Bioquímica Actividad Antihiperglicemiante de Bauhinia megalandra.(Revisión)
Referencias
Nelson DL, Cox MM. Lehninger Principles of Biochemistry.
1. Fourth Edition. WH. Freedman & Co. New York. 2005
Ashmore J, Weber G. The role of hepatic
glucose-6-phosphatase in the regulation of carbohydrate metabolism. In
Vitamins and Hormones, Harris RS, Morrison GF (eds). Academic Press: New
York; 26: 91 "“ 132.
Arion WJ, Wallin BK, Lange AJ, Ballas LM.
On the involvement of a glucose 6-phosphate transport system in the
function of microsomal glucose 6-phosphatase. Mol Cell Biochem 1975; 6: 75
"“ 83.
Burchell A, Waddell ID. The molecular
basis of the hepatic microsomal glucosa-6-phosphatase system. Biochem
Biophys Acta 1991; 1092:
129-137.
Joost HG, Thorens B. The extended GLUT-family of
sugar/polyol transport facilitators: nomenclature, sequence
characteristics, and potential function of its novel members. Mol Membr Biol. 2001; 18: 247 "“ 56.
McCormack JG, Westergaard N, Kristiansen
M, Brand CL, Lau J. Pharmacological approaches to inhibit endogenous
glucose production as means of anti-diabetic therapy. Curr Pharm Design. 2001; 7: 1451 "“
1474.
Arion WJ, Ballas LM, Lange AJ, Tallin WK.
Microsomal membrana permeability and the hepatic microsomal glucose-6-phosphatase
system with D-mannose-6 phosphate. J Biol Chem 1976; 251: 4891 "“ 4897.
Hoyos J. Flora Tropical Ornamental. Sociedad
de Ciencias Naturales La
Salle: Caracas Venezuela. 1978.
González-Mujica F, Motta N, Becerra A.
Inhibition of hepatic neoglucogenesis an glucose-6-phosphatase by aqueous
extracto of Bauhinia megalandra
leaves. Phytother Res 1998; 12: 291 "“ 293.
Estrada O, Hasegawa M, González-Mujica F,
Motta N, Perdomo E, Solórzano A, Méndez J, Méndez B, Zea EG. Evaluation of
flavonoids from B. megalandra leaves
as inhibitors of glucose-6-phosphatase system. Phytother Res 2005: 19: 859
"“ 863.
Arion WJ, Lange AJ, Walls HE. Microsomal
membrana integrity and the interaction of phlorizin with
glucose-6-phosphatase system. J boil. Chem. 1980; 255: 10387 "“ 10395.
González-Mujica F, Motta N, Estrada O,
Perdomo E, Méndez J, Hasegawa M. Inhibition of hepatic neoglucogenesis and
glucose-6-phosphatase by quercetin 3-O-α-(2"galloyl)-rhamnoside isolated
from Bauhinia megalandra leaves.
2005; 19: 624 "“ 627.
Cori C, Cori G. The mechanism of epinephrine
action. i. the influence of epinephrine on the carbohydrate metabolism of
fasting rats, with a note on new formation of carbohydrates. J Biol Chem
1928; 79: 309 "“ 319.
Fernández-Peña C, González-Mujica F, Motta N,
Tillett S. Efecto de extracto acuoso de hojas de Bauhinia megalandra sobre la glucogenólisis hepática en ratas.
Arch. Venez Farmacol. Ter. 2008; 27: 129 "“ 131.
González-Mujica F, Motta N, Márquez AH,
Capote-Zulueta J. Effects of Bauhinia
megalandra leaf aqueous extract on intestinal glucose absorption and
uptake by enterocyte brush border membrana. Fitoterapia 2003; 74: 84 "“ 90.
Panayotova-Heiermann M, Loo DDF, Wright M.
Kinetics of steady-state currents and charge movements associated with the
rat Na+/glucose cotransporter. J Biol Chem. 1995; 270: 27099 "“ 27105.
Kessler M, Acuto O, Storellic C, Murer H,
Muller M, Semenza G. A modified procedure for the rapid preparation of
efficiently transporting vesicles from small intestinal brush border
membranes. Their use in investigating some properties of D-glucose and
choline transport systems. Biochem Biophys Acta. 1978; 506: 136 "“ 154.
Kobayashi Y, Suzuki M, Satsu H, Arai S, Hara
Y, Suzulki K, et al.Green tea polyphenols inhibit the
sodium-dependent glucose transporter of intestinal epithelial cells by a
competitive mechanism. J
Agric Food Chem. 2000; 48: 5618 "“ 5623.
Vedavanam K, Srijayanta S, O"™Reilly J,
Raman A, Wiseman H. Antioxidant action and potential antidiabetic
properties of an isoflavonoid-containing soyabean phytochemical extract
(SPE). Phytother Res. 1999; 13: 601 "“ 608.
Campbell LK, White JR, Campbell RK. Acarbose:
its role in the treatment of diabetes mellitus. Ann Pharmacother 1996; 30:
1255 "“ 1262.
Rodriguez P. Identificación del compuesto
presente en el extracto de Bauhinia
megalandra, responsable de la inhibición de la absorción intestinal de
glucosa. Trabajo especial de grado. Escuela de Biología. Facultad de
Ciencias. Universidad Central de Venezuela. 2009.
Ader P, Blí¶ck M, Pietzsch S, Wolffram S.
Interaction of quercetin glucosides with the intestinal sodium/glucose
co-transporter
(SGLT-1) Cancer Letters 2001; 162: 175 "“ 180.
Li JM, Che CT, Lau CBS, Leung PS, Cheng
CHK. Inhibition of intestinal and renal Na+-glucose
cotransporter by naringenin. Int J Biochem Cell Biol. 2006; 38: 985 "“ 995.
Daubront V, González-Mujica F, Motta N,
Rodríguez M, Hasegawa M. Purificación parcial de un compuesto presente en
las hojas de Bauhinia megalandra
capaz de inhibir la absorción intestinal de glucosa. Arch. Venez. Farmacol.
Ter. 2009; 28: 40 "“ 42.
Coronil G. Absorción intestinal de
flavonoides presentes en las hojas de Bauhinia
megalandra y sus efectos sobre la eliminación urinaria de glucosa en
ratas. Trabajo Especial de Grado. Escuela de Biología. Facultad de
Ciencias. Universidad Central de Venezuela. 2009..
Hopfer U, Nelson K, Perroto J,
Isselbaccher KJ. Glucose transport in isolated brush border membrane from
rat small intestine. J. Biol. Chem. 1973; 248: 25-32
NOTA:Toda la información que se brinda en este artículo es de carácter investigativo y con fines académicos y de actualización para estudiantes y profesionales de la salud. En ningún caso es de carácter general ni sustituye el asesoramiento de un médico. Ante cualquier duda que pueda tener sobre su estado de salud, consulte con su médico o especialista.
Instituto de Medicina Tropical - Facultad de Medicina - Universidad Central de Venezuela.
Elaborado por el Centro de Análisis de Imágenes Biomédicas Computarizadas CAIBCO, caibco@ucv.ve
Este portal ha sido desarrollado gracias al apoyo del Fonacit