Automated oxygen titration with non-invasive ventilation in hypoxaemic adults with cardiorespiratory disease: a randomised cross-over trial. Kirton, L., Kung, S., Bird, G., Black, M., Semprini, R., Eathorne, A., Weatherall, M., Semprini, A., & Beasley, R. BMJ Open Respiratory Research, 11(1):e002196, June, 2024. ![Automated oxygen titration with non-invasive ventilation in hypoxaemic adults with cardiorespiratory disease: a randomised cross-over trial [link]](https://bibbase.org/img/filetypes/link.svg "link")
Paper doi abstract bibtex Background Closed-loop oxygen control systems automatically adjust the fraction of inspired oxygen (FiO 2 ) to maintain oxygen saturation (SpO 2 ) within a predetermined target range. Their performance with low and high-flow oxygen therapies, but not with non-invasive ventilation, has been established. We compared the effect of automated oxygen on achieving and maintaining a target SpO 2 range with nasal high flow (NHF), bilevel positive airway pressure (bilevel) and continuous positive airway pressure (CPAP), in stable hypoxaemic patients with chronic cardiorespiratory disease. Methods In this open-label, three-way cross-over trial, participants with resting hypoxaemia (n=12) received each of NHF, bilevel and CPAP treatments, in random order, with automated oxygen titrated for 10 min, followed by 36 min of standardised manual oxygen adjustments. The primary outcome was the time taken to reach target SpO 2 range (92%–96%). Secondary outcomes included time spent within target range and physiological responses to automated and manual oxygen adjustments. Results Two participants were randomised to each of six possible treatment orders. During automated oxygen control (n=12), the mean (±SD) time to reach target range was 114.8 (±87.9), 56.6 (±47.7) and 67.3 (±61) seconds for NHF, bilevel and CPAP, respectively, mean difference 58.3 (95% CI 25.0 to 91.5; p=0.002) and 47.5 (95% CI 14.3 to 80.7; p=0.007) seconds for bilevel and CPAP versus NHF, respectively. Proportions of time spent within target range were 68.5% (±16.3), 65.6% (±28.7) and 74.7% (±22.6) for NHF, bilevel and CPAP, respectively. Manually increasing, then decreasing, the FiO 2 resulted in similar increases and then decreases in SpO 2 and transcutaneous carbon dioxide (PtCO 2 ) with NHF, bilevel and CPAP. Conclusion The target SpO 2 range was achieved more quickly when automated oxygen control was initiated with bilevel and CPAP compared with NHF while time spent within the range across the three therapies was similar. Manually changing the FiO 2 had similar effects on SpO 2 and PtCO 2 across each of the three therapies. Trial registration number ACTRN12622000433707.
@article{kirton_automated_2024,
title = {Automated oxygen titration with non-invasive ventilation in hypoxaemic adults with cardiorespiratory disease: a randomised cross-over trial},
volume = {11},
issn = {2052-4439},
shorttitle = {Automated oxygen titration with non-invasive ventilation in hypoxaemic adults with cardiorespiratory disease},
url = {https://bmjopenrespres.bmj.com/lookup/doi/10.1136/bmjresp-2023-002196},
doi = {10.1136/bmjresp-2023-002196},
abstract = {Background
Closed-loop oxygen control systems automatically adjust the fraction of inspired oxygen (FiO
2
) to maintain oxygen saturation (SpO
2
) within a predetermined target range. Their performance with low and high-flow oxygen therapies, but not with non-invasive ventilation, has been established. We compared the effect of automated oxygen on achieving and maintaining a target SpO
2
range with nasal high flow (NHF), bilevel positive airway pressure (bilevel) and continuous positive airway pressure (CPAP), in stable hypoxaemic patients with chronic cardiorespiratory disease.
Methods
In this open-label, three-way cross-over trial, participants with resting hypoxaemia (n=12) received each of NHF, bilevel and CPAP treatments, in random order, with automated oxygen titrated for 10 min, followed by 36 min of standardised manual oxygen adjustments. The primary outcome was the time taken to reach target SpO
2
range (92\%–96\%). Secondary outcomes included time spent within target range and physiological responses to automated and manual oxygen adjustments.
Results
Two participants were randomised to each of six possible treatment orders. During automated oxygen control (n=12), the mean (±SD) time to reach target range was 114.8 (±87.9), 56.6 (±47.7) and 67.3 (±61) seconds for NHF, bilevel and CPAP, respectively, mean difference 58.3 (95\% CI 25.0 to 91.5; p=0.002) and 47.5 (95\% CI 14.3 to 80.7; p=0.007) seconds for bilevel and CPAP versus NHF, respectively. Proportions of time spent within target range were 68.5\% (±16.3), 65.6\% (±28.7) and 74.7\% (±22.6) for NHF, bilevel and CPAP, respectively.
Manually increasing, then decreasing, the FiO
2
resulted in similar increases and then decreases in SpO
2
and transcutaneous carbon dioxide (PtCO
2
) with NHF, bilevel and CPAP.
