Conditioned respiratory threat in the subdivisions of the human periaqueductal gray

Faull, Olivia K.; Jenkinson, Mark; Ezra, Martyn; Pattinson, Kyle T. S.

doi:10.7554/elife.12047

Cited by 74 publications

(122 citation statements)

References 67 publications

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“…which were reported in two studies using pain stimuli and included the amygdala, prefrontal areas, and sensory cortices (Loggia et al, 2015;Seminowicz & Davis, 2006). In addition, neither during the anticipation nor during the perception of dyspnea were significant correlations of dyspnea catastrophizing observed with activations in insula and amygdala, although these areas were activated in previous studies during anticipated and perceived dyspnea (Davenport & Vovk, 2009;Evans, 2010;Faull et al, 2016;Herigstad et al, 2011), including the original study of Subsample 2 (Stoeckel et al, 2016). These discrepancies might be attributable to several differences between the present study and previous studies.…”

Section: Discussioncontrasting

confidence: 84%

“…These areas are not only involved in the processing of dyspnea and other aversive bodily sensations such as pain (Craig, 2002;Tracey & Mantyh, 2007;Van Oudenhove & Aziz, 2013;von Leupoldt et al, 2009), but are also key areas in the processing of negative affectivity such as anxiety (Adolphs, 2013;Etkin, Egner, & Kalisch, 2011;Etkin & Wager, 2007;Sehlmeyer et al, 2009). Notably, activations in these areas are not restricted to the perception of aversive stimuli, but are already present during their anticipation including the expectation of upcoming dyspnea (Faull, Jenkinson, Ezra, & Pattinson, 2016;Grupe & Nitschke, 2013;Holtz, Pan e-Farr e, Wendt, Lotze, & Hamm, 2012;Paulus et al, 2012;Stoeckel, Esser, Gamer, Kalisch et al, 2015;Stoeckel, Esser, Gamer, B€ uchel, & von Leupoldt, 2016).…”

Section: Introductionmentioning

confidence: 99%

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Dyspnea catastrophizing and neural activations during the anticipation and perception of dyspnea

et al. 2017

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Dyspnea is an aversive symptom in various diseases. High levels of negative affectivity are typically associated with increased dyspnea and changes in its neural processing. Recently, more dyspnea-specific forms of negative affectivity such as dyspnea catastrophizing were suggested to contribute to increased perception of dyspnea beyond effects of rather unspecific negative affectivity such as general anxiety levels. The involved neural mechanisms have not yet been explored. Therefore, the present retrospective analysis examined the associations of dyspnea catastrophizing with neural activations during the anticipation and perception of dyspnea. Sixty-six healthy volunteers underwent 20 blocks of inspiratory resistive load breathing with parallel acquisition of fMRI data. Loads inducing either severe or mild dyspnea (dyspnea conditions) were presented in alternating order, with each condition being visually cued (anticipation conditions). Dyspnea catastrophizing and general trait anxiety were measured with the Breathlessness Catastrophizing Scale (BCS) and the State-Trait Anxiety Inventory, respectively. Correlating the BCS scores with neural activations during the perception of dyspnea yielded no significant results. However, during the anticipation of dyspnea, BCS scores correlated positively with activations of the anterior cingulate cortex (ACC), even after controlling for general anxiety levels. These activations in the ACC were not related to concurrent respiratory parameters. Results suggest that dyspnea catastrophizing in healthy volunteers is associated with stronger ACC recruitment during dyspnea anticipation. Given the established role of the ACC in processing affective states, affect regulation, and antinociception, this might reflect increased affective and/or top-down modulatory processing in individuals with higher dyspnea catastrophizing when anticipating dyspnea.

