Factors intrinsic

The amount of each element required in daily dietary intake varies with the individual bioavailabihty of the mineral nutrient. BioavailabiUty depends both on body need as deterrnined by absorption and excretion patterns of the element and by general solubiUty, and on the absence of substances that may cause formation of iasoluble products, eg, calcium phosphate, Ca2(P0 2- some cases, additional requirements exist either for transport of substances or for uptake or binding. For example, calcium-binding proteias are iavolved ia calcium transport an intrinsic factor is needed for vitamin cobalt,... 

Intrinsic Factor. Vitamin B 2 deficiency commonly is caused by inadequate absorption resulting from a lack or insufficient intrinsic factor (IF) (153). 

Intrinsic factor is a glycoprotein, mol wt ca 50,000, which binds vitamin B22 in a 1 1 molar ratio. The B22 IF complex, formed in the stomach, is absorbed... 

In 1929, Castie (7) tied the work of Combe and Addison with that of Whipple, Miaot, and Murphy by ptoposiag that both an extrinsic factor and an intrinsic factor ate iavolved ia the coatrol of pernicious anemia. The extrinsic factor, from food, is vitamin 2- Th intrinsic factor is a specific B22-biading protein secreted by the stomach. This protein is requited for vitamin B 2 absorption. 

Clinical manifestation of vitamin B 2 deficiency is usually a result of absence of the gastric absorptive (intrinsic) factor. Dietary deficiency of vitamin B 2 is uncommon and may take 20 to 30 years to develop, even in healthy adults who foUow a strict vegetarian regimen. An effective enterohepatic recycling of the vitamin plus small amounts from bacterial sources and other contaminants greatly minimizes the risk of a complete dietary deficiency. Individuals who have a defect in vitamin B 2 absorption, however, may develop a deficiency within three to seven years. 

Food vitamin B 2 appears to bind to a saUvary transport protein referred to as the R-protein, R-binder, or haptocorrin. In the stomach, R-protein and the intrinsic factor competitively bind the vitamin. Release from the R-protein occurs in the small intestine by the action of pancreatic proteases, leading to specific binding to the intrinsic factor. The resultant complex is transported to the ileum where it is bound to a cell surface receptor and enters the intestinal cell. The vitamin is then freed from the intrinsic factor and bound to transcobalamin II in the enterocyte. The resulting complex enters the portal circulation. 

Approximately 0.05 to 0.2% of vitamin > 2 stores are turned over daily, amounting to 0.5—8.0 )J.g, depending on the body pool size. The half-life of the body pool is estimated to be between 480 and 1360 days with a daily loss of vitamin > 2 of about 1 )J.g. Consequentiy, the daily minimum requirement for vitamin B22 is 1 fig. Three micrograms (3.0 J.g) vitamin B22 are excreted in the bile each day, but an efficient enterohepatic circulation salvages the vitamin from the bile and other intestinal secretions. This effective recycling of the vitamin contributes to the long half-life. Absence of the intrinsic factor intermpts the enterohepatic circulation. Vitamin > 2 is not catabolized by the body and is, therefore, excreted unchanged. About one-half of the vitamin is excreted in the urine and the other half in the bile. 

Radioisotope dilution assays are based on the principle of competition between radioactive labeled ( Co) vitamin B 2 and cobalamins extracted from matrices for binding sites on the intrinsic factor (a glycoprotein). Binding is in proportion to the concentration of the radioactive and nonradio active B 2 with the concentration of intrinsic factor as the limiting factor. Free cobalamins are separated from those bound on the intrinsic factor by absorption... 

Also, the outcome covers a large spectrum. Autoantibodies can specifically block an important protein (such as the gastric intrinsic factor required for the uptake of orally taken vitamin B12), or the receptor for —> acetylcholine (as in myasthenia gravis), but also can... 

The treatment of an autoimmune disease very much depends on the nature of the clinical outcome it causes. Although the formation of autoantibodies causes the inactivation of the gastric intrinsic factor, the subsequent shortage of vitamin B12 can be easily overcome by supplying it via an parenteral route. Lifelong immunosuppression (with all its side effects) thus is inappropriate. When, however, as in sympathetic ophtalmia, after damage of the first eye the second eye is endangered, an even drastic immunosuppression is mandatory. 

Vitamin B12 is special in as far as its absorption depends on the availability of several secretory proteins, the most important being the so-called intrinsic factor (IF). IF is produced by the parietal cells of the fundic mucosa in man and is secreted simultaneously with HC1. In the small intestine, vitamin B12 (extrinsic factor) binds to the alkali-stable gastric glycoprotein IF. The molecules form a complex that resists intestinal proteolysis. In the ileum, the IF-vitamin B 12-complex attaches to specific mucosal receptors of the microvilli as soon as the chymus reaches a neutral pH. Then either cobalamin alone or the complex as a whole enters the mucosal cell. 

