AUTHOR=Driver Ian D. , Wise Richard G. , Murphy Kevin 

TITLE=Graded Hypercapnia-Calibrated BOLD: Beyond the Iso-metabolic Hypercapnic Assumption

JOURNAL=Frontiers in Neuroscience

VOLUME=11

YEAR=2017

URL=https://www.frontiersin.org/journals/neuroscience/articles/10.3389/fnins.2017.00276

DOI=10.3389/fnins.2017.00276

ISSN=1662-453X

ABSTRACT=<p>Calibrated BOLD is a promising technique that overcomes the sensitivity of conventional fMRI to the cerebrovascular state; measuring either the basal level, or the task-induced response of cerebral metabolic rate of oxygen consumption (CMRO<sub>2</sub>). The calibrated BOLD method is susceptible to errors in the measurement of the calibration parameter <italic>M</italic>, the theoretical BOLD signal change that would occur if all deoxygenated hemoglobin were removed. The original and most popular method for measuring <italic>M</italic> uses hypercapnia (an increase in arterial CO<sub>2</sub>), making the assumption that it does not affect CMRO<sub>2</sub>. This assumption has since been challenged and recent studies have used a corrective term, based on literature values of a reduction in basal CMRO<sub>2</sub> with hypercapnia. This is not ideal, as this value may vary across subjects and regions of the brain, and will depend on the level of hypercapnia achieved. Here we propose a new approach, using a graded hypercapnia design and the assumption that CMRO<sub>2</sub> changes linearly with hypercapnia level, such that we can measure <italic>M</italic> without assuming prior knowledge of the scale of CMRO<sub>2</sub> change. Through use of a graded hypercapnia gas challenge, we are able to remove the bias caused by a reduction in basal CMRO<sub>2</sub> during hypercapnia, whilst simultaneously calculating the dose-wise CMRO<sub>2</sub> change with hypercapnia. When compared with assuming no change in CMRO<sub>2</sub>, this approach resulted in significantly lower <italic>M</italic>-values in both visual and motor cortices, arising from significant dose-dependent hypercapnia reductions in basal CMRO<sub>2</sub> of 1.5 ± 0.6%/mmHg (visual) and 1.8 ± 0.7%/mmHg (motor), where mmHg is the unit change in end-tidal CO<sub>2</sub> level. Variability in the basal CMRO<sub>2</sub> response to hypercapnia, due to experimental differences and inter-subject variability, is accounted for in this approach, unlike previous correction approaches, which use literature values. By incorporating measurement of, and correction for, the reduction in basal CMRO<sub>2</sub> during hypercapnia in the measurement of <italic>M</italic>-values, application of our approach will correct for an overestimation in both CMRO<sub>2</sub> task-response values and absolute CMRO<sub>2</sub>.</p>