Covid19
Conditions
Keywords
COVID, monoclonal antibodies
Brief summary
Multiple monoclonal antibodies (mABs) have been shown to reduce viral burden and improve clinical outcomes, have been granted FDA Emergency Use Authorization (EUA) for use in select populations, and are routinely used in the UPMC Health System, which has made expanded access a priority. However, the comparative effectiveness of these mABS is unknown. The National Academies of Sciences, Engineering, and Medicine has called for expanded access and clinical use of mABs, noting it is critical to collect data and evaluate whether they are working as predicted. This pragmatic evaluation will determine the relative effects of the EUA-governed mABs versus each other. When U.S. government mAB policies change (e.g., FDA grants or revokes EUAs), UPMC Health System policies and the evaluated mABs will accordingly change.
Detailed description
While COVID-19 vaccination will reduce COVID-19-related morbidity and mortality, the learned immune response may vary between individuals. This means interventions such as monoclonal antibodies (mAB) will still be needed to prevent progression of COVID-19 illness. Monoclonal antibodies seek to mimic or enhance the natural immune system response against a pathogen and are often used in the care of patients with cancer or infection. For viral infections, mABs are created by exposing a white blood cell to a particular viral protein, which is then cloned to mass produce antibodies to target that virus. For SARS-CoV-2, the virus that causes COVID-19, IgG1 mABs target the spike protein of SARS-CoV-2 and block viral attachment and entry into cells. The SARS-CoV-2 mABs bamlanivimab and etesevimab, and the REGN-COV2 combination (casirivimab + imdevimab) reduce nasopharyngeal viral burden plus clinical outcomes including future emergency department visits and hospitalizations. Each received FDA Emergency Use Authorization (EUA) for use in selected populations. As of February 2021, there are over 60,000 new cases of COVID-19 diagnosed daily in the US, with over 7000 daily COVID-19 related hospital admissions. Although case volumes are currently declining, COVID-19 remains a significant public health threat. Despite the EUAs, the clinical use of mABs is low due in part to lack of patient access, complexities in drug allocation, and lack of knowledge among providers are contributing factors. Further, the comparative effectiveness of different mABs is unknown and not yet directly studied. The National Academies of Sciences, Engineering, and Medicine recently called for expanded access and clinical use of mABs, noting it is critical to collect data and evaluate whether they are working as predicted. This evaluation seeks to determine their relative effects versus each other, starting with those governed by EUAs. OPTIMISE-C19 is a quality improvement (QI) study, governed by approvals from both the UPMC QI committee and the University of Pittsburgh IRB. Currently, mAB therapy is approved for use under EUA issued by the FDA. There are no data on the relative benefits of one mAB versus any other. mABs are ordered by UPMC physicians as a generic referral order and the order is filled by UPMC pharmacy via therapeutic interchange. The selection of mABs available within pharmacy is overseen by the UPMC pharmacy and therapeutics committee. OPTIMISE-C19 provides the therapeutic interchange via random allocation. The UPMC Quality Improvement Committee approved the OPTIMISE-C19 study, including the random therapeutic interchange. The University of Pittsburgh IRB considered the randomized therapeutic interchange to be quality improvement and approved the additional data collection and analyses. Patients provide verbal consent to receive mAB therapy. UPMC requires physicians to provide and review with patients the EUA Fact Sheet for each mAB, and explain that the patient could receive any of the EUA-governed mABs. As per EUA requirements, physicians discuss the risks and benefits of mABs with patients, and patients consent to receive a mAB as part of routine care, should they desire mAB treatment. Patients are told which mAB they are receiving, and physicians and patients can agree to the assigned mAB or request a specific mAB. It is the treating physicians' and patients' choice to accept the assigned mAB or not. The QI committee considered these steps to represent adequate consent to participate. The IRB considered that the provision of mAB therapy therefore fell under quality improvement and only the additional data collection and analyses represented research. The IRB waived any additional consent requirements.
