Global ETD Search

1	Plasticity of Brainstem Motor Systems in Response to Developmental Nicotine Exposure Wollman, Lila Buls, Wollman, Lila Buls January 2017 (has links) Developmental nicotine exposure (DNE) is known to cause abnormal development of multiple brain regions and results in impaired control of breathing and altered behaviors that rely on proper coordination of the muscles of the tongue. The adverse effects of nicotine are presumably caused by its actions on nicotinic acetylcholine receptors (nAChRs), which modulate fast-synaptic transmission and play a prominent role during brain development. Previous work has shown that DNE alters nAChR function in multiple brainstem regions (Pilarski et al., 2012, Wollman et al, 2016). Moreover, DNE causes multiple changes to XIIMNs, which innervate the muscles of the tongue (Powell et al., 2016, Powell et al., 2015, Pilarski et al., 2011). These changes likely reflect both altered development as a primary outcome of the chronic presence of nicotine, as well as, homeostatic adjustments made in an attempt to maintain normal motoneuron output. With the experiments described here, we tested the hypothesis that DNE alters the development of fast-synaptic transmission to XIIMNs, which, along with intrinsic properties of these neurons, is a main determinant of motor output to the muscles of the tongue. Additionally, we tested the hypothesis that DNE alters the function of nAChRs located on multiple brainstem neurons, including those that modulate fast-synaptic transmission to XIIMNs. For these experiments, we used whole cell patch clamp recordings from XIIMNs in a transverse slice of the medulla, and extracellular recordings from the 4th cervical ventral root in the brainstem spinal cord, split bath preparation. All preparations were obtained from control or DNE neonatal rats in the first week of life. Overall, the results of these experiments show that DNE alters fast-synaptic transmission to XIIMNs, which likely reflects appropriate homeostatic adjustments aimed at maintaining normal motor output at rest. However, these results also show that nAChR function is significantly altered by DNE, indicating fast-synaptic transmission may not be appropriately modulated in response to increased release of acetylcholine (ACh), the endogenous neurotransmitter for nAChRs. brainstem control of breathing hypoglossal motoneurons Nicotine
2	Role of the Carotid Chemoreceptors in the Hyperpnea of Exercise in the Cat Aggarwal, D., Milhorn. Jr., H. T., Lee, L. Y. 01 January 1976 (has links) The role of the carotid chemoreceptors in the hyperpnea of exercise was investigated. The activity of the sinus nerve of the cat was monitored while the blood supply to the carotid body was controlled independently of the systemic circulation. By this technique, fluctuations in the arterial blood gases during a short interval of exercise induced by electrical stimulation of hindlimb muscles were unable to affect the chemoreceptor activity. While minute ventilation increased by an average of 51%, chemoreccptor discharge was found to be unchanged in 12 experiments, 6 while perfusing with normoxic blood and 6 while perfusing with hypoxic blood. Thus, it must be concluded that alteration of carotid chemoreceptor sensitivity does not occur during artificially induced exercise in anesthetized cats. However, the difference in the time course of ventilation following the initiation of artificially induced exercise between cats and other species does not allow it to be ruled out in other species, including man. Indirect evidence is against such a role. carotid chemoreceptors exercise control of breathing hyperpnea
3	Ventilatory drive and the apnea-hypopnea index in six-to-twelve year old children Fregosi, Ralph, Quan, Stuart, Jackson, Andrew, Kaemingk, Kris, Morgan, Wayne, Goodwin, Jamie, Reeder, Jenny, Cabrera, Rosaria, Antonio, Elena January 2004 (has links) BACKGROUND:We tested the hypothesis that ventilatory drive in hypoxia and hypercapnia is inversely correlated with the number of hypopneas and obstructive apneas per hour of sleep (obstructive apnea hypopnea index, OAHI) in children.METHODS:Fifty children, 6 to 12 years of age were studied. Participants had an in-home unattended polysomnogram to compute the OAHI. We subsequently estimated ventilatory drive in normoxia, at two levels of