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This study is being conducted to determine if patients with compromised B-cell function due to anti-CD20 therapy and newly diagnosed COVID-19 infection benefit from convalescent plasma.
This is a retrospective cohort study comparing patients, with newly diagnosed COVID-19 infection, previously treated with anti-CD20 drugs for diseases including vasculitis or hematologic malignancy, who are given high titer convalescent plasma with similar patients receiving usual care that does not include convalescent plasma.
The goals are:
Data will be extracted from a data registry, built in the electronic health record (EHR) environment, automatically logging subjects based on data in the electronic health record and extracting relevant data metrics. This is put into a data mart nightly via an extract, transform and load process used as part of routine operations and validated as part of routine maintenance. Metric definitions in the registry system include validation of data as being within defined limits based on the entry of EHR values to prevent outliers inconsistent with reasonable data. The registry is built in the medical record system, and is checked for consistency as part of the EHR architecture and maintenance. All data is extracted from the Epic electronic health record. Diagnoses and procedures are coded using ICD-10-CM and SNOMED-CT and laboratory data identified using appropriate LOINC codes. Rules based metrics calculate demographic information and risks scores such as the Charlson comorbidity index, as indicated in the attached data dictionary.
Outcome analyses will be subjected to propensity score (PS) adjustment to account for non-random treatment selection. First, the investigators will estimate the PS from a multivariable logistic regression in which predictors of receiving CP (within the first 30 days) are determined as a function of patient baseline characteristics. The propensity model will include age, sex, race, APACHE-3 score, and additional baseline covariates chosen a priori based on clinical relevance. Finally, comparison of the CP and no CP treatment outcomes will be adjusted for baseline differences by including PS (as restricted cubic spline in the logit PS to allow for nonlinear effects) in the outcome regression model with the CP treatment variable. As an additional PS technique, patients treated without CP will be matched to patients who received CP based on disease group (vasculitis or hematologic malignancy) and propensity score within a tolerance of 0.2 standard deviations of logit-PS. To avoid survival bias, the matching process will consider only the eligible controls who were followed as long or longer than the time-to-first transfusion of the CP case.
Separate proportional odds logistic regression models will be fitted for the univariate WHO ordinal outcome score at 30 days and for multivariate outcome scores at 30, 60 and 90 days (as a repeated measures analysis), with the patients' CP status, time, baseline WHO score, and PS included as independent variables. ICU-free days, defined as the number of days alive and free of ICU between study entry and day 30 or day 90 will be calculated and compared between CP and no CP groups using Poisson regression. For this analysis, the investigators will initially start all patients at time of positive PCR in the no CP group. When patients receive their first transfusion, their non-CP follow-up will be truncated, and their follow-up will be restarted at time zero in the CP group. The investigators will use an offset in the model to allow for difference in observation days between the two groups. Lastly, treatment heterogeneity will be explored for pre-specified baseline characteristics (e.g., time since anti-CD20, sex, race) by testing treatment-by-covariate interactions in the outcome models. Time since anti-CD20 will be analyzed as a continuous variable using an expanded cohort to consider a wider range of times (within 3 years). The investigators will also examine the association between time since anti-CD20 use and study outcomes, irrespective of plasma treatment. Again, time will be considered on a continuum and modeled flexibly using regression splines to allow for nonlinear relationships with the outcome.
Sensitivity analyses:
Stratification by category of disease (vasculitis vs. hematologic malignancies) and stratification by titer of antibodies, seroconversion achieved, time (from initial positive PCR) when plasma was given.
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| Label | Type | Description | Intervention Names |
|---|---|---|---|
| COVID-19 with previous anti-CD20 therapy and Convalescent plasma | Patients with COVID-19, treated in the past 3 years with anti-CD20 therapy and who received Convalescent plasma in addition to standard treatment for COVID-19 |
| |
| COVID-19 with previous anti-CD20 therapy and no convalescent plasma | Patients with COVID-19, treated in the past 3 years with anti-CD20 therapy treated with standard COVID-19 treatment and who did not receive Convalescent plasma treatment for COVID-19 |
| Name | Type | Description | Arm Group Labels | Other Names |
|---|---|---|---|---|
| Convalescent Plasma | Biological | Convalescent Plasma |
|
| Measure | Description | Time Frame |
|---|---|---|
| Change in WHO Clinical Progression scale | In this observational study examining the use of convalescent plasma (CP) for treatment of CD20-depleted patients with COVID-19, we will describe the clinical course of these patients and conduct a comparative treatment analysis. "Time zero" will be considered the date the patient first tested positive for COVID-19, and the time-dependent nature of CP transfusion will be explicitly used in the analysis. The primary outcome of interest is the WHO ordinal outcome score measured repeatedly over 90-day follow-up. The WHO ordinal scale for Clinical Improvement ranges from 0 uninfected to 8 for Dead. Lower scores are seen with better clinical outcomes. | 90 days |
| Measure | Description | Time Frame |
|---|---|---|
| 90-day mortality | "Time zero" will be considered the date the patient first tested positive for COVID-19, and the time-dependent nature of CP transfusion will be explicitly used in the analysis. The first secondary outcome will be 90-day mortality. | 90 days |
| ICU-free days |
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Inclusion Criteria:
Exclusion Criteria:
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Patients hospitalized in any hospital of the Mayo Clinic Enterprise and enrolled in the Mayo Clinic COVID-19 registry.
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| Name | Affiliation | Role |
|---|---|---|
| Mary Kasten, MD | Mayo Clinic | Principal Investigator |
| Facility | Status | City | State | ZIP | Country | Contacts |
|---|---|---|---|---|---|---|
| Mayo Clinic | Rochester | Minnesota | 55905 | United States |
There is not a plan to make IPD available.
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| ID | Term |
|---|---|
| D000086382 | COVID-19 |
| ID | Term |
|---|---|
| D011024 | Pneumonia, Viral |
| D011014 | Pneumonia |
| D012141 | Respiratory Tract Infections |
| D007239 | Infections |
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The number of days the patient spent at home or in the hospital not in the ICU will be counted over the 90 days following the date the patient first tested positive for COVID-19, and following convalescent plasma transfusion |
| 90 days |
| D014777 |
| Virus Diseases |
| D018352 | Coronavirus Infections |
| D003333 | Coronaviridae Infections |
| D030341 | Nidovirales Infections |
| D012327 | RNA Virus Infections |
| D008171 | Lung Diseases |
| D012140 | Respiratory Tract Diseases |