Vagal and sympathetic effects on the pacemaker fibers in the sinus venosus of the heart

1. Action potentials from sinus venosus and auricle fibers of spontaneously beating frog hearts have been recorded with intracellular electrodes. 2. Sinus fibers show a slow depolarization, the pacemaker potential, during diastole. The amplitude of this potential varies in different parts of the sinus. In some fibers the membrane potential falls by 11 to 15 mv. during diastole and the transition to the upstroke of the action potential is comparatively gradual. In other regions the depolarization develops more slowly and the action potential takes off more abruptly from a higher membrane potential. It is proposed that the fibers showing the largest fall in membrane potential during diastole are the pacemaker fibers of the heart, and that the rest of the preparation is excited by conduction. In auricle fibers the membrane potential is constant during diastole. 3. The maximum diastolic membrane potential and the overshoot of the action potential vary inversely with the amplitude of the pacemaker potential. The highest values were measured in auricle fibers. 4. Stimulation of vagi suppresses the pacemaker potentials. While the heart is arrested the membrane potential of the sinus fibers rises to a level above the maximum diastolic value reached in previous beats. In 28 experiments vagal stimulation increased the membrane potential from an average maximal diastolic value of 55 mv. to a "resting" level of 65.4 mv. The biggest vagal polarization was 23 mv. 5. In contrast to the sinus fibers vagal inhibition does not change the diastolic membrane potential of frog auricle fibers. 6. Vagal stimulation greatly accelerates the repolarization of the action potential and reduces its amplitude. These changes were seen both in the sinus and in auricle fibers stimulated by direct shocks during vagal arrest. 7. The conduction velocity in the sinus venosus of the tortoise is reduced by vagal stimulation. Block of conduction often occurs. 8. In the frog sinus venosus sympathetic stimulation increases the rate of rise of the pacemaker potential, accelerating the beat. The threshold remains unchanged. The rate of rise of the upstroke and the amplitude of the overshoot are increased. 9. The analogies between the vagal inhibition of the heart and the nervous inhibition of other preparations are discussed.     

The effects of noradrenaline, applied by microelectrophoresis on different cells of the rabbit's atrial pacemaker

Noradrenaline has been applied by microelectrophoresis to a small portion of the atrial pacemaker area in the rabbit's heart in order to study the local effects of this chemical transmitter separately from the ones deriving from other parts of the pacemaker area. In a first group of cells, whose action potential and location assimilate them to true pacemaker cells, noradrenaline caused a reduction in cycle length and an increase in the steepness of slow diastolic depolarization. In a second group of cells similar to latent pacemaker cells, noradrenaline caused no change in cycle length, the outstanding effect being an increase in the steepness of the slow diastolic depolarization which afterwards changed into a subthreshold oscillation. A third type of cells showed intermediate characteristics between the two previous groups. These results suggest that: a) the chronotropic effect of noradrenaline on the heart atrial pacemaker seems to be due to changes in the steepness of slow diastolic depolarization which can assume, in some instances, the shape of subthreshold oscillations; the effects on the other parameters in our preparation seem to be either less constant or less significant; b) the different effects which are obtained on various kinds of cells seem to be the result of a different degree of sensitivity to noradrenaline and to the more or less premature activation of mechanisms antagonizing the action of noradrenaline. The results are discussed on the basis of a model of spontaneous atrial pacemaking which has been recently proposed.     

Similarity of the effects of first-generation antiarrhythmia agents and decreased extracellular concentration of sodium ions on action potentials of atrial myocytes]

In rabbit right atria beating in a spontaneous sinus rhythm, myocytes of two types were studied, which differ by the initial form of action potentials. First-class antiarrhythmics and a gradual decrease in extracellular Na+ concentration induced qualitatively similar and unidirectional changes in the form of action potentials of myocytes. In some myocytes of the "conducting system" type, a slow diastolic depolarization was observed after repolarization, and the form of their action potentials became similar to that of the pacemaker cells. An enhancement of the action caused short-time arrhythmias.     

