COVID-19 Clinical Trials and Expanded Access

SNG001 is an inhaled drug that contains a antiviral protein called interferon beta (IFN-β). IFN-β in produced in the lungs during viral lung infections. It has been shown that older people and people with some chronic diseases have an IFN-β deficiency. Many viruses inhibit IFN-β as part of their strategy to evade the immune system. Addition of IFN-β in vitro protects lung cells from viral infection. IFN-β protects cells against the MERS and SARS coronaviruses (close relatives of SARS-CoV-2, the virus that causes COVID-19). SNG001 is an inhaled formulation of interferon beta-1a it is currently in Phase II clinical trials for COPD patients. Synairgen has conducted randomised placebo controlled clinical trials of SNG001 involving >200 asthma and COPD patients. These trials have shown that SNG001 has: - been well tolerated during virus infections - enhanced antiviral activity in the lungs (measured in sputum and blood samples) - provided significant lung function benefit over placebo in asthma in two Phase II trials. Synairgen believes SNG001 could help prevent worsening or accelerate recovery of severe lower respiratory tract illness in COVID-19 patients. Patients who are in hospital or non-hospitalised but are a high risk groups (e.g. elderly or diabetics) will be invited to take part in the trial. The patient would receive either SNG001 or placebo once daily for 14 days. The severity of the patients condition would be recorded on a scale developed by the World Health Organisation and the patient would be asked questions about their breathlessness, cough and sputum every day, as well as assess their general medical condition and safety. The study will start as a Pilot phase where 100 patients will be randomised in the hospital setting and a 120 patients randomised in the home setting. Once each of the Pilot phases are complete, a Pivotal phase will be conducted. It is estimated that the size of each of the Pivotal phases (hospital and home) will be around 100 to 300 patients per arm. The actual number will be determined after the data review at the end of each of the Pilot phases. If SNG001 proves to be beneficial it would be a major breakthrough for the treatment of COVID-19.

Pilot study of tolerability and efficacy of transfusion of 200mL of convalescent plasma in patients with COVID-19 respiratory disease.

The purpose of this study is to identify healthcare workers with SARS CoV 2 antibodies who have not been previously diagnosed and are presumed COVID-19 negative, then determine the level of immunity in this population which could inform further decisions about widespread antibody testing in a healthcare worker population.

The vital signs are critical in assessing the severity and prognosis of infections, such as Covid-19. The devices used today for measuring the vital signs have to be in physical contact with the patients. There is an apparent risk of transferring infections from one patient to the next (or to healthcare professionals). This project aims to evaluate a new camera-based system for contactless measurement of vital signs as well as an artificial intelligence (AI) predicting hospitalization or death within 30 days. This particular study will evaluate the new system's ability without interfering with standard care of the patient.

Background: People who have had contact with a person with a known SARS-CoV-2 infection are being told to self-quarantine for 14 days. This is done to avoid potential virus spread. But the actual time it takes for a person to develop an infection after being exposed to the virus is not well known. The proper quarantine time could be less or more than 2 weeks. Researchers hope this study can be used to help improve public health guidelines for quarantines, social distancing, and returning to work after a possible SARS-CoV-2 exposure. Objective: To better understand how long it takes a person to develop (or not develop) an infection with the SARS-CoV-2 virus after they have had contact with a person who has a confirmed infection. Eligibility: NIH staff members age 18 and older who had recent contact with a person who has a SARS-CoV-2 infection Design: Participants will have 3 study visits at the NIH Clinical Center. They may be asked to have an extra visit depending on the test results at the third visit. At each visit, participants will give a blood and saliva sample. It will be used to test for SARS-CoV-2 antibodies. Their temperature will be taken. They will complete a short survey to collect data about possible COVID-19 symptoms. At the first visit only, they will also complete a survey that asks about their recent social contacts. Two types of nasal samples will be collected at each visit. These samples will be tested for the SARS-CoV-2 virus. 1. a swab will be inserted deep into the back of the nose and 2. a swab will be inserted to the middle of your nose. Participation lasts 3 to 4 weeks.

The general aim of this study is to estimate the rate of disease progression for adults testing positive for SARS-CoV-2. The primary endpoint for this study and the basis for sample size is hospitalization or death during the 28 day follow-up period. In some locations special facilities are being built/utilized for quarantine/public health reasons for those who are SARS-CoV-2 positive. Hospitalization is defined as a stay for at least 18 hours, irrespective of reason, at a hospital or one of these special facilities after study enrollment. Secondary outcomes include participant-reported health status and change in severity of dyspnoea.

A multicenter randomized, double-blind, placebo-controlled clinical trial of Convalescent SARS COVID-19 plasma versus Placebo to evaluate the effect between arms on an ordinal score of six mutually exclusive categories of clinical status at day 30 after study initiation.

