Nitrogenous Health Dictionary

Nitrogenous: From 1 Different Sources


A compound or molecule that contains nitrogen; in my context, a substance that is or was a part of protein metabolism.
Health Source: Herbal Medical
Author: Health Dictionary

Abal

Calligonum comosum

Description: The abal is one of the few shrubby plants that exists in the shady deserts. This plant grows to about 1.2 meters, and its branches look like wisps from a broom. The stiff, green branches produce an abundance of flowers in the early spring months (March, April).

Habitat and Distribution: This plant is found in desert scrub and waste in any climatic zone. It inhabits much of the North African desert. It may also be found on the desert sands of the Middle East and as far eastward as the Rajputana desert of western India.

Edible Parts: This plant’s general appearance would not indica te its usefulness to the survivor, but while this plant is flowering in the spring, its fresh flowers can be eaten. This plant is common in the areas where it is found. An analysis of the food value of this plant has shown it to be high in sugar and nitrogenous components.... abal

Aconitum Violaceum

Jacq. ex Stapf. 15

Family: Ranunculaceae. ^A

Habitat: The alpine Himalayas of Sikkim, Nepal, the adjoining parts of southern Tibet, between altitudes of 3,000 m and 4,800 m. Ayurvedic: Prativishaa, Shyaamkan- daa, Patis. Folk: Bikhamaa.

Action: Root—antiemetic, antidiar- rhoeal, antirheumatic, antiperiodic.

The root contains diterpenoid alkaloids and a nitrogenous non-alkaloid compound, benzamide. Alkaloids include vakognavine, palmatisine, vaka- tisine, vakatisinine and vakatidine.

The root is intensely bitter, like quinine, is used with Piper longum for diarrhoea and vomiting; used externally as an application for rheumatism.... aconitum violaceum

Alkaloids

Substances found commonly in various plants. They are natural nitrogenous organic bases and combine with acids to form crystalline salts. Among alkaloids, morphine was discovered in 1805, strychnine in 1818, quinine and ca?eine in 1820, nicotine in 1829, and atropine in 1833. Only a few alkaloids occur in the animal kingdom, the outstanding example being ADRENALINE, which is formed in the medulla of the suprarenal, or adrenal, gland. Alkaloids are often used for medicinal purposes. The name of an alkaloid ends in ‘ine’ (in Latin, ‘ina’).

Neutral principals are crystalline substances with actions similar to those of alkaloids but having a neutral reaction. The name of a neutral principal ends in ‘in’, e.g. digitalin, aloin.

The following are the more important alkaloids, with their source plants:

Aconite, from Monkshood.

Atropine, from Belladonna (juice of Deadly

Nightshade).

Cocaine, from Coca leaves.

Hyoscine, from Henbane.

Morphine, Codeine, from Opium (juice of

Poppy). Thebaine, Nicotine, from Tobacco. Physostigmine, from Calabar beans. Pilocarpine, from Jaborandi leaves. Quinidine, from Cinchona or Peruvian bark. Strychnine, from Nux Vomica seeds.... alkaloids

Amino Acids

Chemical compounds that are the basic building-blocks of all proteins. Each molecule consists of nitrogenous amino and acidic carboxyl groups of atoms joined to a group of carbon atoms. Polypeptides are formed by amino-acid molecules linking via peptide bonds. Many polypeptides link up in various con?gurations to form protein molecules. In humans, proteins are made up from 20 di?erent amino acids: nine of these are labelled ‘essential’ (or, as is now preferred, ‘indispensable’) amino acids because the body cannot manufacture them and is dependent on the diet for their provision. (See also INDISPENSABLE AMINO ACIDS.)... amino acids

Azotaemia

Azotaemia means the presence of UREA and other nitrogenous bodies in greater concentration than normal in the blood. The condition is generally associated with advanced types of kidney disease (see KIDNEYS, DISEASES OF).... azotaemia

Creatine

A nitrogenous substance, methyl-guanidineacetic acid. The adult human body contains about 120 grams – 98 per cent of which is in the muscles. Much of the creatine in muscles is combined with phosphoric acid as phosphocreatine, which plays an important part in the chemistry of muscular contraction.... creatine

Proteolytic

An enzyme or agent that speeds up the breaking down or digestive hydrolysis of proteins into smaller proteins, peptides, polypeptides, oligopeptides, amino acids, and all that delicious nitrogenous slurry-stuff.... proteolytic

