Automatic patient-ventilator asynchrony detection framework using objective asynchrony definitions

Lars van de Kamp; Joey Reinders; Bram Hunnekens; Tom Oomen; Nathan van de Wouw

doi:10.1016/j.ifacsc.2023.100236

Automatic patient-ventilator asynchrony detection framework using objective asynchrony definitions

Lars van de Kamp (Corresponding author), Joey Reinders, Bram Hunnekens, Tom Oomen, Nathan van de Wouw

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

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Abstract

Patient-ventilator asynchrony is one of the largest challenges in mechanical ventilation and is associated with prolonged ICU stay and increased mortality. The aim of this paper is to automatically detect and classify the different types of patient-ventilator asynchronies during a patient's breath using the typically available data on commercially available ventilators. This is achieved by a detection and classification framework using an objective definition of asynchrony and a supervised learning approach. The achieved detection performance of the near-real time framework on a clinical dataset is a significant improvement over current clinical practice, therewith and, this framework has the potential to significantly improve the patient comfort and treatment outcomes.

Original language	English
Article number	100236
Number of pages	10
Journal	IFAC Journal of Systems and Control
Volume	27
DOIs	https://doi.org/10.1016/j.ifacsc.2023.100236
Publication status	Published - Mar 2024

Keywords

Classification
Detection
Mechanical ventilation
Patient-ventilator asynchrony
Recurrent neural networks
Supervised learning

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10.1016/j.ifacsc.2023.100236

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title = "Automatic patient-ventilator asynchrony detection framework using objective asynchrony definitions",

abstract = "Patient-ventilator asynchrony is one of the largest challenges in mechanical ventilation and is associated with prolonged ICU stay and increased mortality. The aim of this paper is to automatically detect and classify the different types of patient-ventilator asynchronies during a patient's breath using the typically available data on commercially available ventilators. This is achieved by a detection and classification framework using an objective definition of asynchrony and a supervised learning approach. The achieved detection performance of the near-real time framework on a clinical dataset is a significant improvement over current clinical practice, therewith and, this framework has the potential to significantly improve the patient comfort and treatment outcomes.",

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AU - Oomen, Tom

AU - van de Wouw, Nathan

PY - 2024/3

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N2 - Patient-ventilator asynchrony is one of the largest challenges in mechanical ventilation and is associated with prolonged ICU stay and increased mortality. The aim of this paper is to automatically detect and classify the different types of patient-ventilator asynchronies during a patient's breath using the typically available data on commercially available ventilators. This is achieved by a detection and classification framework using an objective definition of asynchrony and a supervised learning approach. The achieved detection performance of the near-real time framework on a clinical dataset is a significant improvement over current clinical practice, therewith and, this framework has the potential to significantly improve the patient comfort and treatment outcomes.

AB - Patient-ventilator asynchrony is one of the largest challenges in mechanical ventilation and is associated with prolonged ICU stay and increased mortality. The aim of this paper is to automatically detect and classify the different types of patient-ventilator asynchronies during a patient's breath using the typically available data on commercially available ventilators. This is achieved by a detection and classification framework using an objective definition of asynchrony and a supervised learning approach. The achieved detection performance of the near-real time framework on a clinical dataset is a significant improvement over current clinical practice, therewith and, this framework has the potential to significantly improve the patient comfort and treatment outcomes.

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KW - Detection

KW - Mechanical ventilation

KW - Patient-ventilator asynchrony

KW - Recurrent neural networks

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Automatic patient-ventilator asynchrony detection framework using objective asynchrony definitions

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Keywords

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