As of March 25, 2020, 414,179 cases and 18,440 deaths secondary to Coronavirus 2019 disease (COVID-19) have been reported worldwide. The unfavorable course of the patients is characterized on the immunological level by an intense pro-inflammatory response which can go as far as a cytokinic storm. This pandemic affects a naive world population from an immunological point of view with respect to SARS-CoV-2 responsible for COVID-19. The evolution is favorable without hospitalization in almost 85% of cases. Among patients hospitalized for pneumonia, some will not require ventilatory support while others will need intensive care. To date, two main types of unfavorable evolution have been described. The first is a bi-phasic evolution beginning with a paucisymptomatic form which is worsened secondarily with respiratory distress associated with a decrease in the viral load in the airways. The second is associated with persistent high viral loads in the airways and detection of the virus in the blood. These different clinical profiles could depend on the quantitative and qualitative response of the innate immune system. At the early stage of a viral infection the innate immunity is capable of detecting certain conserved microbial patterns (PAMP, pathogen-associated molecular pattern) recognized by receptors dedicated to these patterns (PRR, pattern recognition receptor). This process allows to initiate the pro-inflammatory response via different signaling pathways. Activating multiprotein complexes called inflammasomes, which cause pro-IL-1β and pro-IL-18 to be transformed into active pro-inflammatory cytokines are one of these pathways. The central role of inflammasomes in the secretion of these pro-inflammatory cytokines deserves an in-depth study of their activation during COVID-19, whereas the inadequate inflammatory response appears to be the determining factor in the unfavorable development of patients. The objective of this project is to analyze the level of activation of the inflammasomes and then to search for inactivating or activating mutations among the genes which code for the proteins constituting the inflammasomes in Covid-19 patients. The identification of mutations in patients with a serious clinical presentation or even death would be followed by fundamental work by analyzing in a cellular model the impact of these mutations on the secretion of IL-1β.

The emergence and rapid spread of the coronavirus disease 2019 (COVID-19) since December 2019 across 188 countries globally has become a major public health crisis. COVID-19 was declared a pandemic by the World Health Organisation (WHO) on the 11th March 2020. To date, more than 14,000,000 cases and 600,000 deaths have been reported. COVID-19 is an acute respiratory disease caused by the novel SARS-CoV-2 virus from the Betacoronavirus genus, just like SARS-CoV and MERS-CoV. SARS-CoV-2 is primarily transmitted person-to-person through respiratory droplets or close contact. Fomite transmission has also been implicated as a transmission route. Common respiratory symptoms such as fever, sore throat, cough and shortness of breath, may appear 2 - 14 days after exposure. About 20% of infected cases progress to severe disease resulting in an estimated 2 - 5% mortality reported. With the unrelenting increase in cases being reported worldwide, there is thus an urgent need for therapeutics to be developed and used to disrupt the ongoing pandemic. To date, there is no specific proven antiviral treatment for COVID-19. Supportive care is recommended for symptom relief and for severe cases, organ support is critical for optimal outcome. Numerous vaccine candidates against SARS-CoV-2 are under development and a couple have entered Phase 1 clinical trials. Remdesivir, a nucleotide analog, developed by Gilead Sciences as a treatment for Ebola virus disease is currently being repurposed and undergoing multiple clinical trials to evaluate safety and efficacy in COVID-19 patients. In a preliminary study, convalescent plasma containing neutralizing antibodies against SARS-CoV-2 has also been experimentally administered in critically ill COVID-19 patients with promising results. Donor plasma used was rich in virus specific IgG and IgM antibodies as determined by ELISA. Within days of convalescent plasma treatment, patients showed decrease in viral load (via qRT-PCR), as well as improved clinical status being observed. Tychan's TY027 will be the first biologics in the world, specifically targeting SARS-CoV-2, to enter human clinical trials. It is anticipated that a SARS-COV-2 specific monoclonal antibody therapeutic administered to acutely infected patients could reduce disease severity as well as prevent transmission by reducing viral load and viral shedding. It could also be used as prophylaxis against COVID-19 amongst high risk contacts.

This is a randomized, double-blind, placebo-controlled, in which one dose of nangibotide will be tested versus placebo. All patients with a diagnosis of COVID-19, and a requirement for respiratory support will be considered for study participation. The applicable local requirements for informed consent will be followed. Where permissible, an emergency consent procedure will be followed for patients unable to provide consent by themselves. All potential study patients will receive standard of care treatment throughout the study. Patients will receive a continuous intravenous (i.v.) infusion of nangibotide at 1.0 mg/kg/h or a matching placebo. Treatment with study drug must be initiated as early as possible but no later than 48 hours after the initiation of ventilatory support (Patients will be treated for 5 days or until discharge from critical care, whichever is sooner). Follow-up visits will be performed on days 8 and 14. The end of study visit is at day 28. A further follow up visit will be undertaken on day 60.