View clinical trials related to Covid19.
Filter by:SARS-CoV-2 infection induces a hyperinflammatory syndrome, causing the acute respiratory distress syndrome, massive lung cell destruction and, as a plausible sequelae, pulmonary fibrosis in COVID-19 patients. Current focus has been on the development of novel immunosuppressant therapies, in order to control the cytokine storm in COVID-19 patients. Thus, the effect of steroids, intravenous immunoglobulin, non-steroidal immunosuppressants, selective cytokine blockade, JAK/STAT pathway inbhibition, and mesenchymal precursor cells have been evaluated. Based on the above information, we propose COLLAGEN-POLYVINYLPYRROLIDONE (Distinctive name: FibroquelMR, active substance: Collagen-polyvinylpyrrolidone, pharmaceutical form: intramuscular injectable solution, with sanitary registration No. 201M95 SSA IV and SSA code: 010 000 3999) as a potential drug for the downregulation of the cytokine storm. Polymerized type I collagen reduces the expression of IL-1β, IL-8, TNF-alpha, TGF-β1, IL-17, Cox-1, leukocyte adhesion molecules (ELAM-1, VCAM- 1 and ICAM-1), some other mediators of inflammation and increases the levels of IL-10 and the number of regulatory T cells. In addition, it promotes the mechanisms of inhibition of tissue fibrosis, without adverse effects in rheumatoid arthritis and osteoarthritis.
A prospective, randomized, placebo-controlled, double-blinded, phase III clinical trial of the therapeutic use of convalescent plasma in the treatment of patients with moderate to severe COVID-19
Keeping in mind the rising number of cases in Egypt and the strain they put on hospital infrastructure, the idea of home isolation and follow up for COVID 19 positive cases has been adopted in many countries and was approved by World Health Organization (WHO) and Egyptian Ministry of health (MOH). Telehealth can help to mitigate this risk by minimizing the amount of face-to-face interactions. The WHO mentioned telemedicine among essential services in "strengthening the Health Systems Response to COVID-19" policy. The aim in this study is to study the effectiveness of telemedicine in managing mild COVID cases regarding isolation measures, symptoms, medications adherence, and reporting of red flags and side effects.
This study proposes to evaluate the therapeutic efficacy, immunologic effects and normalization of laboratory parameters for patients at high risk for mortality when infected by SARS-CoV-2 (COVID-19) when administered one unit (approximately 200 mL) of convalescent plasma administered over a period of one hour. Following administration of the convalescent plasma, physical exam/clinical assessment information is collected daily and routine lab result data is collected every three days.
Since initial reports of a novel coronavirus emerged from Hubei province, China, the world has been engulfed by a pandemic with over 3 million cases and 225,000 deaths by 30th April 2020. Health care systems around the world have struggled to cope with the number of patients presenting with COVID-19 (the disease caused by the SARS-CoV-2 virus). Although the majority of people infected with the virus have a mild disease, around 20% experience a more severe illness leading to hospital admission and sometimes require treatment in intensive care. People that survive severe COVID-19 are likely to have persistent health problems that would benefit from rehabilitation. Pulmonary rehabilitation (PR) is a multidisciplinary program which is designed to improve physical and social performance and is typically provided for people with chronic lung conditions. PR courses typically last 6-12 weeks with patients attending classes once or twice weekly and consist of exercise and education components. PR is known to improve symptoms (e.g. breathlessness), quality of life and ability to exercise in those with lung conditions. Breathlessness is a very common symptom reported by people presenting to hospital with COVID-19 and loss of physical fitness will be very common. Using existing pulmonary rehabilitation programmes as a model, we have developed a tele-rehabilitation programme (a programme that will be delivered using video link to overcome the challenges faced by social distancing and shielding advice) for people that have been critically ill with COVID-19. In order to prove whether people benefit from this tele-rehabilitation programme after being admitted to hospital following COVID-19 we would need to perform a large clinical trial. However, before doing this it is important for us to answer some key questions: - How many people that have been admitted to hospital and needed intensive care treatment for COVID-19 still report breathlessness, fatigue, cough and limitation of activities after being discharged from hospital? - Is it possible to recruit these people to a trial of tele-rehabilitation after hospital discharge? - Are people willing and able to perform tele-rehabilitation in their own home using video-link to connect with their therapist? - Are there other rehabilitation needs that are commonly encountered by people requiring intensive care treatment for COVID-19 that could be addressed by tele-rehabilitation that the programme doesn't currently address? Investigators will perform a small study called a feasibility trial to answer these questions and gather some early information about possible benefits of tele-rehabilitation. Based on our understanding of other similar diseases, doctors and therapists think that people will benefit from rehabilitation after COVID-19. The investigators therefore want to test a trial design that makes sure that everyone gets the treatment. This type of trial is called a feasibility, wait-list design randomised controlled trial. People with breathlessness and some limitation of activities will be selected at random to receive tele-rehabilitation within 2 weeks or to wait 6-8 weeks before starting. how many people were eligible to take part, how many agreed to take part and the symptoms and rehabilitation needs that they have will be assessed. Investigators will then monitor symptoms and ability to exercise at the start and end of the trial and before and after tele-rehabilitation.