Uric Acid

The final end product of certain native or dietary proteins, especially the nucleoproteins found in the nucleus of cells. Unlike the much smaller nitrogenous waste product urea, which is mostly recycled to form many amino acids, uric acid is an unrecyclable metabolite. It is a bent nail that won’t restraighten, and it must be excreted: nucleoprotein to purine to uric acid to the outside in the urine or the sweat. (See GOUT, PURINES.)... uric acid

Azo

(azoto-) combining form denoting a nitrogenous compound, such as urea. Example: azothermia (raised temperature due to nitrogenous substances in the blood).... azo

Creatinuria

n. an excess of the nitrogenous compound creatine in the urine.... creatinuria

Nephron

n. the active unit of excretion in the kidney (see illustration). Blood, which is supplied by branches of the renal artery, is filtered through a knot of capillaries (glomerulus) into the cup-shaped Bowman’s capsule so that water, nitrogenous waste, and many other substances (excluding colloids) pass into the renal tubule. Here most of the substances are reabsorbed back into the blood, the remaining fluid (*urine) passing into the collecting duct, which drains into the *ureter.... nephron

Nitrogen

n. a gaseous element and a major constituent of air (79 per cent). Nitrogen is an essential constituent of proteins and nucleic acids and is obtained by animals in the form of protein-containing foods (atmospheric nitrogen cannot be utilized directly). Nitrogenous waste is excreted as *urea. Liquid nitrogen is used to freeze some specimens before pathological examination. Symbol: N.... nitrogen

Desmodium

Desmodium gangeticum

Fabaceae

San: Anshumati, Salaparni;

Hin,

Ben: Salpani;

Mal: Orila;

Tam:Pulladi;

Tel: Gitanaram

Kan: Murelehonne; Mar: Darh;

Guj: Salwan; Ori: Salaparni Pun: Shalpurhi

Importance: Desmodium is a small shrub which is the chief of the ten ingredients in the Dasamula kwatha of Hindu medicine. Roots are useful in vitiated conditions of vata, anorexia, dyspepsia, haemorrhoids, dysentery, strangury, fever, gout, inflammations, cough, asthma, bronchitis, cardiopathy and debility. The unani preparation “Arq dashmul” contains these roots. It is considered a curative for leucorrhoea and for pains due to cold (Warrier et al, 1995).

Distribution: The plant is widely distributed in the tropics and subtropics. It grows wild in the forests of India up to 1500m. It is also cultivated in the plains and in the lower Himalayas.

Botany: Desmodium gangeticum (Linn.) DC. syn. Hedysarum gangeticum Linn., Desmodium gangeticum var. maculatum (Linn.) Baker., belongs to the family Fabaceae (Papilionaceae). It is an erect diffusely branched undershrub, 90-120cm in height with a short woody stem and numerous prostrate branches provided with soft grey hairs. Leaves are unifoliate, ovate- lanceolate, membranceous and mottled with grey patches. Flowers are white, purple or lilac in elongate lax, terminal or axillary racemes. Fruits are moniliform, 6-8 jointed, glabrescent pods, joints of pods separately pubescent with hooked hairs, joint separating when ripe into indehiscent one seeded segments. Seeds are compressed and reniform.

Agrotechnology: Desmodium can grow in a variety of climate and soils. However, it prefers tropical and subtropical climatic conditions. Although it can grow on all types of soils, waterlogged and highly alkaline soils are not suitable. Light sandy loam is preferred for commercial cultivation.

It is propagated through seeds. Seeds can be planted directly in the field or seedlings raised on the nursery beds and transplanted. Transplanting always gives better results in commercial cultivation, as it gives assured crop stand. Planting is done at a spacing of 40x20cm on flat beds or ridges. Organic manures are applied at the time of land preparation and thoroughly mixed with the soil. A little quantity of phosphatic and nitrogenous fertilizers are also applied for better crop growth. The inter-row spaces between plants, both in the field and nursery should be kept free from weeds by frequent weeding and hoeing as the plant suffers from weed competition, especially during early stages of growth. Manual hand weeding is usually done. Irrigation of seedlings just after planting is good for crop establishment. Although it can be cultivated as a rainfed crop under humid tropical conditions, irrigation every month is beneficial during summer. The root is the economic part and harvesting can be commenced after 8-9 months. About 500- 700kg roots can be harvested from a hectare of land per year.

