Functional and anatomical variability of canine cardiac sympathetic efferent pathways: implications for regional denervation of the left ventricle

To further elucidate the functional anatomy of canine cardiac innervation as well as to assess the feasibility of producing regional left ventricular sympathetic denervation, the chronotropic and (or) regional left ventricular inotropic responses produced by stellate or middle cervical ganglion stimulation were investigated in 22 dogs before and after sectioning of individual major cardiopulmonary or cardiac nerves. Sectioning the right or left subclavian ansae abolished all cardiac responses produced by ipsilateral stellate ganglion stimulation. Sectioning a major sympathetic cardiopulmonary nerve, other than the right interganglionic nerve, usually reduced, but seldom abolished, regional inotropic responses elicited by ipsilateral middle cervical ganglion stimulation. Sectioning the dorsal mediastinal cardiac nerves consistently abolished the left ventricular inotropic responses elicited by right middle cervical ganglion stimulation but minimally affected those elicited by left middle cervical ganglion stimulation. In contrast, cutting the left lateral cardiac nerve decreased the inotropic responses in lateral and posterior left ventricular segments elicited by left middle cervical ganglion stimulation but had little effect on the inotropic responses produced by right middle cervical ganglion stimulation. In addition, the ventral mediastinal cardiac nerve was found to be a significant sympathetic efferent pathway from the left-sided ganglia to the left ventricle. These results indicate that the stellate ganglia project axons to the heart via the subclavian ansae and thus effective sympathetic decentralization can be produced by cutting the subclavian ansae; the right-sided cardiac sympathetic efferent innervation of the left ventricle converges intrapericardially in the dorsal mediastinal cardiac nerves; and the left-sided cardiac sympathetic efferent innervation of the left ventricle diverges to innervate the left ventricle by a number of nerves including the dorsal mediastinal, ventral mediastinal, and left lateral cardiac nerves. Thus consistent denervation of a region of the left ventricle can not be accomplished by sectioning an individual cardiopulmonary or cardiac nerve because of the functional and anatomical variability of the neural components in each nerve, as well as the fact that overlapping regions of the left ventricle are innervated by these different nerves.     

Cocaine alters heart rate dynamics in conscious ferrets.

This study was designed to test the hypothesis that cocaine intoxication induces distinctive alterations in sinus rhythm heart rate dynamics. Time-series and spectral analysis techniques were used to examine the effects of lethal doses of cocaine on heart rate variability in conscious, restrained ferrets. In all animals (n = 5), cocaine administration resulted in a marked decrease in sinus rhythm heart rate variability prior to sudden death. Heart rate variability (coefficient of variation of heart rate) just prior to death (0.018 +/- 0.005) was significantly (p less than 0.02) decreased compared to that at baseline prior to cocaine administration (0.061 +/- 0.022). There was also a significant (p less than 0.02) decrease in total spectral power prior to death compared to baseline. Transient low-frequency (0.04-0.10 Hz) oscillations in heart rate were also noted in three of the five animals following cocaine administration. There were, however, no significant changes in mean heart rate in response to cocaine. Alterations in heart rate dynamics were not seen in three saline-treated controls. Lethal effects of cocaine included ventricular arrhythmias (n = 2) and seizures (n = 3). One animal developed transient ST segment elevations that were consistent with coronary vasospasm. In conclusion, lethal doses of cocaine in the conscious ferret induce characteristic alterations in heart rate dynamics. These abnormalities (loss of heart rate variability and the appearance of low-frequency heart rate oscillations) are similar to those reported previously in certain patients at high risk of sudden cardiac death due to organic heart disease.     

Effect of ouabain on the innervated and noninnervated embryonic chick heart.

Attempts to assess the importance of the role played by endogenous catecholamines in the positive inotropic response to ouabain have produced contradictory results. The sympathetic nervous system is not present in the 4-day-old chicken embryo heart but is fully developed after 7 days of embryonic life. This was confirmed by the fact 4-day-old hearts do not respond to tyramine and cocaine while the usual positive inotropic and chronotropic responses were observed when these drugs were administered to 7-day-old hearts. In spite of this difference the positive inotropic response to ouabain was virtually identical at these two stages of development.     

