Ventricular filling slows epicardial conduction and increases action potential duration in an optical mapping study of the isolated rabbit heart

INTRODUCTION: Mechanical stimulation can induce electrophysiologic changes in cardiac myocytes, but how mechanoelectric feedback in the intact heart affects action potential propagation remains unclear. METHODS AND RESULTS: Changes in action potential propagation and repolarization with increased left ventricular end-diastolic pressure from 0 to 30 mmHg were investigated using optical mapping in isolated perfused rabbit hearts. With respect to 0 mmHg, epicardial strain at 30 mmHg in the anterior left ventricle averaged 0.040 +/- 0.004 in the muscle fiber direction and 0.032 +/- 0.006 in the cross-fiber direction. An increase in ventricular loading increased average epicardial activation time by 25%+/- 3% (P < 0.0001) and correspondingly decreased average apparent surface conduction velocity by 16%+/- 7% (P = 0.007). Ventricular loading did not significantly alter action potential duration at 20% repolarization (APD20) but did at 80% repolarization (APD80), from 179 +/- 7 msec to 207 +/- 5 msec (P < 0.0001). The dispersion of APD20 was decreased with loading from 19 +/- 2 msec to 13 +/- 2 msec (P = 0.024), whereas the dispersion of APD80 was not significantly changed. These electrophysiologic changes with ventricular loading were not affected by the nonspecific stretch-activated channel blocker streptomycin (200 microM) and were not attributable to changes in myocardial perfusion or the presence of an electromechanical decoupling agent (butanedione monoxime) during optical mapping. CONCLUSION: Acute loading of the left ventricle of the isolated rabbit heart decreased apparent epicardial conduction velocity and increased action potential duration by a load-dependent mechanism that may not involve stretch-activated channels.     

Monophasic Action Potential Recordings from Intact Mouse Heart: Validation, Regional Heterogeneity, and Relation to Refractoriness

INTRODUCTION: The monophasic action potential (MAP) technique has been validated in humans and larger animals, but, in mice, MAP recordings available to date show little resemblance to the murine ventricular transmembrane action potential (TAP) measured by conventional microelectrodes. We developed a miniaturized MAP contact electrode technique to establish in isolated mouse hearts: (1) optimal electrode size; (2) validation against TAP; (3) relationship between repolarization and refractoriness; and (4) regional repolarization differences. METHODS AND RESULTS: In 30 Langendorff-perfused mouse hearts, MAP electrodes of tip diameter 1.5, 1.0, and 0.25 mm were tested by comparing MAPs and TAPs from epicardial and endocardial surfaces of both ventricles. Only the MAP contact electrode of 0.25-mm tip diameter consistently produced MAP recordings that had wave shapes nearly identical to TAP recordings. MAP durations measured at 30%, 50%, 70%, and 90% repolarization (APD30, APD50, APD70, APD90) highly correlated with TAP measurements (r = 0.97, P < 0.00001). APD50 was significantly longer in endocardial than in epicardial recordings (right ventricle: 9.3+/-1.1 msec vs 3.9+/-1.1 msec; left ventricle: 9.9+/-2.1 msec vs 6.2+/-1.9 msec; both P < 0.001), demonstrating transmural repolarization differences. Effective refractory period (ERP) determined at basic cycle lengths from 70 to 200 msec correlated with 80%+/-6% of total repolarization, with an ERP/APD90 ratio of 0.85+/-0.14. CONCLUSION: Murine myocardial repolarization, regional repolarization heterogeneity, and relation to refractoriness can be assessed reliably by this miniaturized MAP contact electrode technique, which renders action potential wave shapes similar to that of intracellular microelectrodes. This technique may be useful for exploring repolarization abnormalities in genetically altered mice.     

Gender and seasonally related differences in myocardial recovery and susceptibility to sotalol-induced arrhythmias in isolated rabbit hearts

