One key problem in modern medical imaging is linking measured data and actual physiological quantities. In this article we derive such a link between the electrical bioimpedance of lung parenchyma, which can be measured
by electrical impedance tomography (EIT), and the magnitude of regional ventilation, a key towards understanding lung mechanics and developing novel protective ventilation strategies. Two rat-derived three-dimensional alveolar
microstructures obtained from synchrotron-based X-ray tomography are each exposed to a constant potential difference for different states of ventilation in a finite element simulation. While the alveolar wall volume remains constant
during stretch, the enclosed air volume varies, similar to the lung volume during ventilation. The enclosed air, serving as insulator in the alveolar ensemble, determines the resulting current and accordingly local tissue bioimpedance.
From this we can derive a relationship between lung tissue bioimpedance and regional alveolar ventilation. The derived relationship shows linear dependency between air content and tissue impedance and matches clinical data determined from a ventilated patient at bedside.
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One key problem in modern medical imaging is linking measured data and actual physiological quantities. In this article we derive such a link between the electrical bioimpedance of lung parenchyma, which can be measured
by electrical impedance tomography (EIT), and the magnitude of regional ventilation, a key towards understanding lung mechanics and developing novel protective ventilation strategies. Two rat-derived three-dimensional alveolar
microstructures obtained from synchrotron-based X-r...
»