Around the world, researchers are working extremely hard to develop new treatments and interventions for COVID-19 with new clinical trials opening nearly every day. This directory provides you with information, including enrollment detail, about these trials. In some cases, researchers are able to offer expanded access (sometimes called compassionate use) to an investigational drug when a patient cannot participate in a clinical trial.
The information provided here is drawn from ClinicalTrials.gov. If you do not find a satisfactory expanded access program here, please search in our COVID Company Directory. Some companies consider expanded access requests for single patients, even if they do not show an active expanded access listing in this database. Please contact the company directly to explore the possibility of expanded access.
Emergency INDs
To learn how to apply for expanded access, please visit our Guides designed to walk healthcare providers, patients and/or caregivers through the process of applying for expanded access. Please note that given the situation with COVID-19 and the need to move as fast as possible, many physicians are requesting expanded access for emergency use. In these cases, FDA will authorize treatment by telephone and treatment can start immediately. For more details, consult FDA guidance. Emergency IND is the common route that patients are receiving convalescent plasma.
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Displaying 270 of 715Cardresearch
The COVID-19 pandemic has been characterized by high morbidity and mortality, especially in certain subgroups of patients. To date, no treatment has been shown to be effective in controlling this disease in hospitalized patients with moderate and / or severe cases of this disease. Hydroxychloroquine and lopinavir / ritonavir have been shown to inhibit SARS-CoV viral replication in experimental severe acute respiratory symptoms models and have similar activity against SARS-CoV2. Although widely used in studies of critically ill patients, to date, no study has demonstrated its role on the treatment of high-risk, newly diagnosed patients with COVID-19 and mild symptoms.
Dhaka Medical College
As of March 18, 2020, COVID-19 cases were reported in approximately 195 countries. No specific therapeutic agents or vaccines for COVID-19 are available. Several therapies, such as remdesivir and favipiravir, are under investigation, but the antiviral efficacy of these drugs is not yet known. The use of convalescent plasma (CP) was recommended as an empirical treatment during outbreaks of Ebola virus in 2014. A protocol for treatment of Middle East respiratory syndrome coronavirus (MERS-CoV) with CP was established in 2015. This approach with other viral infections such as SARS-CoV, H5N1 avian influenza, and H1N1 influenza also suggested that transfusion of CP was effective. In previous reports, most of the patients received the CP by single transfusion. In a study involving patients with pandemic influenza A(H1N1) 2009 virus infection, treatment of severe infection with CP (n = 20 patients) was associated with reduced respiratory tract viral load, serum cytokine response, and mortality. In another study involving 80 patients with SARS, the administration of CP was associated with a higher rate of hospital discharge at day 22 from symptom onset compared with patients who did not receive CP. Accordingly, these findings raise the hypothesis that use of CP transfusion could be beneficial in patients infected with SARS-CoV-2. The objective of this study is to describe the initial clinical experience with CP transfusion administered to severe COVID-19 patients. The primary endpoint of this trial would be to assess the tolerability, efficacy, and dose-response of CP in severe COVID-19 patients. The secondary endpoint would be to assess the clinical and laboratory parameters after therapy, in-hospital mortality, length of hospital stay, reduction in the proportion of deaths, length of ICU stay, requirement of ventilator and duration of ventilator support. All RT-PCR positive cases with features of severe infection will be enrolled in this study. Apheretic CP will be collected from a recovered patient (consecutive two RT-PCR samples negative) between day 22 to 35 days of recovery and those with the antibody titre above 1:320. This RCT will consist of three arms, a. standard care, b. standard care and 200 ml CP and c. standard care and 400 ml CP as a single transfusion. Twenty (20) patients will be enrolled for each arm. Randomization will be done by someone not associated with the care or assessment of the patients by means of a random number table. Allocations will be concealed in sequentially numbered, opaque, sealed envelopes. Clinical parameters [fever, cough, dyspnea, respiratory rate, PaO2/ FiO2 level, pulse, BP, the requirement of O2, and others] will be recorded before and after CP. Laboratory parameters such as complete blood count, CRP, chest X-ray, SGPT, SGOT, S. Ferritin, and serum antibody titre will be measured before and after transfusion. Allergic or serum sickness-like reactions will be noted and adjusted with outcome. Laboratory tests including RT-PCR will be done at BSMMU virology and laboratory medicine department. Apheretic plasma will be collected at the transfusion medicine department of SHNIBPS hospital, ELISA, antibody titre will be done at CMBT, and patients will be enrolled at DMC and MuMCH. All necessary screening tests will be done before transfusion. Graphpad Prism v 7.0 will be used for analysis. One way ANOVA test, a non-parametric Mann-Whitney test, and a Kruskal-Wallis test will be performed to compare the arms. For parametric outcomes, the investigators will compare the odds ratios across the pairs.
VistaGen Therapeutics, Inc.
