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Amber glass dropper vial of Sobetirome (GC-1) solution, 200 mcg/mL concentration, labeled Batch No.002 with expiration date 22-08-2025, displayed against a clean beige background.
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Sobetirome(GC-1) 10.000mcg sublingual/oral vial

Sobetirome(GC-1) 10.000mcg sublingual/oral vial

€120,00 EUR
Z wliczonymi podatkami.

                                             NOT FOR HUMAN CONSUMPTION

Sobetirome is an oral, small-molecule TRβ-selective thyromimetic designed to deliver the lipid-lowering and hepatic/metabolic benefits of T3 while minimizing TRα-mediated cardiac and bone effects. By activating TRβ(highly expressed in liver and CNS oligodendrocyte lineage), sobetirome increases hepatic LDL-receptor expression, enhances reverse cholesterol transport, stimulates fatty-acid oxidation, and reprograms bile-acid and lipoprotein metabolism. It is investigational (not FDA/EMA-approved).

Additional Benefits of Sobetirome Now Under Investigation

Benefit Key take-aways
1 LDL-C and non-HDL reduction Dose-dependent LDL-C and apoB/non-HDL lowering via TRβ-driven LDLR up-regulation and increased cholesterol disposal; add-on to statins shows complementary effects. <br/><em>Journal of Clinical Endocrinology & Metabolism; Circulation</em>
2 Triglycerides & remnant lipoproteins Hepatic FAO and VLDL output tuning reduce fasting TG and remnant cholesterol; small HDL-C shifts vary by dose and background therapy. <br/><em>Atherosclerosis; J Lipid Research</em>
3 NAFLD/MASH activity MRI-PDFF and enzyme improvements with steatosis ↓; transcriptional programs favor β-oxidationand lipophagy, with anti-inflammatory signals downstream of TRβ. <br/><em>Hepatology; Liver International</em>
4 Lp(a) trend Early clinical signals suggest modest Lp(a) lowering (magnitude study-dependent); mechanism likely via hepatic transcriptional remodeling. <br/><em>European Heart Journal; JAMA Cardiology</em>
5 Energy expenditure & weight signals Mild ↑ resting energy expenditure and waist reduction in dyslipidemic/NAFLD phenotypes without frank hyperthyroid symptoms at TRβ-selective exposures. <br/><em>Cell Metabolism; Metabolism</em>
6 Combination lipid therapy Additive LDL-C reduction with statins or ezetimibe; potential synergy with PCSK9 inhibitors for aggressive apoB lowering. <br/><em>Circulation; JCEM</em>
7 Atheroprotection (preclinical) Plaque cholesterol ↓, improved lesional inflammation and macrophage efflux (ABCA1/ABCG1) in models; outcomes trials pending. <br/><em>Arteriosclerosis, Thrombosis, and Vascular Biology; Cardiovascular Research</em>
8 CNS myelin/repair biology TRβ activation promotes oligodendrocyte differentiation and remyelination; brain-penetrant prodrug (Sob-AM2) enhances CNS exposure and lowers VLCFAs in ALD models. <br/><em>Brain; Annals of Neurology</em>
9 Very-long-chain fatty acids (ALD/AMN) Sobetirome (± prodrug) reduces C26:0 VLCFAs in ABCD1-deficient models; early human translational work is ongoing for X-linked adrenoleukodystrophy phenotypes. <br/><em>Science Translational Medicine; Neurology</em>

2. Molecular Mechanism of Action

2.1 Receptor Pharmacodynamics

  • Target: TRβ-selective agonism (liver-biased).

  • Hepatic actions:LDLR, CYP7A1/bile-acid synthesis, β-oxidation genes; ↓ SREBP-1c lipogenesisLDL-C/TG lowering and steatosis reduction.

  • CNS actions (experimental): TRβ in OPCs/oligodendrocytesmyelin gene expression and maturation.

2.2 Down-stream Biology

Pathway Functional outcome Context
TRβ → LDLR, bile-acid synthesis Plasma LDL-C ↓, cholesterol disposal ↑ Liver/lipids
PPAR-coordinated FAO programs TG ↓, hepatic fat ↓ Liver
ABCA1/ABCG1 efflux Macrophage cholesterol efflux ↑ Atheroprotection
OPC differentiation genes (MBP/MOG) Remyelination support CNS (prodrug-enabled)

3. Pharmacokinetics

  • Route: Oral, once-daily in trials.

  • Absorption: Rapid; food effect modest (not clinically central).

  • Half-life: Multi-hour (supports QD dosing); hepatic distribution favored.

  • Metabolism/clearance: Oxidative/phase-II metabolism; biliary/renal excretion of metabolites.

  • Prodrug strategy: Sob-AM2 increases brain exposure for CNS targets while limiting systemic thyromimetic load.

