Hostname: page-component-cd9895bd7-7cvxr Total loading time: 0 Render date: 2024-12-25T08:34:54.544Z Has data issue: false hasContentIssue false

Inositol - An effective growth promotor?

Published online by Cambridge University Press:  12 October 2016

S.A. LEE*
Affiliation:
AB Vista, Marlborough, Wiltshire, SN8 4AN, United Kingdom
M.R. BEDFORD
Affiliation:
AB Vista, Marlborough, Wiltshire, SN8 4AN, United Kingdom
*
Corresponding author: [email protected]
Get access

Abstract

Inositol is a naturally occurring sugar-alcohol present in plants and animals, either in its free form, as a phospholipid component or as inositol phosphate (IP) esters. Dietary inositol is readily absorbed from the intestine via SMIT1 with levels being detectable in the blood as well as in various tissues. Recent studies have revealed a potential link between free inositol content and improved growth response in animals. There is limited data suggesting why an increase in inositol would result in improved growth; however, it would appear that inositol has numerous biological functions within the body. A number of tissues are capable of synthesising this polyol from glucose, although the kidney appears to be the primary site of catabolism. Studies investigating the effect of inositol deficiencies in various animal species have revealed a number of biological processes that are reliant on inositol to function. One of inositol's main functions appears to be its involvement as a phospholipid component of cell membranes and lipoproteins. Cell signalling pathways involving phosphoinositide phospholipids, such as the IP3/DAG and IGF/PIK/Akt pathways, lead to a number of cellular responses that are important for cell survival and growth. On a larger scale, inositol appears to be essential for both prenatal and postnatal development of peripheral nerves, CNS and bone. With regards to a potential growth response, upregulation of specific signalling pathways, such as the IGF/Akt/mTOR pathway, in the skeletal muscle has been shown in response to phytase supplementation and the consequential increase in free inositol. These signalling pathways are responsible for protein synthesis and increased glucose absorption in this tissue. Since inositol has also been shown to be an important regulator of the transport and deposition of fat, it may be possible to use inositol to support the growth of a lean animal.

Type
Reviews
Copyright
Copyright © World's Poultry Science Association 2016 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

ASHIZAWA, N., YOSHIDA, M. and AOTSUKA, T. (2000) An enzymatic assay for myo-inositol in tissue samples. Journal of Biochemical and Biophysical Methods 44: 89-94.Google Scholar
BATTAGLIA, F.C., MESCHIA, G., BLECHNER, J.N. and BARRON, D.H. (1961) The free myo-inositol concentration of adult and Fetal tissues of several species. Quarterly Journal of Experimental Physiology and Cognate Medical Sciences 46: 188-193.CrossRefGoogle ScholarPubMed
BEDFORD, M.R. (2000) Exogenous enzymes in monogastric nutrition - their current value and future benefits. Animal Feed Science and Technology 86: 1-13.CrossRefGoogle Scholar
BEDFORD, M.R. and SCHULZE, H. (1998) Exogenous enzymes for pigs and poultry. Nutrition Research Reviews 11: 91-114.Google Scholar
BERDANIER, C.D. (1997) Other Organic Nutrients III. Inositol, in: BERDANIER, C.D. (Ed) Advanced Nutrition Micronutrients, pp. 136-139 (Boca Raton, CRC Press).Google Scholar
BERRIDGE, M.J. and IRVINE, R.F. (1984) Inositol trisphosphate, a novel second messenger in cellular signal transduction. Nature 312: 315-321.Google Scholar
