. 2020 Sep 4;15(9):e0238199.

doi: 10.1371/journal.pone.0238199. eCollection 2020.

Improving preoperative risk-of-death prediction in surgery congenital heart defects using artificial intelligence model: A pilot study

João Chang Junior^{1

2

3}, Fábio Binuesa¹, Luiz Fernando Caneo¹, Aida Luiza Ribeiro Turquetto^{1

4}, Elisandra Cristina Trevisan Calvo Arita¹, Aline Cristina Barbosa¹, Alfredo Manoel da Silva Fernandes¹, Evelinda Marramon Trindade^{1

4

5}, Fábio Biscegli Jatene¹, Paul-Eric Dossou⁶, Marcelo Biscegli Jatene¹

Affiliations

¹ Department of Cardiovascular Surgery-Pediatric Cardiac Unit, Heart Institute of University of São Paulo Medical School-HCFMUSP-InCor, São Paulo, Brazil.
² Fundação Armando Alvares Penteado-FAAP, São Paulo, Brazil.
³ Escola Superior de Engenharia e Gestão-ESEG, São Paulo, Brazil.
⁴ Health Technology Assessment Center of Clinics Hospital-NATS-HCFMUSP, São Paulo, Brazil.
⁵ São Paulo State Health Secretariat-SES-SP, São Paulo, Brazil.
⁶ Institut Catholique des Arts et Métiers-Icam, Paris-Sénart, France.

PMID: 32886688
PMCID: PMC7473591
DOI: 10.1371/journal.pone.0238199

Improving preoperative risk-of-death prediction in surgery congenital heart defects using artificial intelligence model: A pilot study

João Chang Junior et al. PLoS One. 2020.

. 2020 Sep 4;15(9):e0238199.

doi: 10.1371/journal.pone.0238199. eCollection 2020.

Authors

Affiliations

¹ Department of Cardiovascular Surgery-Pediatric Cardiac Unit, Heart Institute of University of São Paulo Medical School-HCFMUSP-InCor, São Paulo, Brazil.
² Fundação Armando Alvares Penteado-FAAP, São Paulo, Brazil.
³ Escola Superior de Engenharia e Gestão-ESEG, São Paulo, Brazil.
⁴ Health Technology Assessment Center of Clinics Hospital-NATS-HCFMUSP, São Paulo, Brazil.
⁵ São Paulo State Health Secretariat-SES-SP, São Paulo, Brazil.
⁶ Institut Catholique des Arts et Métiers-Icam, Paris-Sénart, France.

PMID: 32886688
PMCID: PMC7473591
DOI: 10.1371/journal.pone.0238199

Abstract

Background: Congenital heart disease accounts for almost a third of all major congenital anomalies. Congenital heart defects have a significant impact on morbidity, mortality and health costs for children and adults. Research regarding the risk of pre-surgical mortality is scarce.

Objectives: Our goal is to generate a predictive model calculator adapted to the regional reality focused on individual mortality prediction among patients with congenital heart disease undergoing cardiac surgery.

Methods: Two thousand two hundred forty CHD consecutive patients' data from InCor's heart surgery program was used to develop and validate the preoperative risk-of-death prediction model of congenital patients undergoing heart surgery. There were six artificial intelligence models most cited in medical references used in this study: Multilayer Perceptron (MLP), Random Forest (RF), Extra Trees (ET), Stochastic Gradient Boosting (SGB), Ada Boost Classification (ABC) and Bag Decision Trees (BDT).

Results: The top performing areas under the curve were achieved using Random Forest (0.902). Most influential predictors included previous admission to ICU, diagnostic group, patient's height, hypoplastic left heart syndrome, body mass, arterial oxygen saturation, and pulmonary atresia. These combined predictor variables represent 67.8% of importance for the risk of mortality in the Random Forest algorithm.

Conclusions: The representativeness of "hospital death" is greater in patients up to 66 cm in height and body mass index below 13.0 for InCor's patients. The proportion of "hospital death" declines with the increased arterial oxygen saturation index. Patients with prior hospitalization before surgery had higher "hospital death" rates than who did not required such intervention. The diagnoses groups having the higher fatal outcomes probability are aligned with the international literature. A web application is presented where researchers and providers can calculate predicted mortality based on the CgntSCORE on any web browser or smartphone.

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Conflict of interest statement

The authors have declared that no competing interests exist.

Figures

**Fig 1. Steps performed in the model development.**

**Fig 3. Confusion matrix of the RF algorithm.**

**Fig 4. Performance metrics of the RF algorithm.**

**Fig 5. ROC AUC curve of the RF algorithm.**

**Fig 6. Precision-Recall curve of the RF algorithm.**

See this image and copyright information in PMC

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References

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Improving preoperative risk-of-death prediction in surgery congenital heart defects using artificial intelligence model: A pilot study

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Improving preoperative risk-of-death prediction in surgery congenital heart defects using artificial intelligence model: A pilot study

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