Clinical and Non-clinical Proof of Concept Supporting the Development of RJX As an Adjunct to Standard of Care Against Severe COVID-19 (preprint)

BackgroundThe identification of effective strategies capable of reducing the case mortality rate of high-risk COVID-19 is an urgent and unmet medical need. We recently reported the clinical safety profile of RJX, a well-defined intravenous GMP-grade pharmaceutical formulation of anti-oxidant and anti-inflammatory vitamins as active ingredients, in a Phase 1 study in healthy volunteers (ClinicalTrials.gov Identifier: NCT03680105) (Uckun et al., Front. Pharmacol. 11, 594321. 10.3389/fphar.2020.594321). Here we report data from a pilot clinical study (RPI-015) which examined the safety, tolerability, and feasibility of using RJX in combination with clinical standard of care (SOC) in hospitalized COVID-19 patients with pneumonia (ClinicalTrials.gov Identifier: NCT04708340). In addition to our early clinical proof of concept (POC) data, we also present non-clinical POC from a mouse model of CRS and ARDS that informed the design of the reported clinical study. Methods13 patients, who were hospitalized with COVID-19 pneumonia and abnormally elevated serum inflammatory biomarkers markers [≥]3 months prior to the identification of the first confirmed U.S case of the Omicron variant, were treated with IV RJX (daily x 7 days) plus SOC. Non-clinical POC study examined the ability of RJX plus dexamethasone (DEX) to improve the survival outcome in the lipopolysaccharide (LPS)-Galactosamine (GalN) mouse model of fatal cytokine release syndrome (CRS), sepsis and acute respiratory distress syndrome (ARDS). FindingsIn the Phase 1 clinical study, none of the 13 patients developed a treatment-related DLT, SAE, or Grade 3-5 AEs. Nine (9) of the 12 evaluable patients, including 3 patients with hypoxemic respiratory failure, showed rapid clinical recovery. In the non-clinical POC study in LPS-GalN challenged mice, the combination of RJX plus DEX was more effective than RJX alone or DEX alone, reversed the CRS as well as inflammatory tissue damage in the lungs and liver, and improved the survival outcome. Taken together, these findings provide the early clinical and non-clinical POC for the development of RJX as an adjunct to the SOC in the multi-modality management of high-risk COVID-19.

Rejuveinix Mitigates Sepsis-Associated Oxidative Stress in the Brain: Clinical Impact Potential in COVID-19 and Nervous System Disorders (preprint)

Here, we demonstrate that our anti-sepsis drug candidate Rejuveinix (RJX), at a dose level that is >10-times lower than its maximum tolerated dose (MTD) for human subjects, improves the survival outcome in the LPS-GalN model of sepsis and multi-organ failure. One hundred (100) percent (%) of untreated control mice remained alive throughout the experiment. By comparison, 100% of LPS-GalN injected mice died at a median of 4.6 hours. In contrast to the invariably fatal treatment outcome of vehicle-treated control mice, 40% of mice treated with RJX (n=25) remained alive with a 2.4-fold longer median time survival time of 10.9 hours (Log-rank X2=20.60, P<0.0001). Notably, RJX increased the tissue levels of antioxidant enzymes SOD, CAT, and GSH-Px, and it reduced oxidative stress in the brain. These findings demonstrate the clinical impact potential of RJX as a neuroprotective COVID-19 and sepsis drug candidate, which is currently being evaluated in a placebo-controlled, double-blind Phase II multi-institutional US study in hospitalized patients with COVID-19 associated viral sepsis.

Rejuveinix Mitigates Sepsis-Associated Oxidative Stress in the Brain of Mice: Clinical Impact Potential in COVID-19 and Nervous System Disorders (preprint)

Here, we demonstrate that our anti-sepsis and COVID-19 drug candidate Rejuveinix (RJX) substantially improves the survival outcome in the LPS-GalN animal model of sepsis and multi-organ failure. One hundred (100) percent (%) of untreated control mice remained alive throughout the experiment. By comparison, 100% of LPS-GalN injected mice died at a median of 4.6 hours. In contrast to the invariably fatal treatment outcome of vehicle-treated control mice, 40% of mice treated with RJX (n=25) remained alive with a 2.4-fold longer median time survival time of 10.9 hours (Log-rank X2=20.60, P<0.0001). Notably, RJX increased the tissue levels of antioxidant enzymes SOD, CAT, and GSH-Px, and reduced oxidative stress in the brain. These findings demonstrate the clinical impact potential of RJX as a neuroprotective COVID-19 and sepsis drug candidate.

Hydroxyzine inhibits SARS-CoV-2 Spike protein binding to ACE2 in a qualitative in vitro assay (preprint)

COVID-19 currently represents a major public health problem. Multiple efforts are being performed to control this disease. Vaccinations are already in progress. However, no effective treatments have been found so far. The disease is caused by the SARS-CoV-2 coronavirus that through the Spike protein interacts with its cell surface receptor ACE2 to enter into the host cells. Therefore, compounds able to block this interaction may help to stop disease progression. In this study, we have analyzed the effect of compounds reported to interact and modify the activity of ACE2 on the binding of the Spike protein. Among the compounds tested, we found that hydroxyzine could inhibit the binding of the receptor-binding domain of Spike protein to ACE2 in a qualitative in vitro assay. This finding supports the reported clinical data showing the benefits of hydroxyzine on COVID-19 patients, raising the need for further investigation into its effectiveness in the treatment of COVID-19 given its well-characterized medical properties and affordable cost.