Intra-breath arterial oxygen oscillations detected by a fast oxygen sensor in an animal model of acute respiratory distress syndrome

F Formenti; Rongsheng Chen; H McPeak; P J Murison; M Matejovic; Clive E W Hahn; A D Farmery

doi:10.1093/bja/aeu407

Intra-breath arterial oxygen oscillations detected by a fast oxygen sensor in an animal model of acute respiratory distress syndrome

F Formenti, Rongsheng Chen, H McPeak, P J Murison, M Matejovic, Clive E W Hahn, A D Farmery

Centre for Human & Applied Physiological Sciences

University of Oxford

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

22 Citations (Scopus)

224 Downloads (Pure)

Abstract

BACKGROUND: There is considerable interest in oxygen partial pressure (Po2) monitoring in physiology, and in tracking Po2 changes dynamically when it varies rapidly. For example, arterial Po2 ([Formula: see text]) can vary within the respiratory cycle in cyclical atelectasis (CA), where [Formula: see text] is thought to increase and decrease during inspiration and expiration, respectively. A sensor that detects these [Formula: see text] oscillations could become a useful diagnostic tool of CA during acute respiratory distress syndrome (ARDS).

METHODS: We developed a fibreoptic Po2 sensor (<200 µm diameter), suitable for human use, that has a fast response time, and can measure Po2 continuously in blood. By altering the inspired fraction of oxygen ([Formula: see text]) from 21 to 100% in four healthy animal models, we determined the linearity of the sensor's signal over a wide range of [Formula: see text] values in vivo. We also hypothesized that the sensor could measure rapid intra-breath [Formula: see text] oscillations in a large animal model of ARDS.

RESULTS: In the healthy animal models, [Formula: see text] responses to changes in [Formula: see text] were in agreement with conventional intermittent blood-gas analysis (n=39) for a wide range of [Formula: see text] values, from 10 to 73 kPa. In the animal lavage model of CA, the sensor detected [Formula: see text] oscillations, also at clinically relevant [Formula: see text] levels close to 9 kPa.

CONCLUSIONS: We conclude that these fibreoptic [Formula: see text] sensors have the potential to become a diagnostic tool for CA in ARDS.

Original language	English
Pages (from-to)	683-8
Number of pages	6
Journal	British Journal of Anaesthesia
Volume	114
Issue number	4
Early online date	28 Jan 2015
DOIs	https://doi.org/10.1093/bja/aeu407
Publication status	Published - Apr 2015

Keywords

Animals
Disease Models, Animal
Female
Fiber Optic Technology
Oxygen
Respiratory Distress Syndrome, Adult
Swine

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1093/bja/aeu407Licence: CC BY

Br._J._Anaesth._2015_Formenti_683_8Final published version, 251 KBLicence: CC BY

22 Citations
4 Article
2 Letter

The wider context of fibre optic oxygen sensing
Formenti, F., 5 Jan 2022, (Accepted/In press) In: OPTICAL FIBER TECHNOLOGY. 68
Research output: Contribution to journal › Letter › peer-review

Open Access
File
Continuous measurement of arterial oxygenation in mechanically ventilated horses
Hummer, E., Soares, J. H. N., Crockett, D., Aguiar, A. J. A., Tran, M., Cronin, J., Brosnan, R. J., Braun, C. & Formenti, F., 11 Nov 2021, (Accepted/In press) In: Equine Veterinary Journal.
Research output: Contribution to journal › Article › peer-review
Bedside monitoring of lung volume available for gas exchange
Tran, M., Crockett, D., Cronin, J., Borges Sobrinho Dorini, J., Hedenstierna, G., Larsson, A., Farmery, A. D. & Formenti, F., 2 Dec 2020, (Accepted/In press) In: Intensive Care Medicine Experimental.
Research output: Contribution to journal › Article › peer-review

Open Access
File

6 Citations (Scopus)

97 Downloads (Pure)

Cite this

@article{19a6ff13b3054cb2bd4552c490f2ac63,

title = "Intra-breath arterial oxygen oscillations detected by a fast oxygen sensor in an animal model of acute respiratory distress syndrome",

abstract = "BACKGROUND: There is considerable interest in oxygen partial pressure (Po2) monitoring in physiology, and in tracking Po2 changes dynamically when it varies rapidly. For example, arterial Po2 ([Formula: see text]) can vary within the respiratory cycle in cyclical atelectasis (CA), where [Formula: see text] is thought to increase and decrease during inspiration and expiration, respectively. A sensor that detects these [Formula: see text] oscillations could become a useful diagnostic tool of CA during acute respiratory distress syndrome (ARDS).METHODS: We developed a fibreoptic Po2 sensor (<200 µm diameter), suitable for human use, that has a fast response time, and can measure Po2 continuously in blood. By altering the inspired fraction of oxygen ([Formula: see text]) from 21 to 100% in four healthy animal models, we determined the linearity of the sensor's signal over a wide range of [Formula: see text] values in vivo. We also hypothesized that the sensor could measure rapid intra-breath [Formula: see text] oscillations in a large animal model of ARDS.RESULTS: In the healthy animal models, [Formula: see text] responses to changes in [Formula: see text] were in agreement with conventional intermittent blood-gas analysis (n=39) for a wide range of [Formula: see text] values, from 10 to 73 kPa. In the animal lavage model of CA, the sensor detected [Formula: see text] oscillations, also at clinically relevant [Formula: see text] levels close to 9 kPa.CONCLUSIONS: We conclude that these fibreoptic [Formula: see text] sensors have the potential to become a diagnostic tool for CA in ARDS.",