INTRODUCTION: Gender differences and seasonal variations in cardiac electrophysiology and susceptibility to arrhythmias have been described clinically. The present study was undertaken to determine if there are similar gender and seasonally related differences in the electrophysiology of the rabbit heart. METHODS AND RESULTS: We analyzed epicardial electrograms, left ventricular endocardial monophasic action potentials (MAPs), and simulated X and Y lead ECGs from 145 isolated rabbit hearts studied over a period of 41 months. Hearts from males had seasonal increases in the duration of myocardial recovery. During the months of June to September compared with October to January and February to May, epicardial activation-recovery intervals (231.6+/-23.4 vs 215.6+/-19.2 and 213.5+/-18.8 msec, P = 0.003), MAP durations (256.5+/-25.4 vs 237.0+/-19.6 and 230.7+/-26.4 msec, P < 0.001), and QT intervals (278.3+/-25.6 vs 267.3+/-11.8 and 261.3+/-13.0 msec, P = 0.037) were longer. Overall, hearts from females had shorter QT intervals than males (257.7+/-15.7 vs 270.1+/-20.3 msec, P < 0.001), and this difference was reflected in their shorter epicardial activation-recovery intervals and MAP durations. However, hearts from females showed a greater prolongation of epicardial recovery (P = 0.007) and greater incidence of arrhythmias (P < 0.001) with sotalol than males. Also, the incidence of arrhythmias was greater in the winter months October to May (P < 0.001). CONCLUSION: The isolated rabbit heart provides a spontaneous model of gender and seasonally related differences in cardiac electrophysiology and arrhythmia susceptibility. These differences may be related to variation in the expression of or regulation of the membrane ion channels mediating repolarization.     

In vivo validation of the coincidence of the peak and end of the T wave with full repolarization of the epicardium and endocardium in swine.

OBJECTIVES/BACKGROUND: Previous in vitro studies have suggested full repolarization of the epicardium coincides with the peak of the T wave (T(peak)) and that of the M cells coincides with the end of the T wave (T(end)). However, in vivo validation of the theory is lacking. METHODS: Monophasic action potentials (MAPs) were recorded using the CARTO mapping system from 51 +/- 10 epicardial sites and 64 +/- 9 endocardial sites of the left ventricle in 10 pigs and from 41 +/- 4 epicardial sites and 53 +/- 2 endocardial sites of the right ventricle in two of the 10 pigs. End of repolarization (EOR) times over the epicardium (EOR(epi)), endocardium (EOR(endo)), and over both (EOR(total)) were obtained. QT(peak) and QT(end) intervals were measured from simultaneously recorded 12-lead ECG. RESULTS: Minimal and maximal EOR(total) were observed in the left ventricle in all pigs. Minimal EOR(total) was on the epicardium in five pigs, and maximal EOR(total) was on the endocardium in nine pigs. Minimal, mean, and maximal QT(peak) intervals all were significantly smaller than maximal EOR(epi) (322 +/- 23 ms, P <.01). No significant difference was found between maximal QT(end) interval (338 +/- 30 ms) and maximal EOR(endo) (339 +/- 24 ms, difference = 1 +/- 19 ms, P =.92), between maximal QT(end) interval and maximal EOR(total) (341 +/- 24 ms, difference = 2 +/- 18 ms, P =.69), or between minimal QT(peak) interval (283 +/- 28 ms) and minimal EOR(total) (282 +/- 20 ms, difference = 0 +/- 15 ms, P =.95). CONCLUSIONS: In in vivo pig models, T(peak) does not coincide with full repolarization of the epicardium but coincides well with the earliest EOR, whereas the T(end) corresponds with the latest EOR. These findings suggest that not only the transmural gradients but also the apicobasal repolarization gradients contribute to genesis of the T wave.     

家兔心室肌各层细胞的动作电位及瞬间外向钾电流特性

研究心室肌各层细胞的动作电位 (AP)、瞬间外向钾电流 (Ito)特性、并探讨两者之间关系。采用膜片钳技术记录心室肌内膜、中层 (M细胞 )、外膜层细胞的Ito及苯巴比妥对其影响 ,并与AP复极化达 90 %时程 (APD90 )进行比较。结果 :M细胞AP呈尖峰 圆顶形并有切迹 ,且APD90 最长。使用苯巴比妥后心室肌三层细胞 (由内→外 )APD90 在30 0ms基础刺激周长 (BCL)下缩短了 11.3% ,19.4%和 31.2 % (P <0 .0 5 ) ;在 6 0 0 0msBCL下分别下降了 11.5 % ,31.2 %和 13.4% (P <0 .0 5 )。M细胞、外膜层细胞的Ito比内膜层细胞大 (14.85± 1.1PA·PF- 1 、15 .2± 2 .3PA·PF- 1 vs 8.30± 0 .5 5PA·PF- 1 ;P <0 .0 5 )使用苯巴比妥后心室肌三层细胞 (由内→外 )下降了 2 9.5 % ,46 .7% ,47.2 % (P <0 .0 5或0 .0 1)。结果提示Ito呈正向影响APD ,影响程度受基础频率和不同层次细胞的制约     

