Browsing by Author "O'Brien, Sean M"
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Item Open Access Abatacept, Cenicriviroc, or Infliximab for Treatment of Adults Hospitalized With COVID-19 Pneumonia: A Randomized Clinical Trial.(JAMA, 2023-07) O'Halloran, Jane A; Ko, Emily R; Anstrom, Kevin J; Kedar, Eyal; McCarthy, Matthew W; Panettieri, Reynold A; Maillo, Martin; Nunez, Patricia Segura; Lachiewicz, Anne M; Gonzalez, Cynthia; Smith, P Brian; de Tai, Sabina Mendivil-Tuchia; Khan, Akram; Lora, Alfredo J Mena; Salathe, Matthias; Capo, Gerardo; Gonzalez, Daniel Rodríguez; Patterson, Thomas F; Palma, Christopher; Ariza, Horacio; Lima, Maria Patelli; Blamoun, John; Nannini, Esteban C; Sprinz, Eduardo; Mykietiuk, Analia; Alicic, Radica; Rauseo, Adriana M; Wolfe, Cameron R; Witting, Britta; Wang, Jennifer P; Parra-Rodriguez, Luis; Der, Tatyana; Willsey, Kate; Wen, Jun; Silverstein, Adam; O'Brien, Sean M; Al-Khalidi, Hussein R; Maldonado, Michael A; Melsheimer, Richard; Ferguson, William G; McNulty, Steven E; Zakroysky, Pearl; Halabi, Susan; Benjamin, Daniel K; Butler, Sandra; Atkinson, Jane C; Adam, Stacey J; Chang, Soju; LaVange, Lisa; Proschan, Michael; Bozzette, Samuel A; Powderly, William G; ACTIV-1 IM Study Group MembersImportance
Immune dysregulation contributes to poorer outcomes in COVID-19.Objective
To investigate whether abatacept, cenicriviroc, or infliximab provides benefit when added to standard care for COVID-19 pneumonia.Design, setting, and participants
Randomized, double-masked, placebo-controlled clinical trial using a master protocol to investigate immunomodulators added to standard care for treatment of participants hospitalized with COVID-19 pneumonia. The results of 3 substudies are reported from 95 hospitals at 85 clinical research sites in the US and Latin America. Hospitalized patients 18 years or older with confirmed SARS-CoV-2 infection within 14 days and evidence of pulmonary involvement underwent randomization between October 2020 and December 2021.Interventions
Single infusion of abatacept (10 mg/kg; maximum dose, 1000 mg) or infliximab (5 mg/kg) or a 28-day oral course of cenicriviroc (300-mg loading dose followed by 150 mg twice per day).Main outcomes and measures
The primary outcome was time to recovery by day 28 evaluated using an 8-point ordinal scale (higher scores indicate better health). Recovery was defined as the first day the participant scored at least 6 on the ordinal scale.Results
Of the 1971 participants randomized across the 3 substudies, the mean (SD) age was 54.8 (14.6) years and 1218 (61.8%) were men. The primary end point of time to recovery from COVID-19 pneumonia was not significantly different for abatacept (recovery rate ratio [RRR], 1.12 [95% CI, 0.98-1.28]; P = .09), cenicriviroc (RRR, 1.01 [95% CI, 0.86-1.18]; P = .94), or infliximab (RRR, 1.12 [95% CI, 0.99-1.28]; P = .08) compared with placebo. All-cause 28-day mortality was 11.0% for abatacept vs 15.1% for placebo (odds ratio [OR], 0.62 [95% CI, 0.41-0.94]), 13.8% for cenicriviroc vs 11.9% for placebo (OR, 1.18 [95% CI 0.72-1.94]), and 10.1% for infliximab vs 14.5% for placebo (OR, 0.59 [95% CI, 0.39-0.90]). Safety outcomes were comparable between active treatment and placebo, including secondary infections, in all 3 substudies.Conclusions and relevance
Time to recovery from COVID-19 pneumonia among hospitalized participants was not significantly different for abatacept, cenicriviroc, or infliximab vs placebo.Trial registration
