Monotonicity-based electrical impedance tomography for lung imaging

Liangdong Zhou; Bastian Harrach; Jin Keun Seo

doi:10.1088/1361-6420/aaaf84

Monotonicity-based electrical impedance tomography for lung imaging

Liangdong Zhou, Bastian Harrach, Jin Keun Seo

Research output: Contribution to journal › Article › peer-review

46 Scopus citations

Abstract

This paper presents a monotonicity-based spatiotemporal conductivity imaging method for continuous regional lung monitoring using electrical impedance tomography (EIT). The EIT data (i.e. the boundary current-voltage data) can be decomposed into pulmonary, cardiac and other parts using their different periodic natures. The time-differential current-voltage operator corresponding to the lung ventilation can be viewed as either semi-positive or semi-negative definite owing to monotonic conductivity changes within the lung regions. We used these monotonicity constraints to improve the quality of lung EIT imaging. We tested the proposed methods in numerical simulations, phantom experiments and human experiments.

Original language	English
Article number	045005
Journal	Inverse Problems
Volume	34
Issue number	4
DOIs	https://doi.org/10.1088/1361-6420/aaaf84
State	Published - 2 Mar 2018
Externally published	Yes

Keywords

continuous lung monitoring
electrical impedance tomography
inverse problem
monotonicity
monotonicity-based regularization

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10.1088/1361-6420/aaaf84

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title = "Monotonicity-based electrical impedance tomography for lung imaging",

abstract = "This paper presents a monotonicity-based spatiotemporal conductivity imaging method for continuous regional lung monitoring using electrical impedance tomography (EIT). The EIT data (i.e. the boundary current-voltage data) can be decomposed into pulmonary, cardiac and other parts using their different periodic natures. The time-differential current-voltage operator corresponding to the lung ventilation can be viewed as either semi-positive or semi-negative definite owing to monotonic conductivity changes within the lung regions. We used these monotonicity constraints to improve the quality of lung EIT imaging. We tested the proposed methods in numerical simulations, phantom experiments and human experiments.",

keywords = "continuous lung monitoring, electrical impedance tomography, inverse problem, monotonicity, monotonicity-based regularization",

author = "Liangdong Zhou and Bastian Harrach and Seo, {Jin Keun}",

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AU - Zhou, Liangdong

AU - Harrach, Bastian

AU - Seo, Jin Keun

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Y1 - 2018/3/2

N2 - This paper presents a monotonicity-based spatiotemporal conductivity imaging method for continuous regional lung monitoring using electrical impedance tomography (EIT). The EIT data (i.e. the boundary current-voltage data) can be decomposed into pulmonary, cardiac and other parts using their different periodic natures. The time-differential current-voltage operator corresponding to the lung ventilation can be viewed as either semi-positive or semi-negative definite owing to monotonic conductivity changes within the lung regions. We used these monotonicity constraints to improve the quality of lung EIT imaging. We tested the proposed methods in numerical simulations, phantom experiments and human experiments.

AB - This paper presents a monotonicity-based spatiotemporal conductivity imaging method for continuous regional lung monitoring using electrical impedance tomography (EIT). The EIT data (i.e. the boundary current-voltage data) can be decomposed into pulmonary, cardiac and other parts using their different periodic natures. The time-differential current-voltage operator corresponding to the lung ventilation can be viewed as either semi-positive or semi-negative definite owing to monotonic conductivity changes within the lung regions. We used these monotonicity constraints to improve the quality of lung EIT imaging. We tested the proposed methods in numerical simulations, phantom experiments and human experiments.

KW - continuous lung monitoring

KW - electrical impedance tomography

KW - inverse problem

KW - monotonicity

KW - monotonicity-based regularization

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VL - 34

JO - Inverse Problems

JF - Inverse Problems

IS - 4

M1 - 045005

ER -

Monotonicity-based electrical impedance tomography for lung imaging

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Keywords

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