesity, Weight Linked to Prostate Cancer Deaths – National Cancer Institute Archived 7 June 2011 at the Wayback Machine. Cancer.gov. Retrieved on 2011-10-17.
- Obesity and Overweight for Professionals: Causes | DNPAO | CDC Archived 24 February 2016 at the Wayback Machine. Cdc.gov (16 May 2011). Retrieved on 2011-10-17.
- Metabolic syndrome – PubMed Health. Ncbi.nlm.nih.gov. Retrieved on 2011-10-17.
- Omega-3 fatty acids. Umm.edu (5 October 2011). Retrieved on 2011-10-17.
- What I need to know about Eating and Diabetes – National Diabetes Information Clearinghouse. Diabetes.niddk.nih.gov. Retrieved on 2011-10-17.
- Diabetes Diet and Food Tips: Eating to Prevent and Control Diabetes Archived 20 May 2011 at the Wayback Machine. Helpguide.org. Retrieved on 2011-10-17.
- Osteoporosis & Vitamin D: Deficiency, How Much, Benefits, and More. Webmd.com (7 July 2005). Retrieved on 2011-10-17.
- Dietary Supplement Fact Sheet: Vitamin D. Ods.od.nih.gov. Retrieved on 2011-10-17.
- Brody, Jane E. (19 March 1998). “Osteoporosis Linked to Vitamin D Deficiency”. The New York Times. Archived from the original on 9 March 2008.
- Payne-Palacio, June R.; Canter, Deborah D. (2014). The Profession of Dietetics. Jones & Bartlett Learning. pp. 3–4. ISBN 978-1-284-02608-5.
- Gratzer 2005, p. 40.
- Gratzer 2005, p. 41.
- Gratzer 2005, p. 36.
- Daniel 1:5–16. Biblegateway.com. Retrieved on 2011-10-17.
- McCollum, Elmer V. (1957). A History of Nutrition. Cambridge, Mass.: The Riverside Press (Houghton Mifflin). pp. 8–9.
- History of the Study of Nutrition in Western Culture (Rai University lecture notes for General Nutrition course, 2004)
- Smith, Richard (24 January 2004). “Let food by thy medicine…”. BMJ. 328 (7433): 0–g–0. doi:10.1136/bmj.328.7433.0-g. PMC 318470.
- Gratzer 2005, p. 37.
- Gratzer 2005, pp. 38, 39, 41.
- Gratzer 2005, p. 38.
- Gratzer 2005, p. 39.
- Bhatt, Arun (January – March 2010). “Evolution of Clinical Research: A History Before and Beyond James Lind”. Perspectives in Clinical Research. 1 (1): 6–10. PMC 3149409. PMID 21829774.
- Gratzer 2005, p. 48.
- Gratzer 2005, pp. 48–50, 52–54.
- Willett, Walter C.; Skerrett, Patrick J. (2005) . Eat, Drink, and be Healthy: The Harvard Medical School Guide To Healthy Eating. Free Press (Simon & Schuster). p. 183. ISBN 978-0-684-86337-5.
- Gratzer 2005, pp. 21–24, 32.
- Gratzer 2005, p. 60.
- Silberberg, Martin S. (2009). Chemistry: The Molecular Nature of Matter and Change (5 ed.). McGraw-Hill. p. 44. ISBN 978-0-07-304859-8.
- Gratzer 2005, p. 56.
- Muljadi, Paul. Health. Paul Muljadi. p. 42.
- Gratzer 2005, pp. 73–74.
- Ahrens, Richard (1 January 1977). “William Prout (1785–1850): A Biographical Sketch” (PDF). The Journal of Nutrition. 107 (1): 15. doi:10.1093/jn/107.1.15. PMID 319206.
- Gratzer 2005, p. 82.
- Carpenter 1994, p. 224.
- Gratzer 2005, pp. 86, 92, 95, 115.
- Gratzer 2005, pp. 98–99.
- Carpenter 1994, p. 220.
- Willcock, Edith G.; F. Gowland Hopkins (1906). “The importance of individual amino-acids in metabolism: Observations on the effect of adding tryptophane to a dietary in which zein is the sole nitrogenous constituent”. The Journal of Physiology. 35 (1–2): 88–102. doi:10.1113/jphysiol.1906.sp001181. PMC 1465819. PMID 16992872.
- Semenza, G., ed. (2012). Comprehensive Biochemistry: Selected Topics in the History of Biochemistry: Personal Recollections, Part 1. 35. p. 117. ISBN 978-0-444-59820-2. Retrieved 15 March 2016.
- Hopkins, F. Gowland (1912). “Feeding Experiments Illustrating the Importance of Accessory Factors in Normal Dietaries”. The Journal of Physiology. 44 (5–6): 425–60. doi:10.1113/jphysiol.1912.sp001524. PMC 1512834. PMID 16993143.
