Predicting heart failure outcomes by integrating breath-by-breath measurements from cardiopulmonary exercise testing and clinical data through a deep learning survival neural network

Heather J Ross; Mohammad Peikari; Julie K K Vishram-Nielsen; Chun-Po S Fan; Jason Hearn; Mike Walker; Edgar Crowdy; Ana Carolina Alba; Cedric Manlhiot

doi:10.1093/ehjdh/ztae005

Predicting heart failure outcomes by integrating breath-by-breath measurements from cardiopulmonary exercise testing and clinical data through a deep learning survival neural network

Eur Heart J Digit Health. 2024 Jan 31;5(3):324-334. doi: 10.1093/ehjdh/ztae005. eCollection 2024 May.

Authors

Heather J Ross¹, Mohammad Peikari¹, Julie K K Vishram-Nielsen¹, Chun-Po S Fan¹, Jason Hearn¹, Mike Walker¹, Edgar Crowdy¹, Ana Carolina Alba¹, Cedric Manlhiot^{1

2}

Affiliations

¹ The Ted Rogers Centre for Heart Research, Peter Munk Cardiac Centre, University Health Network, Department of Medicine, University of Toronto, 200 Elizabeth Street, Toronto, ON M5G 2C4, Canada.
² The Blalock-Taussig-Thomas Pediatric and Congenital Heart Center, Department of Pediatrics, Johns Hopkins School of Medicine, Johns Hopkins University, 1800 Orleans Street, Baltimore, MD 21287, USA.

Abstract

Aims: Mathematical models previously developed to predict outcomes in patients with heart failure (HF) generally have limited performance and have yet to integrate complex data derived from cardiopulmonary exercise testing (CPET), including breath-by-breath data. We aimed to develop and validate a time-to-event prediction model using a deep learning framework using the DeepSurv algorithm to predict outcomes of HF.

Methods and results: Inception cohort of 2490 adult patients with high-risk cardiac conditions or HF underwent CPET with breath-by-breath measurements. Potential predictive features included known clinical indicators, standard summary statistics from CPETs, and mathematical features extracted from the breath-by-breath time series of 13 measurements. The primary outcome was a composite of death, heart transplant, or mechanical circulatory support treated as a time-to-event outcomes. Predictive features ranked as most important included many of the features engineered from the breath-by-breath data in addition to traditional clinical risk factors. The prediction model showed excellent performance in predicting the composite outcome with an area under the curve of 0.93 in the training and 0.87 in the validation data sets. Both the predicted vs. actual freedom from the composite outcome and the calibration of the prediction model were excellent. Model performance remained stable in multiple subgroups of patients.

Conclusion: Using a combined deep learning and survival algorithm, integrating breath-by-breath data from CPETs resulted in improved predictive accuracy for long-term (up to 10 years) outcomes in HF. DeepSurv opens the door for future prediction models that are both highly performing and can more fully use the large and complex quantity of data generated during the care of patients with HF.

Keywords: Exercise testing; Heart failure; Machine learning; Prognosis; Survival analysis.