Global ETD Search

11	Spatially Divergent Cardiac Responses to Nicotinic Stimulation of Ganglionated Plexus Neurons in the Canine Heart Cardinal, René, Pagé, Pierre, Vermeulen, Michel, Ardell, Jeffrey L., Armour, J. A. 28 January 2009 (has links) Ganglionated plexuses (GPs) are major constituents of the intrinsic cardiac nervous system, the final common integrator of regional cardiac control. We hypothesized that nicotinic stimulation of individual GPs exerts divergent regional influences, affecting atrial as well as ventricular functions. In 22 anesthetized canines, unipolar electrograms were recorded from 127 atrial and 127 ventricular epicardial loci during nicotine injection (100 mcg in 0.1 ml) into either the 1) right atrial (RA), 2) dorsal atrial, 3) left atrial, 4) inferior vena cava-inferior left atrial, 5) right ventricular, 6) ventral septal ventricular or 7) cranial medial ventricular (CMV) GP. In addition to sinus and AV nodal function, neural effects on atrial and ventricular repolarization were identified as changes in the area subtended by unipolar recordings under basal conditions and at maximum neurally-induced effects. Animals were studied with intact AV node or following ablation to achieve ventricular rate control. Atrial rate was affected in response to stimulation of all 7 GPs with an incidence of 50-95% of the animals among the different GPs. AV conduction was affected following stimulation of 6/7 GP with an incidence of 22-75% among GPs. Atrial and ventricular repolarization properties were affected by atrial as well as ventricular GP stimulation. Distinct regional patterns of repolarization changes were identified in response to stimulation of individual GPs. RAGP predominantly affected the RA and posterior right ventricular walls whereas CMVGP elicited biatrial and biventricular repolarization changes. Spatially divergent and overlapping cardiac regions are affected in response to nicotinic stimulation of neurons in individual GPs. cardiac innervation cardiac mapping heart rate intrinsic cardiac nervous system nicotine cardiac ganglionated plexus Biomedical Sciences
12	Chronic Myocardial Infarction Induces Phenotypic and Functional Remodeling in the Guinea Pig Cardiac Plexus Hardwick, Jean, Southerland, Elizabeth M., Ardell, Jeffrey L. 01 December 2008 (has links) Chronic myocardial infarction (CMI) is associated with remodeling of the ventricle and evokes adaption in the cardiac neurohumoral control systems. To evaluate the remodeling of the intrinsic cardiac nervous system following myocardial infarction, the dorsal descending coronary artery was ligated in the guinea pig heart and the animals were allowed to recover for 7-9 wk. Thereafter, atrial neurons of the intrinsic cardiac plexus were isolated for electrophysiological and immunohistochemical analyses. Intracellular voltage recordings from intrinsic cardiac neurons demonstrated no significant changes in passive membrane properties or action potential configuration compared with age-matched controls and sham-operated animals. The intrinsic cardiac neurons from chronic infarcted hearts did demonstrate an increase in evoked action potential (AP) frequency (as determined by the number of APs produced with depolarizing stimuli) and an increase in responses to exogenously applied histamine compared with sham and age-matched controls. Conversely, pituitary adenylate cyclase-activating polypeptide (PACAP)-induced increases in intrinsic cardiac neuron-evoked AP frequency were similar between control and CMI animals. Immunohistochemical analysis demonstrated a threefold increase in percentage of neurons immunoreactive for neuronal nitric oxide synthase (NOS) in CMI animals compared with control and the additional expression of inducible NOS by some neurons, which was not evident in control animals. Finally, the density of mast cells within the intrinsic cardiac plexus was increased threefold in preparations from CMI animals. These results indicate that CMI induces a differential remodeling of intrinsic cardiac neurons and functional upregulation of neuronal responsiveness to specific neuromodulators. histamine intracellular recording intrinsic cardiac nervous system mast cells Biomedical Sciences
