View clinical trials related to Cytokine Release Syndrome.
Filter by:COVID-19 pandemic has spread all over the world, and hospitalization of the patients with COVÄ°D-19 Pneumonia has become a great burden to the Intensive Care Units. Unfortunately there is still no curative method for the disease yet. Intensive Care Units provide general care for the patients; including oxygen therapy, maintenance of the organ systems (e.g., cardiovascular, renal), nutrition, antibiotic therapy for secondary infections, and etc. One of the major problems in COVID-19 is macrophage activation syndrome, also known as cytokine storm. It stems from exaggerated inflammatory response, which causes increased cytokine release and results in clinical deterioration of the patients. Many drugs have been used to prevent this exaggerated inflammation, like corticosteroids, interleukin (IL) receptor blockers, plasma exchange, etc. In this study our aim is to investigate the effectiveness of high dose corticosteroid (methylprednisolone 250 mg for 3 days) and an IL-6 receptor antagonist (tocilizumab) in the treatment of the cytokine storm of the COVID-19 patients.
The purpose of this study is to assess the safety and efficacy of repurposing tazemetostat for the treatment of Acute Respiratory Distress Syndrome (ARDS) or Systemic Cytokine Release Syndrome (SCRS) in COVID-19 patients.
The clinical syndrome associated with infection of the Coronavirus Disease 2019 (COVID-19) is notable for its variable clinical expression. Infection and transmission of the virus by asymptomatic individuals have been noted and represent one end of the clinical spectrum, while multi-organ failure, particularly pulmonary failure, and death represent the most severe end of the clinical spectrum. In a recent study published from the investigator's institution about the first 393 patients with COVID-19, 77.1% had a fever, a mechanism driven by IL-1. This suggests that there may be an excess release of IL-1 present. Cytokine storm syndrome (CSS) has been observed in patients with COVID-19 and has been proposed to contribute to the acute pulmonary failure that occurs. In distinct clinical settings, macrophage activation syndrome, elevated levels of pro-inflammatory cytokines, including IL-1, IL-6, and others, as well as elevations in laboratory indicators, including ferritin, CRP, d-dimer, and lymphopenia, have been observed. IL-1 production is induced in response to inflammatory stimuli and mediates various physiologic responses including inflammatory and immunological responses. Anakinra, a recombinant IL-1 receptor antagonist, has shown promise in treating CSS. It inhibits both IL-1-alpha and IL-1-beta. It is an FDA approved medication used in rheumatoid arthritis (RA) and Cryopyrin-Associated Periodic Syndromes (CAPS). Anakinra's ability to inhibit both IL-1 subtypes and short half-life makes it favorable to some experts. In the investigator's case-series, using anakinra in patients with COVID-19 showed promising in preventing the need for mechanical ventilation, and mortality subsequently. This study will determine the efficacy of anakinra, an interleukin (IL) -1 receptor blocker, in reducing the need for mechanical ventilation and/or 28-day mortality among patients with COVID-19 who have features of CSS and severe respiratory failure. The investigators will test the hypothesis that the proportion of subjects with COVID-19, features of CSS, and severe respiratory failure (World Health Organization (WHO) category 4 or 5) alive and without having required mechanical ventilation at day 28 from randomization will be 18% higher among those that receive anakinra compared to those that receive a placebo. A secondary hypothesis is that the number of subjects alive at 60-days will be higher amongst those who receive anakinra compared to those who receive a placebo.
COVID-19 is an infectious disease caused by severe acute respiratory syndrome coronavirus 2. COVID-19 causes life threatening complications known as Cytokine Release Syndrome or Cytokine Storm and Acute Respiratory Distress Syndrome. These complications are the main causes of death in this global pandemic. Over 1000 clinical trials are on-going worldwide to diagnose, treat, and improve the aggressive clinical course of COVID-19. The investigators propose the first, and so far, only gene therapy solution that has the potential to address this urgent unmet medical need. Rationale 1. There are striking similarities between the damaged lung environment of COVID-19 induced ARDS and the tumor microenvironment (exposed collagen from tissue destruction by invading tumor or by the virus-induced immune response, and presence of activated proliferative cells (cancer cells and tumor associated fibroblasts or activated T cells, macrophages and pulmonary fibroblasts in COVID-19); 2. DeltaRex-G is a disease-seeking retrovector encoding a cytocidal dominant negative human cyclin G1 as genetic payload). When injected intravenously, the DeltaRex-G nanoparticles has a navigational system that targets exposed collagenous proteins (XC proteins) in injured tissues (e.g. inflamed lung, kidney, etc.), thus increasing the effective drug concentration at the sites of injury, in the vicinity of activated/proliferative T cells evoked by COVID-19. Our hypothesis is that DeltaRex-G then enters the rapidly dividing T cells and kills them by arresting the G1cell division cycle, hence, reducing cytokine release and ARDS; 3. Intravenous DeltaRex-G has minimal systemic toxicity due to its navigational system (targeting properties) that limits the biodistribution of DeltaRex-G only to areas of injury where exposed collagenous (XC) proteins are abnormally found; and 4. DeltaRex-G is currently available in FDA approved "Right to Try" or Expanded Access Program for Stage 4 cancers for an intermediate size population. To gain this approval, FDA requires DeltaRex-G to have demonstrated safety and efficacy in early clinical trials.
This study seeks to determine the efficacy of tocilizumab (TCZ) in patients with hemophagocytic lymphohistiocytosis (HLH) and high cytokine levels (proteins involved in inflammation) in an attempt to decrease the damage caused by these proteins; and secondarily to assess its safety and impact on disease activity.