- Carpenter’s table gives the year each vitamin was proposed, the year isolated (shown here), the year the structure was determined, and the year that synthesis was achieved. Carpenter, Kenneth J. (1 October 2003). “A Short History of Nutritional Science: Part 3 (1912–1944)”. The Journal of Nutrition. 133 (10): 3023–32. doi:10.1093/jn/133.10.3023. PMID 14519779. from Combs, G.F., Jr (1992). The Vitamins: Fundamental Aspects in Nutrition and Health. Academic Press. ISBN 978-0-12-381980-2.
- Carpenter, Kenneth J. (1 November 2003). “A Short History of Nutritional Science: Part 4 (1945–1985)”. The Journal of Nutrition. 133 (11): 3331–42. doi:10.1093/jn/133.11.3331. PMID 14608041.
- Conlan, Roberta; Elizabeth Sherman (October 2000). “Unraveling the Enigma of Vitamin D” (PDF). National Academy of Sciences. Retrieved 13 June 2016.
- Subcommittee on Vitamin Tolerance, Committee on Animal Nutrition, National Research Council (1987). Vitamin E, in Vitamin Tolerance of Animals. National Academy of Sciences. doi:10.17226/949. ISBN 978-0-309-03728-0. Retrieved 22 December 2013.
- “F.B.I. Joins Hunt for Young German Chemist”. San Bernardino Daily Sun. 18 December 1940. Retrieved 22 December 2013.
- “USDA’s Food Guide Pyramid Booklet, 1992” (PDF). United States Department Of Agriculture. Archived from the original (PDF) on 24 August 2014.
- Nestle, Marion (2013) . Food Politics: How the Food Industry Influences Nutrition and Health. University of California Press. p. 413. ISBN 978-0-520-27596-6.
- Fuhrman, Joel (2014). The End of Dieting. Harper One (Harper Collins). pp. 101–02. ISBN 978-0-06-224932-6.
- “Get the Facts on Fiber”. webmd.com.
- Berg J, Tymoczko JL, Stryer L (2002). Biochemistry (5th ed.). San Francisco: W.H. Freeman. p. 603. ISBN 978-0-7167-4684-3.
- Otto, H (1973). Diabetik Bei Diabetus Mellitus. Bern: Verlag Hans Huber.
- Crapo, P; Reaven, Olefsky (1977). “Postprandial plasma-glucose and -insulin responses to different complex carbohydrates”. Diabetes. 26 (12): 1178–83. doi:10.2337/diabetes.26.12.1178. PMID 590639.
- Crapo, P; Kolterman, Waldeck; Reaven, Olefsky (1980). “Postprandial hormonal responses to different types of complex carbohydrate in individuals with impaired glucose tolerance”. Am J Clin Nutr. 33 (8): 1723–28. doi:10.1093/ajcn/33.8.1723. PMID 6996472.
- Jenkins, David; Jenkins, Alexandra L.; Wolever, Thomas M.S.; Thompson, Lilian H.; Rao, A. Venkat (February 1986). “Simple and complex carbohydrates”. Nutrition Reviews. 44 (2): 44–49. doi:10.1111/j.1753-4887.1986.tb07585.x. PMID 3703387.
- “The Nutrition Source: Carbohydrates”. Harvard School of Public Health. Retrieved 7 July 2011.
- “WHO Technical Report Series. Diet, nutrition and the prevention of chronic diseases.” Report of a Joint WHO/FAO Expert Consultation; Geneva 2003. Retrieved 2011-03-07
- Klonoff, David C. (24 June 2016). “Replacements for Trans Fats—Will There Be an Oil Shortage?”. Journal of Diabetes Science and Technology. 1 (3): 415–22. doi:10.1177/193229680700100316. PMC 2769584. PMID 19885099.
- American Dietetic Association; Dietitians Of, Canada (2003). “Position of the American Dietetic Association and Dietitians of Canada: Vegetarian diets”. Journal of the American Dental Association. 103 (6): 748–65. doi:10.1053/jada.2003.50142. PMID 12778049.
- “Healthy Water Living”. BBC. Retrieved 2007-02-01. Archived from the original on 1 January 2007.
- Valtin, Heinz (2002). ““Drink at least eight glasses of water a day.” Really? Is there scientific evidence for “8 × 8″?”. American Journal of Physiology. Regulatory, Integrative and Comparative Physiology. 283 (5): R993–R1004. doi:10.1152/ajpregu.00365.2002. PMID 12376390.
- Food and Nutrition Board, National Academy of Sciences. Recommended Dietary Allowances, revised 1945. National Research Council, Reprint and Circular Series, No. 122, 1945 (Aug), pp. 3–18.
