key: cord-0759930-zsz1htrb authors: Mendoza, Rachelle; Fyke, William; Daniel, David; Gabutan, Elmer; Das, Ballabh; Bajaj, Harsha; Easy, Maxine; Vasileva, Ana; Colbourn, Robert; Alawad, Mouyed; Dehghani, Amir; Lin, Bo; Emechebe, Dokpe; Patel, Purvi; Jabbar, Absia; Nikolov, Dimitar B.; Giovaniello, Dominick; Kang, Steven; Tatem, Luis; Bromberg, Kenneth; Augenbraun, Michael; Premsrirut, Prem; Libien, Jenny; Norin, Allen J. title: Administration of High Titer Convalescent Anti-SARS-CoV-2 Plasma: From Donor Selection to Monitoring Recipient Outcomes date: 2021-02-16 journal: Hum Immunol DOI: 10.1016/j.humimm.2021.02.007 sha: 55fbcce774984370d4847be42de510a401928a4a doc_id: 759930 cord_uid: zsz1htrb Early in the SARS-CoV-2 pandemic, convalescent plasma (CP) therapy was proposed as a treatment for severely ill patients. We conducted a CP treatment protocol under the Mayo Clinic Extended Access Program at University Hospital Brooklyn (UHB). Potential donors were screened with a lateral flow assay (LFA) for IgM and IgG antibodies against the SARS-CoV-2 S1 receptor-binding domain (RBD). Volunteers that were LFA positive were tested with an ELISA to measure IgG titers against the RBD. Subjects with titers of at least 1:1024 were selected to donate. Most donors with positive LFA had acceptable titers and were eligible to donate. Out of 171 volunteers, only 65 tested positive in the LFA (38.0%), and 55 (32.2%) had titers of at least 1:1024. Before our donation program started, 31 CP units were procured from the New York Blood Center (NYBC). Among the 31 CP units that were obtained from the NYBC, 25 units (80.6%) were positive in the LFA but only 12 units (38.7%) had titers of at least 1:1024. CP was administered to 28 hospitalized COVID-19 patients. Patients who received low titer CP, high titer CP and patients who did not receive CP were followed for 45 days after presentation. Severe adverse events were not associated with CP transfusion. Death was a less frequent outcome for patients that received high titer CP (>1:1024) 38.6% mortality, than patients that received low titer CP (≤1:1024) 77.8% mortality. The COVID-19 pandemic caused by the SARS-CoV-2 has posed a treatment challenge. The disease emerged in Wuhan, China in December 2019 and has since arrived in major cities in the United States. Early in the pandemic, New York City was particularly affected [1] . In the USA, there had been a disproportionate burden of illness and death affecting racial and ethnic minorities [1] . Plasma from individuals who recovered from illness has been used as treatment for infectious diseases since the 1890's [2] . During the 1918 Spanish flu pandemic, convalescent plasma was used to treat those with pneumonia [3, 4] . More recently, convalescent plasma was utilized with reported success in the management of MERS [5] , Ebola [6] , H5N1 [7] , H1N1 [8] , and SARS infections [9] . COVID-19 convalescent plasma (CP) is procured by plasmapheresis from donors who have recently recovered from COVID-19. CP contains specific antibodies that are expected to provide passive immunization to neutralize the pathogen [2] . Challenges to understanding the utility of this procedure include donor procurement, assessing an adequate antibody titer for infusion and selection of CP recipients. Several recent studies have shown a beneficial effect of administering CP to COVID-19 patients [10] [11] [12] [13] , though some studies have not [14, 15] . Differences in when in the course of the disease, CP was administered, and the strength and specificity of CP could account for different outcomes. We hypothesized, therefore, that timely administration of potent CP would provide a survival benefit for hospitalized COVID-19 patients. University Hospital of Brooklyn (UHB) was designated a COVID-19 only hospital on March 28, 2020 by the New York State Governor. Between March 13 and June 30, 765 COVID-19 positive patients were admitted and managed in the institution for moderate to severe symptoms. We describe our experience below in obtaining high titer CP from volunteer donors who had recovered from COVID-19 and the clinical course of 28 severely ill COVID-19 patients who were treated with high titer or low titer CP. This is a retrospective descriptive study on the experience of a CP donation and treatment program. One group, composed of 17 COVID -19 patients who did not receive CP transfusion as part of their management, was observed and compared with two CP recipient groups, one with high titer and one with low titer anti-SARS-CoV-2 IgG antibody as described below. The non-CP treated group had similar severity of illness as the CP treated patients. A cutoff for CP donation was selected based on the Mayo Clinic recommendation of 1:160 titer or greater where inhibition of neutralization decreased by 50%. The Mayo program did not give guidance for an ELISA titer. In preliminary studies, we found that 50% reduction in OD in ELISA assays typically was 1:256 (close to neutralizing titer of 1:160) when the end point titration was 1:1024. Announcements for donation of CP were accomplished by advertisement on the UHB website and e-mail. This led to word-of-mouth spread to external donors, increasing the interest of many. Volunteer donors were screened at UHB based on the following criteria: (1) self-reported recovery from a documented COVID-19 infection, (2) asymptomatic for