4. Pre-clinical and Clinical Evidence

4.1 Dyslipidemia / Mixed hyperlipidemia

Phase 1/2 programs demonstrate clinically relevant LDL-C and TG reductions with favorable apoB/non-HDL changes and TSH suppression consistent with on-target thyroid signaling—without significant TRα-like tachycardia at therapeutic exposures.

4.2 NAFLD / MASH

Imaging/lab signals show hepatic-fat reduction and ALT/AST improvements, aligning with the hepatic TRβ mechanism. Histologic outcomes are being pursued in class programs (TRβ agonists).

4.3 CNS (ALD/MS translational)

Sobetirome and brain-targeted prodrugs reduce VLCFAs and improve remyelination indices in animals; early human translational efforts are underway (biomarkers, safety, and exposure).

Evidence quality note: Robust mechanistic and preclinical data; early-phase human trials show lipid/steatosis signals. Hard outcomes (CV events, MASH histology, neurologic disability) remain unproven.

5. Emerging Clinical Interests

Field Rationale Status
ApoB-driven dyslipidemia Hepatic TRβ LDLR up-regulation Phase 2–style signals
Statin-intolerant / add-on Non-myotoxic mechanism, stackable Investigational
NAFLD/MASH Steatosis ↓, enzymes ↓ Ongoing
Familial hypercholesterolemia (adjunct) Additional LDL-C lowering with PCSK9/statins Exploratory
X-linked ALD/AMN VLCFA lowering; CNS prodrug Translational
MS remyelination (concept) TRβ-driven oligodendrocyte maturation Preclinical/early translational

6. Safety and Tolerability

  • Class/on-target effects: TSH suppression, T3/T4 axis shifts (generally mild); heart-rate/palpitations uncommon at TRβ-selective exposures but possible with over-exposure.

  • Common AEs: Headache, GI upset, mild insomnia, warmth/flush, transaminase drift (usually small).

  • Cardiac/bone: Designed to spare TRα; nonetheless, monitor HR/BP and bone-turnover markers with prolonged use or high dose.

  • Hepatic: Periodic ALT/AST monitoring—particularly in NAFLD/MASH.

  • Endocrine: Avoid in untreated hyperthyroidism; use caution with amiodarone or iodine load.

  • Pregnancy: Avoid (thyroid-axis manipulation).

  • Drug interactions: Potential with warfarin (INR shifts), CYP inducers/inhibitors, and agents affecting thyroid binding/transport; separate from bile-acid sequestrants.

Comparative safety matrix (thyromimetics)

Feature Sobetirome (GC-1) Eprotirome VK2809
Receptor selectivity TRβ-selective TRβ-selective TRβ-selective (liver-targeted prodrug)
Route Oral Oral Oral (hepatocyte-targeted)
LDL/TG effects Robust (dose-dependent) Robust (program halted for tox in dogs) Robust (Phase 2 signals)
Key concerns Axis suppression (manageable), mild HR Preclinical cartilage tox Axis suppression, LFTs (monitor)

7. Regulatory Landscape

  • Not approved for any indication.

  • Being developed for dyslipidemia/NAFLD (adjunct to standard of care) and rare neurologic indications via CNS-targeted prodrugs.

  • No sport relevance (not a performance drug), but off-label/compound use is not advised.

8. Future Directions

  • Cardiometabolic outcomes: ApoB-anchored Phase 3 with MACE endpoints; combination strategies with statins, ezetimibe, PCSK9, ANGPTL3.

  • MASH histology: Biopsy-based trials (NASH resolution, fibrosis endpoints) and MRI-PDFF/MRE composites.

  • Dose-exposure models: Define TRβ selectivity windows that preserve axis efficacy with minimal TRα spillover.

  • CNS programs: Optimize Sob-AM2 or next-gen brain-penetrant analogs; VLCFA, myelin imaging (MTR), and functional outcomes in ALD/AMN and MS.

  • Safety registries: Long-term thyroid axis, cardiac rhythm, bone density, and hepatic surveillance.

Selected References

  • Circulation; Atherosclerosis; Journal of Lipid Research — TRβ agonism, LDLR up-regulation, and lipoprotein remodeling with sobetirome-class agents.

  • Hepatology; Liver International — TRβ-driven steatosis reduction and NAFLD biomarker changes.

  • Journal of Clinical Endocrinology & Metabolism — Early human lipid/thyroid-axis data with sobetirome.

  • Arteriosclerosis, Thrombosis, and Vascular Biology; Cardiovascular Research — Atheroprotection mechanisms (macrophage efflux, plaque biology).

  • Brain; Annals of Neurology — TRβ in oligodendrocyte maturation and remyelination paradigms.

  • Science Translational Medicine; Neurology — Sobetirome/Sob-AM2 lowering VLCFAs in ABCD1 models and translational steps for X-ALD/AMN.

  • Cell Metabolism; Metabolism — Energy-expenditure and hepatic transcriptional programs under thyroid hormone mimetics.