Follistatin 344 vs MGF

Binds and neutralizes myostatin (GDF-8) and activin; removes the natural brake on muscle growth allowing supraphysiological hypertrophy

Follistatin-344 is the predominant endogenous isoform of follistatin, a glycoprotein that binds and neutralizes the TGF-β superfamily members activin A and myostatin, preventing their engagement with skeletal muscle ActRII receptors and thereby relieving their inhibitory effects on muscle protein synthesis and satellite cell activation. By sequestering both myostatin and activin A simultaneously, follistatin-344 neutralizes two complementary negative regulators of muscle growth through a dual-pathway mechanism, a property that distinguishes it from agents that target only the myostatin pathway. Transgenic expression of human follistatin-344 has produced significant skeletal muscle mass increases in animal models, and a phase 1/2a gene therapy trial delivering the follistatin-344 gene via AAV to patients with Becker muscular dystrophy established initial proof of concept and safety data in a human clinical context. Follistatin-344 has not received FDA approval for any indication; exogenous administration as a recombinant protein or peptide is investigational and no human safety data exists for this route of administration outside gene therapy trial contexts. Follistatin-344 as a research compound: recombinant follistatin-344 protein is available through research biochemical suppliers as a laboratory reagent, used in cell culture and animal models to probe myostatin and activin A biology. Interest in exogenous follistatin-344 administration in performance contexts has grown from the animal model hypertrophy data; however, the protein's large molecular weight (~35 kDa glycoprotein) creates significant bioavailability challenges for subcutaneous or intramuscular routes, and no human pharmacokinetic data supports assumed tissue distribution from injection. This distinguishes it from smaller peptide-based myostatin modulators. Follistatin-344 vs myostatin propeptide: both target myostatin inhibition but through different binding mechanisms. Follistatin-344 binds activin A in addition to myostatin, providing a broader TGF-β inhibition profile. Myostatin propeptide is the endogenous inhibitory domain of the myostatin precursor protein — it is myostatin-specific but structurally derived from the same protein rather than from a binding antagonist class. Both compounds remain at the research stage for performance applications with no approved human use. Providers offering research peptides in the performance and muscle recovery category are listed in the PeptideBase directory.

Splice variant of IGF-1; acts locally at site of muscle damage to activate satellite cells (muscle stem cells) for repair and hypertrophy

Mechano growth factor (MGF), also designated IGF-1Ec, is a splice variant of the IGF-1 gene produced locally in skeletal muscle in response to mechanical loading and tissue microdamage, and is proposed to function as an autocrine/paracrine signal that activates muscle satellite cells and initiates the early repair response, a role distinct from the endocrine actions of systemic IGF-1. The unique C-terminal E-peptide domain of MGF is proposed to be the bioactive moiety responsible for satellite cell activation and progenitor cell proliferation, acting through mechanisms that are at least partially independent of IGF-1R and specific to the mechanical stress response rather than systemic growth signaling. Human muscle progenitor cell studies have demonstrated that the MGF E-peptide activates muscle progenitor cells and enhances their fusion potential across different age groups, suggesting a role in the age-related decline in muscle repair capacity. MGF is a research compound with no regulatory approval in any jurisdiction; exogenous administration is investigational, no human clinical pharmacokinetic or safety data has been established, and published evidence is limited to in vitro and preclinical contexts. MGF vs PEG-MGF: native MGF has a very short half-life in circulation, limiting its duration of action after exogenous administration. PEG-MGF (pegylated MGF) is a chemically stabilized version in which polyethylene glycol is conjugated to the peptide to extend its biological half-life — the same technology used to extend the half-life of therapeutic proteins such as PEG-EPO. Research compound suppliers often offer both forms; PEG-MGF is the more commonly studied variant in animal myopathy models for this pharmacokinetic reason. Neither form has human clinical data. MGF in muscle research: interest in MGF as a research compound centers on its proposed role in the lag phase of muscle repair following eccentric exercise-induced damage — the window when satellite cells are activated before proliferating and fusing into existing myofibers. In aged muscle, MGF expression following mechanical loading is reduced relative to young tissue, and this deficit has been proposed as a contributing factor to age-related sarcopenia in the research literature. Providers offering research peptides in the performance and recovery category are listed in the PeptideBase directory.