Differential pre- and postsynaptic effects of desipramine on cardiac sympathetic nerve terminals in RHF

Right heart failure (RHF) is characterized by chamber-specific reductions of myocardial norepinephrine (NE) reuptake, beta-receptor density, and profiles of cardiac sympathetic nerve ending neurotransmitters. To study the functional linkage between NE uptake and the pre- and postsynaptic changes, we administered desipramine (225 mg/day), a NE uptake inhibitor, to dogs with RHF produced by tricuspid avulsion and progressive pulmonary constriction or sham-operated dogs for 6 wk. Animals receiving no desipramine were studied as controls. We measured myocardial NE uptake activity using [(3)H]NE, beta-receptor density by [(125)I]iodocyanopindolol, inotropic responses to dobutamine, and noradrenergic terminal neurotransmitter profiles by glyoxylic acid-induced histofluorescence for catecholamines, and immunocytochemical staining for tyrosine hydroxylase and neuropeptide Y. Desipramine decreased myocardial NE uptake activity and had no effect on the resting hemodynamics in both RHF and sham animals but decreased myocardial beta-adrenoceptor density and beta-adrenergic inotropic responses in both ventricles of the RHF animals. However, desipramine treatment prevented the reduction of sympathetic neurotransmitter profiles in the failing heart. Our results indicate that NE uptake inhibition facilitates the reduction of myocardial beta-adrenoceptor density and beta-adrenergic subsensitivity in RHF, probably by increasing interstitial NE concentrations, but protects the cardiac noradrenergic nerve endings from damage, probably via blockade of NE-derived neurotoxic metabolites into the nerve endings.     

Modulation of positive inotropy and metabolic coronary dilatation by myocardial alpha-adrenoceptors

Cardiac hyperactivity and its consequent metabolically induced coronary vasodilation (MCD) were studied in isolated, perfused, electrically paced rat hearts. The alpha-adrenoceptor agonists, phenylephrine and methoxamine, produced a concentration-dependent inhibition of the inotropic responses to noradrenaline, dobutamine, isoprenaline, tyramine, and glucagon, while relatively potentiating their MCD reactions. This inhibition was unrelated to the alpha-agonists' known inotropic action and was not affected by catecholamine depletion of the heart. Withdrawal of the alpha-agonists or administration of the alpha-adrenoceptor antagonists phentolamine, phenoxybenzamine, or prazosin returned the inotropic and MCD reactions to normal. Neither the MCD response to electrically induced tachycardia nor the inotropic reactions produced by calcium chloride were affected by alpha-adrenoceptor agonists or antagonists. Alone, alpha-adrenoceptor antagonists were shown to potentiate the inotropic responses to noradrenaline and isoprenaline while the MCD was relatively diminished. The responses to glucagon were unaltered by alpha-antagonists. We postulate that myocardial reactivity to sympathetic stimulation can be modulated through alpha-adrenoceptors by the inhibition of processes that mediate cardiostimulation at post-beta-adrenoceptor sites, together with facilitation of those leading up to MCD. Accordingly, this modulation would act to prevent ischaemic damage to the heart by acting to limit the inotropic responses to increasing sympathetic stimulation while maximizing the blood supply to the myocardium.     

Inotropic, chronotropic, and dromotropic effects mediated via parasympathetic ganglia in the dog heart