Properties and activity: The root contains gangetin, gangetinin, desmodin, N,N-dimethyl tryptamine, hypaphorine, hordenine, candicine, N-methyl tyramine and -phenyl ethyl amine. The total alkaloid fraction showed hypotensive activity. The root is bitter, antiinflammatory, analgesic, aphrodisiac, constipating, diuretic, cardiotonic, expectorant, astringent, antidiarrhoeal, carminative, antiemetic, febrifuge and anti-catarrhal (Thakur et al, 1989).... desmodium

Hiptage Benghalensis

Kurz.

Synonym: H. madablota Gaertn.

Family: Malpighiaceae.

Habitat: Throughout the warmer parts of Maharashtra, Konkan, Karnataka and other parts of India.

Ayurvedic: Atimukta, Atimuktaka, Maadhavi, Vaasanti, Pundrika, Mandaka, Vimukta, Kaamu- ka.

Siddha/Tamil: Madhavi, Vasanda- gala-malligai.

Action: Kernel of seeds is prescribed for reducing abdominal girth (obesity). Leaves—used in chronic rheumatism, asthma and skin diseases. Bark—used in bronchial asthma.

The stem and its bark contain friede- lin, epi-friedelinol, octacosanol, alpha- amyrin, beta-sitosterol and its beta-D- glucoside. The root bark gave a nitrogenous glucoside, hiptagin, identical with endecaphyllin and a glucosyl xanthone, mangiferin.

Dosage: Fruit, seed, root—powder 3-5 g; paste 5-10 g. (CCRAS.)... hiptage benghalensis

Sweat

n. the watery fluid secreted by the *sweat glands. Its principal constituents in solution are sodium chloride and urea. The secretion of sweat is a means of excreting nitrogenous waste; at the same time it has a role in controlling the temperature of the body – the evaporation of sweat from the surface of the skin has a cooling effect. Therefore an increase in body temperature causes an increase in sweating. Other factors that increase the secretion of sweat include pain, nausea, nervousness, and drugs (*diaphoretics). Sweating is reduced by colds, diarrhoea, and certain drugs. Anatomical name: sudor.... sweat

Uraemia

n. the presence of excessive amounts of urea and other nitrogenous waste compounds in the blood. These waste products are normally excreted by the kidneys in urine; their accumulation in the blood occurs in kidney failure and results in nausea, vomiting, lethargy, drowsiness, and eventually (if untreated) death. Treatment may require dialysis or transplantation. —uraemic adj.... uraemia

Urea

n. the main breakdown product of protein metabolism. It is the chemical form in which unrequired nitrogen is excreted by the body in the urine. Urea is formed in the liver from ammonia and carbon dioxide in a series of enzyme-mediated reactions (the urea cycle). Accumulation of urea in the bloodstream together with other nitrogenous compounds is due to kidney failure and gives rise to *uraemia.... urea

Xanthine

n. a nitrogenous breakdown product of the purines adenosine and guanine. Xanthine is an intermediate product of the breakdown of nucleic acids to uric acid.... xanthine

Gymnema

Gymnema sylvestre

Asclepiadaceae

San: Mesasrngi, Madhunasini;

Hin: Gudmar, Merasimgi;

Ben: Merasingi;

Mal: Chakkarakolli, Madhunasini;

Tam: Sirukurumkay, Sakkaraikkolli;

Kan: Kadhasige;

Tel: Podapatra; Mar: Kavali

Importance: Gymnema, Australian Cowplant, Small Indian Ipecacuanha or Periploca of the woods is a woody climber. It is reported to cure cough, dyspnoea, ulcers, pitta, kapha and pain in the eyes. The plant is useful in inflammations, hepatosplenomegaly, dyspepsia, constipation, jaundice, haemorrhoids, strangury, renal and vesical calculi, helminthiasis, cardiopathy, cough, asthma, bronchitis, intermittent fever, amenorrhoea, conjuctivitis and leucoderma. The fresh leaves when chewed have the remarkable property of paralysing the sense of taste for sweet and bitter substance for some time (Warrier et al, 1995). The drug is described as a destroyer of madhumeha (glycosuria) and other urinary disorders. Root has long been reputed as a remedy for snakebite. Leaves triturated and mixed with castor oil are applied to swollen glands and enlargement of internal viscera as the liver and spleen (Nadkarni, 1954). The drug is used to strengthen the function of heart, cure jaundice, piles, urinary calculi, difficult micturition and intermittent fevers (Sharma,1983). The drug enters into the composition of preparations like Ayaskrti, Varunadi kasaya, Varunadighrtam, Mahakalyanakaghrtam, etc. They suppress the activity of taste of tongue for sweet taste and for this reason it was considered that it destroys sugar, hence the name Madhunashini or Gurmar and has been prescribed as an anti-diabetic. The crude drug as well as its dried aqueous extract is mainly used in bronchial troubles.

