Subject-Specific Activation of Central Respiratory Centers during Breath-Holding Functional Magnetic Resonance Imaging

Background: Voluntary breath-holding (BH) triggers responses from central neural control and respiratory centers in order to restore breathing. Such responses can be observed using functional MRI (fMRI). Objectives: We used this paradigm in healthy volunteers with the view to develop a biomarker that could be used to investigate disorders of the central control of breathing at the individual patient level. Method: In 21 healthy human subjects (mean age±SD, 32.8 ± 9.9 years old), fMRI was used to determine, at both the individual and group levels, the physiological neural response to expiratory and inspiratory voluntary apneas, within respiratory control centers in the brain and brainstem. Results: Group analysis showed that expiratory BH, but not inspiratory BH, triggered activation of the pontine respiratory group and raphe nuclei at the group level, with a significant relationship between the levels of activation and drop in SpO2. Using predefined ROIs, expiratory BH, and to a lesser extent, inspiratory BH were associated with activation of most respiratory centers. The right ventrolateral nucleus of the thalamus, right pre-Bötzinger complex, right VRG, right nucleus ambiguus, and left Kölliker-Fuse-parabrachial complex were only activated during inspiratory BH. Individual analysis identified activations of cortical/subcortical and brainstem structures related to respiratory control in 19 out of 21 subjects. Conclusion: Our study shows that BH paradigm allows to reliably trigger fMRI response from brainstem and cortical areas involved in respiratory control at the individual level, suggesting that it might serve as a clinically relevant biomarker to investigate conditions associated with an altered central control of respiration.

© 2023 The Author(s). Published by S. Karger AG, Basel

Introduction

Physiological rhythmic breathing in humans depends on the activity of several brainstem nuclei, including the ventral respiratory group or column (VRG or VRC), dorsal respiratory group (DRG), and nucleus ambiguus (NA) in the medulla oblongata, and pontine respiratory group (PRG) composed of the pneumotaxic center (Kölliker-Fuse/parabrachial complex) with tight connection to the locus coeruleus (LC) and apneustic center [1]. Cortical and subcortical structures are also involved in respiratory control, with the amygdala and frontal cortex, including the cingulate, mediating the affective component of breathing, while the somatosensory cortex and dorsal striatum are involved in the motor control of respiration [2].

Dysfunctions of respiratory centers are likely to occur in several conditions, including obstructive sleep apnea (OSA) [3], sudden unexpected death in epilepsy patients (SUDEP) [4], sudden infant death syndrome [5], Prader-Willi syndrome [6], and congenital central hypoventilation syndrome (Ondine’s syndrome) [7]. Yet, while a number of studies have explored the physiological mechanisms of breathing, such as distribution of respiratory centers in the brainstem or central regulation during hypercapnic challenges in rats [8-10], little is known about the changes in the human brain and brainstem control of respiration in these conditions. A better understanding of the central respiratory function and dysfunctions in humans could help develop clinically relevant biomarkers and interventions, with the view to predict and prevent tragic outcomes, such as SUDEP.

Functional magnetic resonance imaging (fMRI) offers opportunities to investigate this issue using a simple voluntary breath-holding (BH) paradigm which can be implemented in any MRI setting and readily translated into clinical practice if proved useful. Central respiratory activity continues throughout BH which triggers responses from respiratory centers, including suppression of pacemaker cell activity in the VRG [11]. Previous fMRI BH studies in small cohort of healthy subjects showed promising findings in a small sample, with significant brainstem and cortical/subcortical responses [12, 13]. BH does not require any specialized equipment and is rather simple to employ in clinical settings. Previous research suggested that this strategy produced a reliable fMRI BOLD response similar to that triggered by hypercapnia produced by controlled CO2 inhalation [14-18]. These studies identified a variety of anatomical and physiological mechanisms behind the generation and modulation of respiratory rhythm as well as the selective engagement of brainstem respiratory centers in BH control [13, 19]. We further detailed these findings in a very recent review [20] and observed that little information was available as to which type of BH produces the stronger central response or whether the response is identical with inspiratory or expiratory BH. In this study, we aimed at further exploring BH-triggered fMRI activation of brain and brainstem respiratory centers with the view to test the possibility to delineate reliable BOLD responses at the individual level in healthy subjects. Such individual responses would be a prerequisite for the development of fMRI biomarkers for patients with respiratory dysfunction of central origin.