- Le Bellego L, Jean C, Jiménez L, Magnani C, Tang W, Boutrolle I (2010). “Understanding fluid consumption patterns to improve healthy hydration”. Nutr Today. 45 (6): S22–S26. doi:10.1097/NT.0b013e3181fe4314.
- EFSA Panel on Dietetic Products, Nutrition and Allergies (NDA) (2010). “Scientific Opinion on Dietary Reference Values for Water” (PDF). EFSA Journal. 8 (3): 1459. doi:10.2903/j.efsa.2010.1459.
- Armstrong LE, Pumerantz AC, Roti MW, Judelson DA, Watson G, Dias JC, Sokmen B, Casa DJ, Maresh CM, et al. (2005). “Fluid, electrolyte, and renal indices of hydration during 11 days of controlled caffeine consumption”. Int J Sport Nutr Exerc Metab. 15 (3): 252–65. doi:10.1123/ijsnem.15.3.252. PMID 16131696.
- “FAO Corporate Document Repository. Food Balance Sheets- A Handbook.” Retrieved 2011-03-07
- Farrell DJ, Bower L (October 2003). “Fatal water intoxication”. Journal of Clinical Pathology. 56 (10): 803–04. doi:10.1136/jcp.56.10.803-a. PMC 1770067. PMID 14514793.
- “Appendix 9. Alcohol”. health.gov.
- “Alcohol and Nutrition: The Calorie and Carb Breakdown!”. The Catholic University of America.
- ““What We Eat in America, NHANES 2013-2014““ (PDF).
- Mitchell, Dakota; Haroun, Lee (2012). Introduction to Health Care (3 ed.). Delmar Cengage. p. 279. ISBN 978-1-4354-8755-0.
- Nelson, D.L.; Cox, M.M. (2000). Lehninger Principles of Biochemistry (3rd ed.). New York: Worth Publishing. ISBN 978-1-57259-153-0.
- Corbridge, D.E.C. (1995). Phosphorus: An Outline of its Chemistry, Biochemistry, and Technology (5th ed.). Amsterdam: Elsevier. ISBN 978-0-444-89307-9.
- “Chapter 14. Magnesium”. Food and Agriculture Organization of the United States.
- Lippard, S.J.; Berg, J.M. (1994). Principles of Bioinorganic Chemistry. Mill Valley, CA: University Science Books. ISBN 978-0-935702-72-9.
- Shils, M.S.; et al., eds. (2005). Modern Nutrition in Health and Disease. Lippincott Williams and Wilkins. ISBN 978-0-7817-4133-0.
- Dietary Reference Intakes (DRIs): Tolerable Upper Intake Levels, Vitamins, 2011
- d’Archivio, M.; Filesi, C.; Varì, R.; Scazzocchio, B.; Masella, R. (2010). “Bioavailability of the polyphenols: status and controversies”. International Journal of Molecular Sciences. 11 (4): 1321–42. doi:10.3390/ijms11041321. PMC 2871118. PMID 20480022.
- “Common questions about diet and cancer”. American Cancer Society. 5 February 2016. Retrieved 23 November 2018.
- Bjelakovic G; Nikolova, D; Gluud, LL; Simonetti, RG; Gluud, C (2007). “Mortality in randomized trials of antioxidant supplements for primary and secondary prevention: systematic review and meta-analysis”. JAMA. 297 (8): 842–57. doi:10.1001/jama.297.8.842. PMID 17327526.
- Sepkowitz, Kent (3 August 2011). “The Doctor and the Pomegranate”. Slate.
- Khanna S, Tosh PK (January 2014). “A clinician’s primer on the role of the microbiome in human health and disease”. Mayo Clin. Proc. 89 (1): 107–14. doi:10.1016/j.mayocp.2013.10.011. PMID 24388028.
- Guarner, F; Malagelada, J (2003). “Gut flora in health and disease”. The Lancet. 361 (9356): 512–19. doi:10.1016/S0140-6736(03)12489-0. PMID 12583961.
- National Geographic Society (21 January 2011). “herbivore”. National Geographic Society. Retrieved 1 May 2017.
- Allen V. Barker; David J. Pilbeam. Handbook of Plant Nutrition. CRC Press, 2010. p. Preface.
- Lindemann, W.C. and Glover C.R. (2003) Nitrogen Fixation by Legumes. New Mexico State University/
- Canada’s Food Guide. Health Canada
- Sample Menus for a 2000 Calorie Food Pattern. mypyramid.gov
- Guthrie, Joanne F.; Stommes, Eileen; Voichick, Jane (January – February 2006). “Evaluating Food Stamp Nutrition Education: Issues and Opportunities”. Journal of Nutrition Education and Behavior. 38 (1): 6–11. doi:10.1016/j.jneb.2005.11.001. PMID 16595272.
- Commission on Life Sciences. (1985). Nutrition Education in US Medical Schools, p. 4. National Academies Press.