Electrical properties of developing rat heart. Effects of dexamethasone

Action potentials recorded from perinatal rat ventricles exhibited a plateau (phase 2), followed by a rapid repolarization characteristics of all mammalian ventricular cells. Within the second postnatal week, a number of distinct changes occurred in the contour of action potentials. An early slow depolarization, at the foot of the action potential, preceded the beginning of phase zero. The early slow depolarization was observed until day 12 and disappeared by day 13. A second slow depolarization occurred during the terminal phase of the rapid upstroke of the action potential, persisted through day 13 and disappeared by day 14. On day 12, what had been a homogeneous contour of action potentials seen during the first week converted into a heterogeneous contour. Occasionally, action potentials similar to those recorded from Purkinje fibres in adult heart were recorded from hearts as young as 12 days. By day 14, signs of a spike (the hallmark of action potentials from adult heart) were apparent in some fibres. Treatment of newborn rats with dexamethasone on the second day after birth prevented the disappearance of the second slow depolarization. In adult and aged rat hearts, dexamethasone treatment induced a slow depolarization and a plateau in the region of overshoot. In view of the time-dependent change of the second slow depolarization it is suggested that this phase of the action potential is influenced by the levels of circulating glucocorticoid in developing heart and by changes in calcium sensitivity observed in this species. Heterogeneity of action potentials observed on day 12 postnatal may precede structural differentiation of myofilaments.     

Sodium currents in toad cardiac pacemaker cells

Cells in the pacemaker region of toad (Bufo marinus) sinus venosus had spontaneous rhythmic action potentials. The rate of firing of action potentials, the rate of diastolic depolarization and the maximum rate of rise of action potentials were reduced by TTX (10 nm to 1 m). Currents were recorded with the whole cell, tight seal technique from cells enzymatically dissociated from this region. Cells studied were identified as pacemaker cells by their characteristic morphology, spontaneous rhythmic action potential activity that could be blocked by cobalt but not by TTX and lack of inward rectification. When calcium, potassium and nonselective cation currents (I_f) activated by hyperpolarization were blocked, depolarization was seen to generate transient and persistent inward currents. Both were sodium currents: they were abolished by tetrodotoxin (10 to 100 nm), their reversal potential was close to the sodium equilibrium potential and their amplitude and reversal potential were influenced as expected for sodium currents when extracellular sodium ions were replaced with choline ions. The transient sodium current was activated at potentials more positive than –40 mV while the persistent sodium current was obvious at more negative potentials. It was concluded that, in toad pacemaker cells, TTX-sensitive sodium currents contributing both to the upstroke of action potentials and to diastolic depolarization may play an important role in setting heart rate.We thank the Australian National Heart Foundation for their support. D.A.S. is an NHMRC Senior Research Officer.     

The electrical activity of embryonic chick heart cells isolated in tissue culture singly or in interconnected cell sheets

Embryonic chick heart cells were cultured on a plastic surface in sparse sheets of 2–50 cells mutually in contact, or isolated as single cells. Conditions are described which permitted conjoint cells to be impaled with recording microelectrodes with 75 % success, and isolated single cells with 8 % success. It is proposed that cells in electrical contact with neighbors are protected from irreversible damage by the penetrating electrode, by a flow of ions or other substances from connected cells across low-impedance intercellular junctions. Action potentials recorded from conjoint and isolated single cells were similar in form and amplitude. The height or shape of the action potential thus appears not to depend upon spatial relationships of one cell to another. As the external potassium concentration was increased from 1.3 mM to 6 mM, cells became hyperpolarized while the afterhyperpolarization was reduced. At higher potassium levels, the afterhyperpolarization disappeared, the slope of the slow diastolic depolarization decreased, and resting potential fell along a linear curve with a slope of 61 mv per 10-fold increase in potassium. In pacemaker cells the diastolic depolarization consists of two phases: (a) recovery from the afterpotential of the previous action potential and (b) the pacemaker potential. These phases are separated by a point of inflection, and represent manifestations of different mechanisms. Evidence is presented that it is the point of inflection (PBA) rather than the point of maximal diastolic potential, that should be taken as the resting potential.     