isocapnic hypoxia, and at three levels of hyperoxic hypercapnia in each subject. Experiments were done during wakefulness, and the mouth occlusion pressure measured 0.1 seconds after inspiratory onset (P0.1) was measured in all conditions. The slope of the relation between P0.1 and the partial pressure of end-tidal O2 or CO2 (PETO2 and PETCO2) served as the index of hypoxic or hypercapnic ventilatory drive.RESULTS:Hypoxic ventilatory drive correlated inversely with OAHI (r = -0.31, P = 0.041), but the hypercapnic ventilatory drive did not (r = -0.19, P = 0.27). We also found that the resting PETCO2 was significantly and positively correlated with the OAHI, suggesting that high OAHI values were associated with resting CO2 retention.CONCLUSIONS:In awake children the OAHI correlates inversely with the hypoxic ventilatory drive and positively with the resting PETCO2. Whether or not diminished hypoxic drive or resting CO2 retention while awake can explain the severity of sleep-disordered breathing in this population is uncertain, but a reduced hypoxic ventilatory drive and resting CO2 retention are associated with sleep-disordered breathing in 6-12 year old children. control of breathing hypoxia hypercapnia mouth occlusion pressure apnea-hypopnea index
4	induction non-invasive d'une plasticité de la commande ventilatoire chez l'humain sain / Neural plasticity of respiratory control system induced by non-invasive techniques in healthy human subjects Nierat, Marie-Cecile 13 June 2014 (has links) La commande de la ventilation chez l'humain est capable d'adaptation persistante qui repose sur des mécanismes de type LTP. Différentes techniques permettant l'induction de plasticité sont couramment utilisées mais leur application au contrôle ventilatoire n'a fait l'objet que de très peu de travaux.L'objectif de cette thèse est (1) examiner la possibilité d'induire des mécanismes de type LTP par la rTMS et la tsDCS en deux sites de la commande ventilatoire destinée au diaphragme, l'AMS et les métamères C3-C5 ; (2) évaluer les conséquences sur le profil ventilatoire en ventilation de repos et lorsque la ventilation est artificiellement contrainte. Nous avons examiné les effets d'un conditionnement inhibiteur appliqué par rTMS en regard de l'AMS sur l'excitabilité corticophrénique. Nous avons observé la présence d'une diminution persistante de cette excitabilité et en avons tiré la proposition qu'en ventilation de repos l'AMS augmente l'excitabilité de la commande ventilatoire à l'éveil. Nous avons alors considéré les conséquences de la rTMS sur la ventilation expérimentalement contrainte. Les modifications du profil ventilatoire induites par la rTMS sont en faveur d'une participation de l'AMS à la production ou au traitement de la copie d'efférence. Dans une 3ème étude, nous avons examiné les effets de la tsDCS au niveau C3-C5 sur l'excitabilité corticophrénique et sur le profil ventilatoire. L'augmentation de cette excitabilité et du volume courant nous a conduit à suggérer la possibilité d'induire une plasticité respiratoire au niveau spinal.L'ensemble de ces résultats nous permet d'envisager des perspectives thérapeutiques à l'utilisation de la rTMS et de la tsDCS. / A salient feature of the ventilatory control system is its ability to persistently adapt its behaviour. This stems from long-term plasticity mechanisms similar to those described for the neural control in general. Plasticity can be induced by various non-invasive stimulation techniques(e.g. rTMS, TDCS, tsDCS) that are commonly used but have not be systematically applied to ventilatory plasticity. The aim of this thesis is twofold: (1) to examine the possibility of inducing LTP by rTMS and tsDCS at two sites of the ventilatory control system, namely the SMA and the phrenic motoneurons: (2) to evaluate the impact of such plasticity on breathing pattern during spontaneous ventilation and inspiratory threshold loading. We examined the effects of an inhibitory rTMS paradigm applied to the SMA on corticophrenic excitability. We observed a persistent decrease in corticophrenic excitability and therefore proposed that the SMA participates in the increased resting state of the ventilatory motor system during wake. Then we considered the consequences of rTMS on breathing pattern during ITL. The corresponding modifications support a contribution of the SMA to the production or processing of an ventilatory efference copy. In a third study, we examined the effects of a tsDCS delivered to C3-C5 on the corticophrenic excitability and on the respiratory pattern. Increased corticophrenic excitability and tidal volume were observed. This suggests that respiratory plasticity takes place at the spinal level. Taken together, these results open the perspective of harnessing respiratory plasticity as a therapeutic tool in disorders altering the ventilatory command. RTMS TsDCS Plasticité neurale Contrôle de la ventilation Diaphragme Ventilation. Control of breathing Inspiratory loading 611.2