Materials and MethodsSubjects

Healthy volunteers aged 18–55 years old were recruited through advertisement. Exclusion criteria included (1) ongoing or chronic medical conditions, (2) history of respiratory or neurological disease, (3) intake of medication except oral contraceptives, (4) pregnant women, (5) subjects living at high altitude (>2,000 m), (6) subjects practicing free-diving, (7) any contraindication to an MRI investigation. All subjects gave their written informed consent to participate in the study which was approved by the Ethics Committee of Canton de Vaud.

Physiological Signals

Before starting the MRI session, subjects were equipped with MRI-compatible materials that provided permanent measurements of respiratory movements using a respiration transducer (Biopac Systems Inc., Goleta, CA, USA), pulse oximetry using a finger transducer (Nonin Medical, Plymouth, MN), and a mouthpiece with a cannula to measure end-tidal O2 and CO2 (Biopac Systems Inc.).

Behavioral Experiment

The experimental procedure was explained in detail to all subjects prior to their participation. Participants were trained to restrict any head and neck movements during the whole experiment. All participants were visually observed and guided during the initial training period to ensure they fully comply with the instructions to minimize movements after BHs, in particular forced gasping.

Participants were pseudo-randomly assigned to start the fMRI experiment with either the inspiratory or expiratory BH task. The experiment was divided into a resting part and a functional part and lasted on average 60 min during which physiological respiratory data were continuously recorded. In the first 20 min, subjects breathed normally while structural MR images were acquired. This also enabled subjects to adapt to breathing in the MRI gantry in order to ensure stable and regular breathing during the baseline parts of the fMRI experiment.

During the fMRI part, each subject performed four BH runs, including two inspiratory and two expiratory, with six blocks of BH within each run (Fig. 1). Each run lasted between 7 and 11 min depending on the individual’s capacity to fulfill the task. Given the previous observation that BOLD signal variability during BH can be significantly reduced with the use of visually cued tasks [21], we used colored circle instructions on the screen as illustrated in Figure 1. A dedicated workstation running Presentation software (Neurobehavioral Systems, San Francisco, CA, USA) was used to control the presentation of cues and record subjects’ responses. A green dot was first presented on the screen for 30 s during which the subject was instructed to breathe normally through the mouthpiece; then, a 2-s duration yellow dot was shown, indicating that the subject needed to prepare himself for an expiratory or inspiratory BH that shall start at the end of an expiration or inspiration, respectively, and at the end of the 2 s. Finally, a red dot was displayed to indicate the onset and continuation of BH as long as the subject could handle it while keeping comfortable. Subjects pushed a button at the time they resumed breathing, which turned the dot green again.

Fig. 1.

Example of one of the six blocks in a run (expiratory or inspiratory). Subjects performed four runs (two inspiratory unconstrained BH runs and two expiratory unconstrained BH runs).

/WebMaterial/ShowPic/1492145MRI Imaging and Protocol

Participants were examined on a 3T whole-body MRI system (Magnetom Prisma, Siemens Medical Systems, Germany), using a 64-channel RF receiver head coil and body coil for transmission. The structural MRI protocol included 10 min of anatomical imaging (sagittal MPRAGE, slice tilt = 8°, echo time, 2.67 ms; repetition time, 3.50 s; TI = 1,000 ms, matrix size = 256, field of view = 224 mm, slice thickness = 0.9 mm, voxel size 0.9 × 0.9 × 0.9 mm) followed by 6-min time of flight imaging (slice tilt = 18°, echo time, 3.43 ms; repetition time, 0.21 s; slice thickness = 0.6 mm, GRAPPA factor 2) to acquire vascular structures, in particular that of vertebrobasilar arteries. These were used to ensure that BOLD signal changes acquired during the fMRI experiment were deemed located in the brainstem parenchyma and not reflecting spill-over effect from changes occurring in nearby vessels.