13	Stochastic behavior of atrial and ventricular intrinsic cardiac neurons Waldmann, M., Thompson, G. W., Kember, G. C., Ardell, J. L., Armour, J. A. 08 August 2006 (has links) To quantify the concurrent transduction capabilities of spatially distributed intrinsic cardiac neurons, the activities generated by atrial vs. ventricular intrinsic cardiac neurons were recorded simultaneously in 12 anesthetized dogs at baseline and during alterations in the cardiac milieu. Few (3%) identified atrial and ventricular neurons (2 of 72 characterized neurons) responded solely to regional mechanical deformation, doing so in a tightly coupled fashion (cross-correlation coefficient r = 0.63). The remaining (97%) atrial and ventricular neurons transduced multimodal stimuli to display stochastic behavior. Specifically, ventricular chemosensory inputs modified these populations such that they generated no short-term coherence among their activities (cross-correlation coefficient r = 0.21 ± 0.07). Regional ventricular ischemia activated most atrial and ventricular neurons in a noncoupled fashion. Nicotinic activation of atrial neurons enhanced ventricular neuronal activity. Acute decentralization of the intrinsic cardiac nervous system obtunded its neuron responsiveness to cardiac sensory stimuli. Most atrial and ventricular intrinsic cardiac neurons generate concurrent stochastic activity that is predicated primarily upon their cardiac chemotransduction. As a consequence, they display relative independent short-term (beat-to-beat) control over regional cardiac indexes. Over longer time scales, their functional interdependence is manifest as the result of interganglionic interconnections and descending inputs. atrial neuron intrinsic cardiac nervous system myocardial ischemia stochastic control ventricular neuron Biomedical Sciences
14	Vagus Nerve Stimulation Mitigates Intrinsic Cardiac Neuronal Remodeling and Cardiac Hypertrophy Induced by Chronic Pressure Overload in Guinea Pig Beaumont, Eric, Wright, Gary L., Southerland, Elizabeth M., Li, Ying, Chui, Ray, KenKnight, Bruce H., Andrew Armour, J., Ardell, Jeffrey L. 01 May 2016 (has links) Our objective was to determine whether chronic vagus nerve stimulation (VNS) mitigates pressure overload (PO)-induced remodeling of the cardioneural interface. Guinea pigs (n = 48) were randomized to right or left cervical vagus (RCV or LCV) implant. After 2 wk, chronic left ventricular PO was induced by partial (15–20%) aortic constriction. Of the 31 animals surviving PO induction, 10 were randomized to RCV VNS, 9 to LCV VNS, and 12 to sham VNS. VNS was delivered at 20 Hz and 1.14 ± 0.03 mA at a 22% duty cycle. VNS commenced 10 days after PO induction and was maintained for 40 days. Time-matched controls (n = 9) were evaluated concurrently. Echocardiograms were obtained before and 50 days after PO. At termination, intracellular current-clamp recordings of intrinsic cardiac (IC) neurons were studied in vitro to determine effects of therapy on soma characteristics. Ventricular cardiomyocyte sizes were assessed with histology along with immunoblot analysis of selected proteins in myocardial tissue extracts. In sham-treated animals, PO increased cardiac output (34%, P < 0.004), as well as systolic (114%, P < 0.04) and diastolic (49%, P < 0.002) left ventricular volumes, a hemodynamic response prevented by VNS. PO-induced enhancements of IC synaptic efficacy and muscarinic sensitivity of IC neurons were mitigated by chronic VNS. Increased myocyte size, which doubled in PO (P < 0.05), was mitigated by RCV. PO hypertrophic myocardium displayed decreased glycogen synthase (GS) protein levels and accumulation of the phosphorylated (inactive) form of GS. These PO-induced changes in GS were moderated by left VNS. Chronic VNS targets IC neurons accompanying PO to obtund associated adverse cardiomyocyte remodeling. autonomic regulation therapy cardiac hypertrophy guinea pig intrinsic cardiac nervous system pressure overload vagus nerve stimulation Biomedical Sciences