Anisotropic conduction prolongs ventricular repolarization and increases its spatial gradient in the intact canine heart

The effects of the activation sequence on ventricular repolarization and its spatial gradient were examined in anesthetized open-chest dogs. Unipolar and bipolar electrograms were recorded from 47 epicardial sites on the anterior left ventricular wall using a mapping electrode. The local QT interval (QT) and the activation time (AT) at each site were measured on the unipolar and bipolar electrograms, respectively. The QT index (QTI) was defined as the QT minus AT interval, and was used as a measure of local repolarization. QTI was longer at each site during propagation that was longitudinal (L) (219+/-21 ms) than during propagation transverse (T) (202+/-22 ms, p<0.001) to the epicardial fiber orientation or during atrial pacing (165+/-20 ms, p<0.001). During L-propagation, the QTI shortened as a function of the distance from the stimulus. The spatial gradient was steeper during T-propagation (p<0.05). Monophasic action potentials (MAP) were also recorded simultaneously at 4 epicardial sites. The MAP duration during ventricular pacing was longer than during atrial pacing at sites within 1.5 cm of the pacing site. This difference disappeared at more distant sites and was attenuated by a simultaneous stimulus from a site symmetrically aligned along the fiber. These findings indicate that anisotropic conduction prolongs ventricular repolarization and increases its spatial gradient in the intact heart. An electrotonic downstream effect appears to be the cause.     

Effects of activation sequence and anisotropic cellular geometry on the repolarization phase of action potential of dog ventricular muscles

The influence of activation sequences on action potential configuration, especially in the repolarization phase, was examined in isolated canine ventricular muscles. Action potentials were recorded from the epicardial surface in the center of a preparation having nearly uniform fiber orientation (25 X 25 mm). Stimuli applied just adjacent to the recording site produced nearly centrifugal propagation. An activation sequence either parallel (longitudinal) or perpendicular (transverse) to the long axis of the muscle fibers was produced by peripheral stimulation. Action potential duration at -60 mV (APD-60 mV) during centrifugal propagation was significantly longer than that during longitudinal propagation. Further shortening of APD-60 mV was observed during transverse propagation. When a collision of longitudinal or transverse wavefronts (longitudinal or transverse collision) was produced at the action potential recording site, the shortest APD was recorded. During centrifugal propagation, action potential mapping around the stimulating electrodes revealed that APD-60 mV shortened gradually as the recording site was moved further from the stimulation site. The spatial gradient of APD was steeper in the transverse than in the longitudinal direction, causing a distortion in the repolarization sequence and the recovery of excitability near the center of the tissue. Premature stimuli applied to an area near the central stimulation site induced one-way block and circus movement of the wavefront, indicating reentry of excitation. We concluded that the activation sequence and anisotropic cellular geometry substantially affect APD, and that such a change contributes to the spatial inhomogeneity of refractoriness leading to reentrant arrhythmias.     

Monophasic action potential mapping in human subjects with normal electrocardiograms: direct evidence for the genesis of the T wave

T wave concordance in the normal human electrocardiogram (ECG) generally is explained by assuming opposite directions of ventricular depolarization and repolarization; however, direct experimental evidence for this hypothesis is lacking. We used a contact electrode catheter to record monophasic action potentials (MAPs) from 54 left ventricular endocardial sites during cardiac catheterization (seven patients) and a new contact electrode probe to record MAPs from 23 epicardial sites during cardiac surgery (three patients). All patients had normal left ventricular function and ECGs with concordant T waves. MAP recordings during constant sinus rhythm or right atrial pacing were analyzed for activation time (AT) = earliest QRS deflection to MAP upstroke, action potential duration (APD) = MAP upstroke to 90% repolarization, and repolarization time (RT) = AT plus APD. AT and APD varied by 32 and 64 msec, respectively, over the left ventricular endocardium and by 55 and 73 msec, respectively, over the left ventricular epicardium. On a regional basis, the diaphragmatic and apicoseptal endocardium had the shortest AT and the longest APD, and the anteroapical and posterolateral endocardium had the longest AT and the shortest APD (p less than .05 to less than .0001). RT was less heterogeneous than APD, and no significant transventricular gradients of RT were found. In percent of the simultaneously recorded QT interval, epicardial RT ranged from 70.8 to 87.4 (mean 80.7 +/- 3.9) and endocardial RT ranged from 80 to 97.8 (mean 87.1 +/- 4.4) (p less than .001).(ABSTRACT TRUNCATED AT 250 WORDS)     