ClinicalTrials.gov Identifier: NCT04593940.Item Open Access Author Correction: Mortality outcomes with hydroxychloroquine and chloroquine in COVID-19 from an international collaborative meta-analysis of randomized trials.(Nature communications, 2021-05-14) Axfors, Cathrine; Schmitt, Andreas M; Janiaud, Perrine; Van't Hooft, Janneke; Abd-Elsalam, Sherief; Abdo, Ehab F; Abella, Benjamin S; Akram, Javed; Amaravadi, Ravi K; Angus, Derek C; Arabi, Yaseen M; Azhar, Shehnoor; Baden, Lindsey R; Baker, Arthur W; Belkhir, Leila; Benfield, Thomas; Berrevoets, Marvin AH; Chen, Cheng-Pin; Chen, Tsung-Chia; Cheng, Shu-Hsing; Cheng, Chien-Yu; Chung, Wei-Sheng; Cohen, Yehuda Z; Cowan, Lisa N; Dalgard, Olav; de Almeida E Val, Fernando F; de Lacerda, Marcus VG; de Melo, Gisely C; Derde, Lennie; Dubee, Vincent; Elfakir, Anissa; Gordon, Anthony C; Hernandez-Cardenas, Carmen M; Hills, Thomas; Hoepelman, Andy IM; Huang, Yi-Wen; Igau, Bruno; Jin, Ronghua; Jurado-Camacho, Felipe; Khan, Khalid S; Kremsner, Peter G; Kreuels, Benno; Kuo, Cheng-Yu; Le, Thuy; Lin, Yi-Chun; Lin, Wu-Pu; Lin, Tse-Hung; Lyngbakken, Magnus Nakrem; McArthur, Colin; McVerry, Bryan J; Meza-Meneses, Patricia; Monteiro, Wuelton M; Morpeth, Susan C; Mourad, Ahmad; Mulligan, Mark J; Murthy, Srinivas; Naggie, Susanna; Narayanasamy, Shanti; Nichol, Alistair; Novack, Lewis A; O'Brien, Sean M; Okeke, Nwora Lance; Perez, Léna; Perez-Padilla, Rogelio; Perrin, Laurent; Remigio-Luna, Arantxa; Rivera-Martinez, Norma E; Rockhold, Frank W; Rodriguez-Llamazares, Sebastian; Rolfe, Robert; Rosa, Rossana; Røsjø, Helge; Sampaio, Vanderson S; Seto, Todd B; Shahzad, Muhammad; Soliman, Shaimaa; Stout, Jason E; Thirion-Romero, Ireri; Troxel, Andrea B; Tseng, Ting-Yu; Turner, Nicholas A; Ulrich, Robert J; Walsh, Stephen R; Webb, Steve A; Weehuizen, Jesper M; Velinova, Maria; Wong, Hon-Lai; Wrenn, Rebekah; Zampieri, Fernando G; Zhong, Wu; Moher, David; Goodman, Steven N; Ioannidis, John PA; Hemkens, Lars GThe original version of this Article contained an error in the spelling of the author Muhammad Shahzad, which was incorrectly given as Muhammad Shehzad. This has now been corrected in both the PDF and HTML versions of the Article.Item Open Access Author Correction: Mortality outcomes with hydroxychloroquine and chloroquine in COVID-19 from an international collaborative meta-analysis of randomized trials.(Nature communications, 2024-02) Axfors, Cathrine; Schmitt, Andreas M; Janiaud, Perrine; Van't Hooft, Janneke; Abd-Elsalam, Sherief; Abdo, Ehab F; Abella, Benjamin S; Akram, Javed; Amaravadi, Ravi K; Angus, Derek C; Arabi, Yaseen M; Azhar, Shehnoor; Baden, Lindsey R; Baker, Arthur W; Belkhir, Leila; Benfield, Thomas; Berrevoets, Marvin AH; Chen, Cheng-Pin; Chen, Tsung-Chia; Cheng, Shu-Hsing; Cheng, Chien-Yu; Chung, Wei-Sheng; Cohen, Yehuda Z; Cowan, Lisa N; Dalgard, Olav; de Almeida E Val, Fernando F; de Lacerda, Marcus VG; de Melo, Gisely C; Derde, Lennie; Dubee, Vincent; Elfakir, Anissa; Gordon, Anthony C; Hernandez-Cardenas, Carmen M; Hills, Thomas; Hoepelman, Andy IM; Huang, Yi-Wen; Igau, Bruno; Jin, Ronghua; Jurado-Camacho, Felipe; Khan, Khalid S; Kremsner, Peter G; Kreuels, Benno; Kuo, Cheng-Yu; Le, Thuy; Lin, Yi-Chun; Lin, Wu-Pu; Lin, Tse-Hung; Lyngbakken, Magnus Nakrem; McArthur, Colin; McVerry, Bryan J; Meza-Meneses, Patricia; Monteiro, Wuelton M; Morpeth, Susan C; Mourad, Ahmad; Mulligan, Mark J; Murthy, Srinivas; Naggie, Susanna; Narayanasamy, Shanti; Nichol, Alistair; Novack, Lewis A; O'Brien, Sean M; Okeke, Nwora Lance; Perez, Léna; Perez-Padilla, Rogelio; Perrin, Laurent; Remigio-Luna, Arantxa; Rivera-Martinez, Norma E; Rockhold, Frank W; Rodriguez-Llamazares, Sebastian; Rolfe, Robert; Rosa, Rossana; Røsjø, Helge; Sampaio, Vanderson S; Seto, Todd B; Shahzad, Muhammad; Soliman, Shaimaa; Stout, Jason E; Thirion-Romero, Ireri; Troxel, Andrea B; Tseng, Ting-Yu; Turner, Nicholas A; Ulrich, Robert J; Walsh, Stephen R; Webb, Steve A; Weehuizen, Jesper M; Velinova, Maria; Wong, Hon-Lai; Wrenn, Rebekah; Zampieri, Fernando G; Zhong, Wu; Moher, David; Goodman, Steven N; Ioannidis, John PA; Hemkens, Lars GCorrection to: Nature