15	Vagus Nerve Stimulation Mitigates Intrinsic Cardiac Neuronal and Adverse Myocyte Remodeling Postmyocardial Infarction Beaumont, Eric, Southerland, Elizabeth M., Hardwick, Jean C., Wright, Gary L., Ryan, Shannon, Li, Ying, KenKnight, Bruce H., Andrew Armour, J., Ardell, Jeffrey L. 01 January 2015 (has links) This paper aims to determine whether chronic vagus nerve stimulation (VNS) mitigates myocardial infarction (MI)-induced remodeling of the intrinsic cardiac nervous system (ICNS), along with the cardiac tissue it regulates. Guinea pigs underwent VNS implantation on the right cervical vagus. Two weeks later, MI was produced by ligating the ventral descending coronary artery. VNS stimulation started 7 days post-MI (20 Hz, 0.9 ± 0.2 mA, 14 s on, 48 s off; VNS-MI, n = 7) and was compared with time-matched MI animals with sham VNS (MI n = 7) vs. untreated controls (n = 8). Echocardiograms were performed before and at 90 days post-MI. At termination, IC neuronal intracellular voltage recordings were obtained from whole-mount neuronal plexuses. MI increased left ventricular end systolic volume (LVESV) 30% (P = 0.027) and reduced LV ejection fraction (LVEF) 6.5% (P < 0.001) at 90 days post-MI compared with baseline. In the VNS-MI group, LVESV and LVEF did not differ from baseline. IC neurons showed depolarization of resting membrane potentials and increased input resistance in MI compared with VNS-MI and sham controls (P < 0.05). Neuronal excitability and sensitivity to norepinephrine increased in MI and VNS-MI groups compared with controls (P < 0.05). Synaptic efficacy, as determined by evoked responses to stimulating input axons, was reduced in VNS-MI compared with MI or controls (P < 0.05). VNS induced changes in myocytes, consistent with enhanced glycogenolysis, and blunted the MI-induced increase in the proapoptotic Bcl-2-associated X protein (P < 0.05). VNS mitigates MI-induced remodeling of the ICNS, correspondingly preserving ventricular function via both neural and cardiomyocyte-dependent actions. autonomic regulation therapy guinea pig intrinsic cardiac nervous system myocardial infarction vagus nerve stimulation Biostatistics and Epidemiology Biomedical Sciences
16	Remodeling of the Guinea Pig Intrinsic Cardiac Plexus With Chronic Pressure Overload Hardwick, Jean C., Baran, Caitlin N., Southerland, E. Marie, Ardell, Jeffrey L. 01 September 2009 (has links) Chronic pressure overload (PO) is associated with cardiac hypertrophy and altered autonomic control of cardiac function, in which the latter may involve adaptations in central and/or peripheral cardiac neural control mechanisms. To evaluate the specific remodeling of the intrinsic cardiac nervous system following pressure overload, the descending thoracic aorta artery of the guinea pig was constricted ∼20%, and the animals recovered for 9 wk. Thereafter, atrial neurons of the intrinsic cardiac plexus were isolated for electrophysiological and immunohistochemical analyses. Intracellular voltage recordings from intrinsic cardiac neurons demonstrated no significant changes in passive membrane properties or action potential depolarization compared with age-matched controls and sham-operated animals, but afterhyperpolarization duration was increased in PO animals. Neuronal excitability, as determined by the number of action potentials produced with depolarizing stimuli, was differentially increased in phasic neurons derived from PO animals in response to exogenously applied histamine compared with sham and age-matched controls. Conversely, pituitary adenylate cyclase-activating polypeptide-induced increases in intrinsic cardiac neuron evoked AP frequency were similar between control and PO animals. Immunohistochemical analysis demonstrated a two-fold increase in the percentage of neurons immunoreactive for neuronal nitric oxide synthase in PO animals compared with control. The density of mast cells within the intrinsic cardiac plexus from PO animals was also increased twofold compared with preparations from control animals. These results indicate that congestive heart failure associated with chronic pressure overload induces a differential remodeling of intrinsic cardiac neurons and upregulation of neuronal responsiveness to specific neuromodulators. histamine intracellular recording intrinsic cardiac nervous system mast cells nitric oxide synthase Biomedical Sciences