keywords = "Animals, Disease Models, Animal, Female, Fiber Optic Technology, Oxygen, Respiratory Distress Syndrome, Adult, Swine",

author = "F Formenti and Rongsheng Chen and H McPeak and Murison, {P J} and M Matejovic and Hahn, {Clive E W} and Farmery, {A D}",

note = "{\textcopyright} The Author 2015. Published by Oxford University Press on behalf of the British Journal of Anaesthesia.",

year = "2015",

month = apr,

doi = "10.1093/bja/aeu407",

language = "English",

volume = "114",

pages = "683--8",

journal = "British Journal of Anaesthesia",

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T1 - Intra-breath arterial oxygen oscillations detected by a fast oxygen sensor in an animal model of acute respiratory distress syndrome

AU - Formenti, F

AU - Chen, Rongsheng

AU - McPeak, H

AU - Murison, P J

AU - Matejovic, M

AU - Hahn, Clive E W

AU - Farmery, A D

PY - 2015/4

Y1 - 2015/4

N2 - BACKGROUND: There is considerable interest in oxygen partial pressure (Po2) monitoring in physiology, and in tracking Po2 changes dynamically when it varies rapidly. For example, arterial Po2 ([Formula: see text]) can vary within the respiratory cycle in cyclical atelectasis (CA), where [Formula: see text] is thought to increase and decrease during inspiration and expiration, respectively. A sensor that detects these [Formula: see text] oscillations could become a useful diagnostic tool of CA during acute respiratory distress syndrome (ARDS).METHODS: We developed a fibreoptic Po2 sensor (<200 µm diameter), suitable for human use, that has a fast response time, and can measure Po2 continuously in blood. By altering the inspired fraction of oxygen ([Formula: see text]) from 21 to 100% in four healthy animal models, we determined the linearity of the sensor's signal over a wide range of [Formula: see text] values in vivo. We also hypothesized that the sensor could measure rapid intra-breath [Formula: see text] oscillations in a large animal model of ARDS.RESULTS: In the healthy animal models, [Formula: see text] responses to changes in [Formula: see text] were in agreement with conventional intermittent blood-gas analysis (n=39) for a wide range of [Formula: see text] values, from 10 to 73 kPa. In the animal lavage model of CA, the sensor detected [Formula: see text] oscillations, also at clinically relevant [Formula: see text] levels close to 9 kPa.CONCLUSIONS: We conclude that these fibreoptic [Formula: see text] sensors have the potential to become a diagnostic tool for CA in ARDS.

AB - BACKGROUND: There is considerable interest in oxygen partial pressure (Po2) monitoring in physiology, and in tracking Po2 changes dynamically when it varies rapidly. For example, arterial Po2 ([Formula: see text]) can vary within the respiratory cycle in cyclical atelectasis (CA), where [Formula: see text] is thought to increase and decrease during inspiration and expiration, respectively. A sensor that detects these [Formula: see text] oscillations could become a useful diagnostic tool of CA during acute respiratory distress syndrome (ARDS).METHODS: We developed a fibreoptic Po2 sensor (<200 µm diameter), suitable for human use, that has a fast response time, and can measure Po2 continuously in blood. By altering the inspired fraction of oxygen ([Formula: see text]) from 21 to 100% in four healthy animal models, we determined the linearity of the sensor's signal over a wide range of [Formula: see text] values in vivo. We also hypothesized that the sensor could measure rapid intra-breath [Formula: see text] oscillations in a large animal model of ARDS.RESULTS: In the healthy animal models, [Formula: see text] responses to changes in [Formula: see text] were in agreement with conventional intermittent blood-gas analysis (n=39) for a wide range of [Formula: see text] values, from 10 to 73 kPa. In the animal lavage model of CA, the sensor detected [Formula: see text] oscillations, also at clinically relevant [Formula: see text] levels close to 9 kPa.CONCLUSIONS: We conclude that these fibreoptic [Formula: see text] sensors have the potential to become a diagnostic tool for CA in ARDS.

KW - Animals

KW - Disease Models, Animal

KW - Female

KW - Fiber Optic Technology

KW - Oxygen

KW - Respiratory Distress Syndrome, Adult

KW - Swine

U2 - 10.1093/bja/aeu407

DO - 10.1093/bja/aeu407

M3 - Article

C2 - 25631471

SN - 0007-0912

VL - 114

SP - 683

EP - 688

JO - British Journal of Anaesthesia

JF - British Journal of Anaesthesia

IS - 4

ER -

Intra-breath arterial oxygen oscillations detected by a fast oxygen sensor in an animal model of acute respiratory distress syndrome

Abstract

Keywords

UN SDGs

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Research output

The wider context of fibre optic oxygen sensing

Continuous measurement of arterial oxygenation in mechanically ventilated horses

Bedside monitoring of lung volume available for gas exchange

Cite this