Neural Basis of Behavioral and State-Dependent Control of Breathing

1988 ◽  
pp. 79-96 ◽  
Author(s):  
John Orem
Keyword(s):  
Control Of Breathing ◽  
Neural Basis ◽  
State Dependent

Vigilance state-dependent attenuation of hypercapnic chemoreflex and exaggerated sleep apnea in orexin knockout mice

2007 ◽  
Vol 102 (1) ◽  
pp. 241-248 ◽  
Author(s):  
Akira Nakamura ◽  
Wei Zhang ◽  
Masashi Yanagisawa ◽  
Yasuichiro Fukuda ◽  
Tomoyuki Kuwaki
Keyword(s):  
Rem Sleep ◽  
Knockout Mice ◽  
Slow Wave Sleep ◽  
Ventilatory Response ◽  
Control Of Breathing ◽  
Dependent Manner ◽  
Wild Type ◽  
Vigilance State ◽  
State Dependent ◽  
Respiratory Parameters

Exogenous administration of orexin can promote wakefulness and respiration. Here we examined whether intrinsic orexin participates in the control of breathing in a vigilance state-dependent manner. Ventilation was recorded together with electroencephalography and electromyography for 6 h during the daytime in prepro-orexin knockout mice (ORX-KO) and wild-type (WT) littermates. Respiratory parameters were separately determined during quiet wakefulness (QW), slow-wave sleep (SWS), or rapid eye movement (REM) sleep. Basal ventilation was normal in ORX-KO, irrespective of vigilance states. The hypercapnic ventilatory response during QW in ORX-KO (0.19 ± 0.01 ml·min−1·g−1·%CO2−1) was significantly smaller than that in WT mice (0.38 ± 0.04 ml·min−1·g−1·%CO2−1), whereas the responses during SWS and REM in ORX-KO were comparable to those in WT mice. Hypoxic responses during wake and sleep periods were not different between the genotypes. Spontaneous but not postsigh sleep apneas were more frequent in ORX-KO than in WT littermates during both SWS and REM sleep. Our findings suggest that orexin plays a crucial role both in CO2 sensitivity during wakefulness and in preserving ventilation stability during sleep.

scholarly journals A Neural Representation of Sequential States Within an Instructed Task

2010 ◽  
Vol 104 (5) ◽  
pp. 2831-2849 ◽  
Author(s):  
Michael Campos ◽  
Boris Breznen ◽  
Richard A. Andersen
Keyword(s):  
Internal Representation ◽  
Neural Representation ◽  
Neural Basis ◽  
Lateral Intraparietal Area ◽  
State Dependent ◽  
Sensorimotor Transformations ◽  
Saccade Task ◽  
Anticipatory Activity ◽  
Supplementary Eye Fields ◽  
The Brain

In the study of the neural basis of sensorimotor transformations, it has become clear that the brain does not always wait to sense external events and afterward select the appropriate responses. If there are predictable regularities in the environment, the brain begins to anticipate the timing of instructional cues and the signals to execute a response, revealing an internal representation of the sequential behavioral states of the task being performed. To investigate neural mechanisms that could represent the sequential states of a task, we recorded neural activity from two oculomotor structures implicated in behavioral timing—the supplementary eye fields (SEF) and the lateral intraparietal area (LIP)—while rhesus monkeys performed a memory-guided saccade task. The neurons of the SEF were found to collectively encode the progression of the task with individual neurons predicting and/or detecting states or transitions between states. LIP neurons, while also encoding information about the current temporal interval, were limited with respect to SEF neurons in two ways. First, LIP neurons tended to be active when the monkey was planning a saccade but not in the precue or intertrial intervals, whereas SEF neurons tended to have activity modulation in all intervals. Second, the LIP neurons were more likely to be spatially tuned than SEF neurons. SEF neurons also show anticipatory activity. The state-selective and anticipatory responses of SEF neurons support two complementary models of behavioral timing, state dependent and accumulator models, and suggest that each model describes a contribution SEF makes to timing at different temporal resolutions.

The Tritonia Swim Central Pattern Generator

2017 ◽  
pp. 561-568
Author(s):  
Paul S. Katz
Keyword(s):  
Central Pattern Generator ◽  
Sensory Feedback ◽  
Pattern Generator ◽  
Emergent Property ◽  
The Other ◽  
Entire Body ◽  
Neural Basis ◽  
Sea Slug ◽  
Tritonia Diomedea ◽  
State Dependent

Tritonia diomedea is a sea slug that escapes from predatory starfish by rhythmically flexing its entire body in the dorsal and ventral directions. This escape swim behavior is produced by a central pattern generator (CPG), without needing sensory feedback. There are several features of the neural basis for this response that make it of particular interest for neuroscientists. One is that the CPG is a network oscillator; bursting arises as an emergent property of the neurons and their connectivity. Another interesting feature is that the CPG contains state-dependent, intrinsic neuromodulation: one of the CPG neurons uses the neurotransmitter serotonin (5-HT) to modulate the strength of synapses made by the other CPG neurons under certain conditions. This CPG seems to have evolved from a nonoscillatory network. Finally, there are novel mechanisms for plasticity during learning and in response to injury.

