Impact of coronary hyperemia on collateral flow correction of coronary microvascular resistance indices

Coen K M Boerhout; Anna van Veelen; Rutger G T Feenstra; Elize A M de Jong; Hanae F Namba; Marcel A M Beijk; Jose P Henriques; Jan J Piek; Tim P van de Hoef

doi:10.1152/ajpheart.00771.2023

Impact of coronary hyperemia on collateral flow correction of coronary microvascular resistance indices

Am J Physiol Heart Circ Physiol. 2024 Apr 1;326(4):H1037-H1044. doi: 10.1152/ajpheart.00771.2023. Epub 2024 Feb 23.

Authors

Coen K M Boerhout¹, Anna van Veelen¹, Rutger G T Feenstra¹, Elize A M de Jong¹, Hanae F Namba^{1

2}, Marcel A M Beijk¹, Jose P Henriques¹, Jan J Piek¹, Tim P van de Hoef²

Affiliations

¹ Heart Centre, Department of Cardiology, Amsterdam Cardiovascular Sciences, Amsterdam University Medical Center, Amsterdam, The Netherlands.
² Department of Cardiology, University Medical Center Utrecht, Utrecht, The Netherlands.

PMID: 38391315
DOI: 10.1152/ajpheart.00771.2023

Abstract

Recently, a novel method to estimate wedge pressure (P_w)-corrected minimal microvascular resistance (MR) was introduced. However, this method has not been validated since, and there are some theoretical concerns regarding the impact of different physiological conditions on the derivation of P_w measurements. This study sought to validate the recently introduced method to estimate P_w-corrected MR in a Doppler-derived study population and to evaluate the impact of different physiological conditions on the P_w measurements and the derivation of P_w-corrected MR. The method to derive "estimated" hyperemic microvascular resistance (HMR) without the need for P_w measurements was validated by estimating the coronary fractional flow reserve (FFR_cor) from myocardial fractional flow reserve (FFR_myo) in a Doppler-derived study population (N = 53). From these patients, 24 had hyperemic P_w measurements available for the evaluation of hyperemic conditions on the derivation of P_w and its effect on the derivation of both "true" (with measured P_w) and "estimated" P_w-corrected HMR. Nonhyperemic P_w differed significantly from P_w measured in hyperemic conditions (26 ± 14 vs. 35 ± 14 mmHg, respectively, P < 0.005). Nevertheless, there was a strong linear relationship between FFR_cor and FFR_myo in nonhyperemic conditions (R² = 0.91, P < 0.005), as well as in hyperemic conditions (R² = 0.87, P < 0.005). There was a strong linear relationship between "true" HMR and "estimated" HMR using either nonhyperemic (R² = 0.86, P < 0.005) or hyperemic conditions (R² = 0.85, P < 0.005) for correction. In contrast to a modest agreement between nonhyperemic P_w-corrected HMR and apparent HMR (R² = 0.67, P < 0.005), hyperemic P_w-corrected HMR showed a strong agreement with apparent HMR (R² = 0.88, P < 0.005). We validated the calculation method for P_w-corrected MR in a Doppler velocity-derived population. In addition, we found a significant impact of hyperemic conditions on the measurement of P_w and the derivation of P_w-corrected HMR.NEW & NOTEWORTHY The following are what is known: 1) wedge-pressure correction is often considered for the derivation of indices of minimal microvascular resistance, and 2) the Yong method for calculating wedge pressure-corrected index of microvascular resistance (IMR) without balloon inflation has never been validated in a Doppler-derived population and has not been tested under different physiological conditions. This study 1) adds validation for the Yong method for calculated wedge-pressure correction in a Doppler-derived study population and 2) shows significant influence of the physiological conditions on the derivation of coronary wedge pressure.

Keywords: collateral flow; microvasculature; resistance; wedge pressure.

MeSH terms

Blood Flow Velocity
Coronary Angiography
Coronary Circulation / physiology
Coronary Stenosis*
Coronary Vessels / diagnostic imaging
Fractional Flow Reserve, Myocardial*
Heart
Humans
Hyperemia*