Invited Review: Intermittent hypoxia and respiratory plasticity

Mitchell, Gordon S.; Baker, Tracy L.; Nanda, Steven A.; Fuller, David D.; Zabka, A. G.; Hodgeman, Bradley A.; Bavis, Ryan W.; Mack, Kenneth J.; Olson, E. B.

doi:10.1152/jappl.2001.90.6.2466

Cited by 347 publications

(358 citation statements)

References 87 publications

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“…State-dependent changes in ventilation in response to local perturbations of raphé neurons support the hypothesis that midline neurons are elements of a distributed brainstem system of central chemoreceptors (Nattie & Li 2009), as well as modulators of central chemoreceptors at other sites, including the retrotrapezoid nucleus (Mulkey et al 2004;Dias et al 2008). Stimulation of peripheral chemoreceptors also evokes changes in raphé neuron activity (Morris et al 1996a, and repeated intermittent stimulation of peripheral carotid body chemoreceptors or medullary raphé neurons can induce a long-term facilitation of phrenic nerve amplitude and cycling frequency (Millhorn et al 1980;Morris et al 1996aMorris et al ,b, 2001Mitchell et al 2001). Similar patterns of central chemoreceptor stimulation do not produce this respiratory memory (Millhorn 1986).…”

Section: Introductionmentioning

confidence: 79%

Central and peripheral chemoreceptors evoke distinct responses in simultaneously recorded neurons of the raphé-pontomedullary respiratory network

Nuding

Segers

Shannon

et al. 2009

Phil. Trans. R. Soc. B

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The brainstem network for generating and modulating the respiratory motor pattern includes neurons of the medullary ventrolateral respiratory column (VRC), dorsolateral pons (PRG) and raphé nuclei. Midline raphé neurons are proposed to be elements of a distributed brainstem system of central chemoreceptors, as well as modulators of central chemoreceptors at other sites, including the retrotrapezoid nucleus. Stimulation of the raphé system or peripheral chemoreceptors can induce a long-term facilitation of phrenic nerve activity; central chemoreceptor stimulation does not. The network mechanisms through which each class of chemoreceptor differentially influences breathing are poorly understood. Microelectrode arrays were used to monitor sets of spike trains from 114 PRG, 198 VRC and 166 midline neurons in six decerebrate vagotomized cats; 356 were recorded during sequential stimulation of both receptor classes via brief CO 2 -saturated saline injections in vertebral (central) and carotid arteries (peripheral). Seventy neurons responded to both stimuli. More neurons were responsive only to peripheral challenges than those responsive only to central chemoreceptor stimulation (PRG, 20 : 4; VRC, 41 : 10; midline, 25 : 13). Of 16 474 pairs of neurons evaluated for short-time scale correlations, similar percentages of reference neurons in each brain region had correlation features indicative of a specific interaction with at least one target neuron: PRG (59.6%), VRC (51.0%) and raphé nuclei (45.8%). The results suggest a brainstem network architecture with connectivity that shapes the respiratory motor pattern via overlapping circuits that modulate central and peripheral chemoreceptor-mediated influences on breathing.

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Section: Introductionmentioning

confidence: 79%

Central and peripheral chemoreceptors evoke distinct responses in simultaneously recorded neurons of the raphé-pontomedullary respiratory network

Nuding

Segers

Shannon

et al. 2009

Phil. Trans. R. Soc. B

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“…This simple, functional definition is similar to the working definition used by the Society for Neuroscience (218). Phrenic long-term facilitation (LTF) following intermittent hypoxia qualifies as an example of plasticity in respiratory motor control because it reflects an enhanced respiratory motor output that outlasts the stimulus (episodic hypoxia) (166).…”

Section: Plasticitymentioning

confidence: 99%

“…Thus sensory receptors provide negative feedback, adjusting breathing to meet changing conditions. Less widely appreciated functions of sensory receptors in respiratory control include their effects on neuromodulatory systems (101,157), on cortical areas associated with arousal and respiratory sensation (13,99), and their actions as guides to respiratory plasticity (166,167,193).…”

Section: Sensory Neuronsmentioning

confidence: 99%

“…Serotonin-dependent plasticity is also important in respiratory motor control (Ref. 166; see Serotonin-Dependent Respiratory Plasticity below), although the detailed cellular and/or synaptic mechanisms may differ. Other neurochemicals such as norepinephrine (8,117) or trophic factors such as brain-derived neurotrophic factor (BDNF) may initiate or regulate synaptic plasticity (124,147,191,214,231).…”