BERRY, G.T., MALLEE, J.J., KWON, H.M., RIM, J.S., MULLA, W.R., MUENKE, M. and SPINNER, N.B. (1995) The human osmoregulatory Na+/myo-inositol cotransporter gene (SLC5A3): molecular cloning and localization to chromosome 21. Genomics 25: 507-513.Google Scholar
BURTON, L.E., RAY, R.E., BRADFORD, J.R., ORR, J.P., NICKERSON, J.A. and WELLS, W.W. (1976) Myo-Inositol metabolism in the neonatal and developing rat fed a myo-inositol-free diet. Journal of Nutrition 106: 1610-1616.CrossRefGoogle ScholarPubMed
BURTON, L.E. and WELLS, W.W. (1974) Studies on the developmental pattern of the enzymes converting glucose 6-phosphate to myo-inositol in the rat. Developmental Biology 37: 35-42.Google Scholar
CASPARY, W.F. and CRANE, R.K. (1970) Active transport of myo-inositol and its relation to the sugar transport system in hamster small intestine. Biochimica et Biophysica Acta (BBA) - Biomembranes 203: 308-316.Google Scholar
CELMER, W.D. and CARTER, H.E. (1952) Chemistry of Phosphatides and Cerebrosides. Physiological Reviews 32: 167-196.Google Scholar
CHARALAMPOUS, F.C. and LYRAS, C. (1957) Biochemical studies on inositol: iv. Conversion of inositol to glucuronic acid by rat kidney extracts. Journal of Biological Chemistry 228: 1-13.Google Scholar
CHAU, J.F.L., LEE, M.K., LAW, J.W.S., CHUNG, S.K. and CHUNG, S.S.M. (2005) Sodium/myo-inositol cotransporter-1 is essential for the development and function of the peripheral nerves. The FASEB Journal 19: 1887-1889.Google Scholar
CHU, S.H. and GEYER, R.P. (1981) myo-Inositol action on gerbil intestine: Reversal of a diet-induced lipodystrophy and change in microsomal lipase activity. Biochimica et Biophysica Acta (BBA) - Lipids and Lipid Metabolism 664: 89-97.Google Scholar
CHU, S.H. and GEYER, R.P. (1983) Tissue Content and Metabolism of myo-Inositol in Normal and Lipodystrophic Gerbils. The Journal of Nutrition 113: 293-303.Google Scholar
CHU, S.H. and HEGSTED, D.M. (1980) Myo-Inositol Deficiency in Gerbils: Comparative Study of the Intestinal Lipodystrophy in Meriones unguiculatus and Meriones libycus. The Journal of Nutrition 110: 1209-1216.Google Scholar
CLEMENTS, R.S. and DIETHELM, A.G. (1979) The metabolism of myo-inositol by the human kidney. Journal of Laboratory and Clinical Medicine 93: 210-219.Google Scholar
COADY, M.J., WALLENDORFF, B., GAGNON, D.G. and LAPOINTE, J.Y. (2002) Identification of a Novel Na+/myo-Inositol Cotransporter. Journal of Biological Chemistry 277: 35219-35224.Google Scholar
CORRADO, F., D'ANNA, R., DI VIESTE, G., GIORDANO, D., PINTAUDI, B., SANTAMARIA, A. and DI BENEDETTO, A. (2011) The effect of myoinositol supplementation on insulin resistance in patients with gestational diabetes. Diabetic Medicine 28: 972-975.CrossRefGoogle ScholarPubMed
COWIESON, A.J., AURELI, R., GUGGENBUHL, P. and FRU-NJI, F. (2015) Possible involvement of myo-inositol in the physiological response of broilers to high doses of microbial phytase. Animal Production Science 55: 710-719.Google Scholar
COWIESON, A.J., PTAK, A., MACKOWIAK, P., SASSEK, M., PRUSZYNSKA-OSZMALEK, E., ZYLA, K., SWIATKIEWICZ, S., KACZMAREK, S. and JÓZEFIAK, D. (2013) The effect of microbial phytase and myo-inositol on performance and blood biochemistry of broiler chickens fed wheat/corn-based diets. Poultry Science 92: 2124-2134.Google Scholar
COWIESON, A.J., WILCOCK, P. and BEDFORD, M.R. (2011) Super-dosing effects of phytase in poultry and other monogastrics. World's Poultry Science Journal 67: 225-236.Google Scholar
CROZE, M.L., GELOEN, A. and SOULAGE, C.O. (2015) Abnormalities in myo-inositol metabolism associated with type 2 diabetes in mice fed a high-fat diet: benefits of a dietary myo-inositol supplementation. British Journal of Nutrition 113: 1862-1875.Google Scholar