The fMRI protocol used a gradient-echo T2*-weighted echo-planar imaging sequence as described in the study by Beissner et al. 2014 [22] (slice tilt = 40°, echo time, 30 ms; repetition time, 2.52 s; slice thickness = 2.5 mm, GRAPPA factor 2) covering the whole brain, including the lower brainstem. The proposed protocol is based on experiments previously published in the field and which proved effective at investigating brain and brainstem BOLD response [12, 21].

Data Preprocessing

Times of onset, termination, and duration of each BH were determined by using several sources of information: (1) those that were automatically recorded through the Presentation software which provided the theoretical times of BH onset (red cue) and termination (button pressed by the subject), and (2) the recorded respiratory movements whose peaks were automatically identified by an in-house MATLAB-based software. As a rule, these sources of information were highly concordant, while in a few subjects, BH was slightly delayed following the red cue or terminated slightly prior to pressing the button. We also inspected the evolution of end-tidal CO2 and O2 during BH to ensure lack of inconsistency. BH blocks associated with variations in gas concentration and thoracic movements were discarded from the analysis. Apnea events were defined in this study as cessation of airflow for more than 10 s. Whenever BH was associated with a drop in SpO2 ≥4% from baseline, which is considered clinically significant [23], we marked the decline between the onset and offset of the SpO2 drop.

We tested the similarity of the apnea duration values automatically obtained from the recording system to those corrected manually, using a correlation coefficient. The difference in drop of SpO2 between inspiratory and expiratory BH was assessed for homogeneity (Levene’s test) and compared between conditions using a Mann-Whitney U test. The duration of apnea reported by subjects highly correlated with that measured through objective respiratory movements (correlation coefficient, R = 0.963 for expiratory BH, R = 0.954 for inspiratory BH) (see Table 1).

Table 1./WebMaterial/ShowPic/1492159

fMRI studies of the human brainstem have proved challenging for various methodological reasons [24]. BH maneuver is accompanied by changes in breathing rate and depth across the various phases of the experiment, which cause significant and faster respiration-induced BOLD-like signal fluctuations that need to be filtered [25, 26]. BH also alters the levels of O2 and CO2, thus inducing mild hypoxia and increased hypercapnia, which directly influence the BOLD contrast [27]. Finally, cardiac-related artifacts are arising from brain movement caused by fluctuating blood pressure and blood volume during each heart beat [28]. Delineating the temporal dynamics of these susceptibility-induced changes is thus required to measure the true BOLD signal changes occurring in the brain and brainstem respiratory centers and reduce the risk of false-positive and false-negative findings [27, 29, 30]. To this end, end-tidal CO2 was convolved with the response function and regressed out of the BOLD signal at each voxel, producing the corrected data. The subject-specific end-tidal CO2 was calculated from the points of maximum CO2 values at the end of each exhale, linearly interpolating between them, and resampling the result to the TR timing (2,520 ms). For BH periods in which there were no end-tidal CO2 values, the interpolation range was between the last exhale before BH and the first after, as described previously [31]. The detection of the “respiration and circulation response function” was accomplished by incorporating the measurement of thoracic breathing movements and cardiac heartbeats into the model [22, 25, 32].

MRI data were processed using MATLAB 7.6 (Mathworks Inc., Sherborn, MA, USA) with statistical parametric mapping software (SPM12, Wellcome Department of Imaging Neuroscience, London, UK). The first four volumes were discarded to allow the MRI signal to reach equilibrium. All images were then realigned to the mean functional image, which was co-registered with the anatomical image. The T1 volume was segmented by DARTEL. The deformation maps were applied to the realigned functional volumes for spatial normalization and the volume resliced to 2 × 2 × 2 mm voxels in MNI space. Normalized volumes were then smoothed at 4 mm full-width half-maximum.