5	The Effect of Temperature on the Chronic Hypoxia-induced Changes to pH/CO2-sensitive Fictive Breathing in the Cane Toad (Bufo marinus) Jenkin, Sarah 25 August 2011 (has links) This study examined the effects of temperature and chronic hypoxia (CH) on pH/CO2- sensitive fictive breathing, and central pH/CO2 chemosensitivity, in cane toads (Bufo marinus). Toads were exposed to CH (10% or 15% O2) or control conditions (21% O2) for 10 days at either room temperature (controls), 10°C or 30°C following which in vitro brainstem-spinal cord preparations were used to examine central pH/CO2-sensitive fictive breathing (i.e., motor output from respiratory nerves which is the neural correlate of breathing). A reduction in artificial cerebral spinal fluid (aCSF) pH increased fictive breathing frequency (fR) and total fictive ventilation (TFV). Cold temperature reduced and hot temperature increased fR and TFV under control conditions. CH attenuated fictive breathing independently of temperature. Additional experiments in which the aCSF temperature was varied indicate that the effects of temperature acclimation result from neural plastic changes within respiratory control centres in the brain. Control of Breathing Temperature Hypoxia Amphibian in vitro brainstem-spinal cord 0317 0433
6	The Effect of Menopause on Acid-Base Regulation and the Chemoreflex Control of Breathing during Wakefulness Preston, Megan E. 28 September 2007 (has links) Acid-base regulation, as reflected by hydrogen ion concentration ([H+]), and the chemoreflex control of breathing were examined in healthy pre- (PRE; n=20) and postmenopausal (POST; n=15) women of a comparable age (45 ± 2.7 vs. 52 ± 1.8 years). [H+] behaviour was examined in both groups at rest and during exercise above the ventilatory threshold using Stewart’s physicochemical approach to acid-base analysis. Ventilatory chemoreflex characteristics were assessed using Duffin’s modified rebreathing protocol that includes 5 min of prior hyperventilation and maintenance of either hyperoxic (150 mmHg) or hypoxic (50 mmHg) iso-oxia. As expected, the ovarian hormones progesterone ([P4]) and estrogen ([E2]) were significantly lower in the POST group. [H+] was unaffected by menopausal status at rest or during exercise. At rest the POST group exhibited significantly higher PaCO2 and [SID] values relative to the PRE group. In general, the acidifying effects of increased PaCO2 were offset by the alkalizing effect of increases in [SID] (or vice versa) in the POST group such that [H+] did not differ between PRE and POST groups. The central ventilatory chemoreflex also differed between groups with the POST group exhibiting a significantly higher threshold and a lower sensitivity in the response to CO2 relative to the PRE group. [P4] was found to partially account for the significant group differences in acid-base and central ventilatory chemoreflex control characteristics supporting the role of [P4] as an important determinant of acid-base status and the chemical control of ventilation in healthy women. Findings of the current study may have potential relevance in understanding the increased occurrence of various health conditions such as osteoporosis and sleep disordered breathing in females following the onset of menopause. / Thesis (Master, Kinesiology & Health Studies) -- Queen's University, 2007-09-21 08:53:00.841 Menopause Acid-base regulation Chemoreflex Chemical control of breathing Strong ion difference Progesterone
