A machine-learning regional clustering approach to understand ventilator-induced lung injury: a proof-of-concept experimental study

Pablo Cruces, Jaime Retamal, Andrés Damián, Graciela Lago, Fernanda Blasina, Vanessa Oviedo, Tania Medina, Agustín Pérez, Lucía Vaamonde, Rosina Dapueto, Sebastian González-Dambrauskas, Alberto Serra, Nicolas Monteverde-Fernandez, Mauro Namías, Javier Martínez, Daniel E. Hurtado

Research output: Contribution to journalArticlepeer-review

Abstract

Background: The spatiotemporal progression and patterns of tissue deformation in ventilator-induced lung injury (VILI) remain understudied. Our aim was to identify lung clusters based on their regional mechanical behavior over space and time in lungs subjected to VILI using machine-learning techniques. Results: Ten anesthetized pigs (27 ± 2 kg) were studied. Eight subjects were analyzed. End-inspiratory and end-expiratory lung computed tomography scans were performed at the beginning and after 12 h of one-hit VILI model. Regional image-based biomechanical analysis was used to determine end-expiratory aeration, tidal recruitment, and volumetric strain for both early and late stages. Clustering analysis was performed using principal component analysis and K-Means algorithms. We identified three different clusters of lung tissue: Stable, Recruitable Unstable, and Non-Recruitable Unstable. End-expiratory aeration, tidal recruitment, and volumetric strain were significantly different between clusters at early stage. At late stage, we found a step loss of end-expiratory aeration among clusters, lowest in Stable, followed by Unstable Recruitable, and highest in the Unstable Non-Recruitable cluster. Volumetric strain remaining unchanged in the Stable cluster, with slight increases in the Recruitable cluster, and strong reduction in the Unstable Non-Recruitable cluster. Conclusions: VILI is a regional and dynamic phenomenon. Using unbiased machine-learning techniques we can identify the coexistence of three functional lung tissue compartments with different spatiotemporal regional biomechanical behavior.

Original languageEnglish
Article number60
JournalIntensive Care Medicine Experimental
Volume12
Issue number1
DOIs
Publication statusPublished - Dec 2024

Keywords

  • Computed tomography
  • Diagnostic imaging
  • Lung strain
  • Mechanical ventilation
  • Ventilator-induced lung injury

ASJC Scopus subject areas

  • Emergency Medicine
  • Critical Care and Intensive Care Medicine
  • Physiology (medical)

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