Our primary endpoint was the BOLD activation measured in brainstem respiratory centers following inspiratory and expiratory BH as compared to baseline, at both the individual and group levels. According to this specific objective and in order to increase statistical power, we created and used a mask of the brainstem and cortical/subcortical areas known to participate in breathing control. This mask was built using the regions of interest (ROIs) derived from “Hammersmith atlas n30r83” atlas [2, 33-35]. Brain structures described in the literature as playing a significant role in the regulation of breathing during apnea and selected for the mask included the prefrontal cortex [2, 36, 37], pre- and postcentral gyrus [33, 36, 37], thalamic nuclei (ventrolateral nucleus [VL], anterior nucleus [ANT]) [33, 36, 37], hypothalamus [33, 36, 37], insula, hippocampus [2, 33-35], amygdala [2, 33-35], and anterior cingulate [2, 33-35].

Because the brainstem structures involved in respiratory control are fairly small, besides looking at the signal change in the whole structure, we also opted for individual ROIs to observe their response during our experiment. Spherical ROIs (diameter = 3 mm) were placed in the volumetric center of respiratory centers in the brainstem and subcortical nuclei involved in breathing control. The ROI location was adjusted to include only gray matter voxels and limit any overlapping voxels when possible. The coordinates of the circular ROIs of the brainstem and subcortical structures are listed in Table 2. Their location was identified either by validating their location in human brain atlases, if available, or identifying their position according to described landmarks (refer to Table 2).

Table 2.

Coordinates of circular ROIs selected based on the literature

/WebMaterial/ShowPic/1492157Statistics

SPM analyses of preprocessed MRI data were performed using a general linear model. We created several contrasts to identify a significant difference once comparing two variables to one another. General linear model included inspiratory BH, expiratory BH, SpO2 falls and rises during inspiratory and expiratory BH, and deactivations during BH. Contrasts of interest were generated by comparing the beta weights associated with BOLD activation in response to BH. Cluster corrected significance level was set at p < 0.05 after family-wise error correction for multiple comparisons for the number of voxels tested for the group analyses and individual subject responses (for visualization purpose, figures also show clusters at p = 0.001). BOLD activation maps from each individual subject were also compared to those from the group composed of all other subjects with the view to test whether some normal subjects would significantly differ from the others. Ideally, one would hope not to detect significant findings in subjects without respiratory disorder but only in patients with such disorders.

ROI-based analyses of the mean % change in BOLD signal in brainstem and diencephalon respiratory centers were performed using a multivariate statistic (MANOVA) and post hoc non-parametric tests (LSD) for every individual ROI (p < 0.05). We compared the mean β value of each ROI, during the expiratory BH, inspiratory BH, and baseline. We assessed the percentage of subjects presenting a BOLD signal change in the brainstem and investigated the relation between such changes and the duration of apnea and drop in SpO2.

ResultsSubjects Characteristics

We included 21 healthy subjects in the study (52.4% females, 47.6% males), with a mean age ± SD of 32.8 ± 9.9 years, Table 3. No subject was excluded from the study.

Table 3./WebMaterial/ShowPic/1492155Behavioral Response

We observed a great inter-individual heterogeneity in the duration of apneas, which lasted longer for inspiratory BH (median 44.7 s, range 26.6–67.4 s) than for expiratory BH (median 28.4 s, range 16.9–53.5 s). During expiratory BH, two of the 21 subjects (9.5%) achieved a maximal apnea duration <20 s, ten (47.6%) in the range of 20–30 s, eight (38.1%) in the range of 30–40 s, and one (4.8%) > 40 s. During inspiratory BH, all subjects achieved a maximal apnea duration >20 s, including four (19%) in the range of 20–30 s, six (28.6%) in the range of 30–40 s, and eleven (52.4%) > 40 s.

