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Box of Reduced Glutathione for injection with vials on a beige background
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L-glutathione 1500mg vial

L-glutathione 1500mg vial

€30,00 EUR
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                                                NOT FOR HUMAN CONSUMPTION

L-Glutathione is a tripeptide (γ-glutamyl-cysteinyl-glycine) that serves as the cell’s master redox buffer, principal ROS/RNS scavenger, and detoxification cofactor. Via glutathione peroxidases (GPx) and glutathione S-transferases (GSTs) it reduces lipid peroxides and conjugates xenobiotics; glutathione reductase (GR) recycles oxidized GSSG back to GSH using NADPH. GSH also modulates signaling through S-glutathionylation, shapes mitochondrial function, and underpins immune and skin pigment biology. Orally, it is sold as a dietary supplement; IV/IM use exists in some regions but is not broadly approved for disease treatment.

Additional Benefits of L-Glutathione Repletion Now Under Investigation

Benefit Key take-aways
1 Oxidative-stress reduction Supplementation increases GSH/GSSG ratio, lowers 8-iso-PGF₂α and MDA across stress phenotypes, improving cellular redox tone. <br/><em>Free Radical Biology & Medicine; Redox Biology</em>
2 Immune support GSH influences Th1/Th2 balance, NK cell activity, and antiviral defenses (glutathionylation of viral/host proteins); deficient states show impaired responses. <br/><em>Immunity; Journal of Clinical Investigation</em>
3 Liver health & detox In NAFLD and toxicant exposure, GSH supports phase II conjugation and lowers transaminases in small trials; NAC (a GSH precursor) has stronger clinical precedent. <br/><em>Hepatology; Liver International</em>
4 Mitochondrial function Restores mitochondrial GSH, reduces ROS-induced mtDNA damage, and improves bioenergetic efficiency in muscle/neuronal models. <br/><em>Journal of Physiology; Neurobiology of Disease</em>
5 Skin tone & pigment modulation Oral/topical/IV protocols have shown modest skin-lightening via tyrosinase inhibition and pheomelanin shift; effects are variable and reversible. <br/><em>Journal of Dermatological Science; Clinical, Cosmetic & Investigational Dermatology</em>
6 Metabolic syndrome Redox improvement can reduce inflammatory markers and slightly improve HOMA-IR/TG, often when combined with exercise or precursors. <br/><em>Diabetes Care; Metabolism</em>
7 Respiratory & mucosal redox Nebulized or precursor-driven GSH replenishes epithelial lining fluid, supporting mucus rheology and antioxidant capacity (e.g., COPD/cystic fibrosis programs). <br/><em>Thorax; American Journal of Respiratory and Critical Care Medicine</em>
8 Neuroprotection signals Low brain GSH correlates with neurodegeneration; precursor strategies elevate brain GSH and improve surrogate motor/cognitive measures in early studies. <br/><em>Annals of Neurology; Movement Disorders</em>
9 Exercise recovery & performance GSH or precursors reduce exercise-induced oxidative stress, with small effects on fatigue perceptionand time-to-exhaustion in select protocols. <br/><em>Medicine & Science in Sports & Exercise; European Journal of Applied Physiology</em>

2. Molecular Mechanism of Action

2.1 Core pharmacodynamics

  • Antioxidant enzyme substrate: GPx uses GSH to reduce peroxides → GSSG, then GR + NADPH regenerate GSH.

  • Detoxification: GSTs conjugate GSH to electrophiles (drugs, pollutants), enhancing solubility/excretion.

  • Redox signaling: Protein S-glutathionylation regulates NF-κB, Keap1-Nrf2, and mitochondrial proteins.

  • Cysteine reservoir: Maintains intracellular cysteine and supports thiol-disulfide balance.

2.2 Down-stream biology

Pathway Functional outcome Context
Nrf2 activation (often via precursors) Up-regulates endogenous antioxidant/phase-II genes Liver, immune, endothelium
NF-κB restraint ↓ Pro-inflammatory cytokines Metabolic/immune stress
Tyrosinase modulation ↓ Melanin synthesis Skin
Mitochondrial redox ↓ ROS, preserved ATP production Muscle, neurons

3. Pharmacokinetics

  • Oral GSH (reduced form): Historically thought to be degraded by γ-glutamyltransferase in gut; newer data show dose-dependent plasma/tissue GSH rises with sustained dosing, especially with liposomal or sublingualforms.

  • Precursors: N-acetylcysteine (NAC) and glycine (sometimes with glutamine) reliably increase intracellular GSH via γ-glutamyl cycle; GlyNAC shows robust effects in older adults.

  • Parenteral: IV GSH yields transient high plasma levels; intracellular uptake depends on breakdown/transport—used off-label in some regions (e.g., dermatology), not broadly approved.

  • Distribution: Highest in liver, then erythrocytes, kidney, lung; mitochondrial GSH sustained by dedicated transporters.

  • Elimination: Renal excretion of metabolites (cysteinylglycine, cysteine, mercapturates).

4. Pre-clinical and Translational Evidence

4.1 Redox & inflammation

Consistent improvements in oxidative biomarkers and cytokine profiles across stress states (aging, diabetes, pollution exposure), especially with precursor strategies.