The investigators present a randomised open label phase Ib/IIa trial of nebulised unfractionated heparin to evaluate the effect of nebulised unfractionated heparin on the procoagulant response in ICU patients with SARS-CoV-2 requiring advanced respiratory support. As this is one of the first studies of nebulised heparin in COVID 19 lung disease the investigators will assess safety as a co-primary outcome.
Viral respiratory infections are common infectious complications after kidney transplantation, especially in the pediatric age group, and immunosuppressed patients may develop more severe disease. Immunosuppressive medications alter the patient's immune response by acting on humoral, cellular immunity and neutrophil function, increasing the risk of serious viral infections. Little is known about how these patients respond to infection by the new coronavirus (SARS-CoV-2). Experience with SARS caused by the Influenza H1N1 virus suggests that the severity of the disease depends on pre-existing comorbidities and the individual immune response. In more severe cases, an imbalance between the inflammatory system and the immune system is observed, determining direct consequences when pro and anti-inflammatory cytokines reach the systemic circulation in an exacerbated and unbalanced manner. Such fact can generate "cytokine storm syndrome", resulting in multiple organ dysfunction syndrome. March 2020 reports from Papa Giovanni XXIII Hospital in Bergamo, Italy - one of the largest pediatric liver transplant centers - showed that the number of transplant patients infected with Coronavirus disease 2019 (COVID- 19) increased progressively. However, they did not see greater severity and complications in this population. Immunosuppression could act as a protective factor. The present study aims to describe the prevalence of viral infection by SARS-CoV-2 in a sample of immunosuppressed children, from three groups: kidney transplants, liver transplants and oncohematological. The investigators will also look for the epidemiological profile and clinical evolution of these patients, enabling a better understanding of the COVID-19 in this special population. The investigators' hypothesis is that infection with the new coronavirus may be asymptomatic in a large number of children and that immunosuppression, observed in liver and kidney transplant patients and also seen in cancer patients, may act as protection for severe forms of COVID-19. After obtaining written informed consent from the family, the investigators will include patients from 0-18 years of age, on regular outpatient follow-up, symptomatic or not, and will check for the presence of IgM/IgG antibodies against the SARS-CoV-2. For those symptomatic or with a positive IgM result, material (oro/nasopharyngeal swabs) for RT-PCR trial for the new coronavirus will be collected. Demographic and clinical variables will be registered. The outcomes are: Serology for COVID-19 result; PCR for COVID-19 result; presence of symptoms of COVID-19; proportion of patients with viral shedding on days 3,7,14,21 and 30 after diagnosis; need for hospital admission; need for Intensive care admission; death.