17	Regional Cardiac Ganglia Projections in the Guinea Pig Heart Studied by Postmortem DII Tracing Harrison, Theresa A., Perry, Kristi M., Hoover, Donald B. 01 August 2005 (has links) Our purpose was to identify and localize intrinsic cardiac ganglia innervating distinct regions of the heart using postmortem tracing of nerve projections with DiI, a method not previously used to study the intrinsic cardiac nervous system. We also investigated the possibility of collateral innervation of myocardium and intrinsic ganglia. In isolated paraformaldehyde-fixed guinea pig hearts, crystals of DiI (1,1′- dioctadecyl-3,3,3′,3′-tetramethylin-docarbocyanine perchlorate) were inserted into the posterior ventricular myocardium below the atrioventricular groove, the right atrium, or the left ventricular septum. Hearts were placed in the dark at 37°C for 2-14 weeks to allow DiI diffusion within neuronal membranes. Labeled neurons were observed in intracardiac ganglia after at least 4 weeks of dye exposure. Labeling was restricted to the inferior-most ganglia (those near the atrioventricular groove) when DiI was inserted into the posterior ventricular myocardium and to ganglia near the sinus node after right atrial DiI placement. Application of DiI to the left ventricular septum resulted in neuron labeling in ganglia primarily in the interatrial septum near the atrioventricular node. After 8 weeks, DiI-labeled nerve fibers and varicosities were seen surrounding unlabeled neurons in some ganglia, suggesting that axons terminating in or passing through the DiI application site in posterior ventricular tissue had collateral branches innervating these ganglia. These results indicate that intrinsic innervation of major cardiac subdivisions is accomplished by regionally segregated cardiac ganglia. Also, tracing with DiI has provided evidence for collateral nerve projections that could be the substrate for novel intracardiac regulatory circuits. autonomic nervous system cardiac innervation cardiac regulation intracardiac ganglia intrinsic cardiac nervous system parasympathetic neuron Biomedical Sciences
18	Spinal Cord Activation Differentially Modulates Ischaemic Electrical Responses to Different Stressors in Canine Ventricles Cardinal, René, Ardell, Jeffrey L., Linderoth, Bengt, Vermeulen, Michel, Foreman, Robert D., Armour, J. Andrew 31 March 2004 (has links) Spinal cord stimulation (SCS) represents an acceptable treatment modality for patients with chronic angina pectoris refractory to standard therapy, but its mechanism of action remains unclear. To develop an experimental paradigm to study this issue, ameroid (AM) constrictors were implanted around the left circumflex coronary artery (LCx) in canines. Six weeks later, unipolar electrograms were recorded from 191 sites in the LCx territory in the open-chest, anesthetized state under basal pacing at 150 beats/min. We investigated the effect of SCS on ST segment displacements induced in the collateral-dependent myocardium in response to two stressors: (i) transient bouts of rapid ventricular pacing (TRP: 240/min for 1 min) and (ii) angiotensin II administered to right atrial neurons via their coronary artery blood supply. ST segment responses to TRP consisted of ST segment elevation in central areas of the LCx territory and ST depression at more peripheral areas. Such responses were unchanged when TRP was applied under SCS. Shortening of repolarization intervals in the metabolically compromised myocardium in response to TRP was also unaffected by SCS. In contrast, ST segment responses to intracoronary angiotensin II, which consisted of increased ST elevation, were attenuated by SCS in 6/8 preparations. The modulator effects of SCS were greatest at sites at which the greatest responses to angiotensin II occurred in the absence of SCS. These data indicate that spinal cord stimulation may attenuate the deleterious effects that stressors exert on the myocardium with reduced coronary reserve, particularly stressors associated with chemical activation of the intrinsic cardiac nervous system. angiotensin II coronary artery occlusion intrinsic cardiac nervous system rapid ventricular pacing spinal cord stimulation Biomedical Sciences
