Clinical consequences of altered chemoreflex control

Plataki, Maria; Sands, Scott A.; Malhotra, Atul

doi:10.1016/j.resp.2013.04.020

Cited by 28 publications

(24 citation statements)

References 126 publications

(172 reference statements)

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“…[44][45] Metabolic acidosis enhances peripheral chemosensitivity, causing marked alterations in the ventilatory recruitment threshold of pCO 2 and ultimately predisposing central or OSA. 39,[46][47] It is thought that hypocapnia (reduced pCO 2 levels), a respiratory compensatory mechanism during metabolic acidosis, enhances chemoreceptor sensitivity to CO 2 , thus altering chemoreflex control, and ultimately destabilizing respiratory control during sleep by decreasing pCO 2 levels below the apneic threshold. [37][38][39]41,[48][49][50][51] On the other hand, chemoreflex sensitivity is markedly altered by hypercapnia.…”

Section: Chemoreflex Responsivenessmentioning

confidence: 99%

Obstructive Sleep Apnea and Kidney Disease: A Potential Bidirectional Relationship?

Abuyassin

Sharma

Ayas

et al. 2015

Journal of Clinical Sleep Medicine

114

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Section: Chemoreflex Responsivenessmentioning

confidence: 99%

Obstructive Sleep Apnea and Kidney Disease: A Potential Bidirectional Relationship?

Abuyassin

Sharma

Ayas

et al. 2015

Journal of Clinical Sleep Medicine

114

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“…The propensity for ventilation to oscillate (one potential source of variability) can be encapsulated by the engineering concept of loop gain, which describes the overall stability of the feedback system controlling ventilation (28). The ventilatory control system can be characterized by three main components: 1) the "controller gain," which is the response as a change in ventilation per change in unit PaCO 2 or PaO 2 (related to chemical drive); 2) the "plant gain," which can be expressed as the change in PaCO 2 or PaO 2 per unit change in ventilation; and 3) the circulation delay between the lungs and the peripheral and central chemoreceptors (28). Importantly, Khoo in his review illustrates the point that the same amount of ventilatory variability may be found in systems with different levels of stability (20).…”

Section: New and Noteworthymentioning

confidence: 99%

“…The objectives of this study were to describe the variability of resting ventilation [coefficient of variation (CV) of VT and slope], the stability in respiratory control (loop, controller and plant gains characterizing ventilatory-chemoresponsiveness interactions) and the chaotic-like dynamics (embedding dimension, Kappa values characterizing complexity) of resting ventilation in patients with a well-defined dysfunctional breathing pattern characterized by air hunger and constantly decreased PaCO 2 during a cardiopulmonary exercise test. Compared with 14 healthy subjects with similar anthropometrics, 23 patients with hyperventilation were characterized by increased variability of resting tidal ventilation (CV of VT median [interquartile]: 26% [19][20][21][22][23][24][25][26][27][28][29][30][31][32][33][34][35] vs. 36% [28 -48], P ϭ 0.020; slope: Ϫ6.63 [Ϫ7.65; Ϫ5. 36] vs. Ϫ3.88 [Ϫ5.91; Ϫ2.66], P ϭ 0.004) that was not related to increased chemical drive (loop gain: 0.051 [0.039 -0.221] vs. 0.044 [0.012-0.087], P ϭ 0.149) but that was related to an increased ventilatory complexity (Kappa values, P Ͻ 0.05).…”

mentioning

confidence: 99%

Increased ventilatory variability and complexity in patients with hyperventilation disorder