7	CHEMICAL AND MECHANICAL ADAPTATIONS OF THE RESPIRATORY SYSTEM AT REST AND DURING EXERCISE IN HEALTHY HUMAN PREGNANCY: IMPLICATIONS FOR RESPIRATORY SENSATION Jensen, DENNIS 03 September 2008 (has links) Human pregnancy is characterized by significant increases in central ventilatory drive and perceived respiratory discomfort (breathlessness). The physiological mechanisms of hyperventilation and breathlessness in pregnancy remain largely unknown and understudied. Objective: The main purpose of this research was to elucidate the mechanisms of maternal hyperventilation, and to systematically examine the contribution of alterations in central ventilatory drive, static/dynamic respiratory mechanics and their interaction with respect to the intensity of perceived breathlessness during exercise in pregnancy. General Methods: Experiments were conducted between 34-38 wks gestation and again 4-5 months post-partum in a total of 35 healthy, young women. A comprehensive mathematical model of ventilatory control was used to examine the role of alterations in wakefulness and central chemoreflex drives to breathe, acid-base balance and female sex hormones in maternal hyperventilation. The effects of pregnancy on detailed ventilatory (breathing pattern, airway function, operating lung volumes, esophageal pressure-derived indices of respiratory mechanics) and perceptual (breathing and leg discomfort) responses to incremental cycle exercise to the limits of tolerance were also examined. Results: Maternal hyperventilation resulted from a complex interaction between alterations in arterial and central acid-base balance and other factors that directly affect ventilation, including increased wakefulness and central chemoreflex drives to breathe, increased metabolism and decreased cerebral blood flow. Mechanical adaptations of the respiratory system, including recruitment of resting inspiratory capacity and reduced airway resistance, accommodated the increased demand for tidal volume expansion during exercise in pregnancy, while preserving effort-displacement and breathlessness-ventilation relationships. Variation in the severity of gestational breathlessness could not be explained by respiratory mechanical/muscular factors, but ultimately reflected variation in the amplitude of maternal hyperventilation and temporal desensitization to the sensory consequences of increased ventilation. Conclusion: Our results indicated that 1) the hyperventilation and attendant hypocapnia/alkalosis of pregnancy can be explained by alterations in wakefulness and central chemoreflex drives to breathe, acid-base balance, metabolic rate and cerebral blood flow; 2) mechanical adaptations of the respiratory system obviated the anticipated rise in perceived breathlessness for a given ventilation during exercise in pregnancy, and helped to ensure that peak aerobic working capacity was admirably preserved, even in late gestation; and 3) gestational breathlessness ultimately reflected the normal awareness of increased ventilation and contractile respiratory muscle effort. / Thesis (Ph.D, Kinesiology & Health Studies) -- Queen's University, 2008-08-28 16:01:40.78 Pregnancy Exercise Breathlessness Control of Breathing Acid-Base Balance Female Sex Steroid Hormones Respiratory Mechanics Ventilation
8	The Effect of Temperature on the Chronic Hypoxia-induced Changes to pH/CO2-sensitive Fictive Breathing in the Cane Toad (Bufo marinus) Jenkin, Sarah 25 August 2011 (has links) This study examined the effects of temperature and chronic hypoxia (CH) on pH/CO2- sensitive fictive breathing, and central pH/CO2 chemosensitivity, in cane toads (Bufo marinus). Toads were exposed to CH (10% or 15% O2) or control conditions (21% O2) for 10 days at either room temperature (controls), 10°C or 30°C following which in vitro brainstem-spinal cord preparations were used to examine central pH/CO2-sensitive fictive breathing (i.e., motor output from respiratory nerves which is the neural correlate of breathing). A reduction in artificial cerebral spinal fluid (aCSF) pH increased fictive breathing frequency (fR) and total fictive ventilation (TFV). Cold temperature reduced and hot temperature increased fR and TFV under control conditions. CH attenuated fictive breathing independently of temperature. Additional experiments in which the aCSF temperature was varied indicate that the effects of temperature acclimation result from neural plastic changes within respiratory control centres in the brain. Control of Breathing Temperature Hypoxia Amphibian in vitro brainstem-spinal cord 0317 0433