Ionic mechanisms of pacemaker activity in cardiac Purkinje fibers.

Rhythmic activity in cardiac Purkinje fibers can be analyzed by using the voltage clamp technique to study pacemaker currents. In normally polarized preparations, pacemaker activity can be generated by two distinct ionic mechanisms. The standard pacemaker potential (phase 4 depolarization) involves a slow potassium current, IK2. Following action potential repolarization, the IK2 channels slowly deactivate and thus unmask a steady background inward current. The resulting net inward current causes the slow pacemaker depolarization. Epinephrine accelerates the diastolic depolarization by promoting more complete and more rapid deactivation of IK2 over the pacemaker range of potentials. The catecholamine acts rather selectively on the voltage dependence of the gating mechanism, without altering the basic character of the pacemaker process. The nature of the pacemaker depolarization is altered by intoxication with high concentrations of cardiac glycosides or aglycones. These compounds promote spontaneous impulses in Purkinje fibers by a mechanism that supersedes the ordinary IK2 pacemaker. The digitalis-induced depolarization is generated by a transient inward current that is either absent or very small in untreated preparations. The transient inward current is largely carried by sodium ions. Its unusual time course probably reflects an underlying subcellular event, the oscillatory release of calcium ions from intracellular stores.     

Cardiac pacemaker mechanisms in the ostracod crustacean Vargula hilgendorfii

The heart of the ostracod crustacean Vargula hilgendorfii has a single intrinsic neuron that morphologically appears to innervate the myocardium. We, therefore, examined the heart activity electrophysiologically to determine whether the heartbeat is neurogenic. Each heartbeat is associated with a myocardial action potential composed of a spike potential followed by a plateau potential. The frequency of the action potential is not stable but changes successively over a wide range. The action potential is not preceded by a pacemaker potential and has an inflection in its rising phase. The myocardial cells couple electrically and fire almost simultaneously. The frequency of the action potential was unchanged by injection of depolarizing or hyperpolarizing current into the myocardium. However, slow oscillatory potentials appeared during the depolarization and its frequency was higher with increasing current intensity. Application of 1-microM tetrodotoxin (TTX) depolarized the myocardial membrane and completely prevented the action potential. During this depolarization, slow oscillatory potentials often appeared spontaneously. These results suggest that, although the myocardium has a property of conditional oscillator, the heartbeat is driven by the single cell cardiac ganglion that has both pacemaker and motor functions.     

兔主动脉前庭自律细胞与窦房结电生理特性的比较

为进一步阐明左心室流出道(主动脉前庭)自律细胞的特性,及其与窦房结细胞的异同,本实验利用常规的玻璃微电极细胞内记录技术,观察了一些离子通道阻断剂分别对离体兔窦房结起搏细胞与左心室流出道慢反应自律细胞的电生理特性的影响,重点探讨了这两种自律细胞的0期、4期去极离子流的异同。结果表明:(1)用1μmol/L维拉帕米(verapamil,VER)灌流后,窦房结及主动脉前庭自律细胞的动作电位幅值(APA)、0相最大除极速率(V_(max))、最大舒张电位(MDP)绝对值、舒张期除极速率(VDD)、自发放电频率(RPF)均明显下降,复极90％时间(APD_(90))延长(P<0.05)。(2)用180μmol/L氯化镍(NiCl_2)灌流,两自律细胞的VDD均明显下降;APA、V_(max)和RPF也显著降低,且窦房结细胞的APD_(90)明显延长。(3)给予2 mmol/L 4-氨基吡啶(4-AP)后,窦房结及主动脉前庭自律细胞的VDD均明显增快,MDP绝对值、APA和V_(max)显著下降,APD_(90)明显延长(P<0.05)。(4)给予2 mmol/L氯化铯(CsCl),两自律细胞的VDD及RPF均明显变慢。结果提示:(1)主动脉前庭自发慢反应电位的0相、4相去极离子流及复极离子流均与窦房结优势起搏细胞相似。(2)主动脉前庭起搏细胞Ca~(2+)内流为其0相主要去极离子流,复极过程主要由K~+外流引起,4相自动除极以K~+外流衰减为主,另外     

