Nutrients
There are six major classes of nutrients: carbohydrates, fats, minerals, protein, vitamins, and water.These nutrient classes can be categorized as either macronutrients (needed in relatively large amounts) or micronutrients (needed in smaller quantities). The macronutrients include carbohydrates (including fiber), fats, protein, and water. The micronutrients are minerals and vitamins.
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. A third class of dietary material, fiber (i.e., non-digestible material such as cellulose), is also required, for both mechanical and biochemical reasons, although the exact reasons remain unclear.
Molecules of carbohydrates and fats consist of carbon, hydrogen, and oxygen atoms. Carbohydrates range from simple monosaccharides (glucose, fructose, 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, some glucose can be produced internally; the remaining amino acids are discarded, primarily as urea in urine. This occurs normally only during prolonged starvation.
Other micronutrients include antioxidants and phytochemicals, which are said to influence (or protect) some body systems. Their necessity is not as well established as in the case of, for instance, vitamins.
Most foods contain a mix of some or all of the nutrient classes, together with other substances, such as toxins of various sorts. Some nutrients can be stored internally (e.g., the fat soluble vitamins), while others are required more or less continuously. Poor health can be caused by a lack of required nutrients or, in extreme cases, too much of a required nutrient. For example, both salt and water (both absolutely required) will cause illness or even death in excessive amounts.
Carbohydrates
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. 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 were 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) which result in only a partial catabolism to glucose, while many complex carbohydrates may be digested at essentially the same rate as simple carbohydrates. Glucose stimulates the production of insulin through food entering the bloodstream, which is grasped by the beta cells in the pancreas.
Fiber
Dietary
fiber is a carbohydrate
(or a polysaccharide) 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 that is indigestible because 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
digesta 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 which 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.
Fat
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
vs omega-6 has wide effects on general health, and specific effects
on immune function and inflammation, and mitosis (i.e. cell division).Protein
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| Spirulina contains all amino acids |
It is possible to combine 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 don't need to be eaten at the same meal to be used together by the body. Sources of dietary protein include meats, tofu and other soy-products, eggs, legumes, and dairy products such as milk and cheese. Excess amino acids from protein can be converted into glucose and used for fuel through a process called gluconeogenesis. The amino acids remaining after such conversion are discarded.
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