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Section: Discussioncontrasting

confidence: 84%

Section: Introductionmentioning

confidence: 99%

Dyspnea catastrophizing and neural activations during the anticipation and perception of dyspnea

et al. 2017

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“…The previous circuitry that has been employed to manually administer inspiratory resistances within an MRI scanner 16,26,27 is outlined in Figure 1A. In this experimental setup, compressed and humidified medical air was delivered to the participant via a breathing system, whereby air flow was maintained at a rate to adequately allow free breathing and access to an available air reservoir (within a reservoir bag) of 2 L. When a (conditioned) visual cue appeared on the screen, the delivery of compressed air was manually halted via closure of the corresponding air flowmeters, allowing the reservoir bag to empty over the course of approximately 3-8 seconds (anticipation period), followed by the application of inspiratory resistance once the air reservoir was empty.…”

Section: Previous Inspiratory Resistance Administration Circuitrymentioning

confidence: 99%

“…We focus on respiration, presenting an advanced circuitry for the automated administration of inspiratory resistances. This circuitry builds on a previously-published magnetic resonance imaging (MRI)-compatible inspiratory resistance circuit 16,26,27 , incorporating computer-controlled solenoid valves for timely commencement and elimination of resistance, and an electronicallycontrolled, flow-mediated inspiratory valve device (POWERbreathe, IMT Technologies Ltd., Birmingham, UK) to allow for adjustable maximal resistances. While the previous methodology has been employed to measure the brain activity (via functional magnetic resonance imaging, or fMRI) related to the conditioned anticipation and perception of inspiratory resistive loads, these advances significantly aid the development of complicated protocols required for a more detailed study of dynamic brain-body interactions 28 .…”

Section: Introductionmentioning

confidence: 99%

Tools and Resources: Remote, automated and MRI-compatible administration of interoceptive inspiratory resistive loading

2019

Preprint

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Research on how humans perceive sensory inputs from their bodies ('interoception') has been rapidly gaining momentum, with interest across a host of disciplines from physiology through to psychiatry. However, studying interoceptive processes is not without significant challenges, and many methods utilised to access internal states have been largely devoted to capturing and relating naturally-occurring variations in interoceptive signals (such as heartbeats) to measures of how the brain processes these signals. An alternative procedure involves the controlled perturbation of specific interoceptive axes. This is challenging because it requires non-invasive interventions that can be repeated many times within a subject and that are potent but safe.Here we present an effective methodology for instigating these perturbations within the breathing domain. We describe a custom-built circuitry that is capable of delivering inspiratory resistive loads automatically and precisely. Importantly, our approach is compatible with magnetic resonance imaging environments, allowing for the administration of complicated experimental designs in neuroimaging as increasingly required within developing fields such as computational psychiatry/psychosomatics. We describe the experimental setup for both the control and monitoring of the inspiratory resistive loads, and demonstrate its possible utilities within different study designs. This methodology represents an important step forward from the previously utilised, manually-controlled resistive loading setups, which present significant experimental burdens with prolonged and/or complicated sequences of breathing stimuli.

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“…Observations on breathlessness anxiety in COPD suggest that fear conditioning related to learned negative associations between everyday situations and dyspnoea exacerbate the downward spiral of breathlessness and inactivity. Neuroimaging studies testing this are starting to emerge [22,23], and implicate emotional processes in the medial prefrontal cortex contributing to chronic breathlessness. Whether neurodegeneration in frontal and other emotion-processing brain regions specifically contributes to breathlessness in ALS remains unknown.…”

mentioning

confidence: 99%

A wider pathological network underlying breathlessness and respiratory failure in amyotrophic lateral sclerosis

Pattinson

Turner

2016

Eur Respir J

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Conditioned respiratory threat in the subdivisions of the human periaqueductal gray

Cited by 74 publications

References 67 publications

Dyspnea catastrophizing and neural activations during the anticipation and perception of dyspnea

Dyspnea catastrophizing and neural activations during the anticipation and perception of dyspnea

Tools and Resources: Remote, automated and MRI-compatible administration of interoceptive inspiratory resistive loading

A wider pathological network underlying breathlessness and respiratory failure in amyotrophic lateral sclerosis

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