Pacemaker Current in Frog Atrium

PACEMAKER currents have been investigated by voltage clamp studies in Purkinje fibres^1,2 but not in tissues from those regions of the heart where the natural pacemaker lies: the amphibian sinus and mammalian sino-atrial node. Repetitive activity can often be induced in normally quiescent frog atrial trabeculae by application of small depolarizing constant current pulses³. These currents impose on the atrial cells the low membrane potential characteristic of sinus muscle⁴, Moreover, the potential changes involved are very similar to those which may be recorded from spontaneously active sinus, successive action potentials being separated by phases of slow diastolic depolarization⁴ (Fig. 1a). It seems likely therefore that the membrane current controlling this diastolic depolarization in atrium will closely resemble that which generates the natural sinus pacemaker.     

Effect of temperature on the electrical and mechanical activity of lizard ventricular myocardium

Intracellular action potentials and isometric twitches were recorded from lizard ventricles electrically driven at 20 and 4 beats/min and submitted to temperatures changes between 10.5 and 21 degrees C. It was found that cooling induced a depolarization of the diastolic membrane potential ER, which below 15 degrees C exceeded that predictable for a diffusion potential; on the contrary, during the recovery from hypothermia ER underwent a transitory hyperpolarization. Other effects of the low temperature were a decrease of the maximum rate of depolarization, a lengthening of both the action potential duration and the time to peak contraction, an increase of the strength of contraction, in the hearts driven at 20/min it became apparent also an increase of the action potential overshoot. The hypothesis is discussed that the positive inotropic effect of low temperatures may be due not only to a slowing down of the repolarization of the action potential, but also to an increase of the slow inward current intensity.     

Na(+) current contribution to the diastolic depolarization in newborn rabbit SA node cells

Isolated newborn, but not adult, rabbit sinoatrial node (SAN) cells exhibit spontaneous activity that (unlike adult) are highly sensitive to the Na(+) current (I(Na)) blocker TTX. To investigate this TTX action on automaticity, cells were voltage clamped with ramp depolarizations mimicking the pacemaker phase of spontaneous cells (-60 to -20 mV, 35 mV/s). Ramps elicited a TTX-sensitive current in newborn (peak density 0.89 +/- 0.14 pA/pF, n = 24) but not adult (n = 5) cells. When depolarizing ramps were preceded by steplike depolarizations to mimic action potentials, ramp current decreased 54.6 +/- 8.0% (n = 3) but was not abolished. Additional experiments demonstrated that ramp current amplitude depended on the slope of the ramp and that TTX did not alter steady-state holding current at pacemaker potentials. This excluded a steady-state Na(+) window component and suggested a kinetic basis, which was investigated by measuring TTX-sensitive I(Na) during long step depolarizations. I(Na) exhibited a slow but complete inactivation time course at pacemaker voltages (tau = 33.9 +/- 3.9 ms at -50 mV), consistent with the rate-dependent ramp data. The data indicate that owing to slow inactivation of I(Na) at diastolic potentials, a small TTX-sensitive current flows during the diastolic depolarization in neonatal pacemaker myocytes.     