Conclusion
The target SpO
2
range was achieved more quickly when automated oxygen control was initiated with bilevel and CPAP compared with NHF while time spent within the range across the three therapies was similar. Manually changing the FiO
2
had similar effects on SpO
2
and PtCO
2
across each of the three therapies.
Trial registration number
ACTRN12622000433707.},
language = {en},
number = {1},
urldate = {2024-08-11},
journal = {BMJ Open Respiratory Research},
author = {Kirton, Louis and Kung, Stacey and Bird, Georgina and Black, Melissa and Semprini, Ruth and Eathorne, Allie and Weatherall, Mark and Semprini, Alex and Beasley, Richard},
month = jun,
year = {2024},
pages = {e002196},
}
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{"_id":"aXbvKhypftPtowMun","bibbaseid":"kirton-kung-bird-black-semprini-eathorne-weatherall-semprini-etal-automatedoxygentitrationwithnoninvasiveventilationinhypoxaemicadultswithcardiorespiratorydiseasearandomisedcrossovertrial-2024","author_short":["Kirton, L.","Kung, S.","Bird, G.","Black, M.","Semprini, R.","Eathorne, A.","Weatherall, M.","Semprini, A.","Beasley, R."],"bibdata":{"bibtype":"article","type":"article","title":"Automated oxygen titration with non-invasive ventilation in hypoxaemic adults with cardiorespiratory disease: a randomised cross-over trial","volume":"11","issn":"2052-4439","shorttitle":"Automated oxygen titration with non-invasive ventilation in hypoxaemic adults with cardiorespiratory disease","url":"https://bmjopenrespres.bmj.com/lookup/doi/10.1136/bmjresp-2023-002196","doi":"10.1136/bmjresp-2023-002196","abstract":"Background Closed-loop oxygen control systems automatically adjust the fraction of inspired oxygen (FiO 2 ) to maintain oxygen saturation (SpO 2 ) within a predetermined target range. Their performance with low and high-flow oxygen therapies, but not with non-invasive ventilation, has been established. We compared the effect of automated oxygen on achieving and maintaining a target SpO 2 range with nasal high flow (NHF), bilevel positive airway pressure (bilevel) and continuous positive airway pressure (CPAP), in stable hypoxaemic patients with chronic cardiorespiratory disease. Methods In this open-label, three-way cross-over trial, participants with resting hypoxaemia (n=12) received each of NHF, bilevel and CPAP treatments, in random order, with automated oxygen titrated for 10 min, followed by 36 min of standardised manual oxygen adjustments. The primary outcome was the time taken to reach target SpO 2 range (92%–96%). Secondary outcomes included time spent within target range and physiological responses to automated and manual oxygen adjustments. Results Two participants were randomised to each of six possible treatment orders. During automated oxygen control (n=12), the mean (±SD) time to reach target range was 114.8 (±87.9), 56.6 (±47.7) and 67.3 (±61) seconds for NHF, bilevel and CPAP, respectively, mean difference 58.3 (95% CI 25.0 to 91.5; p=0.002) and 47.5 (95% CI 14.3 to 80.7; p=0.007) seconds for bilevel and CPAP versus NHF, respectively. Proportions of time spent within target range were 68.5% (±16.3), 65.6% (±28.7) and 74.7% (±22.6) for NHF, bilevel and CPAP, respectively. Manually increasing, then decreasing, the FiO 2 resulted in similar increases and then decreases in SpO 2 and transcutaneous carbon dioxide (PtCO 2 ) with NHF, bilevel and CPAP. Conclusion The target SpO 2 range was achieved more quickly when automated oxygen control was initiated with bilevel and CPAP compared with NHF while time spent within the range across the three therapies was similar. Manually changing the FiO 2 had similar effects on SpO 2 and PtCO 2 across each of the three therapies. Trial registration number ACTRN12622000433707.","language":"en","number":"1","urldate":"2024-08-11","journal":"BMJ Open Respiratory Research","author":[{"propositions":[],"lastnames":["Kirton"],"firstnames":["Louis"],"suffixes":[]},{"propositions":[],"lastnames":["Kung"],"firstnames":["Stacey"],"suffixes":[]},{"propositions":[],"lastnames":["Bird"],"firstnames":["Georgina"],"suffixes":[]},{"propositions":[],"lastnames":["Black"],"firstnames":["Melissa"],"suffixes":[]},{"propositions":[],"lastnames":["Semprini"],"firstnames":["Ruth"],"suffixes":[]},{"propositions":[],"lastnames":["Eathorne"],"firstnames":["Allie"],"suffixes":[]},{"propositions":[],"lastnames":["Weatherall"],"firstnames":["Mark"],"suffixes":[]},{"propositions":[],"lastnames":["Semprini"],"firstnames":["Alex"],"suffixes":[]},{"propositions":[],"lastnames":["Beasley"],"firstnames":["Richard"],"suffixes":[]}],"month":"June","year":"2024","pages":"e002196","bibtex":"@article{kirton_automated_2024,\n\ttitle = {Automated oxygen titration with non-invasive ventilation in hypoxaemic adults with cardiorespiratory disease: a randomised cross-over trial},\n\tvolume = {11},\n\tissn = {2052-4439},\n\tshorttitle = {Automated oxygen titration with non-invasive ventilation in hypoxaemic adults with cardiorespiratory disease},\n\turl = {https://bmjopenrespres.bmj.com/lookup/doi/10.1136/bmjresp-2023-002196},\n\tdoi = {10.1136/bmjresp-2023-002196},\n\tabstract = {Background \n \n Closed-loop oxygen control systems automatically adjust the fraction of inspired oxygen (FiO \n 2 \n ) to maintain oxygen saturation (SpO \n 2 \n ) within a predetermined target range. Their performance with low and high-flow oxygen therapies, but not with non-invasive ventilation, has been established. We compared the effect of automated oxygen on achieving and maintaining a target SpO \n 2 \n range with nasal high flow (NHF), bilevel positive airway pressure (bilevel) and continuous positive airway pressure (CPAP), in stable hypoxaemic patients with chronic cardiorespiratory disease. \n \n \n \n Methods \n \n In this open-label, three-way cross-over trial, participants with resting hypoxaemia (n=12) received each of NHF, bilevel and CPAP treatments, in random order, with automated oxygen titrated for 10 min, followed by 36 min of standardised manual oxygen adjustments. The primary outcome was the time taken to reach target SpO \n 2 \n range (92\\%–96\\%). Secondary outcomes included time spent within target range and physiological responses to automated and manual oxygen adjustments. \n \n \n \n Results \n Two participants were randomised to each of six possible treatment orders. During automated oxygen control (n=12), the mean (±SD) time to reach target range was 114.8 (±87.9), 56.6 (±47.7) and 67.3 (±61) seconds for NHF, bilevel and CPAP, respectively, mean difference 58.3 (95\\% CI 25.0 to 91.5; p=0.002) and 47.5 (95\\% CI 14.3 to 80.7; p=0.007) seconds for bilevel and CPAP versus NHF, respectively. Proportions of time spent within target range were 68.5\\% (±16.3), 65.6\\% (±28.7) and 74.7\\% (±22.6) for NHF, bilevel and CPAP, respectively. \n \n Manually increasing, then decreasing, the FiO \n 2 \n resulted in similar increases and then decreases in SpO \n 2 \n and transcutaneous carbon dioxide (PtCO \n 2 \n ) with NHF, bilevel and CPAP. \n \n \n \n Conclusion \n \n The target SpO \n 2 \n range was achieved more quickly when automated oxygen control was initiated with bilevel and CPAP compared with NHF while time spent within the range across the three therapies was similar. Manually changing the FiO \n 2 \n had similar effects on SpO \n 2 \n and PtCO \n 2 \n across each of the three therapies. \n \n \n \n Trial registration number \n ACTRN12622000433707.},\n\tlanguage = {en},\n\tnumber = {1},\n\turldate = {2024-08-11},\n\tjournal = {BMJ Open Respiratory Research},\n\tauthor = {Kirton, Louis and Kung, Stacey and Bird, Georgina and Black, Melissa and Semprini, Ruth and Eathorne, Allie and Weatherall, Mark and Semprini, Alex and Beasley, Richard},\n\tmonth = jun,\n\tyear = {2024},\n\tpages = {e002196},\n}\n\n","author_short":["Kirton, L.","Kung, S.","Bird, G.","Black, M.","Semprini, R.","Eathorne, A.","Weatherall, M.","Semprini, A.","Beasley, R."],"key":"kirton_automated_2024","id":"kirton_automated_2024","bibbaseid":"kirton-kung-bird-black-semprini-eathorne-weatherall-semprini-etal-automatedoxygentitrationwithnoninvasiveventilationinhypoxaemicadultswithcardiorespiratorydiseasearandomisedcrossovertrial-2024","role":"author","urls":{"Paper":"https://bmjopenrespres.bmj.com/lookup/doi/10.1136/bmjresp-2023-002196"},"metadata":{"authorlinks":{}}},"bibtype":"article","biburl":"https://api.zotero.org/users/6607533/collections/34TFFZQV/items?key=hSjrOPQRRHHWY81SKs6CEz45&format=bibtex&limit=100","dataSources":["AxsrLkzeAo8Y8KauF","mSXLJgYNdKnSRXmnZ"],"keywords":[],"search_terms":["automated","oxygen","titration","non","invasive","ventilation","hypoxaemic","adults","cardiorespiratory","disease","randomised","cross","over","trial","kirton","kung","bird","black","semprini","eathorne","weatherall","semprini","beasley"],"title":"Automated oxygen titration with non-invasive ventilation in hypoxaemic adults with cardiorespiratory disease: a randomised cross-over trial","year":2024}