Obesity, COVID-19 Infection Clinical Trial
— NIVISCOOfficial title:
Study of the Efficiency and Security of NIVOLUMAB Therapy, Used in Immuno-stimulation, in Hospitalized Obese Individuals at Risk to Evolve Towards Severe Forms of COVID-19 Infection. Multicentric, Paralleled, Randomized, Controlled Trial
Although SARS-CoV-2 (Severe Acute Respiratory Syndrome-associated coronavirus) due to
COVID-19 evolves poorly towards ARDS (Acute Respiratory Distress Syndrome) and death, there
is to date no validated drug available for severe forms of COVID-19. Patients with COVID-19
undergo a drastic decrease of T lymphocytes (LT) count, while the remaining ones display an
"exhausted" phenotype, due to immunosuppressive pathway activation among which the Programed
cell Death 1 (PD1) receptor pathways. LT exhaustion is responsible for host anergy towards
viral infection and leads to increased risk of severe forms of COVID-19. Moreover, while the
number of systemic LT PD1+ correlates with poor prognosis clinical stages of COVID-19
infection, healing from COVID-19 associates with LT PD1 expression normalization. Chinese
epidemiologic data identified clinical risk factors of poor clinical evolution (i.e. ARDS or
death), among which is found obesity, similarly to observation previously obtained during
H1N1 infection (flu virus).
Obese persons display meta-inflammation and immune dysfunction, a condition similar to
ageing, thus termed "Inflamm-aging", thus also used during obesity. Inflamm-aging,
characterized by cytotoxic LT exhaustion and reduced NK cell (Natural Killer cell) cytotoxic
function secondary to PD1 pathway activation, could contribute to the poor prognosis observed
during cancer and infection in obese individuals. We hypothesize that the immunocompromised
profile observed during obesity contribute to their vulnerability towards COVID-19.
In cancer or certain infection diseases, NIVOLUMAB, an anti-PD1 monoclonal antibody, restores
exhausted LT immunity. We thus hypothesize that NIVOLUMAB-induced immunity normalization
could (i) stimulate anti-viral response also during COVID-19 infection and (ii) prevent ARDS
development, which has previously been associated with low LT count concomitant with
increased inflammatory cytokine production.
This randomized controlled therapeutic trial, using an add-on strategy to usual standard of
care, aims at demonstrating the efficacy and safety of NIVOLUMAB-induced cytotoxic LT
normalization, to improve clinical outcomes in hospitalized COVID-19+ adult obese individuals
with low LT, since they are at risk of poor prognosis. We postulate that NIVOLUMAB will
increase the number of individuals able to stop oxygen therapy at D15
| Status | Not yet recruiting |
| Enrollment | 120 |
| Est. completion date | September 15, 2021 |
| Est. primary completion date | June 15, 2021 |
| Accepts healthy volunteers | No |
| Gender | All |
| Age group | 18 Years to 70 Years |
| Eligibility |
Inclusion Criteria: - Patients between 18 and 70 years old - COVID-19+ patients diagnosed upon biological testing (PCR Coronavirus SARS-CoV2) - Hospitalized patients - Obese individuals (BMI=30kg/m²) - Lymphocyte counts between 500 and 1500/mm3. - Patients upon oxygen (either using mask or nasal cannula). - Patients within their first 7 days after the beginning of symptoms. - Women of childbearing potential: effective contraception for the duration of the study and 5 months after the administration of treatment. - Patient who understands and accepts the need for a long term follow-up, - Patients who agrees to be included in the study and who signs the informed consent form, - Patients affiliated to a healthcare insurance plan. Exclusion Criteria: - CRITERIA LINKED TO THE DISEASE SEVERITY : - Patients hospitalized in ICU or constant care unit. - Patients with clinical symptoms requiring ICU admission (respiratory rate>30/min, oxygen requirement> 4Liters/min (using high concentration mask) to reach and maintain O2saturation>90%, qSOFA= 2(quick score of Sepsis-related Organ Failure Assessment), or associated multi-visceral failure. - Patients with high biological probability of macrophage activation syndrome (hemoglobin < 9.2 g/dl AND a blood platelets < 110000/mm3 AND AST > 30 U/l AND ferritin > 600 mg/l). CRITERIA LINKED TO THE TREATMENT TOXICITY : - Patients currently treated for cancer or with personal history of cancer within the last 3 years. - Patients with Chronic Obstructive Pulmonary Disease (COPD) (GOLD 3 and 4 stages). - Chronic respiratory insufficiency treated with oxygen. - Patients aged above 70 years old. - Active smoking. - Personal history of thoracic radiotherapy. - Patients with known sensibility to NIVOLUMAB or one of its component. - Patients upon immunosuppressive dosage of corticoids. - Patients upon immunosuppressive therapy or immunosuppressed patients. - Patients already presenting severe autoimmune disease, for whom additional immunologic activation response would potentially precipitate lethal prognosis GENERAL CRITERIA: - Minor Patients - Mentally unbalanced patients, under supervision or guardianship, - Patient deprived of liberty, - Patient who does not understand French/ is unable to give consent, - Patient already included in a trial who may interfere with the study or in a period of exclusion following participation in a previous study. - Pregnant (controlled by a pregnancy test) or lactating woman |
| Country | Name | City | State |
|---|---|---|---|
| France | Hôpital Lyon Sud Service Endocrinologie, Diabète et Nutrition | Pierre-Bénite |
| Lead Sponsor | Collaborator |
|---|---|
| Hospices Civils de Lyon |
France,
| Type | Measure | Description | Time frame | Safety issue |
|---|---|---|---|---|
