Development of a Mechanical Test Lung for Respiratory Mechanics Research

Wei Yang Tay; Yeong Shiong Chiew; Christopher Yew Shuen Ang

doi:10.1007/978-981-97-1920-4_22

Development of a Mechanical Test Lung for Respiratory Mechanics Research

Wei Yang Tay, Yeong Shiong Chiew, Christopher Yew Shuen Ang

Malaysia School of Engineering

Research output: Chapter in Book/Report/Conference proceeding › Conference Paper › Other

Abstract

Due to the high nonlinearity and variability of the respiratory system in the human body, the physiological response of patients to mechanical ventilation (MV) treatment is often unpredictable. Hence, there is a lack of proper guidelines for optimising MV settings in standard clinical protocols. By giving clinicians the opportunity to test multiple MV settings, a mechanical test lung could assist in determining the optimal settings that suit a particular patient. Therefore, this warrants the design and development of an active test lung with a spontaneous breathing system, reasonable tidal volume and ranges of lung mechanics. The finished prototype consists of three subsystems: the lung compartment, the airway, and the spontaneous breathing system. The performance of this test lung was evaluated through several experiments, and the results show that it can achieve continuous respiratory elastance that spans from 20 to 90 cmH₂O/L, whereas the respiratory resistance ranges from 20 to 50 cmH₂O·s/L. Moreover, it has a maximum tidal volume of 850 mL and can simulate spontaneous breathing with different frequencies, inspiratory, and expiratory times.

Original language	English
Title of host publication	Proceedings of the Annual Congress of the Asia-Pacific Society for Artificial Organs - APSAO
Subtitle of host publication	Making Breakthrough via Multidisciplinary Approach
Editors	Mohd Jamil Mohamed Mokhtarudin, Azam Ahmad Bakir, Andrew Stephens, Nadiah Sulaiman
Publisher	Springer
Pages	225-231
Number of pages	7
ISBN (Print)	9789819721108
DOIs	https://doi.org/10.1007/978-981-97-1920-4_22
Publication status	Published - 2024
Event	Annual Congress of the Asia-Pacific Society for Artificial Organs 2023 - University of Malaya. PAUM Clubhouse, Kuala Lumpur, Malaysia Duration: 25 Sept 2023 → 26 Sept 2023 Conference number: 7th https://link.springer.com/book/10.1007/978-981-97-1920-4 (Published Proceedings) https://asiancardiac.com/ap23a.html (Website)

Publication series

Name	Lecture Notes in Bioengineering
ISSN (Print)	2195-271X
ISSN (Electronic)	2195-2728

Conference

Conference	Annual Congress of the Asia-Pacific Society for Artificial Organs 2023
Abbreviated title	APSAO 2023
Country/Territory	Malaysia
City	Kuala Lumpur
Period	25/09/23 → 26/09/23
Internet address	https://link.springer.com/book/10.1007/978-981-97-1920-4 (Published Proceedings) https://asiancardiac.com/ap23a.html (Website)

Keywords

Mechanical test lung
Model-based method
Spontaneous breathing

Access to Document

10.1007/978-981-97-1920-4_22

Cite this

Tay, W. Y., Chiew, Y. S., & Ang, C. Y. S. (2024). Development of a Mechanical Test Lung for Respiratory Mechanics Research. In M. J. Mohamed Mokhtarudin, A. Ahmad Bakir, A. Stephens, & N. Sulaiman (Eds.), Proceedings of the Annual Congress of the Asia-Pacific Society for Artificial Organs - APSAO: Making Breakthrough via Multidisciplinary Approach (pp. 225-231). (Lecture Notes in Bioengineering). Springer. https://doi.org/10.1007/978-981-97-1920-4_22

Tay, Wei Yang ; Chiew, Yeong Shiong ; Ang, Christopher Yew Shuen. / Development of a Mechanical Test Lung for Respiratory Mechanics Research. Proceedings of the Annual Congress of the Asia-Pacific Society for Artificial Organs - APSAO: Making Breakthrough via Multidisciplinary Approach. editor / Mohd Jamil Mohamed Mokhtarudin ; Azam Ahmad Bakir ; Andrew Stephens ; Nadiah Sulaiman. Springer, 2024. pp. 225-231 (Lecture Notes in Bioengineering).

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title = "Development of a Mechanical Test Lung for Respiratory Mechanics Research",

abstract = "Due to the high nonlinearity and variability of the respiratory system in the human body, the physiological response of patients to mechanical ventilation (MV) treatment is often unpredictable. Hence, there is a lack of proper guidelines for optimising MV settings in standard clinical protocols. By giving clinicians the opportunity to test multiple MV settings, a mechanical test lung could assist in determining the optimal settings that suit a particular patient. Therefore, this warrants the design and development of an active test lung with a spontaneous breathing system, reasonable tidal volume and ranges of lung mechanics. The finished prototype consists of three subsystems: the lung compartment, the airway, and the spontaneous breathing system. The performance of this test lung was evaluated through several experiments, and the results show that it can achieve continuous respiratory elastance that spans from 20 to 90 cmH2O/L, whereas the respiratory resistance ranges from 20 to 50 cmH2O·s/L. Moreover, it has a maximum tidal volume of 850 mL and can simulate spontaneous breathing with different frequencies, inspiratory, and expiratory times.",