This placebo-controlled clinical study is designed to evaluate the efficacy, safety and tolerability of administration of PH94B nasal spray four times per day as a treatment of Adjustment Disorder with Anxiety symptoms in adults. Subject participation in the Study will last a total of 6 to 10 weeks, depending on the duration of the screening period and whether they need a washout of concomitant anxiolytics. Upon signing an investigation review board approved informed consent, all subjects will complete Visit 1 (Screening) and enter a screening period lasting 7 to 35 days that could include taper of concomitant anxiolytics, if necessary. Screening visit will consist of safety assessments (medical history, physical examination, laboratory samples, electrocardiogram, urine drug screen, and urine pregnancy test [if appropriate]) and psychiatric assessments to determine eligibility. Subjects will then return to complete Visit 2 (Baseline). If the subject continues to meet inclusion and exclusion criteria, the subject will be randomized 1:1 to PH94B or placebo. Subjects will then commence 4 weeks of double-blind treatment with randomized investigational product (PH94B or placebo) four times per day. Subjects will return for weekly site visits (Visits 3, 4, 5, and 6), in which the subject will return the vial dispensed at the previous visit and receive a new vial, except at Visit 6 in which no new vial will be dispensed. Changes in AEs and concomitant medications will be collected. During these visits, psychiatric scales will be completed. When the subject returns for Visit 6, besides the assessments completed at Visits 3 through 5, the subjects will complete a brief physical examination, electrocardiogram, laboratory tests (chemistry and blood), and urinalysis. Any remaining IP vials will be collected. The subject will then come back after a one week washout period for Follow-up visit (Visit 7).
Bangladesh Medical Research Council (BMRC)
A recent outbreak of coronavirus disease 2019 (COVID-19) caused by the novel coronavirus designated as severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) started in Wuhan, China, at the end of 2019. The clinical characteristics of COVID-19 include respiratory symptoms, fever, cough, dyspnea, and pneumonia. As of 25 February 2020, at least 77 785 cases and 2666 deaths had been identified across China and in other countries; in particular, 977 and 861 cases were identified in South Korea and Japan, respectively. The outbreak has already caused global alarm. On 30 January 2020, the World Health Organization (WHO) declared that the outbreak of SARS-CoV-2 constituted a Public Health Emergency of International Concern (PHEIC), and issued advice in the form of temporary recommendations under the International Health Regulations (IHR).It has been revealed that SARS-CoV-2 has a genome sequence that is 75%-80% identical to that of SARS-CoV, and has more similarities to several bat coronaviruses. SARS-CoV-2 is the seventh reported human-infecting member of the family Coronaviridae, which also includes SARS-CoV and the Middle East respiratory syndrome (MERS)-CoV. It has been identified as the causative agent of COVID-19. Both the clinical and the epidemiological features of COVID-19 patients demonstrate that SARS-CoV-2 infection can lead to intensive care unit (ICU) admission and high mortality. About 16%-21% of people with the virus in China have become severely ill, with a 2%-3% mortality rate. However, there is no specific treatment against the new virus. Therefore, it is urgently necessary to identify effective antiviral agents to combat the disease and explore the clinical effect of antiviral drugs. One efficient approach to discover effective drugs is to test whether the existing antiviral drugs are effective in treating other related viral infections. Several drugs, such as ribavirin, interferon (IFN), Favipiravir (FPV), and Lopinavir (LPV)/ritonavir (RTV), have been used in patients with SARS or MERS, although the efficacy of some drugs remains controversial. It has recently been demonstrated that, as a prodrug, Favipiravir (half maximal effective concentration (EC50) = 61.88 μmol·L-1, half-maximal cytotoxic concentration (CC50) > 400 μmol·L-1, selectivity index (SI) > 6.46) effectively inhibits the SARS-CoV-2 infection in Vero E6 cells (ATCC-1586). Furthermore, other reports show that FPV is effective in protecting mice against Ebola virus challenge, although its EC50 value in Vero E6 cells was as high as 67 μmol·L-1. Therefore, clinical studies are urgently needed to evaluate the efficacy and safety of this antiviral nucleoside for COVID-19 treatment. After enrollment of the patients (day 1) depending on inclusion and exclusion criteria and laboratory findings confirming the presence of the COVID-19 virus, 25 patients will receive Favipiravir plus standard treatment and the second group of 25 patients will receive standard treatment only. The comparison of the findings of the follow up studies on days 4, 7, and 10 in terms of clinical manifestations, chest X-ray and laboratory findings, such as Real Time Polymerase Chain Reaction (RT-PCR) results for viral presence will determine whether Favipiravir has safety and efficacy against COVID-19 infections. All ethical issues related to this trial including right of the participants to withdraw from the study should be maintained according to of guidelines of International Conference on Harmonisation (ICH)-Good Clinical Practice (GCP).
JSS Medical Research Inc.