Some parasympathetic ganglionic cells are located in the epicardial fat pad between the medial superior vena cava and the aortic root (SVC-Ao fat pad) of the dog. We investigated whether the ganglionic cells in the SVC-Ao fat pad control the right atrial contractile force, sinus cycle length (SCL), and atrioventricular (AV) conduction in the autonomically decentralized heart of the anesthetized dog. Stimulation of both sides of the cervical vagal complexes (CVS) decreased right atrial contractile force, increased SCL, and prolonged AV interval. Stimulation of the rate-related parasympathetic nerves to the sinoatrial (SA) node (SAPS) increased SCL and decreased atrial contractile force. Stimulation of the AV conduction-related parasympathetic nerves to the AV node prolonged AV interval. Trimethaphan, a ganglionic nicotinic receptor blocker, injected into the SVC-Ao fat pad attenuated the negative inotropic, chronotropic, and dromotropic responses to CVS by 33 approximately 37%. On the other hand, lidocaine, a sodium channel blocker, injected into the SVC-Ao fat pad almost totally inhibited the inotropic and chronotropic responses to CVS and partly inhibited the dromotropic one. Lidocaine or trimethaphan injected into the SAPS locus abolished the inotropic responses to SAPS, but it partly attenuated those to CVS, although these treatments abolished the chronotropic responses to SAPS or CVS. These results suggest that parasympathetic ganglionic cells in the SVC-Ao fat pad, differing from those in SA and AV fat pads, nonselectively control the atrial contractile force, SCL, and AV conduction partially in the dog heart.     

Effect of experimental diabetes on isolated rat heart responsiveness to isoproterenol

The isolated perfused working rat heart was used to study experimental diabetes-induced alterations in the sensitivity and responsiveness of the myocardium to the effects of isoproterenol. Experimental diabetes was induced by intravenous administration of either 65 mg/kg alloxan or 60 mg/kg streptozotocin. The positive inotropic and cardiac relaxant effects of isoproterenol were studied at various time points after the induction of diabetes. There were no changes either in the sensitivity or in the maximum responses of diabetic rat hearts to the positive inotropic effect of isoproterenol at any time point studied. However, the cardiac relaxant effect of isoproterenol was depressed in acute as well as chronic diabetic rat hearts when compared with age-matched controls. Ventricular noradrenaline content was unchanged in 180-day diabetic rat hearts indicating the absence of a diabetes-induced sympathetic neuropathy in the heart. The depressed relaxing effect of isoproterenol may have resulted from alterations in energy utilization and sarcoplasmic reticular function in diabetic rat hearts.     

Effect of chronic cocaine administration and cocaine withdrawal on coronary flow rate and heart rate responses to epinephrine and cocaine in isolated perfused rat hearts

The acute dose-dependent effects of epinephrine and cocaine on heart rate and coronary flow rate (CFR) were examined in isolated, perfused (Langendorff) rat hearts from animals: i) pretreated with daily cocaine injections (20 mg/kg/day) for 8 weeks; ii) after 2-day withdrawal from 8-week cocaine pretreatment; iii) vehicle-treated controls. Chronic cocaine (CC) hearts were significantly less sensitive to the chronotropic effects of epinephrine than control (C) or withdrawal (CW) hearts. CW hearts exhibited significantly higher heart rates in response to epinephrine than C and CC hearts. Epinephrine alone (2.5 x 10(-7) M) decreased CFR 11% (C), 9%(CC), 14%(CW) from respective baseline levels. Cocaine alone had no significant effect on CFR in C hearts but produced slight dose-dependent decrements in CFR in CC and particularly CW hearts at higher doses. Cocaine plus epinephrine markedly decreased CFR in all groups, particularly in CW hearts. The results indicate that chronic daily cocaine administration produces a functional tolerance of the heart to the chronotropic actions of epinephrine but a 2-day withdrawal from chronic cocaine results in a rebound supersensitivity to adrenergic stimulation and cocaine's sympathomimetic effects. In addition, cocaine produces only minor decrements in coronary flow in the rat heart, while cocaine acts synergisticallly with epinephrine to produce a marked decrease in CFR.     

