Using helium-oxygen to improve regional deposition of inhaled particles: mechanical principles
Using helium-oxygen to improve regional deposition of inhaled particles: mechanical principles
Background: Helium-oxygen has been used for decades as a respiratory therapy conjointly with aerosols. It has also been shown under some conditions to be a means to provide more peripheral, deeper, particle deposition for inhalation therapies. Furthermore, we can also consider deposition along parallel paths that are quite different, especially in a heterogeneous pathological lung. It is in this context that it is hypothesized that helium-oxygen can improve regional deposition, leading to more homogeneous deposition by increasing deposition in ventilation-deficient lung regions.
Methods: Analytical models of inertial impaction, sedimentation, and diffusion are examined to illustrate the importance of gas property values on deposition distribution through both fluid mechanics– and particle mechanics–based mechanisms. Also considered are in vitro results from a bench model for a heterogeneously obstructed lung. In vivo results from three-dimensional (3D) imaging techniques provide visual examples of changes in particle deposition patterns in asthmatics that are further analyzed using computational fluid dynamics (CFD).
Results and Conclusions: Based on analytical modeling, it is shown that deeper particle deposition is expected when breathing helium-oxygen, as compared with breathing air. A bench model has shown that more homogeneous ventilation distribution is possible breathing helium-oxygen in the presence of heterogeneous obstructions representative of central airway obstructions. 3D imaging of asthmatics has confirmed that aerosol delivery with a helium-oxygen carrier gas results in deeper and more homogeneous deposition distributions. CFD results are consistent with the in vivo imaging and suggest that the mechanics of gas particle interaction are the source of the differences seen in deposition patterns. However, intersubject variability in response to breathing helium-oxygen is expected, and an example of a nonresponder is shown where regional deposition is not significantly changed.
71-80
Katz, I.
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Pichelin, M.
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Montesantos, S.
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Majoral, C.
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Martin, A.
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Conway, J.
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Fleming, J.
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Venegas, J.
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Greenblatt, E.
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Caillibotte, G.
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2 March 2014
Katz, I.
c09f6a71-4235-4ab1-9bcc-0dde1addd718
Pichelin, M.
1b641e81-bc19-4720-8c43-01965cd79108
Montesantos, S.
041384bd-8f5a-4eda-8bd6-6ca60c560fc1
Majoral, C.
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Martin, A.
169f0afa-12fc-43b5-a72d-7bfc493aa170
Conway, J.
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Fleming, J.
6876b2b5-6252-465d-8853-216583e4c8a4
Venegas, J.
fd7493e6-e11e-48c5-9ce7-30a11bde7963
Greenblatt, E.
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Caillibotte, G.
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Katz, I., Pichelin, M., Montesantos, S., Majoral, C., Martin, A., Conway, J., Fleming, J., Venegas, J., Greenblatt, E. and Caillibotte, G.
(2014)
Using helium-oxygen to improve regional deposition of inhaled particles: mechanical principles.
Journal of Aerosol Medicine and Pulmonary Drug Delivery, 27 (2), .
(doi:10.1089/jamp.2013.1072).
Abstract
Background: Helium-oxygen has been used for decades as a respiratory therapy conjointly with aerosols. It has also been shown under some conditions to be a means to provide more peripheral, deeper, particle deposition for inhalation therapies. Furthermore, we can also consider deposition along parallel paths that are quite different, especially in a heterogeneous pathological lung. It is in this context that it is hypothesized that helium-oxygen can improve regional deposition, leading to more homogeneous deposition by increasing deposition in ventilation-deficient lung regions.
Methods: Analytical models of inertial impaction, sedimentation, and diffusion are examined to illustrate the importance of gas property values on deposition distribution through both fluid mechanics– and particle mechanics–based mechanisms. Also considered are in vitro results from a bench model for a heterogeneously obstructed lung. In vivo results from three-dimensional (3D) imaging techniques provide visual examples of changes in particle deposition patterns in asthmatics that are further analyzed using computational fluid dynamics (CFD).
Results and Conclusions: Based on analytical modeling, it is shown that deeper particle deposition is expected when breathing helium-oxygen, as compared with breathing air. A bench model has shown that more homogeneous ventilation distribution is possible breathing helium-oxygen in the presence of heterogeneous obstructions representative of central airway obstructions. 3D imaging of asthmatics has confirmed that aerosol delivery with a helium-oxygen carrier gas results in deeper and more homogeneous deposition distributions. CFD results are consistent with the in vivo imaging and suggest that the mechanics of gas particle interaction are the source of the differences seen in deposition patterns. However, intersubject variability in response to breathing helium-oxygen is expected, and an example of a nonresponder is shown where regional deposition is not significantly changed.
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Accepted/In Press date: 2 January 2014
Published date: 2 March 2014
Organisations:
Faculty of Health Sciences
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Local EPrints ID: 378875
URI: http://eprints.soton.ac.uk/id/eprint/378875
ISSN: 1941-2711
PURE UUID: f097e3f6-640b-41c6-a8bf-f88fd0d9c8c9
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Date deposited: 16 Jul 2015 10:21
Last modified: 14 Mar 2024 20:30
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Contributors
Author:
I. Katz
Author:
M. Pichelin
Author:
S. Montesantos
Author:
C. Majoral
Author:
A. Martin
Author:
J. Conway
Author:
J. Fleming
Author:
J. Venegas
Author:
E. Greenblatt
Author:
G. Caillibotte
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