| Primary | Patient's clinical state | Patient's clinical state will be evaluated by the proportion of patients able to be weaned of oxygen at D15 after randomization (randomization date is the day where the experimental treatment (i.e. NIVOLUMAB) is administered). | 15 days after randomization | |
| Secondary | Readmission | Proportion of in-coming patients in ICU at D7 and D15 post-randomization | 7 days and 15 days after randomization | |
| Secondary | Mortality | Proportion of death at D7 and D15 post-randomization | 7 days and 15 days after randomization | |
| Secondary | Oxygen flow needs | Proportion of patients weaned out of oxygen at D7 post-randomization | 7 days after randomization | |
| Secondary | Requirement of oxygen | Mean oxygen flow needed | 7 days and 15 days after randomization | |
| Secondary | Discharge from hospital | Proportion of out-coming patients from hospitalization at D7 and D15 post-randomization | 7 days and 15 days after randomization | |
| Secondary | Adverse events | Report of all adverse events linked or not to experimental treatment during the study | Within 15 days post-randomization and 90 days and 6 months after randomization | |
| Secondary | Presence of nasopharyngeal SARS-CoV-2 | Presence or not of nasopharyngeal SARS-CoV-2 determined by PCR response | On day 0 before randomization and 15 days after randomization | |
| Secondary | nasopharyngeal SARS-CoV-2 viral charge | Presence or not of nasopharyngeal SARS-CoV-2 Quantified by PCR | On day 0 before randomization and 15 days after randomization | |
| Secondary | Number of total Lymphocytes T | Number of total LT (using immuno-phenotyping) will explore the immune response | On day 0 before randomization and 15 days after randomization | |
| Secondary | Number of CD3+ Lymphocytes T(lymphocyte subpopulation of CD3+ T cells) | Number of CD3+ LT (using immuno-phenotyping) will explore the immune response | On day 0 before randomization and 15 days after randomization | |
| Secondary | Number of CD4+ Lymphocytes T(lymphocyte subpopulation of CD4+ T cells) | Number of total CD4+ LT (using immuno-phenotyping) will explore the immune response | On day 0 before randomization and 15 days after randomization | |
| Secondary | Number of CD8+ Lymphocytes T(lymphocyte subpopulation of CD8+ T cells) | Evaluation of number of CD8+ LT (using immuno-phenotyping) will explore the immune response | On day 0 before randomization and 15 days after randomization | |
| Secondary | Interleukin 6 (IL-6) | Systemic concentration measurement of IL-6 will explore the inflammatory response | On day 0 before randomization and 15 days after randomization | |
| Secondary | Interleukin 10 (IL-10) | Systemic concentration measurement of IL-10 will explore the inflammatory response | On day 0 before randomization and 15 days after randomization | |
| Secondary | Tumor Necrosis Factor alpha (TNFa ) | Systemic concentration measurement of TNFa will explore the inflammatory response | On day 0 before randomization and 15 days after randomization | |
| Secondary | Interferon gamma (IFN?) | Systemic concentration measurement of IFN? will explore the inflammatory response | On day 0 before randomization and 15 days after randomization | |
| Secondary | Type I Interferon (type I IFN) | Systemic concentration measurement of type I IFN will explore the inflammatory response | On day 0 before randomization and 15 days after randomization | |
| Secondary | Tim3 expression | Evaluation of Tim3 expression on CD4+ and CD8+ lymphocytes will explore the fundamental research on obesity and COVID-19 | On day 0 before randomization and 15 days after randomization | |
| Secondary | PD1 expression | Evaluation of PD1 expression on CD4+ and CD8+ lymphocytes will explore the fundamental research on obesity and COVID-19 | On day 0 before randomization and 15 days after randomization | |
| Secondary | PD-L1 expression | Measurement of PD-L1 expression on monocytes will explore explore the fundamental research on obesity and COVID-19 | On day 0 before randomization and 15 days after randomization | |
| Secondary | Human Leukocyte Antigen - DR isotype gene expression (HLA-DR expression) | Measurement of HLA-DR expression on monocytes will explore explore the fundamental research on obesity and COVID-19 | On day 0 before randomization and 15 days after randomization | |
| Secondary | Production of IFN? by lymphocytes T | The cytotoxic LT production of IFN? will explore the fundamental research on obesity and COVID-19 | On day 0 before randomization and 15 days after randomization | |
| Secondary | Production of granzyme B by lymphocytesT | The cytotoxic LT production of granzyme B will explore the fundamental research on obesity and COVID-19 | On day 0 before randomization and 15 days after randomization | |
| Secondary | Lipopolysaccharides (LPS) | Measurement of LPS will explore the endotoxemia and perform fundamental research on obesity and COVID-19 | On day 0 before randomization and 15 days after randomization | |
| Secondary | LBP(LPS-Binding Protein) | Measurement of LBP (endotoxin transporter) will explore the endotoxemia and perform fundamental research on obesity and COVID-19 | On day 0 before randomization and 15 days after randomization | |
| Secondary | sCD14 | Measurement of sCD14 (endotoxin transporter) will explore the endotoxemia and perform fundamental research on obesity and COVID-19 | On day 0 before randomization and 15 days after randomization | |
| Secondary | High Density Lipoproteins | Measurement of High Density Lipoproteins proteomic will explore the lipoprotein metabolism and perform fundamental research on obesity and COVID-19 | On day 0 before randomization and 15 days after randomization | |
| Secondary | Apolipoprotein | Measurement of apolipoprotein proteomic will explore the lipoprotein metabolism and perform fundamental research on obesity and COVID-19 | On day 0 before randomization and 15 days after randomization |