CROZE, M.L. and SOULAGE, C.O. (2013) Potential role and therapeutic interests of myo-inositol in metabolic diseases. Biochimie 95: 1811-1827.CrossRefGoogle ScholarPubMed
CROZE, M.L., VELLA, R.E., PILLON, N.J., SOULA, H.D.A., HADJI, L., GUICHARDANT, M. and SOULAGE, C.O. (2013) Chronic treatment with myo-inositol reduces white adipose tissue accretion and improves insulin sensitivity in female mice. The Journal of Nutritional Biochemistry 24: 457-466.Google Scholar
DAI, Z., CHUNG, S.K., MIAO, D., LAU, K.S., CHAN, A.W. and KUNG, A.W. (2011) Sodium/myo-inositol cotransporter 1 and myo-inositol are essential for osteogenesis and bone formation. Journal of Bone and Mineral Research 26: 582-590.Google Scholar
DANG, N.T., MUKAI, R., YOSHIDA, K. and ASHIDA, H. (2010) D-Pinitol and myo-Inositol Stimulate Translocation of Glucose Transporter 4 in Skeletal Muscle of C57BL/6 Mice. Bioscience, Biotechnology, and Biochemistry 74: 1062-1067.Google Scholar
DAWSON, R. and FREINKEL, N. (1961) The distribution of free mesoinositol in mammalian tissues, including some observations on the lactating rat. Biochemical Journal 78: 606-610.Google Scholar
DI DANIEL, E., MOK, M.H., MEAD, E., MUTINELLI, C., ZAMBELLO, E., CABERLOTTO, L.L., PELL, T.J., LANGMEAD, C.J., SHAH, A.J., DUDDY, G., KEW, J.N.C. and MAYCOX, P.R. (2009) Evaluation of expression and function of the H+/myo-inositol transporter HMIT. BMC Cell Biology 10: 1-12.Google Scholar
DI PAOLO, G. and DE CAMILLI, P. (2006) Phosphoinositides in cell regulation and membrane dynamics. Nature 443: 651-657.Google Scholar
DULIÑSKI, R., STARZYNSKA-JANISZEWSKA, A., STODOLAK, B. and ZYLA, K. (2011) Comparison of high-performance ion chromatography technique with microbiological assay of myo-inositol in plant components of poultry feed. Journal of Animal and Feed Sciences 20: 143-156.Google Scholar
EAGLE, H., OYAMA, V., LEVY, M. and FREEMAN, A. (1956) Myo-inositol as an essential growth factor for normal and malignant human cells in tissue culture. Science 123: 845-847.Google Scholar
EISENBERG, F. and BOLDEN, A.H. (1963) Biosynthesis of inositol in rat testis homogenate. Biochemical and Biophysical Research Communications 12: 72-77.Google Scholar
FRIELER, R.A., MITTENESS, D.J., GOLOVKO, M.Y., GIENGER, H.M. and ROSENBERGER, T.A. (2009) Quantitative determination of free glycerol and myo-inositol from plasma and tissue by high-performance liquid chromatography. Journal of Chromatography B 877: 3667-3672.Google Scholar
GRASES, F., SIMONET, B.M., VUCENIK, I., PRIETO, R.M., COSTA-BAUZA, A., MARCH, J.G. and SHAMSUDDIN, A.M. (2001) Absorption and excretion of orally administered inositol hexaphosphate (lP(6) or phytate) in humans. Biolactors 15: 53-61.CrossRefGoogle ScholarPubMed
GUO, S. (2014) Insulin signaling, resistance, and metabolic syndrome: insights from mouse models into disease mechanisms. Journal of Endocrinology 220: T1-T23.CrossRefGoogle ScholarPubMed
GUO, W., SHIMADA, S., TAJIRI, H., YAMAUCHI, A., YAMASHITA, T., OKADA, S. and TOHYAMA, M. (1997) Developmental regulation of Na+/myo-inositol cotransporter gene expression. Molecular Brain Research 51: 91-96.CrossRefGoogle ScholarPubMed
HANKES, L.V., POLITZER, W.M., TOUSTER, O. and ANDERSON, L. (1970) Myo-inositol catabolism in human pentosurics: the predominant role of the glucuronate-xylulose-pentose phosphate pathway. Annals of the New York Academy of Sciences 165: 564-576.Google Scholar
HASAN, S.H., KOTAKI, A. and YAGI, K. (1970) Studies on myoinositol. VI. Effect of myoinositol on plasma lipoprotein metabolism of rats suffering from fatty liver. The Journal of Vitaminology 16: 144-148.CrossRefGoogle ScholarPubMed