9	Inspiratory Off-Switch Mediated by Optogenetic Activation of Inhibitory Neurons in the preBötzinger Complex In Vivo Hülsmann, Swen, Hagos, Liya, Eulenburg, Volker, Hirrlinger, Johannes 02 February 2024 (has links) The role of inhibitory neurons in the respiratory network is a matter of ongoing debate. Conflicting and contradicting results are manifold and the question whether inhibitory neurons are essential for the generation of the respiratory rhythm as such is controversial. Inhibitory neurons are required in pulmonary reflexes for adapting the activity of the central respiratory network to the status of the lung and it is hypothesized that glycinergic neurons mediate the inspiratory off-switch. Over the years, optogenetic tools have been developed that allow for cell-specific activation of subsets of neurons in vitro and in vivo. In this study, we aimed to identify the effect of activation of inhibitory neurons in vivo. Here, we used a conditional transgenic mouse line that expresses Channelrhodopsin 2 in inhibitory neurons. A 200 m multimode optical fiber ferrule was implanted in adult mice using stereotaxic surgery, allowing us to stimulate inhibitory, respiratory neurons within the core excitatory network in the preBötzinger complex of the ventrolateral medulla. We show that, in anesthetized mice, activation of inhibitory neurons by blue light (470 nm) continuously or with stimulation frequencies above 10 Hz results in a significant reduction of the respiratory rate, in some cases leading to complete cessation of breathing. However, a lower stimulation frequency (4–5 Hz) could induce a significant increase in the respiratory rate. This phenomenon can be explained by the resetting of the respiratory cycle, since stimulation during inspiration shortened the associated breath and thereby increased the respiratory rate, while stimulation during the expiratory interval reduced the respiratory rate. Taken together, these results support the concept that activation of inhibitory neurons mediates phase-switching by inhibiting excitatory rhythmogenic neurons in the preBötzinger complex. info:eu-repo/classification/ddc/610 ddc:610
10	Functional Connectivity and Responses to Chemoreceptor Stimulation of Medullary Ventrolateral Respiratory Column Neurons Ott, Mackenzie M 09 April 2010 (has links) Ventrolateral medullary neurons have important roles in cardiorespiratory coordination. A rostral extension of the ventral respiratory column (RVRC), including the retrotrapezoid nucleus (RTN), has neurons responsive to local perturbations of CO2 / pH. Respiratory-modulated firing patterns of RVRC neurons are attributed to influences of more caudal (CVRC) neurons. These circuits remain poorly understood. This study addressed the hypothesis that both local interactions and influences from the CVRC shape rostral neuron discharge patterns and responses. Spike trains from 294 rostral and 490 caudal neurons were recorded with multi-electrode arrays along with phrenic nerve activity in 14 decerebrate, vagotomized cats. Overall, 214 rostral and 398 caudal neurons were respiratory-modulated; 124 and 95, respectively, were cardiac-modulated. Subsets of these neurons were evaluated for responses to sequential, selective, transient stimulation of central and peripheral chemoreceptors and arterial baroreceptors. In 5 experiments, Mayer wave-related oscillations (MWROs) in neuronal firing rates were evoked, enhanced, or reduced following central chemoreceptor stimulation. Overall, 174 of the rostral neurons (59.5%) had short- time scale correlations with other RVRC neurons. Of these, 49 triggered cross-correlograms with RVRC targets yielding 330 offset features indicative of paucisynaptic actions from a total of 2,884 rostral pairs evaluated. Forty-nine of the CVRC neurons (10.0%) were triggers in 142 CVRC-RVRC correlograms - from a total of 8,490 - with offset features indicative of actions on RVRC neurons. Correlation linkage maps support the hypothesis that local circuit mechanisms contribute to the respiratory and cardiac modulation of RVRC neurons and their responses to chemoreceptor and baroreceptor challenges. Control of breathing brainstem respiratory network respiratory modulation cross-correlation rostral ventral lateral medulla Mayer waves American Studies Arts and Humanities

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