Communicationshttps://doi.org/10.1038/s41467-021-22446-z, published online 15 April 2021 The original version of this article contained an error in Table 1, which misidentified the trial included in the meta-analysis registered as NCT04323527 as CloroCOVID19II instead of CloroCOVID19III. The NCT04323527 registration includes the trials CloroCOVID19I and CloroCOVID19III. CloroCOVID19I was not included in the meta-analysis. In addition, the original version of the Methods section inadvertently omitted details of which formulations of hydroxychloroquine or chloroquine the reported dosages refer to. The following information has been included in the legend for Table 1 and in the corrected methods section: “In all trials that used hydroxychloroquine, dosages refer to hydroxychloroquine sulfate. In trials that used chloroquine, the dosages for ARCHAIC, ChiCTR2000030054 and ChiCTR2000031204 refer to chloroquine phosphate, while those for CloroCOVID19II and CloroCOVID19III refer to chloroquine base. The American Journal of Tropical Medicine and Hygiene has issued a retraction note (1) for one of the trials (2) that had been included in the calculations of our meta-analysis. Exclusion of the data from this trial changes neither the results nor inferences of the meta-analysis. For hydroxychloroquine, the original odds ratio for mortality was 1.11 (95% CI: 1.02–1.20; I2 = 0%; 26 trials; 10,012 patients) and excluding the retracted trial the odds ratio for mortality would remain 1.11 (95% CI: 1.02–1.20, I2 = 0%; 25 trials; 9818 patients). Retraction Notice. The American Journal of Tropical Medicine and Hygiene 107, 728-728, https://doi.org/10.4269/ajtmh.1073ret (2022). Abd-Elsalam, S. et al. RETRACTED: Hydroxychloroquine in the Treatment of COVID-19: A Multicenter Randomized Controlled Study. Am J Trop Med Hyg 103, 1635-1639, https://doi.org/10.4269/ajtmh.20-0873 (2020). The errors in Table 1 and in the Methods section have been corrected in both the PDF and HTML versions of the Article.Item Open Access COVID-19 Trials: Who Participates and Who Benefits?(Southern medical journal, 2022-04) Narayanasamy, Shanti; Mourad, Ahmad; Turner, Nicholas A; Le, Thuy; Rolfe, Robert J; Okeke, Nwora Lance; O'Brien, Sean M; Baker, Arthur W; Wrenn, Rebekah; Rosa, Rossana; Rockhold, Frank W; Naggie, Susanna; Stout, Jason EObjectives
The coronavirus disease 2019 (COVID-19) pandemic has disproportionately afflicted vulnerable populations. Older adults, particularly residents of nursing facilities, represent a small percentage of the population but account for 40% of mortality from COVID-19 in the United States. Racial and ethnic minority individuals, particularly Black, Hispanic, and Indigenous Americans have experienced higher rates of infection and death than the White population. Although there has been an unprecedented explosion of clinical trials to examine potential therapies, participation by members of these vulnerable communities is crucial to obtaining data generalizable to those communities.Methods
We undertook an open-label, factorial randomized clinical trial examining hydroxychloroquine and/or azithromycin for hospitalized patients.Results
Of 53 screened patients, 11 (21%) were enrolled. Ten percent (3/31) of Black patients were enrolled, 33% (7/21) of White patients, and 50% (6/12) of Hispanic patients. Forty-seven percent (25/53) of patients declined participation despite eligibility; 58%(18/31) of Black patients declined participation. Forty percent (21/53) of screened patients were from a nursing facility and 10% (2/21) were enrolled. Enrolled patients had fewer comorbidities than nonenrolled patients: median modified Charlson comorbidity score 2.0 (interquartile range 0-2.5), versus 4.0 (interquartile range 2-6) for nonenrolled patients (P = 0.006). The limitations of the study were the low participation rate and the multiple treatment trials concurrently recruiting at our institution.Conclusions