Dispersion of ventricular repolarization and arrhythmia: study of two consecutive ventricular premature complexes

The effect of two consecutive ventricular premature stimuli (S1S2) during atrial pacing on dispersion of repolarization and inducibility of ventricular arrhythmias was studied in 16 dogs under control conditions and in four dogs in the presence of an increased dispersion of repolarization during atrial pacing induced by general hypothermia and regional warm blood perfusion via selective cannulation of the distal branch of left anterior decending coronary artery. Dispersion of repolarization was measured as the maximal difference between the ends of six simultaneously recorded monophasic action potentials (MAPs) from anterior ventricular surface, and consisted of MAP duration difference and activation time difference. Dispersion of repolarization during atrial pacing at control was 29 +/- 7 msec (activation time difference 4 +/- 6 msec, MAP duration difference 25 +/- 8 msec), that after S1 at paraseptal the site was 81 +/- 8 msec (activation time difference 73 +/- 12 msec, MAP duration difference 8 +/- 5 msec), and that after S1S2 was 148 +/- 27 msec (activation time difference 103 +/- 21, MAP duration difference 44 +/- 26 msec). Neither S1 nor S1S2 induced ventricular arrhythmia. Hypothermia and regional warm blood reperfusion increased dispersion of repolarization during atrial pacing to 70 +/- 22 msec (activation time difference 9 +/- 3 msec, MAP duration difference 61 +/- 19 msec). During hypothermia and regional warm blood reperfusion, S1 produced a dispersion of repolarization of 149 +/- 29 msec (activation time difference 85 +/- 8 msec, MAP duration difference 64 +/- 23 msec) and did not induce ventricular arrhythmia.(ABSTRACT TRUNCATED AT 250 WORDS)     

Vector mapping of myocardial activation

A custom-made probe, consisting of four electrodes arranged so that two orthogonal bipolar electrograms could be recorded from a single site, was used to record epicardial activity during atrial and ventricular pacing in five normal and five anesthetized open-chest mongrel dogs with myocardial infarction. Unfiltered bipolar electrograms recorded with a 2 mm interelectrode distance averaged 36 +/- 15 mV in amplitude and 16 +/- 5 msec in duration in normal areas and 14 +/- 11 mV and 23 +/- 12 msec in infarcted areas (p less than .01 infarct vs normal). The bipolar electrograms were vector summed so that a vector loop could be generated at each site. The direction of epicardial impulse propagation as determined by multipoint isochronal activation mapping was compared with that indicated by maximum x,y deflection of the vector loop. At 203 sites (141 normal and 62 infarcted) there was a median error of only 13 degrees and an excellent correlation by linear regression (r2 = .95). In normal myocardium vector loops were straight (60%), open (21%), or hooked (19%). In infarcted myocardium, notched and irregular loops were occasionally seen. However, a clear maximum x,y deflection was still obtained from 98% of infarcted sites. During ventricular pacing in normal dogs, uniform epicardial conduction was observed for up to 4 cm longitudinal to fiber orientation but only 1 cm transverse to it. At selected sites longitudinal to fiber orientation conduction velocity was 0.618 m/sec, electrogram duration 12 msec, and vector amplitude 76 mV compared with 0.304 m/sec, 18 msec, and 38 mV during conduction transverse to fiber orientation (p less than .05 for all comparisons). Vector mapping of epicardial activation was performed during ventricular tachycardia induced by programmed stimulation in two of five 2-week-old canine myocardial infarcts. Aside from minor irregularities caused by impulse spread around areas of block, vector loops indicated when impulses were spreading away from the area of early epicardial activity and thus directed mapping to the region of earliest activation. We conclude that vector loops generated by summing orthogonal local bipolar electrograms accurately represent the direction of epicardial activation in both normal and infarcted myocardium. Such loops may prove useful in mapping tachycardias and in clarifying details about cardiac activation processes.     