Interventions
BIOLOGICALLilly Bamlanivimab
Administration of Lilly Bamlanivimab to COVID positive patients
BIOLOGICALRegeneron Casirivimab + Imdevimab
Administration of Regeneron Casirivimab + Imdevimab to COVID positive patients
BIOLOGICALLilly Bamlanivimab + Etesevimab
Administration of Lilly Bamlanivimab + Etesevimab to COVID positive patients
BIOLOGICALSotrovimab
Administration of Sotrovimab to COVID positive patients
BIOLOGICALBebtelovimab
Administration of Bebtelovimab to COVID positive patients
Sponsors
University of Pittsburgh
Erin McCreary
Study design
Allocation
RANDOMIZED
Intervention model
PARALLEL
Primary purpose
OTHER
Masking
NONE
Intervention model description
The study is an adaptive platform and as such is intended to study multiple interventions simultaneously, does not have a defined sample size, and is intended to move forward in perpetual fashion with domains and interventions being added and subtracted over time. For example, interventions will be added and subtracted depending on federal decisions regarding monoclonal antibodies, such as granting or revoking authorization for use.
Eligibility
Sex/Gender
ALL
Age
12 Years to 120 Years
Healthy volunteers
No
Inclusion criteria
* COVID-19 positive patients * Eligible for mAB under FDA EUA
Exclusion criteria
* Death is deemed to be imminent or inevitable * Previous participation in this REMAP within the last 90 days
Design outcomes
Primary
| Measure | Time frame | Description |
|---|---|---|
| Hospital-free Days | 28 days after initial participation | Days alive and free from hospitalization. Patients that are both living and not in the hospital will meet criteria to be counted in this outcome. Deaths were rare and therefore the upper and lower end of the IQR are both 28, in addition to the median. This outcome measure does reflect median hospital free days and interquartile ranges for all groups. |
Secondary
| Measure | Time frame | Description |
|---|---|---|
| SARS-CoV-2 Nasopharyngeal Viral Loads | 28 days after initial participation | Where feasible SARS-CoV-2 nasopharyngeal viral loads among participants from baseline and longitudinally through day 28 |
| SARS-CoV-2 Plasma Viral Loads | 28 days after initial participation | Where feasible SARS-CoV-2 plasma viral loads among participants from baseline and longitudinally through day 28 |
| SARS-CoV-2 Antibody Titers | 28 days after initial participation | Where feasible SARS-CoV-2 antibody titers at baseline and longitudinally through day 28 |
| SARS-CoV-2 Antibody Neutralization | 28 days after initial participation | Where feasible SARS-CoV-2 antibody neutralization at baseline and longitudinally through day 28 |
| All-cause Mortality at 28 Days | 28 days after initial participation | All-cause mortality at 28 days. |
| Detection of SARS-CoV-2 Variants Through Next-generation Sequencing | 28 days after initial participation | Where feasible detection of SARS-CoV-2 variants through next-generation sequencing at baseline and longitudinally through day 28 |
| Duration of SAR-CoV-2 Infectivity | 28 days after initial participation | Where feasible determining the duration of SAR-CoV-2 infectivity among patients with persistent nasopharyngeal swab viral shedding |
| Non-culture Surrogates for SARS-CoV-2 Infectivity | 28 days after initial participation | Where feasible determining non-culture surrogates for SARS-CoV-2 infectivity among patients with persistent nasopharyngeal swab viral shedding |
| ED Visit Within 28 Days | Duration of study | — |
| SARS-CoV-2 Immune Responses | 28 days after initial participation | Where feasible SARS-CoV-2 immune responses at baseline and longitudinally through day 28 |
Countries
United States
Participant flow
Participants by arm
| Arm | Count |
|---|---|
| Lilly Bamlanivimab The Lilly monoclonal antibody bamlanivimab will be administered according to FDA EUA guidelines. Dosing is 700 mg intravenously times one within 10 days of COVID-19 symptom onset.
Lilly Bamlanivimab: Administration of Lilly Bamlanivimab to COVID positive patients | 128 |
| Regeneron Casirivimab + Imdevimab The Regeneron monoclonal antibody cocktail Casirivimab + Imdevimab will be administered according to FDA EUA guidelines. Dosing is 1200 mg of each drug (2400 mg total) administered intravenously times one within 10 days of COVID-19 symptom onset.
