RESUMO
Zapnometinib is a MEK inhibitor currently under clinical development for the treatment of COVID-19 and influenza. Zapnometinib has both antiviral and immunomodulatory effects. Information concerning the absorption, distribution, metabolism, and excretion of the compound following single oral doses of 30 mg/kg [14C]-zapnometinib to rats was required to support pharmacology and toxicology studies in animals and clinical studies in man. As part of the development and safety assessment of this substance, zapnometinib was radioactively labeled and used for the investigation of time-dependent plasma concentrations, the rates and routes of excretion, the extent and time-course of compound distribution in body tissues, the metabolite profiles in plasma, urine and feces and the chemical nature of its metabolites. The present study reveals a rapid but low absorption of zapnometinib from the gastrointestinal tract, with more than 90% of the compound being excreted within 48 h, mainly via feces. Whole body autoradiography confirms that zapnometinib was rapidly and widely distributed, with greatest concentrations in the circulatory and visceral tissues. Maximum plasma and tissue concentrations occurred between two and 8 h post dose. Penetration into the brain was low, and elimination from most tissues almost complete after 168 h. Metabolic profiles showed that the main clearance routes were metabolism via oxidative reactions and glucuronidation. These results further strengthen the knowledge of zapnometinib with respect to the clinical development of the drug.
RESUMO
The mitogen-activated protein kinase (MEK) inhibitor zapnometinib is in development to treat acute viral infections like COVID-19 and influenza. While the antiviral efficacy of zapnometinib is well documented, further data on target engagement/pharmacodynamics (PD) and pharmacokinetics (PK) are needed. Here, we report zapnometinib PK and PD parameters in mice, hamsters, dogs, and healthy human volunteers. Mice received 25 mg/kg/day zapnometinib (12.5 mg/kg p. o. twice daily, 8 h interval). Syrian hamsters received 30 mg/kg (15 mg/kg twice daily) or 60 mg/kg/day once daily. Beagle dogs were administered 300 mg/kg/day, and healthy human volunteers were administered 100, 300, 600 and 900 mg zapnometinib (once daily p. o.). Regardless of species or formulation, zapnometinib maximum plasma concentration (Cmax) was reached between 2-4 h after administration with an elimination half-life of 4-5 h in dogs, 8 h in mice or hamsters and 19 h in human subjects. Doses were sufficient to cause up to 80% MEK inhibition. Across all species approximately 10 µg/ml zapnometinib was appropriate to inhibit 50% of peripheral blood mononuclear cells (PBMC) MEK activity. In mice, a 50%-80% reduction of MEK activity was sufficient to reduce influenza virus titer in the lungs by more than 90%. In general, while >50% MEK inhibition was reached in vivo at most doses, 80% inhibition in PBMCs required significantly higher doses and appeared to be the practical maximal level obtained in vivo. However, the period of reduced phosphorylated extracellular-signal regulated kinase (pERK), a measure of MEK inhibition, was maintained even after elimination of zapnometinib from plasma, suggesting a sustained effect on MEK consistent with regulatory effects or a slow off-rate. These data suggest a target plasma Cmax of at least 10 µg/ml zapnometinib in further clinical studies.
RESUMO
BACKGROUND/AIMS: In vitro studies in the subgenomic hepatitis C virus (HCV) replicon system have identified all-trans retinoic acid (ATRA) as a potential therapeutic against hepatitis C. Thus, the antiviral potential of this drug should be assessed in vivo. METHODS: Twenty highly treatment experienced serotype 1 patients with non-response to conventional or pegylated interferon-alpha (Peg-/IFN-alpha) and ribavirin were randomly assigned to 12 weeks of monotherapy with ATRA (group A) or a combination of ATRA and PegIFN-alpha2a (group B). HCV RNA was assessed by bDNA assay and if negative by highly sensitive polymerase chain reaction. RESULTS: During treatment, five of 10 patients in group A had a drop of viraemia >1log, while in group B after 8 weeks five of 10 dropped >2log, and three of 10 cleared HCV RNA from serum. Viraemia relapsed after treatment cessation. ATRA was rather well tolerated, with transient headache, dry skin and mucosa representing the most common side effects. CONCLUSIONS: The viral load reduction under ATRA monotherapy, although limited and transient, supports the antiviral activity of ATRA. However, the rapid loss of HCV RNA in three of 10 previous non-responders under ATRA and PegIFN-alpha2a treatment demonstrates a strong additive or synergistic ATRA effect and calls for a controlled trial to assess the therapeutic potential of this drug.