Glutathione Power Powder by Designs For Health (DFH) 

• Antioxidant/Anti-Aging
• Cigarette smoke
• Radiation exposure
• Heavy metal toxicity
• Chemical exposure
• Drug use
• Alcoholism
• Diabetes
• Cataracts
• Stroke and brain injury
• Ulcers
• Skin problems
• Cancer
• Sports Recovery & Endurance

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In humans, Glutathione is found in all tissues, with the highest levels found in the liver, eyes, spleen, pancreas, and kidneys. Research shows that glutathione is the single most protective antioxidant in virtually every tissue of the body. Glutathione Powder has a bland taste that dissolves quickly in water or other beverage for easy daily intake. This formula is quickly assimilated for instant results, and is suitable for vegetarians.

Bioavailability of dietary glutathione: effect on plasma concentration.

Hagen TM, Wierzbicka GT, Sillau AH, Bowman BB, Jones DP.

Department of Biochemistry, Emory University School of Medicine, Atlanta, Georgia 30322.

Plasma glutathione (GSH) concentration in rats increased from approximately 15 to 30 microM after administration of GSH either as a liquid bolus (30 mumol) or mixed (2.5-50 mg/g) in AIN-76 semisynthetic diet. GSH concentration was maximal at 90-120 min after GSH administration and remained high for over 3 h. Administration of the amino acid precursors of GSH had little or no effect on plasma GSH values, indicating that GSH catabolism and resynthesis do not account for the increased GSH concentration seen. Inhibition of GSH synthesis and degradation by L-buthionine-[S,R]-sulfoximine and acivicin showed that the increased plasma GSH came mostly from absorption of intact GSH instead of from its metabolism. Plasma protein-bound GSH also increased after GSH administration, with a time course similar to that observed for free plasma GSH.

Thus dietary GSH can be absorbed intact and results in a substantial increase in blood plasma GSH. This indicates that oral supplementation may be useful to enhance tissue availability of GSH.

Glutathione transport system in human small intestine epithelial cells. Biochim Biophys Acta. 1997 Dec 4;1330(2):274-83 Iantomasi T, Favilli F .

The present study characterizes for the first time a GSH specific transporter in a human intestinal epithelial cell line (I407). GSH metabolism is very important for the antioxidant and detoxifying action of intestine and for the maintenance of the luminal thiol-disulfide ratio involved in regulation mechanisms of the protein activity of epithelial cells. GSH level decreases have been related to physio-pathological alterations either of intestine or other organs. GSH specific transport systems have been identified in membranes of various cell types of rat, mice and rabbit. The presence of a Na+-independent transport system of GSH is confirmed by the similar behaviour of GSH uptake time-courses when Na+ in extracellular uptake medium was replaced with choline+ or K+ as well as by kinetic saturation and by the trans-stimulation effect on GSH uptake in GSH preloaded cells. Moreover, this transporter is activated when cations are present in extracellular medium and it is affected by membrane potential changes with an increase in GSH uptake values when membrane depolarization occurs. The present results also show a remarkable affinity and specificity of this transporter for GSH; in fact, Km value is very low (90 +/- 20 microM) and only compounds strictly related to GSH structure, such as GSH S-conjugates and GSH-ethyl ester, inhibit GSH uptake in 1407 cells. Finally, a possible hormonal control and modulation by the thiol-disulfide status of GSH transporter activity is suggested.

Intestinal glutathione transport system: a possible detoxication role.
Biochim Biophys Acta. 1991 Apr 9;1073(3):571-9 Vincenzini MT, Favilli F.

The epithelium of the small intestine act by the formation of GSH-S-conjugation, as a first line of defence against various ingested toxic chemicals. GSH and GSH-dependent enzymes are present in the gastrointestinal wall. We and others have characterized the GSH-specific transport systems in intestinal brush-border and in basolateral membrane vesicles, in which gamma-glutamyltranspeptidase (gamma-GT) activity was inactivated by AT-125. In the present study we use inhibition experiments, kinetic studies, trans-stimulation of GSH uptake and HPLC determination to demonstrate (for the first time) that GSH and two GSH-S-conjugates (chosen as model compounds) share a common transport system. Plasma GSH-S-conjugates that may enter the intestinal cells via basolateral membrane, and GSH-S-conjugates that form in intestinal cells, may be eliminated directly by this GSH transporter across brush-border membranes or transported into lumen to the active site of gamma-GT; they are then further metabolized and excreted by various routes. This transport system may thus contribute to the intestinal detoxication role.

Stimulation of glutathione absorption in rat small intestine by alpha-adrenergic agonists. FASEB J. 1991 Sep;5(12):2721-7 Hagen TM, Bai C, Jones DP.

Department of Biochemistry, Emory University School of Medicine, Atlanta, Georgia 30322.

The alpha-adrenergic agonist, phenylephrine (1.6 microM), caused a threefold stimulation of glutathione (GSH) transport from the lumen into the vasculature in isolated, vascularly perfused rat small intestine. Stimulation of GSH transport by phenylephrine was blocked by the alpha-adrenergic antagonists, prazosin or phentolamine. Norepinephrine and epinephrine (both alpha and beta agonists) also stimulated GSH absorption but not to the same extent as phenylephrine. Isoproterenol, a strict beta-adrenergic agonist, had no effect on the rate of GSH absorption. Under physiological luminal GSH concentrations, phenylephrine stimulated GSH efflux from the lumen, accumulation in the intestinal mucosa, and transport into the mesenteric vasculature. Phenylephrine did not stimulate the transport of polyethylene glycol, a high molecular weight molecule, and stimulated uptake of cysteine and glycine by 30%. This suggests that the effect of phenylephrine on GSH transport is not due to enhanced bulk flow through paracellular pathways. Studies with isolated small intestinal epithelial cells showed that phenylephrine also stimulated the release of GSH from the cells. Phenylephrine alone or with the amino acid constituents of GSH caused no increase in plasma GSH concentration. Thus, absorption of dietary GSH is under hormonal regulation. The physiological importance of this regulation is not known, although such regulation may function to control utilization of dietary GSH for detoxication and may have therapeutic benefits for individuals with deficient GSH or increased risk of oxidative or chemically induced injury.

Chem Biol Interact. 1991;80(1):89-97.

Oral glutathione increases tissue glutathione in vivo.
Aw TY, Wierzbicka G, Jones DP. Department of Physiology, Louisiana State University Medical Center, Shreveport 71130.

Mice were given an oral dose of glutathione (GSH) (100 mg/kg) and concentrations of GSH were measured at 30, 45 and 60 min in blood plasma and after 1 h in liver, kidney, heart, lung, brain, small intestine and skin. In control mice, GSH concentrations in plasma increased from 30 microM to 75 microM within 30 min of oral GSH administration, consistent with a rapid flux of GSH from the intestinal lumen to plasma. Under these GSH-sufficient conditions, no increases over control values were obtained in GSH concentrations in most tissues except lung over the same time course. Mice pretreated for 5 days with the GSH synthesis inhibitor, L-buthionine-S,R-sulfoximine (BSO, 80 mumol/day) had substantially decreased tissue concentrations of GSH. Oral administration of GSH to these GSH-deficient animals gave statistically significant increases in GSH concentrations in kidney, heart, lung, brain, small intestine and skin but not in the liver. Administration of the equivalent amount of the constituent amino acids, glutamate, cysteine, and glycine, resulted in little change in GSH concentrations in all tissues in GSH-deficient animals. Thus, the results show that oral GSH can increase GSH concentrations in several tissues following GSH depletion, such as can occur in toxicological and pathological conditions in which GSH homeostasis is compromised.