Pulmonary blood volume assessment from a standard cardiac rubidium-82 imaging protocol

Pulmonary blood volume assessment from a standard cardiac rubidium-82 imaging protocol: impact of adenosine-induced hyperemia

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Standard

Pulmonary blood volume assessment from a standard cardiac rubidium-82 imaging protocol : impact of adenosine-induced hyperemia. / Lassen, Martin Lyngby; Byrne, Christina; Hartmann, Jacob Peter; Kjaer, Andreas; Berg, Ronan M.G.; Hasbak, Philip.

I: Journal of Nuclear Cardiology, Bind 30, Nr. 6, 2023, s. 2504 - 2513.

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › fagfællebedømt

Harvard

Lassen, ML, Byrne, C, Hartmann, JP, Kjaer, A, Berg, RMG & Hasbak, P 2023, 'Pulmonary blood volume assessment from a standard cardiac rubidium-82 imaging protocol: impact of adenosine-induced hyperemia', Journal of Nuclear Cardiology, bind 30, nr. 6, s. 2504 - 2513. https://doi.org/10.1007/s12350-023-03308-1

APA

Lassen, M. L., Byrne, C., Hartmann, J. P., Kjaer, A., Berg, R. M. G., & Hasbak, P. (2023). Pulmonary blood volume assessment from a standard cardiac rubidium-82 imaging protocol: impact of adenosine-induced hyperemia. Journal of Nuclear Cardiology, 30(6), 2504 - 2513. https://doi.org/10.1007/s12350-023-03308-1

Vancouver

Lassen ML, Byrne C, Hartmann JP, Kjaer A, Berg RMG, Hasbak P. Pulmonary blood volume assessment from a standard cardiac rubidium-82 imaging protocol: impact of adenosine-induced hyperemia. Journal of Nuclear Cardiology. 2023;30(6):2504 - 2513. https://doi.org/10.1007/s12350-023-03308-1

Author

Lassen, Martin Lyngby ; Byrne, Christina ; Hartmann, Jacob Peter ; Kjaer, Andreas ; Berg, Ronan M.G. ; Hasbak, Philip. / Pulmonary blood volume assessment from a standard cardiac rubidium-82 imaging protocol : impact of adenosine-induced hyperemia. I: Journal of Nuclear Cardiology. 2023 ; Bind 30, Nr. 6. s. 2504 - 2513.

Bibtex

@article{98145b436d064429ab743d00b0c1733e,

title = "Pulmonary blood volume assessment from a standard cardiac rubidium-82 imaging protocol: impact of adenosine-induced hyperemia",

abstract = "Background: This study aimed to assess the feasibility of estimating the pulmonary blood volume noninvasively using standard Rubidium-82 myocardial perfusion imaging (MPI) and characterize the changes during adenosine-induced hyperemia. Methods: This study comprised 33 healthy volunteers (15 female, median age = 23 years), of which 25 underwent serial rest/adenosine stress Rubidium-82 MPI sessions. Mean bolus transit times (MBTT) were obtained by calculating the time delay from the Rubidium-82 bolus arrival in the pulmonary trunk to the arrival in the left myocardial atrium. Using the MBTT, in combination with stroke volume (SV) and heart rate (HR), we estimated pulmonary blood volume (PBV = (SV × HR) × MBTT). We report the empirically measured MBTT, HR, SV, and PBV, all stratified by sex [male (M) vs female (F)] as mean (SD). In addition, we report grouped repeatability measures using the within-subject repeatability coefficient. Results: Mean bolus transit times was shortened during adenosine stressing with sex-specific differences [(seconds); Rest: Female (F) = 12.4 (1.5), Male (M) = 14.8 (2.8); stress: F = 8.8 (1.7), M = 11.2 (3.0), all P ≤ 0.01]. HR and SV increased during stress MPI, with a concomitant increase in the PBV [mL]; Rest: F = 544 (98), M = 926 (105); Stress: F = 914 (182), M = 1458 (338), all P < 0.001. The following test–retest repeatability measures were observed for MBTT (Rest = 17.2%, Stress = 17.9%), HR (Rest = 9.1%, Stress = 7.5%), SV (Rest = 8.9%, Stress = 5.6%), and for PBV measures (Rest = 20.7%, Stress = 19.5%) Conclusion: Pulmonary blood volume can be extracted by cardiac rubidium-82 MPI with excellent test–retest reliability, both at rest and during adenosine-induced hyperemia.",

keywords = "adenosine, positron emission tomography, pulmonary blood volume, Transit times",

author = "Lassen, {Martin Lyngby} and Christina Byrne and Hartmann, {Jacob Peter} and Andreas Kjaer and Berg, {Ronan M.G.} and Philip Hasbak",

note = "Publisher Copyright: {\textcopyright} 2023, The Author(s).",

year = "2023",

doi = "10.1007/s12350-023-03308-1",

language = "English",

volume = "30",

pages = "2504 -- 2513",

journal = "Journal of Nuclear Cardiology",

issn = "1071-3581",

publisher = "Springer",

number = "6",

}

RIS

TY - JOUR

T1 - Pulmonary blood volume assessment from a standard cardiac rubidium-82 imaging protocol

T2 - impact of adenosine-induced hyperemia

AU - Lassen, Martin Lyngby

AU - Byrne, Christina

AU - Hartmann, Jacob Peter

AU - Kjaer, Andreas

AU - Berg, Ronan M.G.

