Intensive Care Medicine Experimental (Jul 2024)

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

DOI
https://doi.org/10.1186/s40635-024-00641-8
Journal volume & issue
Vol. 12, no. 1
pp. 1 – 9

Abstract

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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.

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