Ectopic atrial arrhythmias arising from canine thoracic veins during in vivo stellate ganglia stimulation

The purpose of the present study was to determine whether thoracic veins may act as ectopic pacemakers and whether nodelike cells and rich sympathetic innervation are present at the ectopic sites. We used a 1,792-electrode mapping system with 1-mm resolution to map ectopic atrial arrhythmias in eight normal dogs during in vivo right and left stellate ganglia (SG) stimulation before and after sinus node crushing. SG stimulation triggered significant elevations of transcardiac norepinephrine levels, sinus tachycardia in all dogs, and atrial tachycardia in two of eight dogs. Sinus node crushing resulted in a slow junctional rhythm (51 +/- 6 beats/min). Subsequent SG stimulation induced 20 episodes of ectopic beats in seven dogs and seven episodes of pulmonary vein tachycardia in three dogs (cycle length 273 +/- 35 ms, duration 16 +/- 4 s). The ectopic beats arose from the pulmonary vein (n = 11), right atrium (n = 5), left atrium (n = 2), and the vein of Marshall (n = 2). There was no difference in arrhythmogenic effects of left vs. right SG stimulation (13/29 vs. 16/29 episodes, P = nonsignificant). There was a greater density of periodic acid Schiff-positive cells (P < 0.05) and sympathetic nerves (P < 0.05) at the ectopic sites compared with other nonectopic atrial sites. We conclude that, in the absence of a sinus node, thoracic veins may function as subsidiary pacemakers under heightened sympathetic tone, becoming the dominant sites of initiation of focal atrial arrhythmias that arise from sites with abundant sympathetic nerves and periodic acid Schiff-positive cells.     

Electrophysiological effects of ouabain in 6-hydroxydopamine pretreated dogs

Chemical sympathectomy and bilateral vagotomy were used to evaluate the contribution of each division of the autonomic nervous system in the electrophysiological actions of ouabain. Intact and chemically sympathectomized dogs were given successive and cumulative doses of ouabain until toxicity became manifest (ventricular extrasystoles and (or) ventricular tachycardia). An additional group of normal and sympathectomized animals was also submitted to bilateral vagotomy in the presence of a therapeutic dose of ouabain. Sinus cycle length, AH interval of the His bundle electrogram, atrioventricular junctional effective and functional refractory periods were increased by ouabain at therapeutic doses. These effects were no different in sympathectomized dogs than in intact dogs, indicating the absence of any significant contribution of efferent sympathetic neural activity. However, our results suggested that vagal enhancement was the main mechanism whereby ouabain produced sinus bradycardia and depression of atrioventricular conduction. Sympathectomy with 6-OHDA did not modify nor abolish ouabain toxicity. However, toxic doses were significantly higher in sympathectomized animals than in normal animals. Considering that increasing heart rate by cardiac pacing or vagotomy significantly lowered toxic doses of ouabain in both intact and sympathectomized dogs, it is possible that sympathectomy could influence ouabain toxicity by altering heart rate alone.     

Prevention of diminished parasympathetic control of the heart in experimental heart failure

Decreased synaptic transmission in parasympathetic ganglia contributes to abnormal parasympathetic function in heart failure (HF). Because nicotinic ACh receptors (nAChR) mediate synaptic transmission at the ganglion and upregulate in response to chronic exposure to agonist in vitro, we tested the hypothesis that repeated exposures of ganglionic neurons to a nAChR agonist can prevent a loss of parasympathetic control in HF. Two sets of experiments were performed. In set 1, unpaced control dogs and dogs undergoing pacing-induced HF were treated with a repeated intravenous nicotinic agonist during the development of HF. Under conditions of sympathetic blockade, R-R responses to a bolus injection of 200 microg 1,1-dimethyl-4-phenylpiperazinium iodide (DMPP; nicotinic agonist) were found to be increased five times over the untreated group after 6 wk. In experimental set 2, dogs treated with weekly DMPP injections and in HF were anesthetized and underwent electrical stimulation of the right vagus nerve, which showed sinus cycle length responses >10 times that of controls (P < 0.05). Complete ganglionic blockade with hexamethonium abolished all responses, confirming that synaptic transmission was mediated entirely by nAChRs in both controls and HF. Despite decreased ganglionic function leading to reduced parasympathetic control of the heart in HF, repeated exposure with a nicotinic agonist during the development of HF results in not only preserved but also supranormal effects of parasympathetic stimulation on the sinus node.     