奎尼丁对吡那地尔诱导的犬右心室跨壁复极离散的影响

目的　由吡那地尔诱导犬右心室肌细胞产生“全或无”复极,观察奎尼丁对这种跨壁复极离散的影响。方法　应用标准玻璃微电极技术在1000ms刺激周长下,记录犬右心室肌细胞不同部位(外膜下、M区、内膜下)在不同情况[正常对照、吡那地尔(2 5μmol/L)、吡那地尔( 2 5μmol/L) +奎尼丁(5μmol/L) ]的动作电位。结果　吡那地尔( 2 5μmol/L)在3层细胞产生“全或无”复极,使跨壁复极离散增大,动作电位时程跨壁复极离散由(48 .5±9 .2)ms升为(128. 7±13. 5)ms(P<0. 01),进一步灌注奎尼丁(5μmol/L)后,减为(54 .3±10 .8)ms(P<0. 01)。奎尼丁部分恢复动作电位2相平台,延长了被吡那地尔缩短的动作电位时程。结论　在犬右心室肌组织,奎尼丁(5μmol/L)减小了由吡那地尔造成的跨壁复极离散,维持了跨壁电稳定性。     

Excitable gap in canine fibrillating ventricular myocardium: effect of subacute and chronic myocardial infarction

INTRODUCTION: The existence of an excitable gap during ventricular fibrillation (VF) has been suggested in several prior studies. However, the effects of myocardial infarction on the presence and duration of an excitable gap during VF have not been evaluated. METHODS AND RESULTS: Electrophysiologic study was performed in normal dogs and in dogs with subacute and chronic infarction. Experimental infarction was produced by left anterior descending coronary ligation. The excitable gap was determined indirectly using either evaluation of intrinsic wavefronts during VF or from the shortest activation interval at individual sites using recordings from a 112-electrode plaque sutured to the epicardial surface of the left ventricle. The excitable gap also was correlated to local electrophysiologic and anatomic properties. The excitable gap using the wavefront propagation method and shortest activation method was significantly longer in subacute infarction dogs (48 +/- 17 msec and 37 +/- 18 msec, respectively) and chronic infarction dogs (41 +/- 14 msec and 35 +/- 14 msec, respectively) than normal dogs (32 +/- 13 msec and 30 +/- 11 msec, respectively; P < 0.05 normal vs subacute and chronic infarction dogs in both methods). The excitable gap occupied approximately 30% and 27% of the VF cycle length in all three groups using the wavefront propagation and shortest activation method, respectively. The excitable gap correlated better with local ventricular refractoriness determined using the wavefront propagation method than with the shortest activation method, but not at all with refractoriness determined using extrastimulus testing. Tissue necrosis was noted in subacute infarction dogs and fibrosis in chronic infarction dogs, but the gap was not highly correlated with anatomic changes. CONCLUSION: During VF, an excitable gap exists in both normal and infarcted canine ventricular myocardium. It is significantly longer in the presence of infarction. These finding have implications for understanding the pathophysiology of VF and targeting antiarrhythmic therapies.     

Repolarization dynamics in patients with long QT syndrome

INTRODUCTION: Dynamics of ventricular repolarization may contribute to cardiac arrhythmias in subjects with the long QT syndrome (LQTS). The aim of the present study was to assess the dynamics of repolarization duration and the dynamics of repolarization complexity in LQTS patients and their unaffected family members. METHODS AND RESULTS: Twelve-lead 24-hour ambulatory ECG recordings were obtained from LQTS patients (n = 38) and unaffected family members (n = 20). The 24-hour dynamics of the QT interval, T wave complexity (TWC) index measured by principal component analysis, and the RR interval were analyzed using standard deviation (SD) and square root of the mean squared differences of successive values of the parameters (RMSSD). QT variability, mean TWC, and TWC variability were increased in the LQTS patients compared with unaffected family members (QT-SD: 38 +/- 20 msec vs 19 +/- 7 msec, P = 0.0001; QT-RMSSD: 36 +/- 20 msec vs 14 +/- 8 msec, P = 0.0001; TWC: 27.7% +/- 11.1% vs 20.4% +/- 6.7%, P = 0.003; TWC-SD: 6.7% +/- 2.8% vs 4.6% +/- 1.8%, P = 0.003; TWC-RMSSD: 5.3% +/- 2.8% vs 3.7% +/- 1.2%, P = 0.004, respectively). At the same time, the measures of heart rate variability were similar between the affected and unaffected LQTS subjects (SD of normal-to-normal RR intervals [SDNN]: 94 +/- 25 msec vs 89 +/- 37 ms, P = 0.56; RMSSD: 49 +/- 26 msec vs 49 +/- 34 ms, P = 0.97, respectively). CONCLUSION: Despite similar heart rate variability, QT variability and the variability of TWC are significantly increased in LQTS patients compared with unaffected family members, suggesting that disturbances in temporal dynamics of repolarization and repolarization complexity in LQTS patients possibly increase vulnerability to arrhythmias.     