4.2 Hepatic/metabolic

Small randomized trials: ALT/AST, hepatic fat (MRI-PDFF) and insulin sensitivity improve modestly; effect size increases when baseline GSH is low.

4.3 Dermatology

Oral/topical studies show mild skin-lightening (one–two shade shifts) over 8–12 weeks; maintenance is required. IV protocols can produce faster effects but raise safety and regulatory concerns.

Evidence quality note: Strong biological plausibility and biomarker improvements; clinical outcomeeffects vary, and many studies are small/short. Precursors (e.g., NAC, GlyNAC) currently have more reproducible human data than high-dose oral GSH alone.

5. Emerging Clinical Interests

Field Rationale Status
Aging biology Low GSH as a hallmark; GlyNAC normalizes redox and some functional measures Phase 2–style signals
NAFLD/MASH adjunct Redox + detox + insulin sensitivity Pilot RCTs
Neurodegeneration Elevate brain GSH; oxidative stress mitigation Early human imaging studies
Oncology-adjacent Support normal tissue redox during therapy (not tumor) Careful, mixed literature
Environmental/toxicant exposure Enhance conjugation/clearance Translational
Pulmonary disease Epithelial lining GSH restoration Mixed clinical data
Dermatologic pigment Cosmetic lightening/brightening Small RCTs; regulatory variability

6. Safety and Tolerability

  • Oral GSH: Generally well tolerated. GI upset, bloating, or cramps at high doses (≥1–2 g/day).

  • Inhaled/nebulized: Can induce bronchospasm in reactive airways (sulfur odor); use caution in asthma.

  • IV GSH (off-label): Rapid infusion can cause flushing, dizziness, nausea; aseptic technique and qualified supervision are essential; long-term safety data are limited.

  • Dermatology: Rare rash or contact sensitivity to topical forms.

  • Interactions: May affect chemotherapy redox dynamics; coordinate with oncology. NAC/GSH can alter some lab assays (e.g., creatinine methods).

  • Pregnancy/lactation: Food-level exposure is normal; high-dose supplemental/IV use lacks robust data—avoid outside medical indication.

Comparative safety matrix

Feature Oral GSH Liposomal/Sublingual GSH GlyNAC/NAC IV GSH
Intracellular GSH rise Modest–moderate Moderate Robust (precursor-driven) Transient plasma, variable intracellular
Evidence for clinical endpoints Mixed Mixed Stronger (redox, metabolic) Limited; cosmetic/adjunctive contexts
AEs Mild GI Mild GI/aftertaste GI (NAC), rare rash Infusion reactions; access risks

7. Regulatory Landscape

  • Dietary supplement status for oral forms in many countries; no FDA/EMA approval for treating disease.

  • IV formulations are not approved for cosmetic indications in many jurisdictions; regulations differ by country.

  • Dermatology/cosmetics: Topical GSH is used in OTC products with appearance claims only.

8. Practical Use & Future Directions

  • Who benefits most: Individuals with oxidative stress or low baseline GSH (aging, metabolic syndrome, pollution exposure) and those needing detox support; for pigment goals, set modest expectations and emphasize photoprotection.

  • Dosing (typical research/supplement ranges):

    • Oral GSH: 250–1,000 mg/day, divided; liposomal/sublingual at the lower end often used.

    • Precursors: NAC 600–1,200 mg/day; GlyNAC protocols supply glycine 1.5–3 g/day + NAC 600–1,200 mg/day.

    • Duration: 8–12 weeks minimum for measurable changes.

  • Stacking: Combine with vitamin C/E, selenium (GPx cofactor), alpha-lipoic acid, exercise, and sleep to reinforce endogenous GSH cycling.

  • Monitoring: Consider GSH/GSSG ratio, 8-iso-PGF₂α, MDA, ALT/AST, and HOMA-IR in research settings.

  • Research needs: Large RCTs comparing oral GSH vs GlyNAC, head-to-head liposomal vs standard, validated clinical endpoints (not just biomarkers), and standardized skin-lightening measures with long-term safety.

Selected References

  • Free Radical Biology & Medicine; Redox Biology — Glutathione metabolism, redox signaling, and clinical biomarker changes.

  • Hepatology; Liver International — GSH/precursor effects in NAFLD/MASH and liver enzymes.

  • Immunity; Journal of Clinical Investigation — Immunological roles of GSH and infection responses.

  • Journal of Physiology; Neurobiology of Disease — Mitochondrial GSH and bioenergetics in muscle/neurons.

  • Journal of Dermatological Science; Clinical, Cosmetic & Investigational Dermatology — Skin-lightening trials and tyrosinase/UV photobiology.

  • Medicine & Science in Sports & Exercise; European Journal of Applied Physiology — Exercise oxidative stress and performance endpoints.

  • Thorax; American Journal of Respiratory and Critical Care Medicine — Airway glutathione biology and inhaled/precursor studies.

  • Annals of Neurology; Movement Disorders — Brain GSH imaging and pilot therapeutic studies.

  • Diabetes Care; Metabolism — Redox, inflammation, and insulin sensitivity under GSH repletion/precursor use.