The high rate of nonparticipation in our trial of nursing facility residents and Black people emphasizes the concern that clinical trials for therapeutics may not target key populations with high mortality rates.Item Open Access Extending Probabilistic Record Linkage(2020) Solomon, Nicole ChanelProbabilistic record linkage is the task of combining multiple data sources for statistical analysis by identifying records pertaining to the same individual in different databases. The need to perform probabilistic record linkage arises in comparative effectiveness research and other clinical research scenarios when records in different databases do not share an error-free unique patient identifier. This dissertation seeks to develop new methodology for probabilistic record linkage to address two highly practical and recurring challenges: how to implement record linkage in a manner that optimizes downstream statistical analyses of the linked data, and how to efficiently link databases having a clustered or multi-level data structure.
In Chapter 2 we propose a new framework for balancing the tradeoff between false positive and false negative linkage errors when linked data are analyzed in a generalized linear model framework and non-linked records lead to missing data for the study outcome variable. Our method seeks to maximize the probability that the point estimate of the parameter of interest will have the correct sign and that the confidence interval around this estimate will correctly exclude the null value of zero. Using large sample approximations and a model for linkage errors, we derive expressions relating bias and hypothesis testing power to the user's choice of threshold that determines how many records will be linked. We use these results to propose three data-driven threshold selection rules. Under one set of simplifying assumptions we prove that maximizing asymptotic power requires that the threshold be relaxed at least until the point where all pairs with >50% probability of being a true match are linked.
In Chapter 3 we explore the consequences of linkage errors when the study outcome variable is determined by linkage status and so linkage errors may cause outcome misclassification. This scenario arises when the outcome is disease status and those linked are classified as having the disease while those not linked are classified as disease-free. We assume the parameter of interest can be expressed as a linear combination of binomial proportions having mean zero under the null hypothesis. We derive an expression for the asymptotic relative efficiency of a Wald test calculated with a misclassified outcome compared to an error-free outcome using a linkage error model and large sample approximations. We use this expression to generate insights for planning and implementing studies using record linkage.
In Chapter 4 we develop a modeling framework for linking files with a clustered data structure. Linking such clustered data is especially challenging when error-free identifiers are unavailable for both individual-level and cluster-level units. The proposed approach improves over current methodology by modeling inter-pair dependencies in clustered data and producing collective link decisions. It is novel in that it models both record attributes and record relationships, and resolves match statuses for individual-level and cluster-level units simultaneously. We show that linkage probabilities can be estimated without labeled training data using assumptions that are less restrictive compared to existing record linkage models. Using Monte Carlo simulations based on real study data, we demonstrate its advantages over the current standard method.
