B-ComplexvsMagnesium Glycinate

Each B vitamin serves specific neurological functions: B1 (thiamine) — cofactor for transketolase (pentose phosphate pathway), pyruvate dehydrogenase, and alpha-ketoglutarate dehydrogenase; essential for glucose metabolism and ATP production in neurons. B2 (riboflavin) — precursor to FAD/FMN, cofactors for Complex I and II of the electron transport chain, and glutathione reductase. B3 (niacin/niacinamide) — precursor to NAD+/NADPH via the salvage pathway; NAD+ is substrate for sirtuins, PARP, and 400+ dehydrogenases. B5 (pantothenic acid) — component of coenzyme A, required for acetylcholine synthesis via choline acetyltransferase and for fatty acid oxidation. B6 (pyridoxine) — cofactor for AADC (5-HTP to serotonin, L-DOPA to dopamine), GABA synthesis (GAD), and homocysteine metabolism. B9 (folate) — tetrahydrofolate donates methyl groups for dTMP and purine synthesis, and for homocysteine remethylation. B12 (cobalamin) — cofactor for methionine synthase (myelin maintenance) and methylmalonyl-CoA mutase.

Magnesium is required for over 300 enzymatic reactions including neurotransmitter synthesis (tyrosine hydroxylase, tryptophan hydroxylase), energy production (ATPases, kinases, glycolytic enzymes), and DNA repair (PARP, DNA polymerases). In the brain, magnesium blocks NMDA receptors at the voltage-dependent Mg2+ binding site within the channel pore (GluN1/GluN2 subunits), preventing excessive calcium influx and excitotoxicity — Mg2+ is displaced only upon depolarization and glycine/glutamate binding. The glycine component activates inhibitory glycine receptors (GlyR alpha1/alpha2) in the brainstem and spinal cord, and serves as an obligatory co-agonist at the GluN1 glycine site of NMDA receptors. Glycine also modulates NMDA receptor function. Together, magnesium and glycine produce calming effects through complementary inhibitory mechanisms: reduced glutamatergic excitability and enhanced inhibitory neurotransmission.