Cardiac responses to exercise in the dog before and after destruction of the sinoatrial node

Chronotropic and dromotropic responses to treadmill exercise were compared in conscious dogs prior to and following excision of the sinoatrial node (SAN). The initial junctional rhythm accompanying removal of the SAN region was replaced within hours to days by subsidiary atrial pacemaker (SAP) foci located in the inferior right atrium along the sulcus terminalis. With SAN intact, cardiac acceleration was immediate at onset of exercise and the tachycardia was directly proportional to work intensity. Atrioventricular (AV) conduction concurrently accelerated during exercise as manifest by shortening in P-R and atrioventricular (A-V) intervals. Following SAN excision, subsidiary atrial pacemaker foci likewise demonstrated prompt tachycardias during exercise, although heart rate was significantly reduced at rest and during steady state exercise. In the SAP state, tachycardia during exercise was related to work intensity and was mediated by changes in cardiac autonomic nerve activity. Combined propranolol-atropine blockade increased heart rate at rest in the SAP state, and significantly attenuated the tachycardia accompanying treadmill exercise. Following SAN excision the P-R (A-V) interval was significantly reduced in the resting animal. In response to exercise, AV conduction time decreased in the SAP state, though the absolute levels during steady state exercise were not significantly different from prior control runs with SAN intact. Blood pressure response to exercise was similar during both SAN and SAP states. We conclude that following an initial unstable period, SAP foci maintain adequate heart rate increases in response to dynamic exercise, primarily mediated via autonomic nerve regulation.     

Autonomic regulation of subsidiary atrial pacemakers during exercise

Cardiac responses to graded treadmill exercise were compared in conscious dogs before and after excision of the sinoatrial node (SAN) and adjacent tissue along the sulcus terminalis. The chronotropic and dromotropic responses to dynamic exercise were compared with and without selective muscarinic (atropine) and/or beta-adrenergic (timolol) blockade. With the SAN intact, cardiac acceleration was prompt during onset of exercise and in proportion to work intensity. Immediately after SAN excision (1-7 days), pacemaker activity exhibited marked instability in rate and pacemaker location, with rapid shifts between atrial and junctional foci. Soon thereafter (1-2 wk), subsidiary atrial pacemakers (SAPs) assumed the primary pacemaker function. Although the SAP foci demonstrated stable heart rates and atrioventricular (AV) intervals at rest and during exercise, heart rates at rest and during steady-state exercise were reduced 34% from corresponding levels in the SAN-intact state, both with and without selective autonomic blockade. For control of dromotropic function, animals with SAP foci showed pronounced shortening in AV interval in conjunction with exercise that was further exacerbated by pretreatment with atropine. Eight weeks after excision of the primary SAN pacemakers, direct electrophysiological mapping localized the SAP foci to either the inferior right atrium along the sulcus terminalis or the dorsal cranial right atrium (in or near Bachmann's bundle). Animals with SAPs localized to the inferior right atrium had a more marked suppression in heart rate with a corresponding greater decrease in AV interval during exercise than dogs with SAP foci identified within the dorsal cranial right atrium.     

Effect of lithium preparations on cardiac arrhythmias resulting from ligation of the common carotid arteries

In experiments on cats with dissected vagus and aortal nerves under chloralose-urethane anesthesia, ventricular disorders of the cardiac rhythm were induced by ligation of the common carotid arteries. Appearance of arrhythmias was preceded by an increase in the sympathetic activity (recorded from the inferior cardiac or renal nerve) accompanied by a rise of the arterial blood pressure and of the heart rate. Intravenous injection of lithium chloride or hydroxybutyrate resulted in lowering of the sympathetic activity, arterial blood pressure, and heart rate, and led to the recovery of the sinus rhythm.     