Section: Changes In Synaptic Strengthmentioning

confidence: 99%

“…Other reviews are available on selected aspects of respiratory plasticity [e.g., developmental plasticity (80,133), respiratory "memories" (46), time-dependent mechanisms of the hypoxic ventilatory response (8,21,60,117,166,197), serotonergic modulation and plasticity (157), plasticity in the exercise ventilatory response (157,236), and activity-dependent synaptic plasticity (105,193,194)]. Comprehensive reviews focused on selected aspects of respiratory plasticity will appear as a part of this Highlighted Topics series in the Journal of Applied Physiology.…”

mentioning

confidence: 99%

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Invited Review: Neuroplasticity in respiratory motor control

Mitchell

Johnson

2003

Journal of Applied Physiology

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351

313

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Although recent evidence demonstrates considerable neuroplasticity in the respiratory control system, a comprehensive conceptual framework is lacking. Our goals in this review are to define plasticity (and related neural properties) as it pertains to respiratory control and to discuss potential sites, mechanisms, and known categories of respiratory plasticity. Respiratory plasticity is defined as a persistent change in the neural control system based on prior experience. Plasticity may involve structural and/or functional alterations (most commonly both) and can arise from multiple cellular/synaptic mechanisms at different sites in the respiratory control system. Respiratory neuroplasticity is critically dependent on the establishment of necessary preconditions, the stimulus paradigm, the balance between opposing modulatory systems, age, gender, and genetics. Respiratory plasticity can be induced by hypoxia, hypercapnia, exercise, injury, stress, and pharmacological interventions or conditioning and occurs during development as well as in adults. Developmental plasticity is induced by experiences (e.g., altered respiratory gases) during sensitive developmental periods, thereby altering mature respiratory control. The same experience later in life has little or no effect. In adults, neuromodulation plays a prominent role in several forms of respiratory plasticity. For example, serotonergic modulation is thought to initiate and/or maintain respiratory plasticity following intermittent hypoxia, repeated hypercapnic exercise, spinal sensory denervation, spinal cord injury, and at least some conditioned reflexes. Considerable work is necessary before we fully appreciate the biological significance of respiratory plasticity, its underlying cellular/molecular and network mechanisms, and the potential to harness respiratory plasticity as a therapeutic tool.

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Inspiratory augmenting bulbospinal neurons express both glutamatergic and enkephalinergic phenotypes

Stornetta

Sevigny

2002

J of Comparative Neurology

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Many of the inspiratory augmenting (I-AUG) neurons of the rostral ventral respiratory group (rVRG) are premotor neurons that excite phrenic motor neurons during inspiration, probably by releasing glutamate. In the present study, we demonstrate that these neurons are indeed glutamatergic, in that their cell bodies contain vesicular glutamate transporter-2 (VGLUT2) mRNA and spinal terminals from neurons in the region of the rVRG contain VGLUT2 protein. We also demonstrate by using parallel in situ hybridization and immunocytochemical evidence that most rVRG inspiratory premotor neurons are enkephalinergic. After iontophoretic deposits of biotinylated dextran amine (BDA) in the area of the rVRG, many BDA-labeled terminals in the ventral horn of cervical spinal cord (C4-C5) were immunoreactive for enkephalin and VGLUT2. Injections of Fluoro-Gold amidst phrenic motor neurons in C4-C5 labeled neurons in the area of the rVRG that contained both VGLUT2 mRNA and preproenkephalin (PPE) mRNA as revealed by double in situ hybridization. Thirty-eight bulbospinal I-AUG neurons were recorded in the rVRG and filled with biotinamide by using the juxtacellular labeling technique. Every biotinamide-filled cell tested was positively labeled for VGLUT2 mRNA (n = 14), and most of the cells tested in a separate population exhibited PPE mRNA (16/18). We conclude that most of the phrenic inspiratory premotor neurons of the rVRG are glutamatergic neurons that may also release enkephalins.

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Invited Review: Intermittent hypoxia and respiratory plasticity

Cited by 347 publications

References 87 publications

Central and peripheral chemoreceptors evoke distinct responses in simultaneously recorded neurons of the raphé-pontomedullary respiratory network

Central and peripheral chemoreceptors evoke distinct responses in simultaneously recorded neurons of the raphé-pontomedullary respiratory network

Invited Review: Neuroplasticity in respiratory motor control

Inspiratory augmenting bulbospinal neurons express both glutamatergic and enkephalinergic phenotypes

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