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| ==What is Vitamin B<sub>6</sub> (Pyridoxine)?== | | ==What is Vitamin B<sub>6</sub> (Pyridoxine)?== |
− | Vitamin B<sub>6</sub>, also commonly called '''pyridoxine''', is an '''essential water-soluble vitamin''' used as a [[Nutrition Glossary#Cofactor|cofactor]] in a number of enzymatic reactions. Vitamin B<sub>6</sub> in the diet is found as pyridoxine, pyridoxal, and pyridoxamine all of which are hydrolysed by a phosphatase before absorption across the intestinal mucosa by passive diffusion. Once within the enterocyte the hydrolysed vitamin B<sub>6</sub> derivative is phosphorylated by pyridoxine kinase and transported to the liver for continued metabolism to its '''active form, pyridoxal-5-phosphate (PLP)'''. In the liver PLP is bound to albumin and then transported to target tissues. Large concentrations of pyridoxine are found in muscle, but this depot is not available during periods of Vitamin B<sub>6</sub> deficiency and is only released during muscle catabolism. Vitamin B<sub>6</sub> derivatives are freely filtered by the renal tubules. | + | Vitamin B<sub>6</sub>, also commonly called '''pyridoxine''', is an '''essential water-soluble vitamin''' used as a [[Nutrition Glossary#Cofactor|cofactor]] in a number of enzymatic reactions. Vitamin B<sub>6</sub> in the diet is found as pyridoxine, pyridoxal, and pyridoxamine all of which are hydrolysed by a phosphatase before absorption across the intestinal mucosa by [[Diffusion - Physiology|passive diffusion]]. Once within the enterocyte the hydrolysed vitamin B<sub>6</sub> derivative is phosphorylated by pyridoxine kinase and transported to the [[Liver - Anatomy & Physiology|liver]] for continued metabolism to its '''active form, pyridoxal-5-phosphate (PLP)'''. In the liver PLP is bound to [[albumin]] and then transported to target tissues. Large concentrations of pyridoxine are found in [[Muscle Development - Anatomy & Physiology|muscle]], but this depot is not available during periods of Vitamin B<sub>6</sub> deficiency and is only released during muscle catabolism. Vitamin B<sub>6</sub> derivatives are freely filtered by the [[Nephron Microscopic Anatomy#Proximal Tubule|renal tubules]]. |
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| ==Why is it Important?== | | ==Why is it Important?== |
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| ==Roles in the Body== | | ==Roles in the Body== |
− | Vitamin B<sub>6</sub> as PLP is an essential cofactor for glycogen phosphorylase during gluconeogenesis. It is also a cofactor in serine palmitoyl transferase used sphingolipid synthesis, a cofactor in γ-aminolevulinic acid synthentase, the first and rate-limiting step in heme synthesis. PLP is also required for synthesis of taurine, dopamine, histamine, and norepinephrine, and is involved in multiple steps in the conversion of [[Tryptophan - Nutrition|tryptophan]] to niacin<ref>Shane B. Folic Acid, Vitamin B12, and Vitamin B6. In Biochemical and physiological aspects of human nutrition. 2000 Philadelphia, PA: WB Saunders Company p. 511-518.</ref>. | + | Vitamin B<sub>6</sub> as PLP is an essential cofactor for glycogen phosphorylase during gluconeogenesis. It is also a cofactor in serine palmitoyl transferase used sphingolipid synthesis, a cofactor in γ-aminolevulinic acid synthentase, the first and rate-limiting step in heme synthesis. PLP is also required for synthesis of [[Taurine - Nutrition|taurine]], dopamine, histamine, and norepinephrine, and is involved in multiple steps in the conversion of [[Tryptophan - Nutrition|tryptophan]] to [[Vitamin B3 (Niacin) - Nutrition|niacin]]<ref>Shane B. Folic Acid, Vitamin B12, and Vitamin B6. In Biochemical and physiological aspects of human nutrition. 2000 Philadelphia, PA: WB Saunders Company p. 511-518.</ref>. |
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| ==Consequences of Vitamin B<sub>6</sub> Deficiency== | | ==Consequences of Vitamin B<sub>6</sub> Deficiency== |
| ====Dogs:==== | | ====Dogs:==== |