Role of cardiac ATP-regulated potassium channels in differential responses of endocardial and epicardial cells to ischemia

Epicardial cells are more susceptible to the electrophysiological effects of ischemia than are endocardial cells. To explore the ionic basis for the differential electrophysiological responses to ischemia at the two sites, we used patch-clamp techniques to study the effects of ATP depletion on action potential duration and the ability of ATP-regulated K+ channels in single cells isolated from feline left ventricular endocardial and epicardial surfaces. During ATP depletion by treatment with 1 mM cyanide (CN-), shortening of action potential durations was significantly greater in epicardial cells than in endocardial cells. Thirty minutes after initiating exposure to 1 mM CN-, action potential duration at 90% repolarization was reduced to 0.70 +/- 0.12 of the control value for endocardial cells versus 0.39 +/- 0.18 for epicardial cells (p less than 0.01), and action potential duration at 20% repolarization was reduced to 0.72 +/- 0.13 for endocardial cells versus 0.12 +/- 0.09 for epicardial cells (p less than 0.01). In both endocardial and epicardial cells, the shortening of action potential by CN- treatment was partially reversed by 0.3 microM glibenclamide; the magnitude of reversal, however, was much greater in epicardial cells. After exposure to 1 mM CN-, the activity of ATP-regulated K+ channels in cell-attached membrane patches was significantly greater in epicardial cells than in endocardial cells. To study the dose-response relation between ATP concentration and open-state probability of the channels, intracellular surfaces of inside-out membrane patches containing ATP-regulated K+ channels were exposed to various concentrations of ATP (10-1,000 microM). The concentration of ATP that produced half-maximal inhibition of the channel was 23.6 +/- 21.9 microM in endocardial cells and 97.6 +/- 48.1 microM in epicardial cells (p less than 0.01). These data indicate that ATP-regulated K+ channels are activated by a smaller reduction in intracellular ATP in epicardial cells than in endocardial cells. The differential ATP sensitivity of ATP-regulated K+ channels in endocardial and epicardial cells may be responsible for the differential shortening in action potentials during ischemia at the two sites.     

Potassium rectifier currents differ in myocytes of endocardial and epicardial origin.

Whole-cell voltage-clamp experiments and single-channel current recordings in cell-attached patch mode were performed on enzymatically dissociated single ventricular myocytes harvested from feline endocardial and epicardial surfaces. The studies were designed to compare the characteristics of inward rectifier K+ current (IK1) and delayed rectifier K+ current (IK) between endocardial and epicardial cells and to test the hypothesis that the differential characteristics of IK1 and/or IK are responsible for the differences in action potential configuration between the two cell types. IK1 in endocardial cells displayed a distinct N-shaped current-voltage (I-V) relation, with a prominent outward current at potentials between -80 and -30 mV. In epicardial cells, an outward current region was much smaller, and the I-V relation demonstrated a blunted N-shaped I-V relation. In single-channel current recordings in cell-attached patch mode, neither unitary current amplitude of IK1 nor probability of channel opening was different between endocardial and epicardial cells, suggesting that the difference in the number of functional channels might be responsible for the differential IK1 I-V relations. The characteristics of IK also differed between endocardial and epicardial cells. The time course of growth of tail current of IK (IK,tail) (activation of IK) was significantly enhanced and that of IK,tail deactivation was delayed in epicardial cells compared with endocardial cells. The time constant of the slow component of IK activation at +20 mV was 3,950 +/- 787 msec in endocardial cells and 2,746 +/- 689 msec in epicardial cells (p less than 0.05); the corresponding values for IK deactivation at -50 mV were 1,041 +/- 387 msec and 1,959 +/- 551 msec, respectively (p less than 0.01). The voltage dependence of steady-state activation of IK,tail was similar between endocardial and epicardial cells, suggesting that the probability of channel opening at any potential was not different in the two cell types. The amplitude and density of fully activated IK (IK,full) were significantly greater in epicardial cells than in endocardial cells. At repolarization to -20 mV, IK,full amplitude was 452 +/- 113 pA in endocardial cells and 578 +/- 135 pA in epicardial cells (p less than 0.05), and the corresponding values for IK,full density were 2.86 +/- 0.73 and 4.21 +/- 0.83 microA/cm2, respectively (p less than 0.05). A nonstationary fluctuation analysis revealed that the amplitude of IK unitary current was similar between endocardial and epicardial cells (0.23 +/- 0.07 versus 0.22 +/- 0.03 pA, p = NS).(ABSTRACT TRUNCATED AT 400 WORDS)     