scholarly journals State-dependent control of breathing by the retrotrapezoid nucleus

2015 ◽  
Vol 593 (13) ◽  
pp. 2909-2926 ◽  
Author(s):  
Peter G.R. Burke ◽  
Roy Kanbar ◽  
Tyler M. Basting ◽  
Walter M. Hodges ◽  
Kenneth E. Viar ◽  
...  
Keyword(s):  
Control Of Breathing ◽  
Retrotrapezoid Nucleus ◽  
State Dependent

scholarly journals Circuits for State-Dependent Modulation of Locomotion

2021 ◽  
Vol 15 ◽  
Author(s):  
Alejandro J. Pernía-Andrade ◽  
Nikolaus Wenger ◽  
Maria S. Esposito ◽  
Philip Tovote
Keyword(s):  
Periaqueductal Gray ◽  
Higher Order ◽  
Postural Adjustment ◽  
Dependent Manner ◽  
Emotional States ◽  
Neural Basis ◽  
Medullary Reticular Formation ◽  
Mesencephalic Locomotor Region ◽  
State Dependent ◽  
Circuit Elements

Brain-wide neural circuits enable bi- and quadrupeds to express adaptive locomotor behaviors in a context- and state-dependent manner, e.g., in response to threats or rewards. These behaviors include dynamic transitions between initiation, maintenance and termination of locomotion. Advances within the last decade have revealed an intricate coordination of these individual locomotion phases by complex interaction of multiple brain circuits. This review provides an overview of the neural basis of state-dependent modulation of locomotion initiation, maintenance and termination, with a focus on insights from circuit-centered studies in rodents. The reviewed evidence indicates that a brain-wide network involving excitatory circuit elements connecting cortex, midbrain and medullary areas appears to be the common substrate for the initiation of locomotion across different higher-order states. Specific network elements within motor cortex and the mesencephalic locomotor region drive the initial postural adjustment and the initiation of locomotion. Microcircuits of the basal ganglia, by implementing action-selection computations, trigger goal-directed locomotion. The initiation of locomotion is regulated by neuromodulatory circuits residing in the basal forebrain, the hypothalamus, and medullary regions such as locus coeruleus. The maintenance of locomotion requires the interaction of an even larger neuronal network involving motor, sensory and associative cortical elements, as well as defined circuits within the superior colliculus, the cerebellum, the periaqueductal gray, the mesencephalic locomotor region and the medullary reticular formation. Finally, locomotor arrest as an important component of defensive emotional states, such as acute anxiety, is mediated via a network of survival circuits involving hypothalamus, amygdala, periaqueductal gray and medullary premotor centers. By moving beyond the organizational principle of functional brain regions, this review promotes a circuit-centered perspective of locomotor regulation by higher-order states, and emphasizes the importance of individual network elements such as cell types and projection pathways. The realization that dysfunction within smaller, identifiable circuit elements can affect the larger network function supports more mechanistic and targeted therapeutic intervention in the treatment of motor network disorders.

Emotional Reactivity to Visual Content as Revealed by ERP Component Clustering

2015 ◽  
Vol 29 (4) ◽  
pp. 135-146 ◽  
Author(s):  
Miroslaw Wyczesany ◽  
Szczepan J. Grzybowski ◽  
Jan Kaiser
Keyword(s):  
Emotional Reactivity ◽  
Brain Activity ◽  
Affective State ◽  
Occipital Lobe ◽  
Stimulus Onset ◽  
Emotional States ◽  
Neural Basis ◽  
Temporoparietal Junction ◽  
The Right ◽  
The Impact

Abstract. In the study, the neural basis of emotional reactivity was investigated. Reactivity was operationalized as the impact of emotional pictures on the self-reported ongoing affective state. It was used to divide the subjects into high- and low-responders groups. Independent sources of brain activity were identified, localized with the DIPFIT method, and clustered across subjects to analyse the visual evoked potentials to affective pictures. Four of the identified clusters revealed effects of reactivity. The earliest two started about 120 ms from the stimulus onset and were located in the occipital lobe and the right temporoparietal junction. Another two with a latency of 200 ms were found in the orbitofrontal and the right dorsolateral cortices. Additionally, differences in pre-stimulus alpha level over the visual cortex were observed between the groups. The attentional modulation of perceptual processes is proposed as an early source of emotional reactivity, which forms an automatic mechanism of affective control. The role of top-down processes in affective appraisal and, finally, the experience of ongoing emotional states is also discussed.

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