HASAN, S.H., NAKAGAWA, Y., NISHIGAKI, I. and YAGI, K. (1971) Studies on myoinositol. 8. The incorporation of 3 H-myoinositol into phosphatidyl-inositol of fatty liver. The Journal of Vitaminology 17: 159-162.Google Scholar
HAUSER, G. and FINELLI, V.N. (1963) The Biosynthesis of Free and Phosphatide Myo-inositol from Glucose by Mammalian Tissue Slices. Journal of Biological Chemistry 238: 3224-3228.Google Scholar
HAWTHORNE, J.N. and PICKARD, M.R. (1979) Phospholipids in synaptic function. Journal of Neurochemistry 32: 5-14.Google Scholar
HAYASHI, E., MAEDA, T. and TOMITA, T. (1974) The effect of myo-inositol deficiency on lipid metabolism in rats. II. The mechanism of triacylglycerol accumulation in the liver of myo-inositol-deficient rats. Biochimica et Biophysica Acta 360: 146-155.Google Scholar
HEGSTED, D.M., HAYES, K.C., GALLAGHER, A. and HANFORD, H. (1973) Inositol deficiency: An intestinal lipodystrophy in the gerbil. Journal of Nutrition 103: 302-307.Google Scholar
HEGSTED, D.M., BRIGGS, G.M., MILLS, R.C., ELVEHJEM, C.A. and HART, E.B. (1941) Inositol in Chick Nutrition. Experimental Biology and Medicine 47: 376-377.Google Scholar
HOKIN, L.E. and HOKIN, M.R. (1955) Effects of acetylcholine on the turnover of phosphoryl units in individual phospholipids of pancreas slices and brain cortex slices. Biochimica et Biophysica Acta 18: 102-110.Google Scholar
HOLUB, B.J. (1986) Metabolism and function of myo-inositol and inositol phospholipids. Annual Review of Nutrition 6: 563-597.Google Scholar
HOOVER, G.A., NICOLOSI, R.J., COREY, J.E., EL LOZY, M. and HAYES, K.C. (1978) Inositol Deficiency in the Gerbil: Altered Hepatic Lipid Metabolism and Triglyceride Secretion. The Journal of Nutrition 108: 1588-1594.Google Scholar
HOWARD, C.F. and ANDERSON, L. (1967) Metabolism of myo-inositol in animals. II. Complete catabolism of myo-inositol-14C by rat kidney slices. Archives of Biochemistry and Biophysics 118: 332-339.Google Scholar
IRVINE, R.F. (2003) Nuclear lipid signalling. Nature Reviews Molecular Cell Biology 4: 349-360.Google Scholar
KINDT, E., SHUM, Y., BADURA, L., SNYDER, P.J., BRANT, A., FOUNTAIN, S. and SZEKELY-KLEPSER, G. (2004) Development and Validation of an LC/MS/MS Procedure for the Quantification of Endogenous myo-Inositol Concentrations in Rat Brain Tissue Homogenates. Analytical Chemistry 76: 4901-4908.Google Scholar
KOHLMEIER, M. (2003) Inositol, in: KOHLMEIER, M. (Ed) Nutrient Metabolism (Food Science and Technology), pp. 634-642 (London, Academic Press).Google Scholar
LARNER, J. (2002) D-chiro-inositol--its functional role in insulin action and its deficit in insulin resistance. International Journal of Experimental Diabetes Research 3: 47-60.Google Scholar
LEE, J. and CHUNG, B.C. (2006) Simultaneous measurement of urinary polyols using gas chromatography/mass spectrometry. Journal of Chromatography B 831: 126-131.Google Scholar
LERNER, J. and SMAGULA, R.M. (1979) Myo-inositol transport in the small intestine of the domestic fowl. Comparative Biochemistry and Physiology Part A: Physiology 62: 939-945.Google Scholar
LETO, D. and SALTIEL, A.R. (2012) Regulation of glucose transport by insulin: traffic control of GLUT4. Nature Reviews Molecular Cell Biology 13: 383-396.Google Scholar
LEUNG, K., MILLS, K., BURREN, K.A., COPP, A.J. and GREENE, N.D.E. (2011) Quantitative analysis of myo-inositol in urine, blood and nutritional supplements by high-performance liquid chromatography tandem mass spectrometry. Journal of Chromatography B 879: 2759-2763.Google Scholar
LEWIN, L.M., YANNAI, Y., SULIMOVICI, S. and KRAICER, P.F. (1976) Studies on the metabolic role of myo-inositol. Distribution of radioactive myo-inositol in the male rat. Biochemical Journal 156: 375-380.Google Scholar