The mean drop in SpO2 ± SD was 2.74% ± 2.24 during expiratory BH (range 0.07–7.75) and significantly greater than that observed during inspiratory BH, e.g., 0.93 ± 0.77 (range 0.03–2.63) (p = 0.0012). Accordingly, SpO2 drops of 4% or more were detected in only five subject (24%) who hold their breath for ≥20 s during expiratory BH (between 25.1 and 52 s), while such a drop was never observed during inspiratory BH. The drop in SpO2 positively correlated with the duration of apnea, both during inspiratory (R = 0.492, p = 0.023) and expiratory BH (R = 0.679, p = 0.001).

Imaging BOLD ResponseGroup-Level Analysis

Mask of the brainstem and subcortical/cortical regions (Table 4): During expiratory BH, significant BOLD activation was observed over the pons, the hippocampus and amygdala, the thalamus, the caudate nuclei, and the frontal and temporal cortices (Table 4; Fig. 2a, c). During inspiratory BH, similar cortical activations were observed, with additional clusters in the parietal cortex and anterior cingulate, but without significant brainstem activation (Table 4; Fig. 2b, d). However, when directly comparing expiratory and inspiratory BH, no significant difference was evidenced between the two conditions. No significant deactivations were detected.

Table 4.

General linear model group analyses

/WebMaterial/ShowPic/1492153Fig. 2.

Group analyses. Expiratory BH (upper row, a, c) and inspiratory BH (lower row, b, d). Images obtained using the FWE threshold are shown on the left, while clusters visible using the uncorrected p = 0.001 threshold are shown on the right. FWE, family-wise error.

/WebMaterial/ShowPic/1492143ROI-Based Analysis

Table 5 details the results from MANOVA analysis using the percentage BOLD change between the task and the baseline obtained from the ROIs located in the brainstem and thalamus. Significant BOLD signal changes were detected in the median and dorsal raphe, left ANT, left NA, left VRG, left lateral reticular nuclei, left pre-Bötzinger complex (PBC), and nucleus tractus solitarus, during both types of BH. Conversely, the right VL nucleus of the thalamus, right PBC, right VRG, right NA, and left Kölliker-Fuse-parabrachial complex were only activated during inspiratory BH. No significant changes were detected in the right ANT, right Kölliker-Fuse-parabrachial complex, LC, and left VL.

Table 5.

Multivariate analysis of ROI beta values in the brainstem and the thalamus

/WebMaterial/ShowPic/1492151Individual Imaging Results

Details about the individual response to the BH within the cortical and subcortical areas involved in respiratory control are provided in Table 6. Nineteen out of the 21 subjects (90.5%) demonstrated a significant response to BH at the individual level within the brainstem-hypothalamic area, including 19 during expiratory BH (90.5%), 17 of whom also showed a significant individual response during inspiratory BH (80.9%). These individual responses involved the brainstem proper in 18 subjects (85.7%), including the mesencephalon in 15 (71.4%), the pons in 17 (80.9%), and the medulla in five (23.8%). As a rule, the majority of these responses were observed during both expiratory and inspiratory BH, with slightly more responses for the former. Conversely, thalamic responses, which were present in 17 subjects (80.9%), were more frequent in inspiratory than expiratory BH (i.e., 80.9% vs. 71.4%). All 19 subjects with a significant BOLD response showed activation in some cortical areas (frontal, temporal, parietal, and limbic regions). Online supplementary Figure 1 (for all online suppl. material, seewww.karger.com/doi/10.1159/000529388) shows examples of individual BOLD activations in two subjects for the two BH tasks.