19	Effet de la galanine sur le système nerveux cardiaque intrinsèque.‎ Abass, Marwa 08 1900 (has links) Les neurones cholinergiques et adrénergiques efférents du système nerveux cardiaque ‎intrinsèque (SNCI) sont impliqués dans la régulation de la fonction cardiaque chronotrope. ‎La galanine, peptide présent et libéré dans les terminaisons nerveuses cardiaques, est capable ‎de diminuer la libération de l’acétylcholine. Notre hypothèse est d’étudier la possibilité que ‎la galanine puisse agir comme un peptide neuromodulateur inhibiteur dans les neurones du ‎SNCI chez le rat. Les oreillettes et les tissus associés du SNCI sont isolés à partir de rats ‎Sprague-Dawley et perfusés en vitro. Les valeurs de la fréquence auriculaire mesurées d’un ‎battement à l’autre sont tirées à partir d’un enregistrement bipolaire auriculaire. La perfusion ‎de la nicotine en forme de bolus (avec des concentrations dans le bain de 20-250 µm) a ‎induit des réponses biphasiques composées d’une réponse chronotrope négative au début ‎suivie d’une réponse chronotrope positive. Au cours de la superfusion de la galanine ‎‎(170 nM), les réponses chronotropes positives à la nicotine sont réduites chez 12/14 ‎préparations (contrôle : 21,35 ± 17,4 à galanine : 5,46 ± 8,0 bpm, n = 14, p = 0,02), tandis que ‎les réponses chronotropes négatives sont réduites chez 8 /14 préparations et affichent une ‎tendance générale vers la réduction (contrôle : -16,09 ± 14,7, galanine : -12,53 ± 13,2 bpm). ‎On peut conclure que la galanine agit comme un peptide neuromodulateur inhibiteur dans les ‎SNCI chez le rat, en modifiant de préférence la stimulation nicotinique de neurones ‎adrénergiques.‎ / Cholinergic and adrenergic efferent neurons of the intrinsic cardiac nervous system ‎‎(ICNS) regulate cardiac chronotropic function. Galanin, a peptide present and released in ‎cardiac nerve endings, is able to reduce the acetylcholine release. Our aim was to investigate ‎the proposition that galanin can act as an inhibitory neuromodulatory peptide in the rat ICNS. ‎Atria and associated ICNS tissues were isolated from Sprague-Dawley rats and superfused in ‎vitro. Beat to beat atrial rate measurements were derived from an atrial bipolar recording. ‎Nicotine bolus infusion (bath concentrations of 20-250 µM) induced biphasic responses ‎consisting of an early negative followed by a positive chronotropic response. During galanin ‎superfusion (170 nM), positive chronotropic responses to nicotine were reduced in 12/14 ‎preparations (control: 21.35±17.4 to galanin: 5.46±8.0 bpm, n=14, p=0.02) whereas the ‎negative chronotropic responses were reduced in 8/14 preparations and displayed an overall ‎tendency towards reduction (control: -16.09±14.7, galanin: -12.53±13.2 bpm). It is concluded ‎that galanin may act as an inhibitory neuromodulatory peptide in the rat ICNS, preferentially ‎modifying nicotinic stimulation of adrenergic neurons.‎ Système nerveux cardiaque intrinsèque Nicotine Galanine Rythme cardiaque Oreillettes ‎isolées de rat‎ Intrinsic cardiac nervous system Nicotine Galanin Heart rate Isolated rat atria
20	Analysis of intrinsic cardiac neuron activity in relation to neurogenic atrial fibrillation and vagal stimulation Salavatian, Siamak 08 1900 (has links) La fibrillation auriculaire est le trouble du rythme le plus fréquent chez l'homme. Elle conduit souvent à de graves complications telles que l'insuffisance cardiaque et les accidents vasculaires cérébraux. Un mécanisme neurogène de la fibrillation auriculaire mis en évidence. L'induction de tachyarythmie par stimulation du nerf médiastinal a été proposée comme modèle pour étudier la fibrillation auriculaire neurogène. Dans cette thèse, nous avons étudié l'activité des neurones cardiaques intrinsèques et leurs interactions à l'intérieur des plexus ganglionnaires de l'oreillette droite dans un modèle canin de la fibrillation auriculaire neurogène. Ces activités ont été enregistrées par un réseau multicanal de microélectrodes empalé dans le plexus ganglionnaire de l'oreillette droite. L'enregistrement de l'activité neuronale a été effectué continument sur une période de près de 4 heures comprenant différentes interventions vasculaires (occlusion de l'aorte, de la veine cave inférieure, puis de l'artère coronaire descendante antérieure gauche), des stimuli mécaniques (toucher de l'oreillette ou du ventricule) et électriques (stimulation du nerf vague ou des ganglions stellaires) ainsi que des épisodes induits de fibrillation auriculaire. L'identification et la classification neuronale ont été effectuées en utilisant l'analyse en composantes principales et