at least 14 days, (3) negative SARS-CoV-2 RNA RT PCR assay (only for those asymptomatic for ≤ 28 days), (4) positive lateral flow test (POS++ or greater), (5) All the plasma/serum samples from NYBC units, potential UHB donors and recipients were tested with a lateral flow test kit (Singuway, Shenzhen City, China) that detects IgM and IgG antibodies against the SARS-CoV-2 S1 spike protein receptor binding domain (RBD), following manufacturer's protocol. In brief, one drop of plasma/serum was placed into the designated sample well followed by two drops of the kit's diluent. The result was observed after exactly 10 minutes and recorded photographically ( Figure 1 ). The presence of at a red line along the marked area (IgM and/or IgG) indicated a positive test. A line must be present in "Control" for the test to be valid. The intensity of the red line was used to stratify the strength of the antibody: a faintly visible red line signifies +/-and red lines of increasing intensity compared to the control line (POS+++) were scored as POS+, POS++ or POS+++. All recipients and donor plasma samples that tested positive by the lateral flow test were tested for levels of IgG antibody against the SARS-CoV-2 S1 spike protein RBD. Depending on the lateral flow result, assay controls and serum samples were diluted from 1:2 to 1:64 followed by 2-fold dilution out to 1:131072 and added to a 96-wells microtiter plate (Thermo Scientific Immulon, Waltham, MA, USA) that was coated with SARS-CoV-2 recombinant RBD (BEI Resources, Manassas, VA, USA). A secondary anti-human IgG (Fab specific) antibody labeled with horse radish peroxidase (Sigma-Aldrich, St. Louis, MO, USA), was added to each well to form a specific complex of antigen-antibody bound to the plate surface. The binding reaction was then enhanced visually with SIGMAFAST TM OPD (Sigma-Aldrich, St. Louis, MO, USA), and after application of the stop solution (3M Hydrochloric acid), the optical density was immediately measured at 490 nm. When the absorbance value was greater than the cut-off value (OD490=0.15), the specimens were reported as a positive result and the resulting titer was reported. SARS-CoV-2 detection in recipients and potential donors was performed in-house using the Cepheid Xpert® Xpress SARS-CoV-2 RT-PCR assay (Cepheid, Sunnyvale, CA) following manufacturer's protocol. Nasopharyngeal swab samples were collected from patients and volunteers, and the swab was placed into a tube containing 3 ml of viral transport medium. Using the pipette included in the Cepheid kit, 300 microliters of the nasopharyngeal swab sample was transferred into the Cepheid cartridge tube, which contains the reacting reagents. The cartridge was then closed with the lid and placed into the GeneXpert® System for 45 minutes. Results were interpreted as positive if at least one of the three targets (N2 gene, E gene, SPC gene) were detected, and negative if none of the targets was present. This treatment was performed at UHB between April 4, 2020 to June 26, 2020. The program ended because patients with severe symptoms were no longer seen in the hospital past this date. The Mayo Clinic protocol for Expanded Access to Convalescent Plasma for the Treatment of Patients with COVID-19 (unique protocol identification number: 20-003312) was utilized. The program received approval from the local institutional review board. The inclusion criteria for treatment with CP were: (1) at least 18 years of age, (2) had a diagnosis of SARS-CoV-2 infection laboratory confirmed by RT PCR assay, (3) admitted to UHB for the treatment of COVID-19 complications, (4) severe or life threatening COVID-19 or judged by the treating provider to be at high risk of progression to severe or life-threatening disease as judged by the need for supportive oxygen therapy, and (5) informed consent provided by the patient or healthcare proxy. There were no exclusion criteria. All patients were followed for 45 days after admission. Clinical chemistry and hematology parameters were monitored until either discharge or death. CP was transfused within 24 hours after thawing. Each CP unit, approximately 250 milliliters, was infused over one to two hours. Recipients were monitored every 15 minutes for signs of transfusion-related reactions and then followed post-transfusion for clinical course. A group of hospitalized critically ill patients who did not receive CP treatment was observed retrospectively and compared with CP recipients for outcomes. These patients, admitted from March 18 to May 1, 2020, were managed with similar COVID-19 therapeutic drugs as the CP recipients, except for the CP therapy itself. Mortality in the CP and control cohorts was described with the use of Kaplan-Meier analysis. A chi-square analysis or Fisher's exact test was used to assess for statistical difference between groups. Associations between cohort pretreatment characteristics, lab values, and mortality were evaluated with Cox proportional hazards regression. Mann-Whitney U test, and Kruskal-Wallis test where used to analyze continuous variables where appropriate. A two-sided p value of less than or equal to 0.05 was considered to indicate statistical significance and all values are shown without correction for multiple testing. The widths of the confidence intervals have not been adjusted for multiple comparisons; therefore, intervals should not be used to