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Purpose In this study, the drug-drug interaction potential of vatiquinone with cytochrome P450 (CYP) substrates was investigated in both in vitro and clinical studies.MethodsThe inhibitory potential of vatiquinone on the activity of CYPs 1A2, 2B6, 2C8, 2C9, 2C19, 2D6, and 3A4/5 was assessed in vitro. In an open-label, drug-drug interaction study in 18 healthy human subjects, a single oral dose of 500 mg tolbutamide and 40 mg omeprazole was administered on day 1, followed by a washout of 7 days. Multiple oral doses of 400 mg vatiquinone (three times a day [TID]) were administered from day 8 to day 13 with coadministration of a single oral dose of 500 mg tolbutamide and 40 mg omeprazole on day 12.ResultsIn vitro, vatiquinone inhibited CYP2C9 (IC50 = 3.7 µM) and CYP2C19 (IC50 = 5.4 µM). In the clinical study, coadministration of vatiquinone did not affect the pharmacokinetic (PK) profile of tolbutamide and omeprazole. The 90% confidence intervals (CIs) of geometric least-square mean ratios for maximum plasma concentration (Cmax), areas under the plasma concentration–time curve (AUC0-t), and AUC0-inf of tolbutamide and omeprazole were entirely contained within the 80 to 125% no effect limit, except a minor excursion observed for Cmax of omeprazole (geometric mean ratio [GMR], 94.09; 90% CI, 78.70–112.50). Vatiquinone was generally well tolerated, and no clinically significant findings were reported.ConclusionThe in vitro and clinical studies demonstrated vatiquinone has a low potential to affect the pharmacokinetics of concomitantly administered medications that are metabolized by CYP enzymes.

Quinones can in principle be viewed as a double-edged sword in the treatment of neurodegenerative diseases, since they are often cytoprotective but can also be cytotoxic due to covalent and redox modification of biomolecules. Nevertheless, low doses of moderately electrophilic quinones are generally cytoprotective, mainly due to their ability to activate the Keap1/Nrf2 pathway and thus induce the expression of detoxifying enzymes. Some natural quinones have relevant roles in important physiological processes. One of them is coenzyme Q10, which takes part in the oxidative phosphorylation processes involved in cell energy production, as a proton and electron carrier in the mitochondrial respiratory chain, and shows neuroprotective effects relevant to Alzheimer’s and Parkinson’s diseases. Additional neuroprotective quinones that can be regarded as coenzyme Q10 analogues are idobenone, mitoquinone and plastoquinone. Other endogenous quinones with neuroprotective activities include tocopherol-derived quinones, most notably vatiquinone, and vitamin K. A final group of non-endogenous quinones with neuroprotective activity is discussed, comprising embelin, APX-3330, cannabinoid-derived quinones, asterriquinones and other indolylquinones, pyrroloquinolinequinone and its analogues, geldanamycin and its analogues, rifampicin quinone, memoquin and a number of hybrid structures combining quinones with amino acids, cholinesterase inhibitors and non-steroidal anti-inflammatory drugs.

Background Genetic mitochondrial diseases are a major challenge in modern medicine. These impact ~ 1:4,000 individuals and there are currently no effective therapies. Leigh syndrome is the most common pediatric presentation of mitochondrial disease. In humans, patients are often treated with antioxidants, vitamins, and strategies targeting energetics. The vitamin-E related compound vatiquinone (EPI-743, α-tocotrienol quinone) has been the subject of at least 19 clinical trials in the US since 2012, but the effects of vatiquinone on an animal model of mitochondrial disease have not yet been reported. Here, assessed the impact of vatiquinone in cellular assays and animal models of mitochondrial disease. Methods The efficacy of vatiquinone in vitro was assessed using human fibroblasts and HEK293 cells treated with the ferroptosis inducers RSL3 and BSO + Fe(III)Citrate, the mitochondrial oxidative stress inducer paraquat, and the electron transport chain complex I inhibitor rotenone. The therapeutic potential of vatiquinone in vivo was assessed using the tamoxifen-induced mouse model for GPX4 deficiency and the Ndufs4 knockout mouse model of Leigh syndrome. Results Vatiquinone robustly prevented death in cultured cells induced by RSL3 or BSO/iron, but had no effect on paraquat induced cell death. Vatiquinone had no impact on disease onset, progression, or survival in either the tamoxifen-inducible GPX4 deficient model or the Ndufs4 (-/-) mouse model, though the drug may have reduced seizure risk. Conclusions Vatiquinone prevents ferroptosis, but fails to attenuate cell death induced by paraquat or rotenone and provided no significant benefit to survival in two mouse models of disease. Vatiquinone may prevent seizures in the Ndufs4 (-/-) model. Our findings are consistent with recent press statements regarding clinical trial results and have implications for drug trial design and reporting in patients with rare diseases.

Introduction: Vatiquinone is a first-in-class, small molecule designed to maintain mitochondrial function in the disorders like Friedreich’s ataxia (FA). Vatiquinone inhibits 15-lipoxygenase, consequently decreasing oxidative stress and neuroinflammatory response pathways. Methods: Population pharmacokinetic modeling analysis was conducted to characterize vatiquinone pharmacokinetic profiles in healthy volunteers and patients and explore the effects of covariates on vatiquinone exposures. Results: A two-compartment model with parallel zero- and first-order absorption was developed and verified. The values of essential parameters were: absorption fraction through the first-order process, 74.4%; absorption rate constant, 0.20 h−1; delay time, 2.79 h; zero-order absorption duration, 6.03 h; apparent volume of distribution, 180.75 L for the central and 4852.69 L for the peripheral compartment; and apparent clearance, 162.72 L/h. Strong CYP3A4 inducers could reduce exposure by 50%; strong CYP3A4 inhibitors could increase it by 252%. Vatiquinone exposure was 19% lower in patients with Friedreich’s ataxia versus healthy volunteers. A medium-fat meal increased exposure up to 25-fold versus a fasted status. Body weight and body mass index had significant clinical relevance to exposures. Conclusions: A two-compartment model effectively described the pharmacokinetic profiles of vatiquinone after oral administration. Covariates significantly impacted exposures, including body weight, meals, disease status, comedications and body mass index.

Short-chain quinones have been investigated as therapeutic molecules due to their ability to modulate cellular redox reactions, mitochondrial electron transfer and oxidative stress, which are pathologically altered in many mitochondrial and neuromuscular disorders. Recently, we and others described that certain short-chain quinones are able to bypass a deficiency in complex I by shuttling electrons directly from the cytoplasm to complex III of the mitochondrial respiratory chain to produce ATP. Although this energy rescue activity is highly interesting for the therapy of disorders associated with complex I dysfunction, no structure-activity-relationship has been reported for short-chain quinones so far. Using a panel of 70 quinones, we observed that the capacity for this cellular energy rescue as well as their effect on lipid peroxidation was influenced more by the physicochemical properties (in particular logD) of the whole molecule than the quinone moiety itself. Thus, the observed correlations allow us to explain the differential biological activities and therapeutic potential of short-chain quinones for the therapy of disorders associated with mitochondrial complex I dysfunction and/or oxidative stress.