Abstract:Mammals must continuously regulate the levels of O and CO , which is particularly important for the brain. Failure to maintain adequate O /CO homeostasis has been associated with numerous disorders including sleep apnoea, Rett syndrome and sudden infant death syndrome. But, O /CO homeostasis poses major regulatory challenges, even in the healthy brain. Neuronal activities change in a differentiated, spatially and temporally complex manner, which is reflected in equally complex changes in O demand. This raises … Show more
“…We refer to the periods of the control inputs as “low”, “medium” or “large” when, if acted on their respected isolated population, they result in tonic spiking, bursting or silence respectively (the actual values will depend on the size of the memory and threshold in each population). The transition from 3- to 2- to 1- phase pattern seen in our model is consistent with reducing energy due, for example, to lack of oxygen 6,14,27 . The system is also capable of displaying tonic spiking if the period of is low and the periods of and are high (not shown in the figure) and silence if the period of is low or if the periods of , and are all high.Figure 3Transition from 3- to 2- to 1-phase pattern in the larger network (Fig.…”
The respiratory rhythm generator is spectacular in its ability to support a wide range of activities and adapt to changing environmental conditions, yet its operating mechanisms remain elusive. We show how selective control of inspiration and expiration times can be achieved in a new representation of the neural system (called a Boolean network). The new framework enables us to predict the behavior of neural networks based on properties of neurons, not their values. Hence, it reveals the logic behind the neural mechanisms that control the breathing pattern. Our network mimics many features seen in the respiratory network such as the transition from a 3-phase to 2-phase to 1-phase rhythm, providing novel insights and new testable predictions.
“…We refer to the periods of the control inputs as “low”, “medium” or “large” when, if acted on their respected isolated population, they result in tonic spiking, bursting or silence respectively (the actual values will depend on the size of the memory and threshold in each population). The transition from 3- to 2- to 1- phase pattern seen in our model is consistent with reducing energy due, for example, to lack of oxygen 6,14,27 . The system is also capable of displaying tonic spiking if the period of is low and the periods of and are high (not shown in the figure) and silence if the period of is low or if the periods of , and are all high.Figure 3Transition from 3- to 2- to 1-phase pattern in the larger network (Fig.…”
The respiratory rhythm generator is spectacular in its ability to support a wide range of activities and adapt to changing environmental conditions, yet its operating mechanisms remain elusive. We show how selective control of inspiration and expiration times can be achieved in a new representation of the neural system (called a Boolean network). The new framework enables us to predict the behavior of neural networks based on properties of neurons, not their values. Hence, it reveals the logic behind the neural mechanisms that control the breathing pattern. Our network mimics many features seen in the respiratory network such as the transition from a 3-phase to 2-phase to 1-phase rhythm, providing novel insights and new testable predictions.
“…The review by Guyenet et al (2018) discusses the functionally important interactions that occur between the carotid bodies and the central CO 2 -sensitive neurons in the retrotrapezoid nucleus in the control of breathing in various conditions. Ramirez et al (2018) extend this discussion with insights into central neural mechanisms of oxygen sensing and homeostasis and the emergent role of central astrocytes as differential modulators of central chemosensory networks.…”
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confidence: 84%
“…Ramirez et al . () extend this discussion with insights into central neural mechanisms of oxygen sensing and homeostasis and the emergent role of central astrocytes as differential modulators of central chemosensory networks.…”
“…Astrocytes respond to metabolic changes in their extracellular environment by increasing intracellular Ca 2+ 20 through G-protein coupled receptor cascades. In the respiratory networks 21,22 , and throughout the central nervous system 23,24 , astrocyte responses spread through gap junctions 25 and involve the release of ATP which modulates neural activity via purinergic mechanisms [26][27][28] . Therefore, we tested the contribution of purinergic signaling to sigh generation in vitro by pharmacological manipulation of ADP and ATP receptors P2Y1 and P2X, respectively (Fig.…”
Section: Astrocytes Modulate Sighing Through Purinergic Signalingmentioning
Sighs prevent the collapse of alveoli in the lungs, initiate arousal under hypoxic conditions, and even express sadness and relief. Sighs are periodically superimposed on normal breaths, known as eupnea. Implicated in the generation of these rhythmic behaviors is the preBötzinger complex (preBötC)1. Yet how this small microcircuit can produce two rhythms with strikingly different periodicities remains unresolved. Our computational simulations predict that sighs are generated by the coincidence of two temporally distinct calcium oscillations and are in agreement with experimental evidence suggesting that astrocytes drive sigh behavior through slower, extrinsically driven calcium oscillations that link the eupnea and sigh rhythms. We found that purinergic signaling is necessary to generate spontaneous and hypoxia- induced sighs, and photo-activation of preBötC astrocytes is sufficient to elicit sigh activity. We conclude that sighs are an emergent property of the preBötC network generated by neuroglial interactions, where the distinct modulatory responses of neurons and glia allow for both rhythms to be independently regulated.
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