AU - Hasbak, Philip

PY - 2023

Y1 - 2023

N2 - Background: This study aimed to assess the feasibility of estimating the pulmonary blood volume noninvasively using standard Rubidium-82 myocardial perfusion imaging (MPI) and characterize the changes during adenosine-induced hyperemia. Methods: This study comprised 33 healthy volunteers (15 female, median age = 23 years), of which 25 underwent serial rest/adenosine stress Rubidium-82 MPI sessions. Mean bolus transit times (MBTT) were obtained by calculating the time delay from the Rubidium-82 bolus arrival in the pulmonary trunk to the arrival in the left myocardial atrium. Using the MBTT, in combination with stroke volume (SV) and heart rate (HR), we estimated pulmonary blood volume (PBV = (SV × HR) × MBTT). We report the empirically measured MBTT, HR, SV, and PBV, all stratified by sex [male (M) vs female (F)] as mean (SD). In addition, we report grouped repeatability measures using the within-subject repeatability coefficient. Results: Mean bolus transit times was shortened during adenosine stressing with sex-specific differences [(seconds); Rest: Female (F) = 12.4 (1.5), Male (M) = 14.8 (2.8); stress: F = 8.8 (1.7), M = 11.2 (3.0), all P ≤ 0.01]. HR and SV increased during stress MPI, with a concomitant increase in the PBV [mL]; Rest: F = 544 (98), M = 926 (105); Stress: F = 914 (182), M = 1458 (338), all P < 0.001. The following test–retest repeatability measures were observed for MBTT (Rest = 17.2%, Stress = 17.9%), HR (Rest = 9.1%, Stress = 7.5%), SV (Rest = 8.9%, Stress = 5.6%), and for PBV measures (Rest = 20.7%, Stress = 19.5%) Conclusion: Pulmonary blood volume can be extracted by cardiac rubidium-82 MPI with excellent test–retest reliability, both at rest and during adenosine-induced hyperemia.

AB - Background: This study aimed to assess the feasibility of estimating the pulmonary blood volume noninvasively using standard Rubidium-82 myocardial perfusion imaging (MPI) and characterize the changes during adenosine-induced hyperemia. Methods: This study comprised 33 healthy volunteers (15 female, median age = 23 years), of which 25 underwent serial rest/adenosine stress Rubidium-82 MPI sessions. Mean bolus transit times (MBTT) were obtained by calculating the time delay from the Rubidium-82 bolus arrival in the pulmonary trunk to the arrival in the left myocardial atrium. Using the MBTT, in combination with stroke volume (SV) and heart rate (HR), we estimated pulmonary blood volume (PBV = (SV × HR) × MBTT). We report the empirically measured MBTT, HR, SV, and PBV, all stratified by sex [male (M) vs female (F)] as mean (SD). In addition, we report grouped repeatability measures using the within-subject repeatability coefficient. Results: Mean bolus transit times was shortened during adenosine stressing with sex-specific differences [(seconds); Rest: Female (F) = 12.4 (1.5), Male (M) = 14.8 (2.8); stress: F = 8.8 (1.7), M = 11.2 (3.0), all P ≤ 0.01]. HR and SV increased during stress MPI, with a concomitant increase in the PBV [mL]; Rest: F = 544 (98), M = 926 (105); Stress: F = 914 (182), M = 1458 (338), all P < 0.001. The following test–retest repeatability measures were observed for MBTT (Rest = 17.2%, Stress = 17.9%), HR (Rest = 9.1%, Stress = 7.5%), SV (Rest = 8.9%, Stress = 5.6%), and for PBV measures (Rest = 20.7%, Stress = 19.5%) Conclusion: Pulmonary blood volume can be extracted by cardiac rubidium-82 MPI with excellent test–retest reliability, both at rest and during adenosine-induced hyperemia.

KW - adenosine

KW - positron emission tomography

KW - pulmonary blood volume

KW - Transit times

U2 - 10.1007/s12350-023-03308-1

DO - 10.1007/s12350-023-03308-1

M3 - Journal article

C2 - 37349559

AN - SCOPUS:85162980780

VL - 30

SP - 2504

EP - 2513

JO - Journal of Nuclear Cardiology

JF - Journal of Nuclear Cardiology

SN - 1071-3581

IS - 6

ER -

ID: 359004725

Biomedicinsk Institut