- Adams KM, Lindell KC, Kohlmeier M, Zeisel SH (2006). “Status of nutrition education in medical schools”. Am. J. Clin. Nutr. 83 (4): 941S–14S. doi:10.1093/ajcn/83.4.941S. PMC 2430660. PMID 16600952.
- McClave, Stephen A.; Mechanick, Jeffrey I.; Bistrian, Bruce; Graham, Toby; Hegazi, Refaat; Jensen, Gordon L.; Kushner, Robert F.; Merritt, Russell (1 December 2016). “What is the significance of a physician shortage in nutrition medicine?”. JPEN. Journal of Parenteral and Enteral Nutrition. 34 (6 Suppl): 7S–20S. doi:10.1177/0148607110375429. PMID 21149831.
- “What is an RDN and DTR?”. Academy of Nutrition and Dietetics. Retrieved 9 May 2015.
- http://www.iaacn.org/ The International & American Associations of Clinical Nutritionist, 2014, Retrieved 2014-12-14
- “FAQs about CNS Certification – Certification Board for Nutrition Specialists”. Retrieved 24 September 2015.
- Baldi, S. (ED.) et al. (2009). Technical Report and Data File User’s Manual for the 2003 National Assessment of Adult Literacy (NCES 2009–47). U.S. Department of Education, National Center for Education Statistics. Washington, DC: U.S. Government Printing Office.
- Zoellner J, Connell C, Bounds W, Crook L, Yadrick K (2009). “Nutrition Literacy Status and Preferred Nutrition Communications Channels Among Adults in the Lower Mississippi Delta”. Preventing Chronic Disease. 6 (4): A128. PMC 2774642. PMID 19755004.
- Berkman N.D., Sheridan, S.L., Donahue, K.E., Halpern, D.J., Viera, A., Crotty, K., Viswanathan, M. (2011). Health and Literacy Intervention Outcomes: an Updated Systematic Review. Evidence Report/Technology Assessment no. 199. Prepared by RTI International – University of North Carolina Evidence-based Practice Center. Publication Number 11-E006. Rockville, MD. Agency for Healthcare Research and Quality.
- “Malnutrition”. www.who.int.
- Nourishing communities through holistic farming, Impatient optimists, Bill & Melinda Gates Foundation. 30 April 2013.
Nutrient recommendations: Dietary Reference Intakes (DRI).
- Tolerable Upper Intake Levels For Vitamins And Minerals (PDF), European Food Safety Authority, 2006
- “What are empty calories?”. USDA MyPlate 2011. 27 March 2015. Archived from the original on 30 January 2014. Retrieved 20 October 2017.
- Jere R. Behrman (1996). “The impact of health and nutrition on education”. World Bank Research Observer. 11 (1): 23–37. doi:10.1093/wbro/11.1.23.
- Lakhan SE, Vieira KF (2008). “Nutritional therapies for mental disorders”. Nutr J. 7 (1): 2. doi:10.1186/1475-2891-7-2. PMC 2248201. PMID 18208598.
- Paola Bozzatello; Elena Brignolo; Elisa De Grandi; Silvio Bellino (July 2016). “Supplementation with Omega-3 Fatty Acids in Psychiatric Disorders: A Review of Literature Data”. J Clin Med. 5 (8): 67. doi:10.3390/jcm5080067. PMC 4999787. PMID 27472373.
- Morris, Audrey; Audia Barnett; Olive-Jean Burrows (2004). “Effect of Processing on Nutrient Content of Foods” (PDF). Cajanus. 37 (3): 160–64. Retrieved 26 October 2006.
- Carpenter, Kenneth J. (1994). Protein and Energy: A Study of Changing Ideas in Nutrition. Cambridge University Press. ISBN 978-0-521-45209-0.
- Curley, S., and Mark (1990). The Natural Guide to Good Health, Lafayette, Louisiana, Supreme Publishing
- Galdston, I. (1960). Human Nutrition Historic and Scientific. New York: International Universities Press.
- Gratzer, Walter (2006) . Terrors of the Table: The Curious History of Nutrition. Oxford University Press. ISBN 978-0-19-920563-9.
- Mahan, L.K.; Escott-Stump, S., eds. (2000). Krause’s Food, Nutrition, and Diet Therapy (10th ed.). Philadelphia: W.B. Saunders Harcourt Brace. ISBN 978-0-7216-7904-4.
- Thiollet, J.-P. (2001). Vitamines & minéraux. Paris: Anagramme.
- Walter C. Willett; Meir J. Stampfer (January 2003). “Rebuilding the Food Pyramid”. Scientific American. 288 (1): 64–71. doi:10.1038/scientificamerican0103-64. PMID 12506426.
- Diet, Nutrition and the prevention of chronic diseases by a Joint WHO/FAO Expert consultation (2003)
- UN Standing Committee on Nutrition – In English, French and Portuguese