Ventricular action potentials, ventricular extracellular potentials, and the ECG of guinea pig

Action potentials were recorded from different regions of the guinea pig ventricle to characterize regional differences in waveform configuration, and to acquire insight into the generation of the T-wave of the electrocardiogram. Isolated tissue preparations were driven at 1 Hz, and microelectrodes were used to map accessible surface regions of the epicardium, endocardium, and septum. There were minimal differences in regional resting potentials (mean -87 mV) and amplitudes (mean 122 mV), but Vmax in the epicardium (mean 110 V/sec) was much smaller than elsewhere (mean 247 V/sec). The action potential duration at the -80 mV repolarization level was longest in the papillary muscles (mean 154 msec), shortest in the septum (mean 126 msec), and generally 10-15 msec longer at the base than at the apex. The characteristics of intramural action potentials were inferred from measurements on enzymatically isolated myocytes, the rationale being that most dissociated myocytes originated from intramural cell layers. The action potentials in about 40% of the myocytes had durations similar to those recorded from the tissue surface (110-170 msec), and the remainder ranged from 170-290 msec long. The existence of longer-than-surface action potentials in the ventricle was also inferred from the body surface electrocardiogram and from bipolar electrograms of isolated left ventricles. In both cases, the Q-T intervals could be accounted for only by action potentials longer than those recorded from the ventricular surface.     

Epicardial activation and repolarization patterns in patients with right ventricular hypertrophy.

To map global epicardial repolarization patterns and test the "SI" model of T wave generation, the patterns of epicardial activation and repolarization in patients with chronic pulmonary thromboembolism and right ventricular hypertrophy were studied by computerized mapping techniques and monophasic action potential (MAP) recording. The ventricular activation patterns were characterized by delayed right ventricular activation and the absence of normal early epicardial ventricular breakthrough in some cases. The repolarization patterns were characterized by nonuniform distribution of T wave morphologies. The T waves were predominantly positive over the left ventricular epicardium and negative or biphasic over the right ventricular epicardium. The activation-recovery (A-R) intervals were measured from the local activation to the maximal dV/dt of the upstroke of the T waves (Wyatt method). The difference between the A-R intervals and the MAP from onset of activation to 90% repolarization (MAP90) varies according to T wave morphology and could be as high as 96 msec with positive T waves, despite significant correlations (r = 0.56-0.90) between MAP90 and A-R intervals for each morphology. Better overall correlations were found if the minimal dV/dt on the downslope of the positive T waves was chosen to estimate the time of local repolarization (alternative method). Using this method, the mean A-R intervals were the same over the right and left ventricles. Cardiopulmonary bypass significantly prolonged the action potential duration equally at all parts of the epicardium. We conclude that in patients with right ventricular hypertrophy, the time of local repolarization can be estimated by our alternative method; the right ventricle completes activation and repolarization later than the left ventricle, and the distribution of T wave morphologies is nonuniform, with predominantly positive T waves observed over the left ventricle and negative or biphasic T waves observed over the right ventricle. These findings are compatible with the SI model of the generation of T waves.     

Prolongation of activation-recovery interval over a preexcited region before and after catheter ablation in patients with Wolff-Parkinson-White syndrome

INTRODUCTION: Preexisting changes in repolarization properties play an important role in T wave abnormalities (cardiac memory) after ablation in patients with Wolff-Parkinson-White (WPW) syndrome. However, no report has provided direct evidence for prolongation of action potential duration (APD) over a preexcited region before and after ablation. METHODS AND RESULTS: We studied 10 patients with ventricular preexcitation due to a left-sided accessory pathway (AP) (group M) and 12 patients with concealed left-sided AP (group C) to clarify prolongation of APD using activation-recovery intervals (ARIs) from epicardial and endocardial unipolar electrograms in patients with WPW syndrome. ARI was calculated from unipolar electrograms at the His bundle and the coronary sinus adjacent to the AP during atrial pacing (100 beats/min) before and 30 minutes after ablation. Before ablation, ARIs at the AP site were significantly longer in group M than in group C (255+/-21 msec vs 211+/-24 msec; P < 0.01), whereas ARIs at the His bundle did not differ between the two groups (255+/-20 msec vs 245+/-27 msec; P = NS). After ablation, group M showed no significant changes in ARIs at the AP and His bundle (256+/-19 msec and 253+/-15 msec) compared with before ablation. CONCLUSION: We found by direct analysis of ARIs from the epicardium that APD prolongation over the preexcited region was present before catheter ablation and persisted after catheter ablation. The gradual changes in repolarization properties, including APD prolongation after discontinuation of AP, may be one mechanism of cardiac memory after catheter ablation in patients with WPW syndrome.     