LIU, N., RU, Y., WANG, J. and XU, T. (2010) Effect of dietary sodium phytate and microbial phytase on the lipase activity and lipid metabolism of broiler chickens. British Journal of Nutrition 103: 862-868.Google Scholar
MACGREGOR, L.C. and MATSCHINSKY, F.M. (1984) An enzymatic fluorimetric assay for myo-inositol. Analytical Biochemistry 141: 382-389.Google Scholar
MAENZ, D.D. and CLASSEN, H.L. (1998) Phytase activity in the small intestinal brush border membrane of the chicken. Poultry Science 77: 557-563.Google Scholar
MARTELLI, A.M., BORTUL, R., TABELLINI, G., ALUIGI, M., PERUZZI, D., BAREGGI, R., NARDUCCI, P. and COCCO, L. (2001) Re-examination of the mechanisms regulating nuclear inositol lipid metabolism. FEBS Letters 505: 1-6.Google Scholar
MARTELLI, A.M., CAPITANI, S. and NERI, L.M. (1999) The generation of lipid signaling molecules in the nucleus. Progress in Lipid Research 38: 273-308.CrossRefGoogle ScholarPubMed
MCDOWELL, L.R. (2000) Vitamin-like substances, in: MCDOWELL, L.R. (Ed) Vitamins in Animal and Human Nutrition, pp. 660-666 (Ames, Iowa State University Press).Google Scholar
MICHELL, R.H. (1975) Inositol phospholipids and cell surface receptor function. Biochimica et Biophysica Acta (BBA) - Reviews on Biomembranes 415: 81-147.Google Scholar
MOSCATELLI, E.A. and LARNER, J. (1959) The metabolism in the rat of photosynthetically prepared myo-inositol-C14. Archives of Biochemistry and Biophysics 80: 26-34.CrossRefGoogle Scholar
NESTLER, J.E., JAKUBOWICZ, D.J., REAMER, P., GUNN, R.D. and ALLAN, G. (1999) Ovulatory and Metabolic Effects of d-Chiro-Inositol in the Polycystic Ovary Syndrome. New England Journal of Medicine 340: 1314-1320.Google Scholar
NIWA, T., YAMAMOTO, N., MAEDA, K., YAMADA, K., OHKI, T. and MORI, M. (1983) Gas chromatographic-mass spectrometric analysis of polyols in urine and serum of uremic patients. Journal of Chromatography B: Biomedical Sciences and Applications 277: 25-39.CrossRefGoogle ScholarPubMed
ORTMEYER, H.K. (1996) Dietary Myoinositol Results in Lower Urine Glucose and in Lower Postprandial Plasma Glucose in Obese Insulin Resistant Rhesus Monkeys. Obesity Research 4: 569-575.Google Scholar
ORTMEYER, H.K., HUANG, L.C., ZHANG, L., HANSEN, B.C. and LARNER, J. (1993) Chiroinositol deficiency and insulin resistance. II. Acute effects of D-chiroinositol administration in streptozotocin-diabetic rats, normal rats given a glucose load, and spontaneously insulin-resistant rhesus monkeys. Endocrinology 132: 646-651.Google Scholar
ORTMEYER, H.K., LARNER, J. and HANSEN, B.C. (1995) Effects of D-Chiroinositol Added to a Meal on Plasma Glucose and Insulin in Hyperinsulinemic Rhesus Monkeys. Obesity Research 3: 605S-608S.Google Scholar
OSHIMA, M., TAYLOR, T.G. and WILLIAMS, A. (1964) Variations in the concentration of phytic acid in the blood of the domestic fowl. Biochemical Journal 92: 42-46.Google Scholar
PAK, Y., HONG, Y., KIM, S., PICCARIELLO, T., FARESE, R.V. and LARNER, J. (1998) In vivo Chiro-Inositol Metabolism in the Rat: A Defect in Chiro-Inositol Synthesis from Myo-Inositol and an Increased Incorporation of Chiro-[3H]Inositol into Phospholipid in the Goto-Kakizaki (G.K.) Rat. Molecules and Cells 8: 301-309.Google Scholar
PEREIRA, G.R., BAKER, L., EGLER, J., CORCORAN, L. and CHIAVACCI, R. (1990) Serum myoinositol concentrations in premature infants fed human milk, formula for infants, and parenteral nutrition. The American Journal of Clinical Nutrition 51: 589-593.Google Scholar
PIRGOZLIEV, V., ALLYMEHR, M., SARWAR, S., ACAMOVIC, T. and BEDFORD, M.R. (2007) The effect of dietary inositol on performance and mucin excretion when fed to chickens. British Poultry Abstracts 3: 4-5.Google Scholar