Distribution: It is a tropical climber. It mainly grows in Western Ghats, Konkan, Tamil Nadu and some parts of Bihar. The plant is cultivated in plains of India but the drug is mainly important from Afghanistan and Iran.

Botany: Gymnema sylvestre (Retz.)R. Br. syn. Asclepias germinata Roxb. belonging to the family Asclepiadaceae is a large, woody much branched climber with pubescent young parts. Leaves are simple, opposite, elliptic or ovate, more or less pubescent on both sides, base rounded or cordate. Flowers are small, yellow and arranged in umbellate cymes. Fruits are slender and follicles are upto 7.5cm long (Warrier et al, 1995).

Two allied species, G. hirsutum found in Bundelkh and Bihar and Western Ghats and G. montanum growing wild in Eastern Ghats and Konkan are also used for the same purpose and are also called “Gurmar” (Thakur et al, 1989).

Agrotechnology: The plant can be propagated both by seeds and stem cuttings. Seedlings are to be raised in polybags. Pits of size 50cm cube are to be taken, filled with 10kg dried cowdung or FYM and covered with topsoil. On these pits about 3-4 months old seedlings are to be transplanted from polybags. Trailing can be facilitated by erecting poles and tying the plants to the poles. The plant will attain good spread within one year. Regular weeding, irrigation and organic manure application are beneficial. The plant is not attacked by any serious pests or diseases. Leaves can be collected from the first year onwards at an internal of one week. This can be continued for 10-12 years. Fresh or dried leaves can be marketed (Prasad et al, 1997).

Properties and activity: Nonacosane and hentriacontane were isolated from the hexane extract of leaves. An attempt to isolate nitrogenous compounds led to the isolation of amino acids such as leucine, iso-leucine, valine, allanine and - amynobutyric acid. Isolation of trimethyl amine oxide was of particular interest. An alkaloid gynamine which is a trace constituent was isolated and identified (Sinsheimer et al, 1967). Antisweet constituent of the leaves has been found to be a mixture of triterpene saponins. These have been designated as gymnemic acids A,B,C and D which have the gymnemagenin and gymnestrogenins as the aglycones of gymnemic acid A and B and gymnemic acid C and D respectively. These are hexahydroxy triterpenes the latter being partially acylated. The sugar residues are glucuronic acid and galacturonic acid while ferulic and angelic acids have been attached as the carboxylic acid.

Chewing of leaves reduces sensitivity to sweet substances. Effects of gymnema extracts had been variable. While verifying the effect of G. sylvestre leaves on detoxification of snake venom, it has been reported that a toxic component of venom ATP and gymnemate bind at the same site inhibiting venom ATP-ase. The active principles which have been identified as glycosides (7 gymnemic acids) suggest that the topical and selective anaesthetic effect of the plant might result from the competition of the receptor sites between glycosides and the sweet substances (Warren et al, 1969). The leaves are antidiabetic and insulinotropic. Gymnemic acid is antiviral. The plant is bitter, astringent, acrid, thermogenic, antiinflammatory, anodyne, digestive, liver tonic, emetic, diuretic, stomachic, stimulant, anthelmintic, alexipharmic, laxative, cardiotonic, expectorant, antipyretic and uterine tonic.... gymnema

Muscle

Muscular tissue is divided, according to its function, into three main groups: voluntary muscle, involuntary muscle, and skeletal muscle – of which the ?rst is under control of the will, whilst the latter two discharge their functions independently. The term ‘striped muscle’ is often given to voluntary muscle, because under the microscope all the voluntary muscles show a striped appearance, whilst involuntary muscle is, in the main, unstriped or plain. Heart muscle is partially striped, while certain muscles of the throat, and two small muscles inside the ear, not controllable by willpower, are also striped.