le partitionnement de données (cluster analysis) dans le logiciel Spike2. Une nouvelle méthode basée sur l'analyse en composante principale est proposée pour annuler l'activité auriculaire superposée sur le signal neuronal et ainsi augmenter la précision de l'identification de la réponse neuronale et de la classification. En se basant sur la réponse neuronale, nous avons défini des sous-types de neurones (afférent, efférent et les neurones des circuits locaux). Leur activité liée à différents facteurs de stress nous ont permis de fournir une description plus détaillée du système nerveux cardiaque intrinsèque. La majorité des neurones enregistrés ont réagi à des épisodes de fibrillation auriculaire en devenant plus actifs. Cette hyperactivité des neurones cardiaques intrinsèques suggère que le contrôle de cette activité pourrait aider à prévenir la fibrillation auriculaire neurogène. Puisque la stimulation à basse intensité du nerf vague affaiblit l'activité neuronale cardiaque intrinsèque (en particulier pour les neurones afférents et convergents des circuits locaux), nous avons examiné si cette intervention pouvait être appliquée comme thérapie pour la fibrillation auriculaire. Nos résultats montrent que la stimulation du nerf vague droit a été en mesure d'atténuer la fibrillation auriculaire dans 12 des 16 cas malgré un effet pro-arythmique défavorable dans 1 des 16 cas. L'action protective a diminué au fil du temps et est devenue inefficace après ~ 40 minutes après 3 minutes de stimulation du nerf vague. / Atrial fibrillation is the most frequent sustained rhythm disorder in humans and often leads to severe complications such as heart failure and stroke. A neurogenic mechanism of atrial fibrillation has been hypothesized. Tachyarrhythmia induction by mediastinal nerve stimulation has been proposed as a model to study neurogenic atrial fibrillation. In this thesis, we studied the activity of intrinsic cardiac neurons and their interactions inside the right atrium ganglionated plexus in a canine model of neurogenic atrial fibrillation. These activities were recorded by a multichannel microelectrode array that was paled into the right atrium ganglionated plexus. The recording was done for up to 4 hours and it covered the neuronal activity during different interventions such as vascular (aorta occlusion, inferior vena cava occlusion, left anterior descending coronary artery occlusion), mechanical (touching atrium and ventricle) and electrical (stimulating of vagus nerve or stellate ganglion) stimuli as well as atrial fibrillation induction. Neuronal identification and classification were done using the principal component analysis and cluster on measurements analysis in Spike2 software. New method based on principal component analysis was proposed to cancel superimposed atrial activity on neuronal signal to increase the accuracy of the neuronal response identification and classification. Based on the neuronal response, we defined subtypes of neurons (afferent, efferent and local circuit neurons) and their related activity to different stressors which provided a more detailed description of the intrinsic cardiac nervous system. The majority of recorded neurons reacted to episodes of atrial fibrillation by becoming more active. This hyperactivity of intrinsic cardiac neurons during atrial fibrillation suggested that controlling that activity might help preventing neurogenic atrial fibrillation. Since low-level vagus nerve stimulation obtunds the intrinsic cardiac neuronal activity (especially for afferent and convergent local circuit neurons), we investigated whether this intervention could be applied as a therapy for atrial fibrillation. Our results showed that right vagus nerve stimulation was able to mitigate atrial fibrillation in 12 of 16 cases and showed an adverse pro-arrhythmic effect in 1 of 16 cases. The protective action however decreased over time and became ineffective after ~40 minutes for 3 minutes vagus nerve stimulation. Arythmies auriculaires Les neurones de circuit local La stimulation du nerf vague Interactivité neuronal stochastique Atrial arrhythmias Intrinsic cardiac nervous system Local circuit neurons Vagus nerve stimulation Stochastic neuronal interactivity

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