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booktitle = "Proceedings of the Annual Congress of the Asia-Pacific Society for Artificial Organs - APSAO",

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Tay, WY, Chiew, YS & Ang, CYS 2024, Development of a Mechanical Test Lung for Respiratory Mechanics Research. in MJ Mohamed Mokhtarudin, A Ahmad Bakir, A Stephens & N Sulaiman (eds), Proceedings of the Annual Congress of the Asia-Pacific Society for Artificial Organs - APSAO: Making Breakthrough via Multidisciplinary Approach. Lecture Notes in Bioengineering, Springer, pp. 225-231, Annual Congress of the Asia-Pacific Society for Artificial Organs 2023, Kuala Lumpur, Malaysia, 25/09/23. https://doi.org/10.1007/978-981-97-1920-4_22

Development of a Mechanical Test Lung for Respiratory Mechanics Research. / Tay, Wei Yang; Chiew, Yeong Shiong; Ang, Christopher Yew Shuen.
Proceedings of the Annual Congress of the Asia-Pacific Society for Artificial Organs - APSAO: Making Breakthrough via Multidisciplinary Approach. ed. / Mohd Jamil Mohamed Mokhtarudin; Azam Ahmad Bakir; Andrew Stephens; Nadiah Sulaiman. Springer, 2024. p. 225-231 (Lecture Notes in Bioengineering).

Research output: Chapter in Book/Report/Conference proceeding › Conference Paper › Other

TY - GEN

T1 - Development of a Mechanical Test Lung for Respiratory Mechanics Research

AU - Tay, Wei Yang

AU - Chiew, Yeong Shiong

AU - Ang, Christopher Yew Shuen

N1 - Conference code: 7th

PY - 2024

Y1 - 2024

N2 - Due to the high nonlinearity and variability of the respiratory system in the human body, the physiological response of patients to mechanical ventilation (MV) treatment is often unpredictable. Hence, there is a lack of proper guidelines for optimising MV settings in standard clinical protocols. By giving clinicians the opportunity to test multiple MV settings, a mechanical test lung could assist in determining the optimal settings that suit a particular patient. Therefore, this warrants the design and development of an active test lung with a spontaneous breathing system, reasonable tidal volume and ranges of lung mechanics. The finished prototype consists of three subsystems: the lung compartment, the airway, and the spontaneous breathing system. The performance of this test lung was evaluated through several experiments, and the results show that it can achieve continuous respiratory elastance that spans from 20 to 90 cmH2O/L, whereas the respiratory resistance ranges from 20 to 50 cmH2O·s/L. Moreover, it has a maximum tidal volume of 850 mL and can simulate spontaneous breathing with different frequencies, inspiratory, and expiratory times.

AB - Due to the high nonlinearity and variability of the respiratory system in the human body, the physiological response of patients to mechanical ventilation (MV) treatment is often unpredictable. Hence, there is a lack of proper guidelines for optimising MV settings in standard clinical protocols. By giving clinicians the opportunity to test multiple MV settings, a mechanical test lung could assist in determining the optimal settings that suit a particular patient. Therefore, this warrants the design and development of an active test lung with a spontaneous breathing system, reasonable tidal volume and ranges of lung mechanics. The finished prototype consists of three subsystems: the lung compartment, the airway, and the spontaneous breathing system. The performance of this test lung was evaluated through several experiments, and the results show that it can achieve continuous respiratory elastance that spans from 20 to 90 cmH2O/L, whereas the respiratory resistance ranges from 20 to 50 cmH2O·s/L. Moreover, it has a maximum tidal volume of 850 mL and can simulate spontaneous breathing with different frequencies, inspiratory, and expiratory times.

KW - Mechanical test lung

KW - Model-based method

KW - Spontaneous breathing

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U2 - 10.1007/978-981-97-1920-4_22

DO - 10.1007/978-981-97-1920-4_22

M3 - Conference Paper

AN - SCOPUS:85207672548

SN - 9789819721108

T3 - Lecture Notes in Bioengineering

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EP - 231

BT - Proceedings of the Annual Congress of the Asia-Pacific Society for Artificial Organs - APSAO

A2 - Mohamed Mokhtarudin, Mohd Jamil

A2 - Ahmad Bakir, Azam

A2 - Stephens, Andrew

A2 - Sulaiman, Nadiah

PB - Springer

T2 - Annual Congress of the Asia-Pacific Society for Artificial Organs 2023

Y2 - 25 September 2023 through 26 September 2023

ER -

Tay WY, Chiew YS, Ang CYS. Development of a Mechanical Test Lung for Respiratory Mechanics Research. In Mohamed Mokhtarudin MJ, Ahmad Bakir A, Stephens A, Sulaiman N, editors, Proceedings of the Annual Congress of the Asia-Pacific Society for Artificial Organs - APSAO: Making Breakthrough via Multidisciplinary Approach. Springer. 2024. p. 225-231. (Lecture Notes in Bioengineering). doi: 10.1007/978-981-97-1920-4_22

Development of a Mechanical Test Lung for Respiratory Mechanics Research

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