COVID-19 patients who develop severe disease often develop acute respiratory distress syndrome (ARDS) as a result of a dysregulated immune response. This in turn stimulates a pro-inflammatory cascade ("cytokine storm") as well as emergency myelopoiesis. This proinflammatory cascade is activated when viral-mediated cell damage occurs in the lungs, resulting in the release of damage-signaling alarmin molecules such as S100A8/A9 (Calprotectin), HMGB1, Resistin, and oxidized phospholipids. These damage-associated molecular patterns (DAMPs) are recognized by the pattern recognition receptor Toll-Like Receptor 4 (TLR4) found on macrophages, dendritic cells and other innate immune cells and result in additional release of pro-inflammatory molecules. Several recent studies have shown that S100A8/A9 serum levels in hospitalized COVID-19 patients positively correlate with both neutrophil count and disease severity. Taken together the DAMP-TLR4 interaction forms a central axis in the innate immune system and is a key driver of the pathological inflammation observed in COVID-19. We hypothesis that targeting the initial step in the signalling pathways of these DAMPs in innate immunity offers the best hope for controlling the exaggerated host response to SARS-CoV-2 infection. EB05 has demonstrated safety in two clinical studies (>120 patients) and was able to block LPS-induced (TLR4 agonist) IL-6 release in humans. Given, this extensive body of evidence we believe EB05 could ameliorate ARDS due to COVID-19, significantly reducing ventilation rates and mortality.
Hope Pharmaceuticals
This multicenter, randomized, double-blind, placebo-controlled clinical trial will evaluate the efficacy and safety of intravenous Sodium Nitrite Injection for treatment of patients infected with COVID-19 who develop lung injury and require mechanical ventilation.
Lomonosov Moscow State University Medical Research and Educational Center
Patients with mild and severe COVID 19 will be randomized 1:1 into two groups: experimental, which will get bromhexine and spironolactone, and control. Patients will get investigated therapy for ten days. Change in clinical assessment score COVID 19 (CAS COVID 19) between baseline and 12th day will be evaluated as a primary endpoint. Forty-five-day risk of death or mechanical ventilation will also be assessed.
Science, Technology & Innovation Funding Authority (STIFA), Egypt
A randomized controlled pilot study on the safety & efficacy of imatinib for the treatment of patient with moderate to severe SARS-COV-2 induced pneumonia.
University of Calgary
This is a cohort study of COVID-19 patients with hyperinflammation. It aims to determine the impact of adjunctive Tocilizumab (TCZ) to standard of care on the reduction of hyperinflammation-related mortality in COVID-19. Patients with COVID-19 are at high risk of life-threatening hyperinflammation and death. One in three COVID-19 patients admitted to ICU was found to develop life-threatening hyperinflammation. The risk of death when untreated is estimated to be 50-80%.
Assistance Publique Hopitaux De Marseille
COVID19-associated disease may have different clinical aspects classified in 3 stages. Some patients initially presenting with a non-hypoxemic viral pneumonia (stage 2a) may evolve toward a more severe stage 2b or 3 (acute respiratory distress syndrome, ARDS) around the 7th or 10th day of evolution, with a severe biological inflammatory syndrome (CRP>200 mg/l), and some times more severe complications such as acute renal insufficiency, consumptive coagulopathy or shock, requiring increasing oxygen therapy, ICU admission, invasive mechanical ventilation and possibly leading to death. This detrimental evolution is due to a host-derived "cytokine storm" with a great excess of circulating inflammatory cytokines. In animal models of ARDS complicating coronavirus or influenza virus infection, the cytokine storm has been linked to hyperactivation of the NLRP3 inflammasome. NLRP3 constitutes an intracellular protein platform which is responsible for caspase1 activation and processing of interleukin (IL)-1beta and IL-18 . IL-1b is a major proinflammatory cytokine which induces IL-6, whereas IL-18 is an inducer of interferon gamma (IFNg) production by Th-1 lymphocytes. A blood IL-1/IL-6 signature can be defined by increased neutrophilia and CRP concentrations, whereas an IL-18/IFNg signature is characterized by severe hyperferritinemia, consumptive coagulopathy and cytopenia. A majority of patients with COVID-19 infections seems to have an IL-1/IL-6 signature, evolving in the more severe forms toward an IL-18/IFNg signature, mimicking cytokine profiles observed in other inflammatory diseases such as Still's disease or hemophagocytic syndromes. In Still's disease, therapeutic inhibition of IL-1 or IL-6 has proven to be very efficient strategies. During hemophagocytic syndromes, inhibition of IFNg is effective in humans notably through blockade of its receptor signalization, using the JAK kinase inhibitor ruxolitinib. Following this strategy, we propose to use biological drugs currently available for inhibition of IL-1 (anakinra), IL-6 (tocilizumab) or IFNg signaling (ruxolitinib) in the severe forms of COVID19-associated disease. Our hypothesis is that IL-1, IL-6 or JAK kinase inhibition will allow: 1. to prevent stage 2b worsening and the need to be admitted in ICU, by decreasing oxygen-requirement and systemic inflammation 2. to improve stage 3 and extremely severe stage 3, allowing invasive mechanical ventilation weaning, improving multi-system organ dysfunction, leading to a faster ICU exit. We propose an open randomized therapeutic trial (1/1/1) on 216 patients with severe stage 2b and 3 of the disease