infer definite associations. The recruitment of patients for CP treatment was performed under registration with the Mayo Clinic Clinical Trial, Expanded Access to Convalescent Plasma for the Treatment of Patients with COVID-19 (ClinicalTrials.gov Identifier: NCT04338360). Prior authorization to publish was secured from the Mayo Clinic PI. The trial protocol was approved by the SUNY Downstate institutional review board. Informed consent was obtained from each patient prior to transfusion. A separate IRB application was approved for retrospective review of electronic medical records of COVID-19 patients. Between April 23, 2020 to June 26, 2020, UHB volunteers (n=171) were screened for possible donation. The process for evaluation of potential donors and initial screening results are shown in Figure for SARS-COV-2 RNA real-time reverse transcription polymerase chain reaction test (RT PCR), and 6 (3.5%) had a previous positive antibody test. All those who donated were at least 14 days without symptoms. The median period from date of last symptom to date of presentation at the donation clinic was 33 days (IQR 23 to 39.5 days). Thirty-one CP units were procured from NYBC. These units were collected from volunteers who were known to have SARS-CoV-2 infection (prior RT PCR positive test) but were not tested for antibody at NYBC. Subsequent lateral flow assays were performed at UHB on all these units and From April 4, 2020 to June 26, 2020, 28 severely ill COVID-19 patients (19 males and 9 females) received CP transfusion at UHB under the Mayo Clinic-led Expanded Access Program. The individual profiles of the 28 patients who received CP are shown in Supplementary Table 1 . Table 2 provides data on demographics and outcomes for the CP recipients and the non-CP group. Most recipients were African American (85.7%), 3.6% were Asian, 3.6% were Hispanicwhite. Two patients declined to identify their ethnicity. Most recipients were male (18/28, 64.3%) and between 50 to 70 years of age (13/28, 46.4%). The most common symptoms at disease onset were shortness of breath (71.4%), fever (50%) and cough (50%). Co-morbidities present in these patients were hypertension (60.7%), diabetes mellitus (37.0%), renal disease (28.6%), heart disease (21.4%), neurological disease (14.3%), lung disease (2.5%), cancer A group of 17 hospitalized critically ill COVID-19 patients who did not receive CP as part of their management was compared to the CP treated groups. These patients, admitted from March 18 to May 2, 2020, were selected based on similarity to the CP treatment groups on age and severity from about 600 admitted patients. We note that CP infusions occurred from April 2 to June 24, 2020. "Severe" COVID-19 respiratory symptoms was defined by deterioration of respiratory function requiring supplemental oxygen greater than 4 liters/minute to maintain oxygen saturation at >90%. The non-CP treated patients received similar COVID-19-related management as the treatment groups except for CP. The major reasons for not receiving CP include: (1) CP was not yet available for treatment, (2) consent was not given by the patient or their health proxy, and (3) the patient recovered or died before CP could be administered. The mortality of the high titer group was lower than that of the non-CP cohort (36.8% and 52.9%, respectively), while the mortality of the low titer group (77.8%) was higher than that of the non-CP and the high titer cohorts. Figure 6 shows a Kaplan-Meier 45-day survival plot for the three cohorts. Patients transfused with high titer CP (>1:1024) had better survival than the cohort the received low titer CP (1:1024) had better survival than patients receiving low titer CP ( 1:1024). Although this finding did not reach statistical significance, a clear trend was observed. Failure to achieve statistical significance may be due to small sample size. Indeed, two larger studies concluded that there was a survival benefit for CP recipients [11, 13] . A recent study found significantly lower mortality rates among recipients that received high titer IgG CP compared to low antibody level plasma units [12, 13] . Our results support the importance of transfusing COVID-19 patients with high titer anti-SARS-CoV-2 antibody in order to provide a survival benefit. However, in our experience such survival benefit may not be solely attributed to CP. At the beginning of the pandemic in March 2020, the medical and nursing staff at UHB were unfamiliar with the disease and most patients arrived in the hospital already in critical condition. Early patients were treated with hydroxychloroquine and azithromycin; both have been linked to poorer outcomes or without benefit [16] . During this period, the only CP units available to our patients were those coming from NYBC, which were later found to have low antibody titers. From the second half of April onwards, COVID-19 patients were given high antibody titer CP units from our screened donors. During this period, the treatment of COVID-19 was also improving as evidence became available on the benefit of dexamethasone, Remdesivir and CP as well. Furthermore, the interval between admission to the hospital and CP treatment decreased so that patients received CP sooner in the course of their disease. An additional factor is that the general public's overall awareness of COVID-19 improved, and patients began to seek medical