Immunomodulatory and clinical effects of receptor-interacting protein kinase 1 (RIPK1) inhibitor eclitasertib (SAR443122) in patients with severe COVID-19: a phase 1b, randomized, double-blinded, placebo-controlled study.

BACKGROUND: Targeting receptor-interacting serine/threonine protein kinase 1 could mitigate the devastating sequelae of the hyperinflammatory state observed in severe cases of COVID-19. This study explored the immunomodulatory and clinical effects of the receptor-interacting serine/threonine protein kinase 1 inhibitor SAR443122 (eclitasertib) in patients with severe COVID-19. METHODS: In this Phase 1b, double-blinded, placebo-controlled study (NCT04469621) a total of 82 patients were screened, of whom 68 patients were eligible and randomized (2:1) to receive eclitasertib 600 mg (300 mg twice daily) or placebo up to 14 days. Primary outcome was relative change in C-reactive protein from baseline to Day 7. Time to clinical improvement using 7-point ordinal scale, ventilator/respiratory failure-free days, change in SpO2/FiO2 ratio, and biomarkers of severe COVID-19 were explored. RESULTS: Geometric mean ratio (point estimate [90% confidence interval]) of the relative change from baseline in C-reactive protein with eclitasertib vs. placebo on Day 7 was 0.85 (0.49-1.45; p = 0.30). Median time to 50% decrease in C-reactive protein from baseline was 3 days vs. 5 days (p = 0.056) with eclitasertib vs. placebo. Median time to ≥ 2-point improvement on 7-point clinical symptoms scale was 8 days vs. 10 days with eclitasertib vs. placebo (p = 0.38). Mean ventilator/respiratory failure-free days, change in baseline-adjusted SpO2/FiO2 ratio, and clinical biomarkers showed consistent numerical improvements with eclitasertib vs. placebo. The most frequently reported treatment-emergent adverse events were gastrointestinal disorders and condition aggravated/worsened COVID-19 pneumonia. CONCLUSIONS: Eclitasertib was well tolerated with consistent trends toward more rapid resolution of inflammatory biomarkers and clinical improvement in severe COVID-19 patients than placebo. GOV IDENTIFIER: NCT04469621, first posted on clinicaltrials.gov on July 14, 2020.

Clopidogrel pharmacodynamics and pharmacokinetics in the fed and fasted state: a randomized crossover study of healthy men.

Clopidogrel requires CYP450-mediated hepatic metabolism to form its active metabolite (clopi-H4). This randomized, placebo-controlled, crossover study was designed to characterize the effect of a high-fat or standard breakfast on adenosine diphosphate (ADP)-induced platelet aggregation and exposure to unchanged clopidogrel and clopi-H4 following clopidogrel (300-mg loading dose, 75 mg/d for 4 days) in 72 healthy men. At day 5 and as assessed by liquid chromatography-tandem mass spectrometry, unchanged clopidogrel area under the concentration- time curve from 0 to 24 hours (AUC(0-24)) increased 3.32-fold (90% confidence interval [CI], 2.88-3.84), and clopi-H4 AUC(0-24) decreased nonsignificantly by 12% (90% CI, 0.82-0.94) upon administration of clopidogrel with a standard breakfast. The estimated treatment difference in maximum platelet aggregation (MPA) induced by ADP 5 µM and assessed by light transmission aggregometry was 4.7%, with the 90% CI (0.9%-8.5%) contained within the prespecified equipotency range of ±15%. The mean ± standard deviation of day 5 inhibition of platelet aggregation was 49.7% ± 17.2% and 54.0% ± 13.3% in the fed and fasted states, respectively. Despite increased unchanged clopidogrel and slightly decreased clopi-H4 exposure following clopidogrel administration, the numerical increase in MPA in the fed versus fasted state was small and within the prespecified limit of equipotency. These findings confirm that clopidogrel can be taken with or without food.

Quantification of antimalarial bisthiazolium compounds and their neutral bioprecursors in plasma by liquid chromatography-electrospray mass spectrometry.

BACKGROUND: A new class of antimalarial drugs targeting membrane biogenesis during intraerythrocytic Plasmodium falciparum development has been identified. The bisthiazolium salts T3 and T4 have superior in vitro and in vivo parasite-killing properties and need to be monitored. METHODS: We used a liquid chromatography-electrospray ionization mass spectrometry method (positive mode) to quantify two bisthiazolium compounds (T3 and T4) and a related prodrug (TE4c) in human and rat plasma. Verapamil was used as internal standard. Verapamil and the TE4c compound were characterized by protonated molecules at m/z 455.7 and m/z 725.7, respectively. T3 and T4 were detected through two ions [(M2+)/2] at m/z 227.7 and m/z 241.8 and by their adducts with trifluoroacetic acid [M+TFA]+ at m/z 568 and m/z 596, respectively. The sample clean-up procedure involved solid-phase extraction. HPLC separation was performed on a reversed-phase column, using a water-acetonitrile gradient, with both solvents containing TFA. Stability under various conditions was also investigated. RESULTS: The peak-area ratios (drugs/internal standard) were linked to concentrations (6.4-1282 microg/L for T3; 6.5-1309.8 microg/L for T4; 20-2000 microg/L for TE4c) according to a quadratic equation. The accuracy ranged from 85% to 113.1%, and the imprecision from 2.2% to 15%. The mean extraction recoveries were 87%, 98%, and 80% for T3, T4, and TE4c, respectively. The lower limit of quantification was 6.4 mug/L for the two bisthiazolium compounds, whereas it was 20 mug/L for TE4c, the related lipophilic prodrug. CONCLUSION: This highly specific and sensitive method is suitable for analyzing samples collected during preclinical pharmacokinetic studies in rats and to determine the percentage binding of T3 and T4 to human plasma proteins.

Prodrugs of bisthiazolium salts are orally potent antimalarials.

We created neutral antimalarial prodrugs that deliver bisthiazolium compounds with antimalarial activity in the nanomolar range. These drugs primarily affect early intraerythrocytic stages through rapid, nonreversible cytotoxicity. The compounds are suitable for both parenteral and oral use and plasma promotes rapid conversion of the prodrug into the drug. We demonstrate that very low doses offer protection in a murine model of malaria. The drugs show great potential for curing high parasitemia with short-course treatments. Oral administration of the TE3 prodrug completely cures Plasmodium cynomolgi infection in rhesus monkeys. The drugs specifically accumulate inside infected erythrocytes, block phosphatidylcholine biosynthesis, and interact with hemozoin. To our knowledge, this class of compounds represents one of the most potent antimalarials tested to date. These unique properties signal a promising future for this class of antimalarial.