Hemostasis is the process that stops bleeding in a blood vessel. Normal hemostasis involves a complex process of extrinsic and intrinsic factors. Figure 44-1 shows the coagulation pathway and factors involved. The copulation cascade is so named because as each factor is activated it acts as a catalyst that enhances the next reaction, with the net result being a large collection of fibrin that forms a plug in the vessel. Fibrin is the insoluble protein that is essential to clot formation. 

Vitamin B12 is essential to growth, cell reproduction, the manufacture of myelin (which surrounds some nerve fibers), and blood cell manufacture. The intrinsic factor, which is produced by cells in the stomach, is necessary for the absorption of vitamin B12 in the intestine A deficiency of the intrinsic factor results in abnormal formation of erythrocytes because of the body s failure to absorb vitamin B12, a necessary component for blood cell formation. The resulting anemia is a type of megaloblastic anemia called pernicious anemia. 

Persons who have had a total gastrectomy or subtotal gastric resection (when the cells producing the intrinsic factor are totally or partially removed)... 

Persons who have a congenital decrease in the number of gastric cells secreting intrinsic factor... 

VITAMIN S12. Fhtients with pernicious anemia are treated with vitamin B12 by tiie parenteral route (IM) weekly stabilized. The parenteral route is used because tiie vitamin is ineffective orally due to the absence of tiie intrinsic factor in tiie stomach, which is necessary for utilization of vitamin B12. After stabilization, maintenance (usually monthly) injections are necessary for life... 

A person with pernicious anemia lacks intrinsic factor, a compound required for the absorption of vitamin B12 and its storage in the liver. The diagnosis is confirmed... 

Intrinsic Factor PK Study Reports (sex, age, race, weight, etc.)... 

Vitamin Bj2 is absorbed bound to intrinsic factor, a small glycoprotein secreted by the parietal cells of the... 

Pernicious anemia arises when vitamin B,2 deficiency blocks the metabohsm of folic acid, leading to functional folate deficiency. This impairs erythropoiesis, causing immature precursors of erythrocytes to be released into the circulation (megaloblastic anemia). The commonest cause of pernicious anemia is failure of the absorption of vitamin B,2 rather than dietary deficiency. This can be due to failure of intrinsic factor secretion caused by autoimmune disease of parietal cells or to generation of anti-intrinsic factor antibodies. 

Megaloblastic anemias Deficiency of vitamin 6,2 Decreased absorption of 6,2, often due to a deficiency of intrinsic factor, normally secreted by gastric parietal cells... 

Shaw, S., Herbert, V., Colman, N. and Jayatilleke, E. (1990). Effect of ethanol-generated free radicals on gastric intrinsic factor and glutathione. Alcohol 7, 153-157. 

Further investigation by administering radiolabeled B12 (i.e., Schilling test) to determine if lack of intrinsic factor. 

Vitamin B12 (cyanocobalmin) administered both orally and parenterally is equally effective in treating anemia from vitamin B12 deficiency. However, use of parenteral cyanacobalamin is the most common method of vitamin B12 replacement because it may be more reliable and practical. Subcutaneous or intramuscular administration is appropriate. Vitamin B12 is absorbed completely following parenteral administration, whereas oral vitamin B12 is absorbed poorly via the GI tract. Furthermore, use of parenteral vitamin B12 to treat megaloblastic anemia may circumvent the need to perform a Schilling test to diagnose lack of intrinsic factor. 

Enterocytes Maternal IgG, dimeric IgA, transcobalamine-Bi2/ intrinsic factor... 

Mammalian intestinal absorption requires the presence of two receptors and two transporters, which is itself a unique feature. Specific transporters such as intrinsic factor, transcobalamin, and haptocorrin have been characterized,1113 as well as a number of receptors for passage across cell membranes. A number of biochemical studies on cell uptake1114 and receptors1115,1116 of cobala-mins have been reported. Genetic disorders that impair the synthesis, transport, or transmembrane passage of cobalamins and their consequences have been reviewed.1117,1118... 

These observations indicate that it is essential to preserve sectors of different latitudes and altitudes in the Pedemontana Jungle, since there are intrinsic factors that are defining differential features in the biomass and carbon stock, as well as, in every ecosystem functions associated with these particular conditions [40], Other authors have already pointed out that the recommendation in all cases is to maintain connectivity of Yungas in distribution, safeguarding different sectors of the Pedemontana Jungle, varying in latitude and altitude [27]. 

Intrinsic factor is produced by the parietal cells. Within the stomach, it combines with vitamin Bu to form a complex necessary for absorption of this vitamin in the ileum of the small intestine. Vitamin B12 is an essential factor in the formation of red blood cells. Individuals unable to produce intrinsic factor cannot absorb vitamin B12 and red blood cell production is impaired. This condition, referred to as Pernicious anemia, occurs as a result of an autoimmune disorder involving destruction of parietal cells. 

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