Table 6./WebMaterial/ShowPic/1492149

Of note, one of the only two subjects in whom the BOLD signal did not significantly vary is a professional athlete (mean variation of SpO2 1.062%), while the second subject suffered significant variations in performance across BH sessions (from 11 to 27 s for expiratory BH and 22–38 s for inspiratory BH). Deactivations within the brainstem were also observed in eight subjects during inspiratory BH, and ten subjects during expiratory BHs.

Adjusting individual analyses to changes in SpO2 did not improve their sensitivity with less subjects showing significant BOLD activation. Yet, all five subjects with a drop in SPO2 ≥4% displayed a significant BOLD response in the medulla and the pons.

The duration of expiratory BH did not seem to influence the likelihood of significant individual response, with comparable findings for all ranges of apnea duration (Table 7). In contrast, the duration of inspiratory BH might have an impact on the proportion of significant BOLD activation, with 83% of subjects performing an apnea of 30 < t ≤40 s showing such an activation, as compared to only 45–50% for shorter or longer apnea (Table 7). Yet, this difference was not statistically tested according to the small number of subjects in each category.

Table 7.

Individual brainstem BOLD response as a function of apnea duration

/WebMaterial/ShowPic/1492147Individual versus Group Comparison

No subject showed a significant difference in BOLD activation maps when compared to the group of all other subjects, including the two subjects who failed to demonstrate a significant fMRI activation during BH.

Discussion

The primary goal of the present human fMRI study was to trigger an activation of the respiratory centers that would prove assessable at the individual patient level, using a simple BH paradigm easily implementable in clinical routine. This would open the door to the development of a clinically relevant biomarker for conditions with a suspected dysfunction of central respiratory control. We observed a significant BOLD response in the brainstem and hypothalamus in 90.5% of our normal subjects, with one of the only two exceptions observed in a professional athlete and the other in a subject with unreliable BH. Furthermore, none of our control subjects showed a significant difference when tested against the group of all other controls. These findings are encouraging toward the possibility of using this simple paradigm in relevant patients with the hope to delineate significant abnormalities at the individual level.

The BH paradigm with unconstrained duration is characterized by very heterogeneous duration of apnea and associated levels of SpO2 [27, 31, 38], as observed in our study. Yet, despite variation in BH duration, the BOLD signal can be robustly mapped [27]. As previously reported, inspiratory BH was significantly longer than expiratory BH while associated with milder reduction in SpO2 [24], with a positive correlation between the duration of apneas and the drop of SpO2, regardless of the type of BH [39]. Our subjects were requested to hold their breath as long as it was bearable, leading the majority to execute expiratory BH lasting between 20 and 30 s and to show a BOLD response, regardless of the duration of expiratory BH. For inspiratory BH, the proportion of significant BOLD response was observed in 83% of participants that performed 30–40 s BH but in only half of those who performed inspiratory BH of shorter or longer duration. Previous reports suggested that apnea duration of 20 s is required to obtain a reliable BOLD response for expiratory BH [27] and more than 20 s for inspiratory BH [40]. While our findings are consistent with these observations for expiratory BH, they suggest that longer inspiratory BH, between 30 and 40 s, is associated with a greater likelihood of a BOLD response within the brainstem. Interestingly, we also found that drops of SpO2 of more than 4% systematically led to a strong individual response from VRG and PRG.

Mechanisms regulating the individual duration of BH remain uncertain [41, 42]. The act of holding one’s breath engages a conscious inhibitory stimulus which is eventually overwhelmed by an involuntary stimulus, forcing the subject to finally inspire or expire [43, 44]. The centers that are responsive for the urge to breathe are located in the medulla oblongata and include serotoninergic neurons that detect increased pCO2 and then fire to stimulate respiration [45, 46]. Their reactivity to the hypercapnic condition seems to vary greatly [2], and the difference in BOLD response to hypercapnia might be due to difference in neuronal activation of these centers [47]. Animal studies [9, 48-52] also helped define the role and associations of structures involved in the semiology of breathing. These studies highlight the essential connections of the thalamus with the supplementary motor area, premotor, frontal, prefrontal, and anterior-cingulate cortex, and the anterior insula. In particular, the thalamocortical serotoninergic projections induce cortical arousal, mediating the “life-saving” response to hypercapnia [45]. The hypothalamus also plays an essential role in hypoxic and hypercapnic conditions [53].

