Measurement of the Distribution of Ventilation-perfusion Ratios in the Human Lung with Proton MRI: Comparison with the Multiple Inert-gas Elimination Technique

Overview

Journal J Appl Physiol (1985)

Publisher American Physiological Society

Date 2017 Mar 11

PMID 28280105

Citations 17

Authors

Rui Carlos Sa

A Cortney Henderson

Tatum Simonson

Tatsuya J Arai

Harrieth Wagner

Rebecca J Theilmann

Peter D Wagner

G Kim Prisk

Susan R Hopkins

Affiliations

Soon will be listed here.

Abstract

We have developed a novel functional proton magnetic resonance imaging (MRI) technique to measure regional ventilation-perfusion (V̇/Q̇) ratio in the lung. We conducted a comparison study of this technique in healthy subjects ( = 7, age = 42 ± 16 yr, Forced expiratory volume in 1 s = 94% predicted), by comparing data measured using MRI to that obtained from the multiple inert gas elimination technique (MIGET). Regional ventilation measured in a sagittal lung slice using Specific Ventilation Imaging was combined with proton density measured using a fast gradient-echo sequence to calculate regional alveolar ventilation, registered with perfusion images acquired using arterial spin labeling, and divided on a voxel-by-voxel basis to obtain regional V̇/Q̇ ratio. LogSDV̇ and LogSDQ̇, measures of heterogeneity derived from the standard deviation (log scale) of the ventilation and perfusion vs. V̇/Q̇ ratio histograms respectively, were calculated. On a separate day, subjects underwent study with MIGET and LogSDV̇ and LogSDQ̇ were calculated from MIGET data using the 50-compartment model. MIGET LogSDV̇ and LogSDQ̇ were normal in all subjects. LogSDQ̇ was highly correlated between MRI and MIGET (R = 0.89, = 0.007); the intercept was not significantly different from zero (-0.062, = 0.65) and the slope did not significantly differ from identity (1.29, = 0.34). MIGET and MRI measures of LogSDV̇ were well correlated (R = 0.83, = 0.02); the intercept differed from zero (0.20, = 0.04) and the slope deviated from the line of identity (0.52, = 0.01). We conclude that in normal subjects, there is a reasonable agreement between MIGET measures of heterogeneity and those from proton MRI measured in a single slice of lung. We report a comparison of a new proton MRI technique to measure regional V̇/Q̇ ratio against the multiple inert gas elimination technique (MIGET). The study reports good relationships between measures of heterogeneity derived from MIGET and those derived from MRI. Although currently limited to a single slice acquisition, these data suggest that single sagittal slice measures of V̇/Q̇ ratio provide an adequate means to assess heterogeneity in the normal lung.

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