Measuring myocardial blood flow with 82rubidium using Gjedde-Patlak-Rutland graphical analysis

Sima Gregg; Georgia Keramida; A Michael Peters

doi:10.1007/s12149-021-01591-x

Measuring myocardial blood flow with ⁸²rubidium using Gjedde-Patlak-Rutland graphical analysis

Ann Nucl Med. 2021 Jul;35(7):777-784. doi: 10.1007/s12149-021-01591-x. Epub 2021 Jun 2.

Authors

Sima Gregg¹, Georgia Keramida¹, A Michael Peters²

Affiliations

¹ Department of Nuclear Medicine, Royal Brompton and Harefield NHS Foundation Trust, London, UK.
² Department of Nuclear Medicine, King's College Hospital NHS Foundation Trust, Denmark Hill, Brixton, London, SE5 9RS, UK. adrien.peters@nhs.net.

PMID: 34076856
DOI: 10.1007/s12149-021-01591-x

Abstract

Objective: Myocardial blood flow (MBF) is measured with ⁸²Rb using non-linear, least-squares computerised modelling. The study aim was to explore the feasibility of Gjedde-Patlak-Rutland (GPR) graphical analysis as a simpler method for measuring MBF.

Methods: Patients had myocardial perfusion imaging using adenosine (n = 45) or regadenoson (n = 33) for stressing. Blood ⁸²Rb clearance into myocytes (K₁) was measured from Cedar-Sinai QPET software using the modified Crone-Renkin equation of Lortie et al. (K₁ = [1-0.77 × e^-B/MBF] × MBF) to convert K₁ to MBF (ml/min/100 ml), where B (63 ml/min/100 ml) is myocardial permeability-surface area product. Using aorta or left ventricular cavity (LV) to measure arterial blood ⁸²Rb concentration, blood ⁸²Rb clearance into myocardium (Z) was measured from GPR analysis based on data acquired between 1 and 3 min post-injection. As units of K₁ and Z are, respectively, ml/min/ml intracellular space and ml/min/ml total tissue including extracellular space, myocardial extracellular fluid volume (ECV) is 1 - [Z/K₁]. Using Z/K₁ (see Results) to modify its index, the Lortie equation was changed to Z = (1-0.77 × [Formula: see text]e^-B_Z^/MBF_Z)*MBF_Z, following which MBF_Z was calculated from Z. In GPR analysis, spillover of activity from LV to myocardium conveniently 'drops out' in the intercept of the plot.

Results: Both agents increased myocardial blood flow almost equally. ECV was ~ 35 ml/100 ml at rest, increasing to ~ 40 ml/100 ml after stress. Z/K₁, averaged between stress, rest, stressing agents and arterial ROI, was 0.62, so B_Z was taken as 39 (i.e. 0.62 × 63) ml/min/100 ml. Based on LV, MBF_Z (y) correlated with MBF (x): y = 0.43x + 22 ml/min/100 ml; r = 0.84; n = 156). Their respective stress/rest ratios showed a moderate correlation (r = 0.64; n = 78).

Conclusions: GPR analysis offers promise as a valid and analytically simpler technique for measuring myocardial blood flow, which, as with any clearance measured from GPR analysis, has units of ml/min/ml total tissue volume, and merits development as a polar map display.

Keywords: Blood flow; Graphical analysis; Myocardium; Rubidium-82.

MeSH terms

Adenosine
Aged
Coronary Circulation*
Feasibility Studies
Female
Humans
Male
Middle Aged
Myocardial Perfusion Imaging* / methods
Purines / pharmacology
Pyrazoles
Rubidium Radioisotopes*

Substances

Rubidium Radioisotopes
Purines
Rubidium-82
regadenoson
Adenosine
Pyrazoles