Structure of muscle Skeletal or voluntary muscle forms the bulk of the body’s musculature and contains more than 600 such muscles. They are classi?ed according to their methods of action. A ?exor muscle closes a joint, an extensor opens it; an abductor moves a body part outwards, an adductor moves it in; a depressor lowers a body part and an elevator raises it; while a constrictor (sphincter) muscle surrounds an ori?ce, closing and opening it. Each muscle is enclosed in a sheath of ?brous tissue, known as fascia or epimysium, and, from this, partitions of ?brous tissue, known as perimysium, run into the substance of the muscle, dividing it up into small bundles. Each of these bundles consists in turn of a collection of ?bres, which form the units of the muscle. Each ?bre is about 50 micrometres in thickness and ranges in length from a few millimetres to 300 millimetres. If the ?bre is cut across and examined under a high-powered microscope, it is seen to be further divided into ?brils. Each ?bre is enclosed in an elastic sheath of its own, which allows it to lengthen and shorten, and is known as the sarcolemma. Within the sarcolemma lie numerous nuclei belonging to the muscle ?bre, which was originally developed from a simple cell. To the sarcolemma, at either end, is attached a minute bundle of connective-tissue ?bres which unites the muscle ?bre to its neighbours, or to one of the connective-tissue partitions in the muscle, and by means of these connections the ?bre affects muscle contraction. Between the muscle ?bres, and enveloped in a sheath of connective tissue, lie here and there special structures known as muscle-spindles. Each of these contains thin muscle ?bres, numerous nuclei, and the endings of sensory nerves. (See TOUCH.) The heart muscle comprises short ?bres which communicate with their neighbours via short branches and have no sarcolemma.

Plain or unstriped muscle is found in the following positions: the inner and middle coats of the STOMACH and INTESTINE; the ureters (see URETER) and URINARY BLADDER; the TRACHEA and bronchial tubes; the ducts of glands; the GALL-BLADDER; the UTERUS and FALLOPIAN TUBES; the middle coat of the blood and lymph vessels; the iris and ciliary muscle of the EYE; the dartos muscle of the SCROTUM; and in association with the various glands and hairs in the SKIN. The ?bres are very much smaller than those of striped muscle, although they vary greatly in size. Each has one or more oval nuclei and a delicate sheath of sarcolemma enveloping it. The ?bres are grouped in bundles, much as are the striped ?bres, but they adhere to one another by cement material, not by the tendon bundles found in voluntary muscle.

Development of muscle All the muscles of the developing individual arise from the central layer (mesoderm) of the EMBRYO, each ?bre taking origin from a single cell. Later on in life, muscles have the power both of increasing in size – as the result of use, for example, in athletes – and also of healing, after parts of them have been destroyed by injury. An example of the great extent to which unstriped muscle can develop to meet the demands made on it is the uterus, whose muscular wall develops so much during pregnancy that the organ increases from the weight of 30–40 g (1–1••• oz.) to a weight of around 1 kg (2 lb.), decreasing again to its former small size in the course of a month after childbirth.

Physiology of contraction A muscle is an elaborate chemico-physical system for producing heat and mechanical work. The total energy liberated by a contracting muscle can be exactly measured. From 25–30 per cent of the total energy expended is used in mechanical work. The heat of contracting muscle makes an important contribution to the maintenance of the heat of the body. (See also MYOGLOBIN.)

The energy of muscular contraction is derived from a complicated series of chemical reactions. Complex substances are broken down and built up again, supplying each other with energy for this purpose. The ?rst reaction is the breakdown of adenyl-pyrophosphate into phosphoric acid and adenylic acid (derived from nucleic acid); this supplies the immediate energy for contraction. Next phosphocreatine breaks down into creatine and phosphoric acid, giving energy for the resynthesis of adenyl-pyrophosphate. Creatine is a normal nitrogenous constituent of muscle. Then glycogen through the intermediary stage of sugar bound to phosphate breaks down into lactic acid to supply energy for the resynthesis of phosphocreatine. Finally part of the lactic acid is oxidised to supply energy for building up the rest of the lactic acid into glycogen again. If there is not enough oxygen, lactic acid accumulates and fatigue results.

All of the chemical changes are mediated by the action of several enzymes (see ENZYME).

Involuntary muscle has several peculiarities of contraction. In the heart, rhythmicality is an important feature – one beat appearing to be, in a sense, the cause of the next beat. Tonus is a character of all muscle, but particularly of unstriped muscle in some localities, as in the walls of arteries.