− | Induced vitamin B<sub>6</sub> deficiency has been reported to cause anorexia, weight loss, and microcytic hypochromic anaemia in puppies, and if left untreated could result in death. Ataxia, hematochezia, seizures, muscle fasciculations, cardiac dilation and hypertrophy of both the left and right auricles and ventricles (with more pronounced changes to the right), and demyelination of peripheral nerves have also been described in adult dogs fed Vitamin B<sub>6</sub> deficient diets<ref>National Research Council (NRC). Vitamins. In Nutrient Requirements for Dogs and Cats. 2006 Washington, DC: National Academies Press p.218-220.</ref><ref>Street HR, et al. Observations on vitamin B6 deficiency in the dog. J Nutr 1941;21:275-290</ref>. | + | Induced vitamin B<sub>6</sub> deficiency has been reported to cause anorexia, weight loss, and microcytic hypo chromic [[Regenerative and Non-Regenerative Anaemias|anaemia]] in puppies, and if left untreated could result in death. Ataxia, hematochezia, seizures, muscle fasciculations, cardiac dilation and hypertrophy of both the left and right auricles and ventricles (with more pronounced changes to the right), and demyelination of peripheral nerves have also been described in adult dogs fed Vitamin B<sub>6</sub> deficient diets<ref>National Research Council (NRC). Vitamins. In Nutrient Requirements for Dogs and Cats. 2006 Washington, DC: National Academies Press p.218-220.</ref><ref>Street HR, et al. Observations on vitamin B6 deficiency in the dog. J Nutr 1941;21:275-290</ref>. |
| ====Cats:==== | | ====Cats:==== |
− | Induced vitamin B<sub>6</sub> deficiency in kittens was reported to result in poor growth rate, microcytic hypochromic anaemia, and calcium oxalate crystalluria<ref>Bai SC, et al. Vitamin B6 deficiency in kittens. J Nutr 1989;119: 1020-1027.</ref>. Increased dietary intake of protein has also been show to increase Vitamin B<sub>6</sub> requirement in cats<ref>Bai SC, et al. The level of dietary protein affects the vitamin B-6 requirement of cats. J Nutr 1991 121;1054-1061.</ref>. | + | Induced vitamin B<sub>6</sub> deficiency in kittens was reported to result in poor growth rate, microcytic hypochromic anaemia, and [[Urolithiasis#Calcium oxalate|calcium oxalate]] crystalluria<ref>Bai SC, et al. Vitamin B6 deficiency in kittens. J Nutr 1989;119: 1020-1027.</ref>. Increased dietary intake of [[Protein Overview - Nutrition|protein]] has also been show to increase Vitamin B<sub>6</sub> requirement in cats<ref>Bai SC, et al. The level of dietary protein affects the vitamin B-6 requirement of cats. J Nutr 1991 121;1054-1061.</ref>. |
− | Vitamin B<sub>6</sub> is '''light sensitive and prone to degradation with heat processing'''. Conditions associated with diuresis (e.g., chronic disease, such as renal disease or diabetes, or therapeutic intervention, such as intravenous fluids or increased water intake with management of lower urinary diseases) can result in increased loss of Vitamin B<sub>6</sub> and may increase daily requirements. Patients on chronic haemodialysis are at an increased risk for development of deficiency. | + | Vitamin B<sub>6</sub> is '''light sensitive and prone to degradation with heat processing'''. Conditions associated with diuresis (e.g., chronic disease, such as renal disease or [[Diabetes Insipidus|diabetes]], or therapeutic intervention, such as intravenous fluids or increased water intake with management of [[Cystitis|lower urinary diseases]]) can result in increased loss of Vitamin B<sub>6</sub> and may increase daily requirements. Patients on chronic haemodialysis are at an increased risk for development of deficiency. |
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| ==Toxicity== | | ==Toxicity== |
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| [[Category:Vitamins]] | | [[Category:Vitamins]] |
| [[Category:To Do - Nutrition]] | | [[Category:To Do - Nutrition]] |
− | [[Category:To Do - Nutrition GGP]] | + | [[Category:To Do - Nutrition preMars]] |