Temperature-sensitive properties of rat suprachiasmatic nucleus neurons

The hypothalamic suprachiasmatic nucleus (SCN) contains a heterogeneous population of neurons, some of which are temperature sensitive in their firing rate activity. Neuronal thermosensitivity may provide cues that synchronize the circadian clock. In addition, through synaptic inhibition on nearby cells, thermosensitive neurons may provide temperature compensation to other SCN neurons, enabling postsynaptic neurons to maintain a constant firing rate despite changes in temperature. To identify mechanisms of neuronal thermosensitivity, whole cell patch recordings monitored resting and transient potentials of SCN neurons in rat hypothalamic tissue slices during changes in temperature. Firing rate temperature sensitivity is not due to thermally dependent changes in the resting membrane potential, action potential threshold, or amplitude of the fast afterhyperpolarizing potential (AHP). The primary mechanism of neuronal thermosensitivity resides in the depolarizing prepotential, which is the slow depolarization that occurs prior to the membrane potential reaching threshold. In thermosensitive neurons, warming increases the prepotential's rate of depolarization, such that threshold is reached sooner. This shortens the interspike interval and increases the firing rate. In some SCN neurons, the slow component of the AHP provides an additional mechanism for thermosensitivity. In these neurons, warming causes the slow AHP to begin at a more depolarized level, and this, in turn, shortens the interspike interval to increase firing rate.     

Pacemaker potentials generated by interstitial cells of Cajal in the murine intestine

Pacemaker potentials were recorded in situ from myenteric interstitial cells of Cajal (ICC-MY) in the murine small intestine. The nature of the two components of pacemaker potentials (upstroke and plateau) were investigated and compared with slow waves recorded from circular muscle cells. Pacemaker potentials and slow waves were not blocked by nifedipine (3 µM). In the presence of nifedipine, mibefradil, a voltage-dependent Ca²⁺ channel blocker, reduced the amplitude, frequency, and rate of rise of upstroke depolarization (dV/dt_max) of pacemaker potentials and slow waves in a dose-dependent manner (1–30 µM). Mibefradil (30 µM) changed the pattern of pacemaker potentials from rapidly rising, high-frequency events to slowly depolarizing, low-frequency events with considerable membrane noise (unitary potentials) between pacemaker potentials. Caffeine (3 mM) abolished pacemaker potentials in the presence of mibefradil. Pinacidil (10 µM), an ATP-sensitive K⁺ channel opener, hyperpolarized ICC-MY and increased the amplitude and dV/dt_max without affecting frequency. Pinacidil hyperpolarized smooth muscle cells and attenuated the amplitude and dV/dt_max of slow waves without affecting frequency. The effects of pinacidil were blocked by glibenclamide (10 µM). These data suggest that slow waves are electrotonic potentials driven by pacemaker potentials. The upstroke component of pacemaker potentials is due to activation of dihydropyridine-resistant Ca²⁺ channels, and this depolarization entrains pacemaker activity to create the plateau potential. The plateau potential may be due to summation of unitary potentials generated by individual or small groups of pacemaker units in ICC-MY. Entrainment of unitary potentials appears to depend on Ca²⁺ entry during upstroke depolarization. pacemaker activity; slow waves; gastrointestinal motility; calcium channel     

Oscillatory zones and their role in normal and abnormal sheep purkinje fiber automaticity

The mechanisms by which low [K(+)](o) induces spontaneous activity was studied in sheep Purkinje fibers. Purkinje strands were superfused in vitro and membrane potentials were recorded by means of a microelectrode technique. The results show that low [K(+)](o) increases the slope and amplitude of early diastolic depolarization, sharpens the transition between early and late diastolic depolarizations, induces an after-potential and large pre-potentials through a negative shift of an oscillatory zone. Pre-potentials occur progressively sooner during diastole and merge with the after-potential to induce uninterrupted spontaneous discharge. During recovery, when the rate slows, after- and pre-potentials separate once more, the slower discharge decreasing the after-potentials but not the pre-potentials. Low [K(+)](o) has little effect on the plateau, but markedly slows phase 3 repolarization and may altogether prevent it. At depolarized levels, voltage oscillations, slow responses, sinusoidal fluctuations or quiescence may be present depending on voltage. During the recovery, a train of either sub-threshold oscillations or spontaneous action potentials appear towards the end of phase 3 repolarization. The cessation of the action potentials unmasks large sub-threshold oscillations, that occur in the oscillatory zone. Drive, high [Ca(2+)](o) and norepinephrine increase slope and amplitude of early diastolic depolarization as low [K(+)](o) does. In low [K(+)](o), Cs(+) prevents spontaneous discharge at polarized levels, but not the decrease in resting potential nor the onset of slow responses at depolarized levels. Cs(+) blocks the train of oscillations and of action potentials occurring during recovery. We conclude that low [K(+)](o) steepens early diastolic depolarization and increases its amplitude through an after-potential that results from an increased Ca(2+) load; allows the attainment of the threshold through Cs(+)-sensitive voltage oscillations which develop when the oscillatory zone is entered either by diastolic depolarization or by phase 3 repolarization; and causes voltage oscillations also at depolarized levels, but through a Cs(+)-insensitive different mechanism.     