Gender differences in electrical remodeling and susceptibility to ventricular arrhythmias in rabbits with left ventricular hypertrophy

BACKGROUND: Left ventricular hypertrophy (LVH) is associated with an increased risk of death, vulnerability to ventricular arrhythmia, and multiple electrophysiological abnormalities. OBJECTIVES: The purpose of the present study was to determine the gender-dependent differences in electrical remodeling and the susceptibility to ventricular arrhythmias in a rabbit model of renovascular hypertension. METHODS: Rabbits of both sexes underwent unilateral renal artery banding and contralateral nephrectomy or were placed in the control group. Data are expressed as mean +/- standard error of the mean. RESULTS: The duration of action potentials was prolonged in the LVH group compared with the control group in both male (123 +/- 2.4 ms and 151 +/- 2.3 ms vs. 180 +/- 5.1 ms and 196 +/- 3.1 ms for action potential duration [APD](90 Epi) and APD(90 Endo) of control [n = 5] and LVH rabbits [n = 8], respectively; P<.05) and female rabbits (131 +/- 1.9 ms and 166 +/- 2.0 ms vs. 156 +/- 4.2 ms and 175 +/- 2.2 ms for APD(90 Epi) and APD(90 Endo) of control [n = 5] and LVH rabbits [n = 7], respectively; P<.05). Moreover, the gender-dependent differences in repolarization were opposite to those seen under control conditions. In LVH rabbits, APD(90) was greater in males than in females. The changes induced in APD lead to a greater transmural dispersion of repolarization (38 +/- 6.6 ms vs. 19 +/- 6.5 ms for males and females, respectively; P<.05). In addition, while control rabbits did not show induction of arrhythmias, an enhanced susceptibility to ventricular arrhythmia was seen in LVH male rabbits (6/8 male vs. 1/7 female LVH rabbits; P<.05). CONCLUSION: We conclude that the electrical remodeling associated with LVH inverted the gender-dependent differences, with male rabbits now exhibiting action potentials with longer durations both in the endocardial and epicardial surface of the left ventricle, increased dispersion of repolarization, and increased vulnerability to ventricular arrhythmia induction.     

Action potential characteristics and arrhythmogenic properties of the cardiac conduction system of the murine heart

Studies have characterized conduction velocity in the right and left bundle branches (RBB, LBB) of normal and genetically engineered mice. However, no information is available on the action potential characteristics of the specialized conduction system (SCS). We have used microelectrode techniques to characterize action potential properties of the murine SCS, as well as epicardial and endocardial muscle preparations for comparison. In the RBB, action potential duration at 50%, 70%, and 90% repolarization (APD(50,70,90)) was 6+/-0.7, 35+/-6, and 90+/-7 ms, respectively. Maximum upstroke velocity (dV/dt(max)) was 153+/-14 V/s, and conduction velocity averaged 0.85+/-0.2 m/s. APD(90) was longer in the Purkinje network of fibers (web) than in the RBB (P<0.01). Web APD(50) was longer in the left than in the right ventricle (P<0.05). Yet, web APD(90) was longer in the right than in the left ventricle (P<0.001). APD(50,70) was significantly longer in the endocardial than in the epicardial (P<0.001; P<0.003). APD(90) in the epicardial and endocardial was shorter than in the RBB ( approximately 36 ms versus approximately 100 ms). Spontaneous electrical oscillations in phase 2 of the SCS occasionally resulted in early afterdepolarizations. These results demonstrate that APDs in the murine SCS are significantly ( approximately 2-fold) longer than in the myocardium and implicate the role of the murine SCS in arrhythmias. The differences should have important implications in the use of the mouse heart to study excitation, propagation, and arrhythmias.