Our group-level analyses showed BH-triggered activation in the majority of regions known to participate in the central regulation of breathing, i.e., the PRG, medial and dorsal raphe nuclei, thalamus, caudate, hippocampus, and cortical areas located in the frontal, parietal, and temporal lobes. When extracting signal from predefined ROIs centered around known respiratory centers, fMRI responses to both expiratory and inspiratory BH were observed over the median and dorsal raphe, thalamus, the DRG, the PBC complex, and the VRG. At the individual level, BOLD activation in both types of BH was observed in cortical areas (frontal, parietal, temporal, and limbic regions), the diencephalon, the mesencephalon, the apneustic and the pneumotaxic centers, the ventral-lateral pons, as well as the DRG, the VRG, and the raphe nuclei. These results are consistent with previous studies which described regions susceptible to hypercapnic challenges [54, 55] and BH [31]. These regions are typically well irrigated and associated with high BOLD sensitivity [56]. Several of these respiratory centers, such as the DRG and inferior ventral pons, the NA, and PBC [2], are also composed of chemo-sensitive and rhythm generator cells [57] which, when activated, reflect the direct impact of hypercapnia and the increase in respiratory motor activity [2].

Numerical differences were observed between expiratory and inspiratory BH using voxel-based SPM analyses, with more brainstem activation during expiratory BH, in particular within the pons, and more cortical activation during inspiratory BH, in particular within the anterior cingulate. These differences did not prove significant, however, possibly due to the limited sample size of our cohort. Few other fMRI studies have investigated the human brainstem in the autonomic or voluntary control of breathing using different methods [2, 13, 26]. Some resting-state fMRI studies aimed at quantifying the noise contribution to the resting BOLD signal, particularly in the brainstem [26, 58]. While quantifying the BOLD response in the brainstem is fairly challenging, it can be reliably quantified if appropriate correction for noise, motion, cardiac and respiratory activities, and end-tidal CO2 is applied [26, 58]. An fMRI study using inhalation of CO2 in 12 healthy volunteers showed changes in BOLD signal in dorsal rostral pons, the inferior ventral pons, and the dorsal and lateral medulla [2]. Another study compared the whole-brain activation during BH to activation after CO2 administration challenge in order to delineate the nonspecific whole-brain activation (vasodilatory effect of CO2) from the local neural-related BOLD signal change [13]. Similar to our study, they found a response to BH in six healthy volunteers over cortical and subcortical structures including the insula, basal ganglia, frontal cortex, parietal cortex and thalamus, and the pons.

In about half of our subjects, we detected simultaneous activation of the limbic structures – amygdala and/or hippocampus during BH. Recent data from direct electrical cortical stimulation experiments suggest that the human amygdalohippocampal complex can exert effects on breathing [34, 59] and might play a crucial role in patients with epilepsy who are at risk of SUDEP [60].

To our knowledge, only one other study provided results of BH-triggered fMRI response at the individual level in six healthy subjects [13]. While most subjects in that study showed significant fMRI activations following inspiratory BH, in particular over the dorsal somatosensory cortex, the cerebellum, and the cingulate gyrus, bilaterally, a large heterogeneity of BOLD activation was observed across individuals. Another study used CO2 challenge in healthy volunteers to trigger central hypercapnic response [47]. Individual maps demonstrated BOLD responses in the cortex, the thalamus, the pons, and the medulla, similar to those reported in our study [47].