Disopyramide phosphate effects on slow and depressed fast responses

We studied the effects of disopyramide phosphate on explanted neonatal rat ventricle cells exhibiting depressed fast responses or naturally occurring slow response action potentials together with automatic activity. Disopyramide suppressed the spontaneous activity at a concentration of 2.5 micrograms/mL with a half-maximal value of 10 micrograms/mL. Before spontaneous activity was lost, there was an increase in beating rate possibly related to membrane depolarization. In depressed fast and slow response action potentials there was an increase in action potential duration (APD) which was consistently found both at the level of the plateau and at 90% repolarization. Comparison of the APD increase observed after disopyramide treatment and that after exposure to 20 mM tetraethylammonium suggested a block of a potassium conductance as a possible cause underlying the change in APD. The Vmax values of the depressed fast response decreased at constant membrane potential and this was attributed to the local anesthetic effect of the drug. In addition, we report two novel findings: (i) a decrease of Vmax of the slow response action potentials which may be secondary to membrane depolarization, and (ii) an increase in the duration of slow action potentials, possibly caused by inhibition of a potassium conductance.     

Organization and development of pacemaker of the gastrointestinal tract

Rhythmical depolarization and automatic contractions of smooth musculature of the gastrointestinal tract are a consequence of pacemaker activity of c-Kit-immunoreactive cells of mesenchymal origin—interstitial Cajal cells (ICC) that have a peculiar mechanism of intercellular Ca²⁺ balance, which is controlled by mitochondria. Intermuscular layer cells (ICC-MY) generate pacemaker potentials. Their induced depolarization is enhanced by unitary potentials generated by intracellular population—ICC-IM. Summation of unitary potentials in the tact of the pacemaker ones leads to creation of the second potential of slow waves—plateau potentials. Due to the presence of synapse-like structures, ICC serve messenger of transmission of the enteral nervous system onto the muscle. Long processes and close intercellular contacts similar to tight junction provide conductance and coordination of excitation in the intestinal musculature. Electrical rhythmicity appears in the intestinal muscle at the prenatal development period in parallel with the structural and functional ICC maturation, but establishment of mature rhythm parameters occurs in early postnatal ontogenesis. Features of similarity and difference in organization of control by pacemakers of the heart and musculature of the gastrointestinal tract are discussed.     