Parasympathetic effects on cardiac electrophysiology during exercise and recovery

Depressed parasympathetic tone is associated with an increased risk of sudden cardiac death. Exercise and the postexercise recovery period, which are associated with parasympathetic withdrawal, are high risk periods for sudden death. However, parasympathetic effects on cardiac electrophysiology during exercise and recovery have not been described. Electrophysiology studies were performed using noninvasive programmed stimulation (NIPS) in nine subjects (age 59 +/- 18 yr) with implanted dual-chamber devices and normal left ventricular function during multiple bicycle exercise sessions. NIPS was performed at rest, during exercise, and in the early recovery period both before and after parasympathetic blockade with atropine. Parasympathetic effect was defined as the value of the parameter of interest in the absence of atropine minus the value of the parameter in the presence of atropine. During exercise, sinus cycle length, atrioventricular (AV) block cycle length, AV interval, and ventricular effective refractory period shortened; in recovery, the values were intermediate between the rest and exercise values (P < 0.0001 by ANOVA). Parasympathetic effects on sinus cycle length, AV block cycle length, AV interval, and ventricular effective refractory period were 247 +/- 140, 58 +/- 20, 76 +/- 20, and 8.6 +/- 7.5 ms at rest, 106 +/- 20, 37 +/- 14, 24 +/- 13, and 2.6 +/- 7.8 ms during exercise, and 209 +/- 114, 50 +/- 23, 35 +/- 21, and 9.5 +/- 11.8 ms during recovery, respectively. There was poor correlation among the parasympathetic effects noted at the sinus node, AV node, and ventricle. Further work evaluating parasympathetic effects on cardiac electrophysiology during exercise and recovery in patients with heart disease is required to elucidate its role in modulating the risk of sudden cardiac death noted at these times.     

Cocaine-enhanced arrhythmogenesis: neural and nonneural mechanisms.

Cocaine abuse increases the susceptibility to cardiovascular complications and sudden cardiac death in man. We used programmed electrical stimulation of the heart to examine the arrhythmogenic influence of cocaine. Twenty-three pentobarbital-anesthetized adult dogs underwent programmed electrical stimulation using one to four extrastimuli before and during cocaine infusion. Autonomic decentralization was performed prior to the protocol in eight dogs. Induced ventricular arrhythmias included single premature ventricular depolarizations, doublets, triplets, ventricular tachycardia, and ventricular fibrillation. Intravenous cocaine, and subsequent adrenergic and muscarinic receptor blockade, or calcium channel blockade were evaluated for their influence on arrhythmogenesis. The incidence of induced ventricular arrhythmias was significantly elevated following cocaine and was reduced following propranolol and atropine. Verapamil, however, did not reduce the incidence of induced arrhythmias. In addition, cocaine significantly increased arrhythmia induction in decentralized animals, but propranolol, atropine, and phentolamine failed to reduce the proarrhythmic effects of cocaine in these animals. Thus, cocaine has a proarrhythmic effect on the heart with multiple mechanisms. The adrenergic mechanism appears to be a result of neurotransmitter uptake blockade, whereas the likely ionic mechanism is a neurally independent, direct effect on the heart.     

Neuropeptide Y (NPY) and the pig heart: release and coronary vasoconstrictor effects

The effects of electrical stimulation of the stellate ganglia on the arterio-venous concentration differences of neuropeptide Y (NPY)-like immunoreactivity (LI) over the pig heart were studied in vivo in relation to changes in heart rate and left ventricular pressure. Furthermore, the effects of NPY on coronary vascular tone were analysed in vivo and in vitro. Stellate ganglion stimulation at a high frequency (10 Hz) caused a clear-cut, long lasting increase in plasma levels of NPY-LI in the coronary sinus compared to the aorta, suggesting release of this peptide from sympathetic terminals within the heart. The stimulation-evoked overflow of NPY-LI from the heart was enhanced about 3-fold by alpha-adrenoceptor blockade using phenoxybenzamine, suggesting that NPY release is under prejunctional inhibitory control by noradrenaline (NA). Combined alpha- and beta-adrenoceptor blockade abolished most of the positive inotropic response of the heart upon stellate ganglion stimulation, while a considerable positive chronotropic effect remained. After guanethidine treatment, stellate ganglion stimulation still produced a small positive inotropic and chronotropic effect on the heart. The stimulation evoked NPY overflow was markedly reduced by guanethidine indicating an origin from sympathetic nerve terminals. Injection of NPY into the constantly perfused left anterior descending artery in vivo caused a long lasting, adrenoceptor antagonist resistant increase in perfusion pressure, suggesting coronary vasoconstriction. NPY contracted coronary arteries in vitro via a nifedipine-sensitive mechanism. NA dilated coronary vessels both in vivo and in vitro via beta-adrenoceptor activation. It is concluded that sympathetic nerve stimulation increases overflow of NPY-LI from the heart suggesting release from cardiac nerves in vivo.(ABSTRACT TRUNCATED AT 250 WORDS)     

