Predicting and Surviving Prolonged Critical Illness After Congenital Heart Surgery

Overview

Journal Crit Care Med

Specialties Critical Care
Emergency Medicine

Date 2020 Jun 24

PMID 32574468

Citations 7

Authors

Aaron G DeWitt

Joseph W Rossano

David K Bailly

Priya N Bhat

Nikhil K Chanani

Brandon W Kirkland

Michael-Alice Moga

Gabe E Owens

Lauren B Retzloff

Wenying Zhang

Mousumi Banerjee

Andrew T Costarino

Geoffrey L Bird

Michael Gaies

Affiliations

Soon will be listed here.

Abstract

Objectives: Prolonged critical illness after congenital heart surgery disproportionately harms patients and the healthcare system, yet much remains unknown. We aimed to define prolonged critical illness, delineate between nonmodifiable and potentially preventable predictors of prolonged critical illness and prolonged critical illness mortality, and understand the interhospital variation in prolonged critical illness.

Design: Observational analysis.

Setting: Pediatric Cardiac Critical Care Consortium clinical registry.

Patients: All patients, stratified into neonates (≤28 d) and nonneonates (29 d to 18 yr), admitted to the pediatric cardiac ICU after congenital heart surgery at Pediatric Cardiac Critical Care Consortium hospitals.

Interventions: None.

Measurements And Main Results: There were 2,419 neonates and 10,687 nonneonates from 22 hospitals. The prolonged critical illness cutoff (90th percentile length of stay) was greater than or equal to 35 and greater than or equal to 10 days for neonates and nonneonates, respectively. Cardiac ICU prolonged critical illness mortality was 24% in neonates and 8% in nonneonates (vs 5% and 0.4%, respectively, in nonprolonged critical illness patients). Multivariable logistic regression identified 10 neonatal and 19 nonneonatal prolonged critical illness predictors within strata and eight predictors of mortality. Only mechanical ventilation days and acute renal failure requiring renal replacement therapy predicted prolonged critical illness and prolonged critical illness mortality in both strata. Approximately 40% of the prolonged critical illness predictors were nonmodifiable (preoperative/patient and operative factors), whereas only one of eight prolonged critical illness mortality predictors was nonmodifiable. The remainders were potentially preventable (postoperative critical care delivery variables and complications). Case-mix-adjusted prolonged critical illness rates were compared across hospitals; six hospitals each had lower- and higher-than-expected prolonged critical illness frequency.

Conclusions: Although many prolonged critical illness predictors are nonmodifiable, we identified several predictors to target for improvement. Furthermore, we observed that complications and prolonged critical care therapy drive prolonged critical illness mortality. Wide variation of prolonged critical illness frequency suggests that identifying practices at hospitals with lower-than-expected prolonged critical illness could lead to broader quality improvement initiatives.

Citing Articles

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Perioperative exposure to volatile organic compounds in neonates undergoing cardiac surgery.

Gaynor J, Graham E, Bhandari D, Fenchel M, Bradman A, Klepczynski B J Thorac Cardiovasc Surg. 2023; 167(3):1166-1176.e2.

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Annexin A2 Loss After Cardiopulmonary Bypass and Development of Acute Postoperative Respiratory Dysfunction in Children.

Hsing D, Stock A, Greenwald B, Bacha E, Flynn P, Carroll S Crit Care Explor. 2023; 5(2):e0862.

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Characterization of "ICU-30": A Binary Composite Outcome for Neonates With Critical Congenital Heart Disease.

Gardner M, Keim G, Hsia J, Mai A, Gaynor J, Glatz A J Am Heart Assoc. 2022; 11(12):e025494.

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Motor development in infants with complex congenital heart disease: A longitudinal study.

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PMID: 35665492 PMC: 10084079. DOI: 10.1111/dmcn.15287.

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