Bokov

Fiamma

Chevalier-Bidaud

et al. 2016

Journal of Applied Physiology

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It has been hypothesized that hyperventilation disorders could be characterized by an abnormal ventilatory control leading to enhanced variability of resting ventilation. The variability of tidal volume (VT) often depicts a nonnormal distribution that can be described by the negative slope characterizing augmented breaths formed by the relationship between the probability density distribution of VT and VT on a log-log scale. The objectives of this study were to describe the variability of resting ventilation [coefficient of variation (CV) of VT and slope], the stability in respiratory control (loop, controller and plant gains characterizing ventilatory-chemoresponsiveness interactions) and the chaotic-like dynamics (embedding dimension, Kappa values characterizing complexity) of resting ventilation in patients with a well-defined dysfunctional breathing pattern characterized by air hunger and constantly decreased PaCO2 during a cardiopulmonary exercise test. Compared with 14 healthy subjects with similar anthropometrics, 23 patients with hyperventilation were characterized by increased variability of resting tidal ventilation (CV of VT median [interquartile]: 26% [19-35] vs. 36% [28-48], P = 0.020; slope: -6.63 [-7.65; -5.36] vs. -3.88 [-5.91; -2.66], P = 0.004) that was not related to increased chemical drive (loop gain: 0.051 [0.039-0.221] vs. 0.044 [0.012-0.087], P = 0.149) but that was related to an increased ventilatory complexity (Kappa values, P < 0.05). Plant gain was decreased in patients and correlated with complexity (with Kappa 5 - degree 5: Rho = -0.48, P = 0.006). In conclusion, well-defined patients suffering from hyperventilation disorder are characterized by increased variability of their resting ventilation due to increased ventilatory complexity with stable ventilatory-chemoresponsiveness interactions.

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“…Numerous disorders of breathing and cardio-respiratory coupling are associated with dysfunctional chemoreceptor drive mechanisms (Dempsey and Smith 2014;Garcia et al 2013;Perez and Keens 2013;Plataki et al 2013). Brain mechanisms that mediate the separate and joint actions of central chemoreceptors, sensors of brain CO 2 and pH, and the peripheral chemoreceptors are topics of active research and debate (Duffin and Mateika 2013; Nuding et al 2009b;Teppema and Smith 2013;Wilson and Day 2013).…”

mentioning

confidence: 99%

Peripheral chemoreceptors tune inspiratory drive via tonic expiratory neuron hubs in the medullary ventral respiratory column network

Segers

Nuding

Ott

et al. 2015

Journal of Neurophysiology

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113: 352-368, 2015. First published October 15, 2014 doi:10.1152/jn.00542.2014.-Models of brain stem ventral respiratory column (VRC) circuits typically emphasize populations of neurons, each active during a particular phase of the respiratory cycle. We have proposed that "tonic" pericolumnar expiratory (t-E) neurons tune breathing during baroreceptor-evoked reductions and central chemoreceptor-evoked enhancements of inspiratory (I) drive. The aims of this study were to further characterize the coordinated activity of t-E neurons and test the hypothesis that peripheral chemoreceptors also modulate drive via inhibition of t-E neurons and disinhibition of their inspiratory neuron targets. Spike trains of 828 VRC neurons were acquired by multielectrode arrays along with phrenic nerve signals from 22 decerebrate, vagotomized, neuromuscularly blocked, artificially ventilated adult cats. Forty-eight of 191 t-E neurons fired synchronously with another t-E neuron as indicated by crosscorrelogram central peaks; 32 of the 39 synchronous pairs were elements of groups with mutual pairwise correlations. Gravitational clustering identified fluctuations in t-E neuron synchrony. A network model supported the prediction that inhibitory populations with spike synchrony reduce target neuron firing probabilities, resulting in offset or central correlogram troughs. In five animals, stimulation of carotid chemoreceptors evoked changes in the firing rates of 179 of 240 neurons. Thirty-two neuron pairs had correlogram troughs consistent with convergent and divergent t-E inhibition of I cells and disinhibitory enhancement of drive. Four of 10 t-E neurons that responded to sequential stimulation of peripheral and central chemoreceptors triggered 25 cross-correlograms with offset features. The results support the hypothesis that multiple afferent systems dynamically tune inspiratory drive in part via coordinated t-E neurons.

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Clinical consequences of altered chemoreflex control

Cited by 28 publications

References 126 publications

Obstructive Sleep Apnea and Kidney Disease: A Potential Bidirectional Relationship?

Obstructive Sleep Apnea and Kidney Disease: A Potential Bidirectional Relationship?

Increased ventilatory variability and complexity in patients with hyperventilation disorder

Peripheral chemoreceptors tune inspiratory drive via tonic expiratory neuron hubs in the medullary ventral respiratory column network

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