Regeneron Casirivimab + Imdevimab: Administration of Regeneron Casirivimab + Imdevimab to COVID positive patients | 2,454 |
| Lilly Bamlanivimab + Etesevimab The Lilly monoclonal antibody cocktail of bamlanivimab + etesevimab will be administered according to FDA EUA guidelines. Dosing is given intravenously times one within 10 days of COVID-19 symptom onset.
Lilly Bamlanivimab + Etesevimab: Administration of Lilly Bamlanivimab + Etesevimab to COVID positive patients | 885 |
| Sotrovimab The monoclonal antibody of sotrovimab will be administered according to FDA EUA guidelines. Dosing is given intravenously times one within 7 days of COVID-19 symptom onset.
Sotrovimab: Administration of Sotrovimab to COVID positive patients | 1,104 |
| Total | 4,571 |
Baseline characteristics
| Characteristic | Lilly Bamlanivimab | Total | Sotrovimab | Lilly Bamlanivimab + Etesevimab | Regeneron Casirivimab + Imdevimab |
|---|---|---|---|---|---|
| Age, Continuous | 57 years STANDARD_DEVIATION 17 | 54 years STANDARD_DEVIATION 18 | 53 years STANDARD_DEVIATION 18 | 56 years STANDARD_DEVIATION 16 | 54 years STANDARD_DEVIATION 18 |
| Race (NIH/OMB) American Indian or Alaska Native | 0 Participants | 0 Participants | 0 Participants | 0 Participants | 0 Participants |
| Race (NIH/OMB) Asian | 0 Participants | 0 Participants | 0 Participants | 0 Participants | 0 Participants |
| Race (NIH/OMB) Black or African American | 15 Participants | 576 Participants | 161 Participants | 148 Participants | 252 Participants |
| Race (NIH/OMB) More than one race | 0 Participants | 0 Participants | 0 Participants | 0 Participants | 0 Participants |
| Race (NIH/OMB) Native Hawaiian or Other Pacific Islander | 0 Participants | 0 Participants | 0 Participants | 0 Participants | 0 Participants |
| Race (NIH/OMB) Unknown or Not Reported | 9 Participants | 217 Participants | 51 Participants | 44 Participants | 113 Participants |
| Race (NIH/OMB) White | 104 Participants | 3778 Participants | 892 Participants | 693 Participants | 2089 Participants |
| Sex: Female, Male Female | 69 Participants | 2458 Participants | 599 Participants | 470 Participants | 1320 Participants |
| Sex: Female, Male Male | 59 Participants | 2113 Participants | 505 Participants | 415 Participants | 1134 Participants |
Adverse events
| Event type | EG000 affected / at risk | EG001 affected / at risk | EG002 affected / at risk | EG003 affected / at risk |
|---|---|---|---|---|
| deaths Total, all-cause mortality | 1 / 128 | 12 / 2,454 | 7 / 885 | 7 / 1,104 |
| other Total, other adverse events | 0 / 128 | 17 / 2,454 | 12 / 885 | 6 / 1,104 |
| serious Total, serious adverse events | 0 / 128 | 7 / 2,454 | 0 / 885 | 4 / 1,104 |
Outcome results
Primary
Hospital-free Days
Days alive and free from hospitalization. Patients that are both living and not in the hospital will meet criteria to be counted in this outcome. Deaths were rare and therefore the upper and lower end of the IQR are both 28, in addition to the median. This outcome measure does reflect median hospital free days and interquartile ranges for all groups.
Time frame: 28 days after initial participation
Population: Every patient who received mAb treatment
| Arm | Measure | Value (MEDIAN) |
|---|---|---|
| Lilly Bamlanivimab | Hospital-free Days | 28 days |
| Regeneron Casirivimab + Imdevimab | Hospital-free Days | 28 days |
| Lilly Bamlanivimab + Etesevimab | Hospital-free Days | 28 days |
| Sotrovimab | Hospital-free Days | 28 days |
Comparison: The primary analysis model was a Bayesian cumulative logistic model that adjusted for treatment location (infusion center or ED), age (\<30, 30-39, 40-49, 50-59, 60-69, 70-79, and ≥ 80 years), sex, and time (2-week epochs). Comparisons between individual mAb were based on the relative odds ratio between a given two arms for the primary outcome. An odds ratio for an arm to a comparator \>1 implies improved outcomes. A sliding scale with different levels of equivalence bounds was pre-definedBayesian cumulative logistic model
Secondary
All-cause Mortality at 28 Days
All-cause mortality at 28 days.
