Regulation of the chemosensory control of breathing by Kölliker-Fuse neurons

Damasceno, Rosélia S.; Takakura, Ana C.; Moreira, Thiago S.

doi:10.1152/ajpregu.00024.2014

Cited by 52 publications

(42 citation statements)

References 62 publications

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“…After birth, the Kölliker-Fuse abruptly reduces its inhibitory effects and becomes active as a respiratory center able to coordinate the pulmonary motor responses to hematic oscillations of pO 2 , pCO 2 , and pH [23,24]. Also the arcuate nucleus contributes to this chemoreceptive activity in the modulation of the eupneic breathing [25].…”

Section: Discussionmentioning

confidence: 99%

The First 5-Year-Long Survey on Intrauterine Unexplained Sudden Deaths from the Northeast Italy

Roncati

Pusiol

Piscioli

et al. 2016

Fetal and Pediatric Pathology

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Section: Discussionmentioning

confidence: 99%

The First 5-Year-Long Survey on Intrauterine Unexplained Sudden Deaths from the Northeast Italy

Roncati

Pusiol

Piscioli

et al. 2016

Fetal and Pediatric Pathology

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“…RTN effects on inspiratory amplitude may derive from direct projections to inspiratory premotor neurons located in the rVRG (Figure 1J), the Kölliker-Fuse nucleus (not illustrated) (Bochorishvili et al, 2012; Damasceno et al, 2014; Mizusawa et al, 1995; Smith et al, 2013; Yokota et al, 2007) and the lateral parabrachial nucleus (Yokota et al, 2015). Control of expiration by the RTN (Abbott et al, 2011; Marina et al, 2010) may involve projections to bulbospinal expiratory premotor neurons located in the cVRG (Bochorishvili et al, 2012; Gerrits and Holstege, 1996) and to the nearby parafacial oscillator for active expiration (Figure 1K) (Feldman et al, 2013; Huckstepp et al, 2015).…”

Section: Pathways Mediating the Effects Of Rtn On Breathingmentioning

confidence: 99%

Neural Control of Breathing and CO2 Homeostasis

Guyenet

Bayliss

2015

Neuron

391

332

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Summary Recent advances have clarified how the brain detects CO2 to regulate breathing (central respiratory chemoreception). These mechanisms are reviewed and their significance is presented in the general context of CO2/pH homeostasis through breathing. At rest, respiratory chemoreflexes initiated at peripheral and central sites mediate rapid stabilization of arterial PCO2 and pH. Specific brainstem neurons (e.g., retrotrapezoid nucleus, RTN; serotonergic) are activated by PCO2 and stimulate breathing. RTN neurons detect CO2 via intrinsic proton receptors (TASK-2, GPR4), synaptic input from peripheral chemoreceptors and signals from astrocytes. Respiratory chemoreflexes are arousal state-dependent whereas chemoreceptor stimulation produces arousal. When abnormal, these interactions lead to sleep-disordered breathing. During exercise, “central command” and reflexes from exercising muscles produce the breathing stimulation required to maintain arterial PCO2 and pH despite elevated metabolic activity. The neural circuits underlying central command and muscle afferent control of breathing remain elusive and represent a fertile area for future investigation.

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“…Other regions of the VRG, including the Bötzinger complex (BötC), the rostral ventral respiratory group (rVRG), and the caudal ventral respiratory group (cVRG), are also thought to be involved in the processing of the respiratory responses to chemoreflex activation, particularly in the forced inspiration and expiration pattern observed following carotid body activation (Guyenet, 2000; Abdala et al, 2009a; Mandel and Schreihofer, 2009; Zoccal et al, 2009b; Zoccal and Machado, 2011; Moraes et al, 2012b). The Retrotrapezoid nucleus (RTN) and the Parafacial Respiratory Group (RTN/pFRG), also receive chemoreflex related input (Figure 4) and are involved in the expiratory and sympatho-excitatory components of the response to hypoxia (Takakura et al, 2006; Abdala et al, 2009a; Abbott et al, 2011; Pagliardini et al, 2011; Takakura and Moreira, 2011; Damasceno et al, 2014a,b). In addition, there is growing evidence that NTS projections to pontine nuclei, especially to the parabrachial nucleus (PBN) and the Kölliker fuse (KF), also play an important role in the respiratory repercussions of chemoreflex activation (Abdala et al, 2009b; Costa-Silva et al, 2010; Song et al, 2011).…”

Section: Physiology Of the Peripheral Chemoreflex In Mammalsmentioning

confidence: 99%

Evolution and physiology of neural oxygen sensing

et al. 2014

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Major evolutionary trends in animal physiology have been heavily influenced by atmospheric O2 levels. Amongst other important factors, the increase in atmospheric O2 which occurred in the Pre-Cambrian and the development of aerobic respiration beckoned the evolution of animal organ systems that were dedicated to the absorption and transportation of O2, e.g., the respiratory and cardiovascular systems of vertebrates. Global variations of O2 levels in post-Cambrian periods have also been correlated with evolutionary changes in animal physiology, especially cardiorespiratory function. Oxygen transportation systems are, in our view, ultimately controlled by the brain related mechanisms, which senses changes in O2 availability and regulates autonomic and respiratory responses that ensure the survival of the organism in the face of hypoxic challenges. In vertebrates, the major sensorial system for oxygen sensing and responding to hypoxia is the peripheral chemoreflex neuronal pathways, which includes the oxygen chemosensitive glomus cells and several brainstem regions involved in the autonomic regulation of the cardiovascular system and respiratory control. In this review we discuss the concept that regulating O2 homeostasis was one of the primordial roles of the nervous system. We also review the physiology of the peripheral chemoreflex, focusing on the integrative repercussions of chemoreflex activation and the evolutionary importance of this system, which is essential for the survival of complex organisms such as vertebrates. The contribution of hypoxia and peripheral chemoreflex for the development of diseases associated to the cardiovascular and respiratory systems is also discussed in an evolutionary context.

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Regulation of the chemosensory control of breathing by Kölliker-Fuse neurons

Cited by 52 publications

References 62 publications

The First 5-Year-Long Survey on Intrauterine Unexplained Sudden Deaths from the Northeast Italy

The First 5-Year-Long Survey on Intrauterine Unexplained Sudden Deaths from the Northeast Italy

Neural Control of Breathing and CO2 Homeostasis

Evolution and physiology of neural oxygen sensing

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