Item Open Access Mortality outcomes with hydroxychloroquine and chloroquine in COVID-19 from an international collaborative meta-analysis of randomized trials.(Nature communications, 2021-04-15) Axfors, Cathrine; Schmitt, Andreas M; Janiaud, Perrine; Van't Hooft, Janneke; Abd-Elsalam, Sherief; Abdo, Ehab F; Abella, Benjamin S; Akram, Javed; Amaravadi, Ravi K; Angus, Derek C; Arabi, Yaseen M; Azhar, Shehnoor; Baden, Lindsey R; Baker, Arthur W; Belkhir, Leila; Benfield, Thomas; Berrevoets, Marvin AH; Chen, Cheng-Pin; Chen, Tsung-Chia; Cheng, Shu-Hsing; Cheng, Chien-Yu; Chung, Wei-Sheng; Cohen, Yehuda Z; Cowan, Lisa N; Dalgard, Olav; de Almeida E Val, Fernando F; de Lacerda, Marcus VG; de Melo, Gisely C; Derde, Lennie; Dubee, Vincent; Elfakir, Anissa; Gordon, Anthony C; Hernandez-Cardenas, Carmen M; Hills, Thomas; Hoepelman, Andy IM; Huang, Yi-Wen; Igau, Bruno; Jin, Ronghua; Jurado-Camacho, Felipe; Khan, Khalid S; Kremsner, Peter G; Kreuels, Benno; Kuo, Cheng-Yu; Le, Thuy; Lin, Yi-Chun; Lin, Wu-Pu; Lin, Tse-Hung; Lyngbakken, Magnus Nakrem; McArthur, Colin; McVerry, Bryan J; Meza-Meneses, Patricia; Monteiro, Wuelton M; Morpeth, Susan C; Mourad, Ahmad; Mulligan, Mark J; Murthy, Srinivas; Naggie, Susanna; Narayanasamy, Shanti; Nichol, Alistair; Novack, Lewis A; O'Brien, Sean M; Okeke, Nwora Lance; Perez, Léna; Perez-Padilla, Rogelio; Perrin, Laurent; Remigio-Luna, Arantxa; Rivera-Martinez, Norma E; Rockhold, Frank W; Rodriguez-Llamazares, Sebastian; Rolfe, Robert; Rosa, Rossana; Røsjø, Helge; Sampaio, Vanderson S; Seto, Todd B; Shahzad, Muhammad; Soliman, Shaimaa; Stout, Jason E; Thirion-Romero, Ireri; Troxel, Andrea B; Tseng, Ting-Yu; Turner, Nicholas A; Ulrich, Robert J; Walsh, Stephen R; Webb, Steve A; Weehuizen, Jesper M; Velinova, Maria; Wong, Hon-Lai; Wrenn, Rebekah; Zampieri, Fernando G; Zhong, Wu; Moher, David; Goodman, Steven N; Ioannidis, John PA; Hemkens, Lars GSubstantial COVID-19 research investment has been allocated to randomized clinical trials (RCTs) on hydroxychloroquine/chloroquine, which currently face recruitment challenges or early discontinuation. We aim to estimate the effects of hydroxychloroquine and chloroquine on survival in COVID-19 from all currently available RCT evidence, published and unpublished. We present a rapid meta-analysis of ongoing, completed, or discontinued RCTs on hydroxychloroquine or chloroquine treatment for any COVID-19 patients (protocol: https://osf.io/QESV4/ ). We systematically identified unpublished RCTs (ClinicalTrials.gov, WHO International Clinical Trials Registry Platform, Cochrane COVID-registry up to June 11, 2020), and published RCTs (PubMed, medRxiv and bioRxiv up to October 16, 2020). All-cause mortality has been extracted (publications/preprints) or requested from investigators and combined in random-effects meta-analyses, calculating odds ratios (ORs) with 95% confidence intervals (CIs), separately for hydroxychloroquine and chloroquine. Prespecified subgroup analyses include patient setting, diagnostic confirmation, control type, and publication status. Sixty-three trials were potentially eligible. We included 14 unpublished trials (1308 patients) and 14 publications/preprints (9011 patients). Results for hydroxychloroquine are dominated by RECOVERY and WHO SOLIDARITY, two highly pragmatic trials, which employed relatively high doses and included 4716 and 1853 patients, respectively (67% of the total sample size). The combined OR on all-cause mortality for hydroxychloroquine is 1.11 (95% CI: 1.02, 1.20; I² = 0%; 26 trials; 10,012 patients) and for chloroquine 1.77 (95%CI: 0.15, 21.13, I² = 0%; 4 trials; 307 patients). We identified no subgroup effects. We found that treatment with hydroxychloroquine is associated with increased mortality in COVID-19 patients, and there is no benefit of chloroquine. Findings have unclear generalizability to outpatients, children, pregnant women, and people with comorbidities.