A. S. McGuirt scite author profile

The objective of this study was to determine how neurons within the right atrial ganglionated plexus (RAGP) and posterior atrial ganglionated plexus (PAGP) interact to modulate right atrial chronotropic, dromotropic, and inotropic function, particularly with respect to their extracardiac vagal and sympathetic efferent neuronal inputs. Surgical ablation of the PAGP (PAGPx) attenuated vagally mediated bradycardia by 26%; it reduced heart rate slowing evoked by vagal stimulation superimposed on sympathetically mediated tachycardia by 36%. RAGP ablation (RAGPx) eliminated vagally mediated bradycardia, while retaining the vagally induced suppression of sympathetic-mediated tachycardia (-83%). After combined RAGPx and PAGPx, vagal stimulation still reduced sympathetic-mediated tachycardia (-47%). After RAGPx alone and after PAGPx alone, stimulation of the vagi still produced negative dromotropic effects, although these changes were attenuated compared with the intact state. Negative dromotropic responses to vagal stimulation were further attenuated after combined ablation, but parasympathetic inhibition of atrioventricular nodal conduction was still demonstrable in most animals. Finally, neither RAGPx nor PAGPx altered autonomic regulation of right atrial inotropic function. These data indicate that multiple aggregates of neurons within the intrinsic cardiac nervous system are involved in sinoatrial nodal regulation. Whereas parasympathetic efferent neurons regulating the right atrium, including the sinoatrial node, are primarily located within the RAGP, prejunctional parasympathetic-sympathetic interactions regulating right atrial function also involve neurons within the PAGP.

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Autonomic interactions for control of atrial rate are maintained after SA nodal parasympathectomy

McGuirt

Schmacht

Ardell

1997

American Journal of Physiology-Heart and Circulatory Physiology

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Autonomic control of atrial rate was evaluated in anesthetized dogs by electrical stimulation of stellate ganglia and/or cervical vagi before and after the intrinsic cardiac right atrial ganglionated plexus (RAGP) was injected with the nicotinic blocker hexamethonium or the membrane stabilizing chemical lidocaine, or the RAGP was surgically removed. Injections of lidocaine or hexamethonium into or surgical removal of the RAGP eliminated the bradycardia elicited by vagal stimulation without reducing the tachycardia induced by stellate stimulation. Yet, after surgical ablation of the RAGP, the tachycardia induced by sympathetic stimulation was still reduced by 94% by parasympathetic stimulation. After injections of hexamethonium or lidocaine into the RAGP were administered, the sympathetically induced tachycardia was reduced by 39 and 85%, respectively, by parasympathetic stimulation. After RAGP ablation, when atrial rate was increased by infusion of beta-adrenergic agonists, parasympathetic stimulation reduced atrial rate by 13%. Sinoatrial (SA) nodal parasympathectomy, produced by disrupting the RAGP, eliminates direct vagal control of the SA node while leaving prejunctional parasympathetic projections to sympathetic afferents innervating the SA node intact.

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Effects of chronic cardiac decentralization on functional properties of canine intracardiac neurons in vitro

Smith¹,

McGuirt

Leger³

et al. 2001

American Journal of Physiology-Regulatory, Integrative and Comp

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Although intrinsic cardiac neurons display ongoing activity after chronic interruption of extrinsic autonomic inputs to the heart, the effects of decentralization on individual neurons remain unknown. The objective of this study was to determine the effects of chronic (3-4 wk) surgical decentralization on intracellular properties of, and neurotransmission among, neurons contained within the canine intrinsic right atrial ganglionated plexus in vitro. Properties of neurons from decentralized hearts were compared with those of neurons from sham-operated hearts (controls). Two populations of neurons were identified by their firing behavior in response to intracellular current injection. Fifty-nine percent of control neurons and 72% of decentralized neurons were phasic (discharged one action potential on excitation). Forty-one percent of control neurons and 27% of decentralized neurons were accommodating (multiple discharge with decrementing frequency). After chronic decentralization, input resistance of phasic neurons increased, whereas the duration of afterhyperpolarization of accommodating neurons decreased. Postsynaptic responses to interganglionic nerve stimulation were evoked in 89% of control neurons and 83% of decentralized neurons; the majority of these responses involved nicotinic receptors. These results show that, after chronic decentralization, intrinsic cardiac neurons 1) undergo changes in membrane properties that may lead to increased excitability while 2) maintaining synaptic neurotransmission within the intrinsic cardiac ganglionated plexus.

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Chronic decentralization of the heart differentially remodels canine intrinsic cardiac neuron muscarinic receptors

Smith

McGuirt

Hoover

et al. 2001

American Journal of Physiology-Heart and Circulatory Physiology

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The objective of the study was to determine if chronic interruption of all extrinsic nerve inputs to the heart alters cholinergic-mediated responses within the intrinsic cardiac nervous system (ICN). Extracardiac nerve inputs to the ICN were surgically interrupted (ICN decentralized). Three weeks later, the intrinsic cardiac right atrial ganglionated plexus (RAGP) was removed and intrinsic cardiac neuronal responses were evaluated electrophysiologically. Cholinergic receptor abundance was evaluated using autoradiography. In sham controls and chronic decentralized ICN ganglia, neuronal postsynaptic responses were mediated by acetylcholine, acting at nicotinic and muscarinic receptors. Muscarine- but not nicotine-mediated synaptic responses that were enhanced after chronic ICN decentralization. After chronic decentralization, muscarine facilitation of orthodromic neuronal activation increased. Receptor autoradiography demonstrated that nicotinic and muscarinic receptor density associated with the RAGP was unaffected by decentralization and that muscarinic receptors were tenfold more abundant than nicotinic receptors in the right atrial ganglia in each group. After chronic decentralization of the ICN, intrinsic cardiac neurons remain viable and responsive to cholinergic synaptic inputs. Enhanced muscarinic responsiveness of intrinsic cardiac neurons occurs without changes in receptor abundance.

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Cardiac Augmentation Can Be Maintained by Continuous Exposure of Intrinsic Cardiac Neurons to a β-Adrenergic Agonist or Angiotensin II

Levett¹,

Murphy²,

McGuirt³

et al. 1996

Journal of Surgical Research

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A. S. McGuirt

Interactions within the intrinsic cardiac nervous system contribute to chronotropic regulation

Autonomic interactions for control of atrial rate are maintained after SA nodal parasympathectomy

Effects of chronic cardiac decentralization on functional properties of canine intracardiac neurons in vitro

Chronic decentralization of the heart differentially remodels canine intrinsic cardiac neuron muscarinic receptors

Cardiac Augmentation Can Be Maintained by Continuous Exposure of Intrinsic Cardiac Neurons to a β-Adrenergic Agonist or Angiotensin II

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