CT-based lung geometry for high-resolution modelling of cardiopulmonary interaction

Krzysztof Jakub Pałko; Dariusz Kołodziej; Tomasz Urbankowski; Jerzy Walecki; Tadeusz Pałko; Marek Darowski

doi:10.2478/pjmpe-2026-0007

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CT-based lung geometry for high-resolution modelling of cardiopulmonary interaction

Polish Journal of Medical Physics and Engineering

Volume 32 (2026): Issue 2 (June 2026)

By: Krzysztof Jakub Pałko , Dariusz Kołodziej , Tomasz Urbankowski , Jerzy Walecki , Tadeusz Pałko and Marek Darowski

Open Access

|Jun 2026

Abstract

Background

Accurate representation of lung geometry is a prerequisite for reliable computational modelling of cardiopulmonary interaction, particularly for simulating regional ventilation–perfusion (V/Q) heterogeneity driven by gravity and vascular anatomy. Most existing models either simplify lung geometry or lack explicit spatial anchoring to physiological reference points.

Material and methods

In this study, diagnostic computed tomography (CT) images were used to reconstruct anatomically faithful lung geometry and subdivide both lungs into 80 spatially coherent regions. For each region, a set of geometric parameters was extracted, including volume and three-dimensional coordinates of the centre of gravity relative to the pulmonary trunk and to horizontal and vertical reference planes. Image preprocessing, vectorization, and geometric reconstruction were performed using widely available software tools, and the resulting feature matrix was implemented in a mathematical model of cardiopulmonary interaction within a virtual patient environment.

Results

The CT-based approach enabled precise localization of the pulmonary trunk and consistent definition of a global coordinate system, allowing simultaneous representation of vertical (gravitational) and radial (vascular resistance–related) perfusion gradients. Example simulations demonstrated physiologically plausible distributions of ventilation and perfusion across lung regions, including reduced ventilation in dependent areas and heterogeneous perfusion within iso-gravitational planes.

Conclusions

CT-based reconstruction of lung geometry from diagnostic images enables high-resolution regional partitioning and generation of a robust geometric matrix suitable for cardiopulmonary simulations. Although limited to a single anatomical dataset and static geometry, the presented model provides a solid foundation for future integration of regional mechanics, dynamic deformation, and validation with functional imaging, supporting advanced research, educational, and clinical applications.

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Articles in this issue

DOI: https://doi.org/10.2478/pjmpe-2026-0007 | Journal eISSN: 1898-0309 | Journal ISSN: 1425-4689

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Language: English

Page range: 59 - 71

Submitted on: Feb 11, 2026

Accepted on: Apr 16, 2026

Published on: Jun 2, 2026

Published by: Polish Society of Medical Physics

In partnership with: Paradigm Publishing Services

Publication frequency: 4 issues per year

Keywords:

CT-based lung reconstruction,

geometric parameters,

modelling,

cardiopulmonary interaction

Related subjects:

Medicine,

Biomedical engineering,

Physics,

Technical and applied physics,

Medical physics

© 2026 Krzysztof Jakub Pałko, Dariusz Kołodziej, Tomasz Urbankowski, Jerzy Walecki, Tadeusz Pałko, Marek Darowski, published by Polish Society of Medical Physics
This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 License.

Volume 32 (2026): Issue 2 (June 2026)