The coronavirus (COVID-19) pandemic continues to grow exponentially. Angiotensin II levels are increased in human influenza and are associated with influenza viral load, disease progression and mortality. Preliminary data shows angiotensin II receptor blockers (ARBs) limits lung injury in murine influenza H7N9, as well as viral titre and RNA. ARBs could limit viral titre and organ injury in COVID-19. We will therefore collect clinical chart data and test angiotensin II levels of patients who are admitted to ICU with COVID-19 to determine whether there is a correlation between taking ARBs and clinical outcomes in these patients. Other blood biomarkers and clinical risk factors for COVID-19 have come to light in recent weeks. We include these in our observational analysis to help generate an understanding of COVID-19 presentation and blood biomarker characterization of disease.
Dogs are some of nature's greatest detectives, owing to their incredible sense of smell and ability to be trained. Most of us will be familiar with seeing trained sniffer dogs at airports looking for drugs and other prohibited items, but their skills don't stop there. The use of medical detection dogs is becoming increasingly common, as they are able to identify cancers, changes in blood sugar levels and even predict seizures. These are just a few examples of dogs playing a key role in public health. Many diseases can alter the way humans smell. A study undertaken by the London School of Hygiene & Tropical Medicine (LSHTM) and Durham University has shown that dogs are able to accurately diagnose malaria. The investigators know that respiratory illnesses can alter your body odours, and thus the investigators plan to determine whether dogs are able to identify the novel coronavirus known as COVID-19 (or SARS-CoV-2). COVID-19 can present itself asymptomatically (i.e. causing no apparent symptoms), which could lead to the spread of infection in the population. The investigators believe that dogs may be able to identify asymptomatic patients, as well as those who have mild symptoms (symptoms not requiring treatment, hospital stay or limiting normal activities). It is thought that a single medical detection dog stationed within an airport would be able to screen up to 750 people for COVID-19 infection in just 1 hour, informing those who are infected to isolate, preventing further spread of the disease. In order to determine whether it is possible for dogs to accurately diagnose COVID-19, the investigators must first collect samples. NHS staff and members of their households that are eligible for SARS-CoV-2 screening, have been selected to participate in this study due to their potential exposure to this disease agent. In addition, participants from the general population who are displaying mild COVID-19 symptoms or have been exposed to COVID-19 will be recruited via hospitals, testing centers, outbreak testing programs and home testing programs. Initially, participants will attend their screening test as planned or confirm that they have had a swab test within the previous 24 hours. Immediately following this, the investigators will ask participants to collect samples of breath odour and body odour, which will be collected passively through the wearing of face masks, shirts, and nylon socks. The investigators will ask to be provided with the results of the SARS-CoV-2 screening swab, which will allow for us to determine whether participants are positive or negative for SARS-CoV-2. These odour samples will be grouped by positive or negative test results, and transported to LSHTM where these will be processed in order to prevent contact with the virus, negating the risk for dogs and their handlers. A pilot study will be undertaken to confirm whether dogs are able to distinguish between positive and negative samples using traditional sniffer dog training methods. If this is possible, the investigators will proceed to the main study to determine the accuracy (known as sensitivity and specificity) of the dogs' ability to identify the virus. Both the handler and the dogs themselves will be 'blinded' to the samples, and thus unaware of which sample is which. When the data generated by these tests is entered, it will be confirmed whether or not the samples have been correctly identified. The dogs will be trained to detect and report the detection of the volatile odours characteristic of COVID-19 infection. For quality control purposes the investigators also aim to characterise the COVID-19 odour profile by analysing samples with a special process called GC (gas chromatography) and/or GC-MS (gas chromatography coupled mass spectrometry). This will help to inform the identification of compounds showing differences between infected and non-infected samples. The investigators believe that this work could be useful in the fight against COVID-19.
The McMaster Multi-Regional Hospital Coronavirus Registry (COREG) is a platform that is collecting detailed case data on laboratory confirmed COVID-19 hospital inpatients and outpatients. The COREG platform will provide rapid high-quality evidence to improve the prevention and clinical management of COVID-19 for older adults in Canada, and internationally. The COREG platform will also provide researchers and partners with complete regional level clinical data on COVID-19 cases to inform rapid decision-making and projections, sub-studies, extensions, and linkage for all affected populations.