BOLD signal failed to be significant in two of our 21 subjects, likely due in one subject to his athletic performances and tolerance to long-lasting apnea, while the second subject was not compliant with the BH challenges. Experimental procedures ought to be considered carefully and conducted properly for triggering the respiratory centers. The critical steps within our protocol included implementing a respiration-triggered paradigm to allow subjects to be comfortable enough to comply with the task. Confounding variables such as habituation, anxiety within the scanner, and respiration patterns in different people need to be considered when designing a paradigm and analyzing the data. Poor compliance to even one BH will affect the recorded time series [31]. The fMRI data are generally highly variable between subjects and even within one subject, and for repetitive or demanding tasks as our BH maneuver, cooperation of the subject is necessary. While BH is fairly easy to implement using a visual cue, noncompliancy might represent an issue in some populations (e.g., patients with cognitive disorders, elderlies, children).

BH task or CO2 inhalation-induced hypercapnia have both been used to evaluate cerebrovascular reactivity in various diseases [61, 62]. BH fMRI has also been used to explore the brain activation patterns in OSA, bipolar disorders, acute stroke, and gliomas [63-66]. In patients with OSA, overall cortical and brainstem activation patterns were significantly reduced compared to healthy controls [63]. Additionally, researchers found positive correlations between resting state and cerebrovascular reactivity following the BH task in elderly [67] and slower BOLD responses in Alzheimer disease following CO2 challenge [68]. Based on our findings, we believe that BH-triggered fMRI could be further used in other patient populations to investigate disorders of central respiratory regulation, in particular in patients with central hypoventilation syndrome, central sleep apnea, sudden infant death syndrome, or syndrome Prader-Willi and those with epilepsy at risk of SUDEP. Indeed, SUDEP has been found to be primarily derived from postictal seizure-triggered central respiratory arrest, suggesting an altered response of the brainstem respiratory centers to hypoxia [69]. We are currently running such a study in persons with epilepsy.

Various limitations should be addressed. First, because we chose to sample the BOLD signal from the entire brain, we chose a larger field of view and a high TR (2,520 ms) that limited the sampling rate of cardiac and respiratory cycles which could have affected the time series [56]. Second, the accuracy in measurements of airflow and exhaled gas pressures may have been altered by the use of the mask without use of a nose clip [12]. Due to logistical capacity, we could not use both instruments. However, the use of a thoracic belt allowed us to visualize the thoracic movement, which, associated with the absence of gas exchanges in the mask (pCO2 and pO2), delineated the apnea period. Finally, the brainstem is a complex structure that is difficult to precisely differentiate in fMRI imaging due to its low spatial resolution. Accordingly, we considered BOLD activity in the mesencephalon as reflecting the anatomical location of the raphe nuclei and clusters in PRG as reflecting the activation of the Kölliker-Fuse/parabrachial complex, LC, and apneustic center. Signal in the VRG was considered to reflect the activity in the parafacial nucleus, Bötzinger, PBC, cVRG, and rVRG.

Conclusion

BH maneuver is an effective and easy to implement trigger of central respiratory centers which provide robust fMRI response in humans at the individual level and could prove to be a useful biomarker in various medical conditions associated with central respiratory dysfunction.

Acknowledgments

We thank all subjects that took part in this research. We would also like to thank the medical and technical staff at LREN, CHUV for assistance and technical support.

Statement of Ethics

This study protocol was reviewed and approved by Ethical committee of Canton de Vaud, approval 2016-02057. All subjects gave written informed consent to participate in this study.

Conflict of Interest Statement

Authors declare no conflict of interest.

Funding Sources

The study was supported by two grants from InnoCentive Challenges – The SUDEP Institute Challenge: Developing Predictive Biomarkers of Epilepsy Seizures.

Author Contributions

CC, MB, and PR wrote the manuscript and performed the statistical analysis. RB developed the in-house software to mark the BH. SR, JH, and SL participated in the design, statistical analysis, and proof-reading. DI was responsible for the design of the technical part of the experiment, from behavioral testing to MR scanning.

Data Availability Statement

All data generated or analyzed during this study are included in this article and its online supplementary material. Further inquiries can be directed to the corresponding author.

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