Fatigue occurs when a muscle is made to act for some time and is due to the accumulation of waste products, especially sarcolactic acid (see LACTIC ACID). These substances affect the end-plates of the nerve controlling the muscle, and so prevent destructive overaction of the muscle. As they are rapidly swept away by the blood, the muscle, after a rest (and particularly if the rest is accompanied by massage or by gentle contractions to quicken the circulation) recovers rapidly from the fatigue. Muscular activity over the whole body causes prolonged fatigue which is remedied by rest to allow for metabolic balance to be re-established.... muscle

Ph

The potential of hydrogen. A “neutral” pH is expressed as 7.0 (water), with greater being alkaline and lesser being acidic. Expressed logarithmically like the Richter’s Scale, 6.9 pH is twice as acidic as 7.0. 9.0 is ten times as alkaline as 8.0, etc., all based on the presumed amount of hydrogen ion (acidity) present. This is a chemical literality, not to be confused with the vitalist and cyto-hologrammic implications of Acid and Alkaline metabolism or foods. A complex protein has a literal pH close to neutral. Run it through your body and it gets broken down into an incredible array of amino acids, ending up as nitrogenous acid waste products. The more rapid the metabolism, the more acids are produced...the ashes of life are acids. The literal pH of the life media, such as blood, lymph and cytoplasm...and most food, is alkaline. This acid/alkaline is a concept only applicable “in vivo”; pH defines acid/alkaline “in vitro”.... ph

Phragmites Communis

Trin.

Family: Gramineae; Poaceae.

Habitat: The Himalayas, from Kashmir to Kumaon up to an altitude of 4,000 m.

English: Common Reed.

Folk: Dila, Dambu (Punjab).

Action: Rhizomes and roots—diuretic, emmenagogue, diaphoretic, hypoglycaemic, antiemetic.

The rhizomes are rich in carbohydrates; contain nitrogenous substances 5.2, fat 0.9, N-free extr. 50.8, crude fibre 32.0, sucrose 5.1, reducing sugars 1.1, and ash (rich in silica) 5.8%; as- paragine 0.1% is also present. Leaves possess a high ascorbic acid content (200 mg/100 g).Nodes and sheaths yield 6.6% and the underground parts over 13% of furfural.

The root of common Reed is prescribed in Chinese traditional medicine as an antipyretic against influenza and fevers. Presence of polyols, betaines and free poline has been reported in the methanolic extract. The extract is reported to show bactericidal activity. The root gave a polysaccha- ride which contains sugars, arabinose, xylose and glucose in a molar ratio of 10:19:94; some ofthe fractions showed immunological activity.... phragmites communis

Protein

The term applies to members of a group of non-crystallisable nitrogenous substances widely distributed in the animal and vegetable kingdoms, and forming the characteristic materials of their tissues and ?uids. They are essentially combinations of AMINO ACIDS. They mostly dissolve in water and are coagulated by heat and various chemical substances. Typical examples of protein substances are white of egg and gelatin.

Proteins constitute an essential part of the diet as a source of energy, and for the replacement of protein lost in the wear and tear of daily life. Their essential constituent from this point of view is the nitrogen which they contain. To be absorbed, or digested, proteins have to be broken down into their constituent amino acids. The adult human body can maintain nitrogenous equilibrium on a mixture of eight amino acids, which are therefore known as the essential (or indispensable) amino acids. They are isoleucine, leucine, lysine, methionine, phenylalanine, threonine, tryptophan and valine. In addition, infants require histidine.... protein

Spinacia Oleracea

Linn.

Synonym: S. tetrandra Roxb.

Family: Chenopodiaceae.

Habitat: Native to South-west Asia; cultivated throughout India.

English: Garden Spinach.

Ayurvedic: Paalankikaa, Paalankya, Paalakyaa.

Unani: Paalak.

Siddha/Tamil: Vasaiyila-keerai.

Action: Seeds—cooling and laxative; given during jaundice. Spinach, as a potherb, is rich in nitrogenous substances, hydrocarbons and iron sesqui-oxide.

Aerial parts afforded rutin, hyperoside, astragalin and caffeic, chloro- genic, neochlorogenic and protocate- chuic acids. Seeds contain glycopro- tein-bound hexosamine. Roots contain spirasaponins.... spinacia oleracea

Kidney

n. either of the pair of organs responsible for the excretion of nitrogenous wastes, principally urea, from the blood (see illustrations). The kidneys are situated at the back of the abdomen, below the diaphragm, one on each side of the spine; they are supplied with blood by the renal arteries. Each kidney is enclosed in a fibrous capsule and is composed of an outer cortex and an inner medulla. The active units of the kidney are the *nephrons, within the cortex and medulla, which filter the blood under pressure and then reabsorb water and selected substances back into the blood. The *urine thus formed is conducted from the nephrons via the renal tubules into the renal pelvis and from here to the ureter, which leads to the bladder. See also haemodialysis; horseshoe kidney; renal function tests.... kidney



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