Mechanisms of adrenergic control of sino-atrial node discharge

Among the mechanisms proposed for the increase in discharge of sino-atrial node (SAN) by norepinephrine (NE) are an increase in the hyperpolarization-activated current I(f) and in the slow inward current I(Ca,L). If I(f) is the primary mechanism, cesium (a blocker of I(f)) should eliminate the positive chronotropic effect of NE. If I(Ca,L), is involved, [Ca(2+)](o) should condition NE effects. We studied the electrophysiological changes induced by NE in isolated guinea pig SAN superfused in vitro with Tyrode solution (both SAN dominant and subsidiary pacemaker mechanisms are present) as well as with high [K(+)](o), higher Cs(+) or Ba(2+) (only the dominant pacemaker mechanism is present). In Tyrode solution, NE (0.5-1microM) increased the SAN rate and adding Cs(+) (approximately 12 mM) caused a decaying voltage tail during diastole in subsidiary pacemakers. NE enhanced the Cs(+)-induced tail, and increased the rate but less than in Tyrode solution. In higher [Cs(+)](o) (15- 18 mM), Ba(2+) (1 mM) or Ba(2+) plus Cs(+) (10 mM) dominant action potentials (not followed by a tail) were present and NE accelerated them as in Tyrode solution. In high [K(+)](o), NE increased the rate in the absence and presence of Cs(+), Ba(2+) or Ba(2+) plus Cs(+). In these solutions, NE increased the overshoot and maximum diastolic potential of dominant action potentials (APs) and increased the rate by steepening diastolic depolarization and shifting the threshold for upstroke to more negative values. High [Ca(2+)](o) alone increased the rate and NE enhanced this action, whereas low [Ca(2+)](o) reduced or abolished the increase in rate by NE. In SAN quiescent in high [K(+)](o) plus indapamide, NE induced spontaneous discharge by decreasing the resting potential and initiating progressively larger voltage oscillations. Thus, NE increases the SAN rate by acting primarily on dominant APs in a manner consistent with an increase of I(Ca,L) and I(K) and under conditions where I(f) is either blocked or not activated. NE INITIATES spontaneous discharge by inducing voltage oscillations unrelated to I(f).     

Sodium nitroprusside increases pacemaker rhythm of sinoatrial nodes via nitric oxide-cGMP pathway

Effects of sodium nitroprusside (SNP), a nitric oxide donor, on the action potential in isolated guinea-pig sinoatrial nodes and ventricular papillary muscles were investigated. In the driven ventricular papillary muscle, SNP (10(-10)-10(-3) M) decreased the twitch tension in a concentration-dependent manner without significantly changing the configuration of action potential and the maximal velocity of depolarizing upstroke. In isolated sinoatrial nodes, SNP (10(-8)-10(-3) M) increased the pacemaker rhythm in a concentration-dependent manner. At 10(-5) M SNP, the pacemaker activity increased from 197.2+/-6.1 to 221.4+/-9.7 bpm. Changes of configuration of the action potential included a decrease of the duration of repolarization, i.e., from peak to the maximal diastolic potential (MDP), from 141.4+/-6.4 to 130.0+/-7.0 ms and an increase of the slope of the diastolic membrane potential from 101.6+/-5.3 to 116.5+/-7.3 mV/s (n=6, p<0.05). However, MDP and threshold potential were not significantly changed. Methylene blue (MB, 10(-5) M), a guanylate cyclase inhibitor, significantly decreased the pacemaker activity of the sinoatrial node by increasing the durations of repolarization and diastolic depolarization. After pretreatment with 10(-5) M MB, the effect of SNP was inhibited. The results indicate that nitric oxide, released from SNP, increases the pacemaker activity by enhancing the rates of repolarization and diastolic depolarization. These effects are possibly due to increases in delayed-rectifier K+ and diastolic slow inward currents, which are involved in a mechanism associated with the NO-cGMP pathway.     

豚鼠主动脉前庭自发性慢反应电位去极离子流的初步分析

为研究主动脉前庭自发慢反应电位的去极离充性质,利用豚鼠的离体以及心脏,常规玻璃微电极细胞内记录方法和离子通道组断剂,观测最大舒张电位（ＭＤＰ）、０相除极幅度（ＡＰＡ）、０相最大除极速度（Ｖｍａｘ）、４个自动除极速度（ＶＤＤ）、复极５０％（ＡＰＤ５０）和９０％（ＡＰＤ９０）的时间以及自发放电频率（ＲＰＦ）。结果发现：⑴０．５μｍｏｌ／Ｌ尼索地平（Ｎｉｓ）可使该慢电位的ＡＰＡ、Ｖｍａｘ、ＶＤＤ明显减小