The effects of sympathetic stimulation and adenosine on coronary circulation and heart function in diabetes mellitus

The aim of the experiment was to clarify whether the altered coronary reactivity in diabetes mellitus might be caused by a general modification of the sympathetic responses. Six of 12 young mongrel dogs of both sexes were made diabetic with alloxan (560 mmol/kg). This amount of alloxan induced a clinically manifest diabetes, however the animals failed to develop ketosis. The remaining six dogs served as controls. The haemodynamic investigation was performed three months after the induction of diabetes. Under pentobarbital anaesthesia (133 mmol/kg) mean arterial blood pressure, blood flow in the left anterior descending coronary artery, myocardial contractile force of left ventricular wall and heart rate were recorded continuously and the conductivity of coronary arterial bed was calculated during electrical stimulation ( 8V , 1-2-4-8-20 s-1) of the cardiac plexus or during the intracoronary infusion of adenosine (30-60-120-240-480 nmol/kg/min). In alloxan-diabetic dogs electrical stimulation evoked vasoconstriction in the coronary arterial bed, while vasodilation was observed in metabolically healthy animals. The vasodilator effect of adenosine was significantly smaller in diabetic than in control dogs. On the other hand there were no differences either in the alterations of heart rate caused by adenosine or in those of myocardial contractile force induced by adenosine or electric stimulation between the two groups. It is concluded that general alteration of sympathetic responses is not, but rather a modified relation of the receptors to the vessel wall might be responsible for the altered vascular responses in diabetes.     

HCN4 provides a 'depolarization reserve' and is not required for heart rate acceleration in mice

Cardiac pacemaking involves a variety of ion channels, but their relative importance is controversial and remains to be determined. Hyperpolarization-activated, cyclic nucleotide-gated (HCN) channels, which underlie the I(f) current of sinoatrial cells, are thought to be key players in cardiac automaticity. In addition, the increase in heart rate following beta-adrenergic stimulation has been attributed to the cAMP-mediated enhancement of HCN channel activity. We have now studied mice in which the predominant sinoatrial HCN channel isoform HCN4 was deleted in a temporally controlled manner. Here, we show that deletion of HCN4 in adult mice eliminates most of sinoatrial I(f) and results in a cardiac arrhythmia characterized by recurrent sinus pauses. However, the mutants show no impairment in heart rate acceleration during sympathetic stimulation. Our results reveal that unexpectedly the channel does not play a role for the increase of the heart rate; however, HCN4 is necessary for maintaining a stable cardiac rhythm, especially during the transition from stimulated to basal cardiac states.     

Diagnostic dilemma with a narrow QRS regular rhythm at normal rates in a patient with corrected transposition of great arteries

A 35 year old male, known case of corrected transposition of great arteries presented with exertional dyspnea and recurrent pre-syncope. 12 lead electrocardiogram revealed a regular rhythm at 75 beats per minute, P waves occurring on the upstroke of T waves and apparent 1:1 P-QRS relationship. The possibilities to be considered – complete AV block with junctional escape, junctional rhythm with 1:1 retrograde conduction, junctional rhythm with isorhythmic AV dissociation and prolonged PR interval have been discussed.