attention earlier in the disease process. All these circumstances may have contributed to the improved survival of the high titer COVID-19 recipients. Indeed, multi-center randomized controlled trials found no benefit with the use of convalescent plasma in severe COVID-19 pneumonia when some of these factors were controlled [14, 15] . However, in the latter studies, most patients were treated with CP late in the course of their disease as compared to our study (>14 days vs 9 days, respectively). Screening and subsequent antibody titer determination of CP potency against the SARS-CoV-2 spike RBD is an essential step to ensure the efficacy of this treatment. Preliminary evidence with COVID-19 suggests that patients with mild symptoms may develop very low titer antibodies [17] [18] [19] . One study observed that 18% of convalescent COVID-19 donors had undetectable neutralizing titers in their plasma samples collected an average of 30 days after the onset of symptoms [20] . A larger study performed by NYBC showed that more than half of CP donors had low neutralizing titers and that there was a large variation in antibody titers among donors [21] . In our experience, using ELISA binding as a surrogate for neutralizing antibodies, among the 171 volunteers, only 55 (32.2%) had high levels of antibody. Out of 31 NYBC CP units, only 12 (38.7%) had titers of at least 1:1024. If CP is considered a valid therapeutic option, there is an existing challenge to screen CP donors for antibody titers, as evidence shows that most mild COVID-19 patients may not develop an adequate level of anti-SARS-CoV-2 antibodies to provide a therapeutic benefit to recipients. The lateral flow assay permitted us to quickly screen volunteers who potentially had high titers. Donors at UHB who tested POS++ with the lateral flow assay had antibody ELISA titers of >1:1024. Automated systems for screening are now available for larger testing capacity. It is important to note that the mortality of our patient population was greater than in previously published cohorts. This circumstance may be why a CP effect was seen despite the small numbers of patients. Joyner et al (2020) reported a seven-day mortality of only 15% among their CP recipients [13] . Liu et al (2020) reported mortality rates of 12.8% among plasma recipients and 24.4% among their matched control patients with a median follow up of 11 days for the plasma group and 9 days for the control group [11] . Our data shows a 44% death rate after a 45day follow-up. The prolonged follow-up period in our study may have revealed a higher mortality rate. However, baseline health status differences, as well as racial and genetic factors, need to be further investigated in a larger cohort. In contrast to previous studies, the patients included in our treatment program were predominantly Black. COVID-19 case surveillance reports showed higher prevalence among racial and ethnic minority group [22] . In a large cohort study in a health institution in Louisiana [23] , 76.9% of COVID-19 patients were Black, whereas Blacks comprise only 31% of the institution's population, and most deaths were also in Black patients (70.6%). CDC has emphasized that inequities in the social determinants of health, such as poverty and healthcare access, affecting minority groups are interrelated and influence a wide range of health and quality-of-life issues and outcomes. Greater mortality rate was also observed at UHB among female patients, with a hazard ratio three times higher than male patients. This result is in contrast with findings published in one Chinese study where it was concluded that male gender is a risk factor for worse outcome in 43 COVID-19 patients independent of age and susceptibility [24] . Racial differences and other Most patients who received high-titer CP units also received the plasma soon after admission. United States COVID-19 Cases and Deaths by State Convalescent plasma: new evidence for an old therapeutic tool? Early use of convalescent serum in influenza Meta-analysis: convalescent blood products for Spanish influenza pneumonia: a future H5N1 treatment? 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NEJM Effect of Convalescent Plasma Therapy on Time to Clinical Improvement in Patients with Severe and Life-threatening COVID-19: A Randomized Clinical Trial Hydroxychloroquine with or without Azithromycin in Mild-to-Moderate COVID-19 Relationship between anti-Spike protein antibody titers and SARS-CoV-2 in vitro virus neutralization in convalescent plasma Sex, age, and hospitalization drive antibody responses in a COVID-19 convalescent plasma donor population Clinical predictors of donor antibody titer and correlation with recipient antibody response in a COVID-19 convalescent plasma clinical trial Convergent antibody responses to SARS-CoV-2 infection in convalescent individuals Serological Assays Estimate Highly Variable SARS-CoV-2 Neutralizing Antibody Activity in Recovered COVID-19 Patients Coronavirus Disease 2019 Case Surveillance -United States Hospitalization and Mortality among Black Patients and White Patients with COVID-19 Gender Differences in Patients with COVID-19: Focus on Severity and Mortality High titer plasma and earlier management with CP were apparent in patients admitted after 4/29/2020 This project has been funded in whole or in part with Federal funds from the Department of