Time frame: 28 days after initial participation
| Arm | Measure | Value (COUNT_OF_PARTICIPANTS) |
|---|---|---|
| Lilly Bamlanivimab | All-cause Mortality at 28 Days | 1 Participants |
| Regeneron Casirivimab + Imdevimab | All-cause Mortality at 28 Days | 12 Participants |
| Lilly Bamlanivimab + Etesevimab | All-cause Mortality at 28 Days | 7 Participants |
| Sotrovimab | All-cause Mortality at 28 Days | 7 Participants |
Secondary
Detection of SARS-CoV-2 Variants Through Next-generation Sequencing
Where feasible detection of SARS-CoV-2 variants through next-generation sequencing at baseline and longitudinally through day 28
Time frame: 28 days after initial participation
Population: Participants were not consented for samples due to limited trial resources, data not collected
Secondary
Duration of SAR-CoV-2 Infectivity
Where feasible determining the duration of SAR-CoV-2 infectivity among patients with persistent nasopharyngeal swab viral shedding
Time frame: 90 days after initial participation
Population: Analysis not feasible due to limitations of pandemic, Participants were not consented for samples due to limited trial resources, data not collected
Secondary
Duration of SAR-CoV-2 Infectivity
Where feasible determining the duration of SAR-CoV-2 infectivity among patients with persistent nasopharyngeal swab viral shedding
Time frame: 28 days after initial participation
Population: Participants were not consented for samples due to limited trial resources, data not collected
Secondary
ED Visit Within 28 Days
Time frame: Duration of study
Population: Not feasible due to nature of data and treatment sites during pandemic, data not collected
Secondary
Non-culture Surrogates for SARS-CoV-2 Infectivity
Where feasible determining non-culture surrogates for SARS-CoV-2 infectivity among patients with persistent nasopharyngeal swab viral shedding
Time frame: 90 days after initial participation
Population: Participants were not consented for samples due to limited trial resources, data not collected
Secondary
Non-culture Surrogates for SARS-CoV-2 Infectivity
Where feasible determining non-culture surrogates for SARS-CoV-2 infectivity among patients with persistent nasopharyngeal swab viral shedding
Time frame: 28 days after initial participation
Population: Participants were not consented for samples due to limited trial resources, data not collected
Secondary
SARS-CoV-2 Antibody Neutralization
Where feasible SARS-CoV-2 antibody neutralization at baseline and longitudinally through day 28
Time frame: 28 days after initial participation
Population: Participants were not consented for samples due to limited trial resources, data not collected
Secondary
SARS-CoV-2 Antibody Titers
Where feasible SARS-CoV-2 antibody titers at baseline and longitudinally through day 28
Time frame: 28 days after initial participation
Population: Participants were not consented for samples due to limited trial resources, data not collected
Secondary
SARS-CoV-2 Immune Responses
Where feasible SARS-CoV-2 immune responses at baseline and longitudinally through day 28
Time frame: 28 days after initial participation
Population: Participants were not consented for samples due to limited trial resources, data not collected
Secondary
SARS-CoV-2 Nasopharyngeal Viral Loads
Where feasible SARS-CoV-2 nasopharyngeal viral loads among participants from baseline and longitudinally through day 28
Time frame: 28 days after initial participation
Population: Participants were not consented for samples due to limited trial resources, data not collected
Secondary
SARS-CoV-2 Plasma Viral Loads
Where feasible SARS-CoV-2 plasma viral loads among participants from baseline and longitudinally through day 28
Time frame: 28 days after initial participation
Population: Participants were not consented for samples due to limited trial resources, data not collected