RAPOPORT, S. and GUEST, G.M. (1941) Distribution of acid-soluble phosphorus in the blood cells of various vertebrates. Journal of Biological Chemistry 138: 269-282.Google Scholar
RAPOPORT, S. (1940) Phytic acid in avian erythrocytes. Journal of Biological Chemistry 135: 403-406.Google Scholar
RHODES, D. and LEA, C. (1957) Phospholipids. 4. On the composition of hen's egg phospholipids. Biochemical Journal 65: 526-533.Google Scholar
ROSEN, G.D. (2002) Multifactorial analysis of the effects of microbial phytase in broiler nutrition. Proceedings of the 49th Maryland Nutrition Conference for Feed Manufacturers, Maryland, pp. 88-101.Google Scholar
SATO, Y., WATANABE, K. and TAKAHASHI, T. (1973) Lipids in Egg White. Poultry Science 52: 1564-1570.Google Scholar
SCHLEMMER, U., JANY, K.D., BERK, A., SCHULZ, E. and RECHKEMMER, G. (2001) Degradation of phytate in the gut of pigs--pathway of gastro-intestinal inositol phosphate hydrolysis and enzymes involved. Archives of Animal Nutrition 55: 255-280.Google Scholar
SCHMEISSER, J., SÉON, A.A., AURELI, R., FRIEDEL, A., GUGGENBUHL, P., DUVAL, S., COWIESON, A.J. and FRU-NJI, F. (2016) Exploratory transcriptomic analysis in muscle tissue of broilers fed a phytase-supplemented diet. Journal of Animal Physiology and Animal Nutrition10.1111/jpn.12482. In Press.Google Scholar
SEKI, Y., SATO, K., KONO, T., ABE, H. and AKIBA, Y. (2003) Broiler chickens (Ross strain) lack insulin-responsive glucose transporter GLUT4 and have GLUT8 cDNA. General and Comparative Endocrinology 133: 80-87.Google Scholar
SPECTOR, R. (1988) Myo-inositol transport through the blood-brain barrier. Neurochemical Research 13: 785-787.Google Scholar
TOKER, A. (2002) Phosphoinositides and signal transduction. Cellular and Molecular Life Sciences 59: 761-779.CrossRefGoogle ScholarPubMed
TOKUSHIMA, Y., TAKAHASHI, K., SATO, K. and AKIBA, Y. (2005) Glucose uptake in vivo in skeletal muscles of insulin-injected chicks. Comparative Biochemistry and Physiology Part B: Biochemistry and Molecular Biology 141: 43-48.Google Scholar
ULDRY, M., IBBERSON, M., HORISBERGER, J.D., CHATTON, J., RIEDERER, B.M. and THORENS, B. (2001) Identification of a mammalian H+-myo-inositol symporter expressed predominantly in the brain. The EMBO Journal 20: 4467-4477.Google Scholar
WALK, C.L., SANTOS, T.T. and BEDFORD, M.R. (2014) Influence of superdoses of a novel microbial phytase on growth performance, tibia ash, and gizzard phytate and inositol in young broilers. Poultry Science 93: 1172-1177.Google Scholar
WHITE, M.F. (2003) Insulin Signaling in Health and Disease. Science 302: 1710-1711.Google Scholar
WILSON, M.S.C., BULLEY, S.J., PISANI, F., IRVINE, R.F. and SAIARDI, A. (2015) A novel method for the purification of inositol phosphates from biological samples reveals that no phytate is present in human plasma or urine. Open Biology 5: 150014.Google Scholar
WOOLLEY, D.W. (1940) The nature of the anti-alopecia factor. Science 92: 384-385.Google Scholar
WOOLLEY, D.W. (1941) Identification of the mouse antialopecia factor. Journal of Biological Chemistry 139: 29-34.Google Scholar
YAO, Y., SHAN, F., BIAN, J., CHEN, F., WANG, M. and REN, G. (2008) d-chiro-Inositol-Enriched Tartary Buckwheat Bran Extract Lowers the Blood Glucose Level in KK-Ay Mice. Journal of Agricultural and Food Chemistry 56: 10027-10031.Google Scholar
ZYLA, K., MIKA, M., STODOLAK, B., WIKIERA, A., KORELESKI, J. and SWIATKIEWICZ, S. (2004) Towards Complete Dephosphorylation and Total Conversion of Phytates in Poultry Feeds. Poultry Science 83: 1175-1186.CrossRefGoogle ScholarPubMed