Impaired contractile function due to decreased cardiac myosin binding protein C content in the sarcomere.

Mutations in cardiac myosin binding protein C (MyBP-C) are a common cause of familial hypertrophic cardiomyopathy (FHC). The majority of MyBP-C mutations are expected to reduce MyBP-C expression; however, the consequences of MyBP-C deficiency on the regulation of myofilament function, Ca²âº homeostasis, and in vivo cardiac function are unknown. To elucidate the effects of decreased MyBP-C expression on cardiac function, we employed MyBP-C heterozygous null (MyBP-C+/-) mice presenting decreases in MyBP-C expression (32%) similar to those of FHC patients carrying MyBP-C mutations. The levels of MyBP-C phosphorylation were reduced 53% in MyBP-C+/- hearts compared with wild-type hearts. Skinned myocardium isolated from MyBP-C+/- hearts displayed decreased cross-bridge stiffness at half-maximal Ca²âº activations, increased steady-state force generation, and accelerated rates of cross-bridge recruitment at low Ca²âº activations (<15% and <25% of maximum, respectively). Protein kinase A treatment abolished basal differences in rates of cross-bridge recruitment between MyBP-C+/- and wild-type myocardium. Intact ventricular myocytes from MyBP-C+/- hearts displayed abnormal sarcomere shortening but unchanged Ca²âº transient kinetics. Despite a lack of left ventricular hypertrophy, MyBP-C+/- hearts exhibited elevated end-diastolic pressure and decreased peak rate of LV pressure rise, which was normalized following dobutamine infusion. Furthermore, electrocardiogram recordings in conscious MyBP-C+/- mice revealed prolonged QRS and QT intervals, which are known risk factors for cardiac arrhythmia. Collectively, our data show that reduced MyBP-C expression and phosphorylation in the sarcomere result in myofilament dysfunction, contributing to contractile dysfunction that precedes compensatory adaptations in Ca²âº handling, and chamber remodeling. Perturbations in mechanical and electrical activity in MyBP-C+/- mice could increase their susceptibility to cardiac dysfunction and arrhythmia.

Role of structural barriers in the mechanism of alternans-induced reentry.

Previously, using an animal model of T-wave alternans in structurally normal myocardium, we demonstrated that repolarization can alternate with opposite phase between neighboring myocytes (ie, discordant alternans), causing spatial dispersions of repolarization that form the substrate for functional block and reentrant ventricular fibrillation (VF). However, the mechanisms responsible for cellular discordant alternans and its electrocardiographic manifestation (ie, T-wave alternans) in patients with structural heart disease are unknown. We hypothesize that electrotonic uncoupling between neighboring regions of cells by a structural barrier (SB) is a mechanism for discordant alternans. Using voltage-sensitive dyes, ventricular action potentials were recorded from 26 Langendorff-perfused guinea pig hearts in the absence (ie, control) and presence of an insulating SB produced by an epicardial laser lesion. Quantitative analysis of magnitude and phase of cellular alternans revealed that in controls, action potential duration alternated in phase at all ventricular sites above a critical heart rate (269+/-17 bpm), ie, concordant alternans. Also, above a faster critical heart rate threshold (335+/-24 bpm), action potential duration alternated with opposite phase between sites, ie, discordant alternans. In contrast, only discordant but not concordant alternans was observed in 80% of hearts with the SB, and discordant alternans always occurred at a significantly slower heart rate (by 68+/-28 bpm) compared with controls. Therefore, the SB had a major effect on the alternans-heart rate relation, which served to facilitate the development of discordant alternans. Whether a SB was present or not, discordant alternans produced considerable increases (by approximately 170%) in the maximum spatial gradient of repolarization, which in turn formed the substrate for unidirectional block and reentry. However, by providing a structural anchor for stable reentry, discordant alternans in the presence of a SB led most often to sustained monomorphic ventricular tachycardia rather than to VF, whereas in the absence of a SB discordant alternans caused VF. SBs facilitate development of discordant alternans between cells with different ionic properties by electrotonically uncoupling neighboring regions of myocardium. This may explain why arrhythmia-prone patients with structural heart disease exhibit T-wave alternans at lower heart rates. These data also suggest a singular mechanism by which T-wave alternans forms a substrate for initiation of both VF and sustained monomorphic ventricular tachycardia.

Interdependence of modulated dispersion and tissue structure in the mechanism of unidirectional block.

We previously showed that a premature stimulus can significantly alter vulnerability to arrhythmias by modulating spatial gradients of ventricular repolarization (ie, modulated dispersion). However, it is not clear if such changes in arrhythmia vulnerability can be attributed to the formation of an electrophysiological substrate for unidirectional block and what the potential role is of tissue structure in this process. Therefore, the main objective of the present study was to examine the concomitant effect repolarization gradients and tissue structure have on unidirectional block. Optical action potentials were recorded from 128 ventricular sites (1 cm(2)) in 8 Langendorff-perfused guinea pig hearts. Propagation was confined to the epicardial surface using an endocardial cryoablation procedure, and a 12-mm barrier with a 1.5-mm isthmus was etched with a laser onto the epicardium. A premature stimulus (S2) was delivered over a range of S1S2 coupling intervals to modulate repolarization gradients in a predictable fashion. When a second premature stimulus (S3) was delivered from the center of the isthmus, the occurrence and orientation of unidirectional block were highly dependent on repolarization gradients created by the S2 beat. In this model, a local repolarization gradient of 3.2 ms/mm was required for unidirectional block at this isthmus. In addition, the formation of unidirectional block was critically dependent on the presence of the source-sink mismatch imposed by the isthmus. These results may explain how the interplay between spatial heterogeneities of repolarization and tissue structure form a substrate for unidirectional block and reentry.

Dynamics of spiral pairs induced by unidirectional propagating pulses.

The dynamics of unidirectionally propagating pulses in a two-dimensional uniform excitable reaction-diffusion medium is investigated. It is shown that under weak diffusion coupling between medium points such a pulse can evolve into a pair of counter-rotating spirals (spiral pair). We analyze the drift of such a pair and examine the collisions between several drifting pairs. It is demonstrated that collisions can result in a special type of reflection or, alternatively, in new types of complex stationary spiral structures. A possible application of these findings for the diagnosis of cardiac arrhythmias is suggested.

Late potentials on the signal-averaged electrocardiogram after canine myocardial infarction: correlation with induced ventricular arrhythmias during the healing phase.

Signal-averaged electrocardiograms (ECGs) and programmed ventricular stimulation were serially performed in 12 dogs (3 weeks of age) after experimental anteroapical myocardial infarction. At electrophysiologic study, sustained ventricular tachyarrhythmia was induced in seven dogs on at least one occasion. Of a total of 39 electrophysiologic studies, sustained monomorphic ventricular tachycardia was induced in seven studies and ventricular fibrillation in eight studies. In the remaining studies, no ventricular arrhythmia could be induced with triple ventricular extrastimuli. There was considerable day to day variability in the response to programmed stimulation and the results of the signal-averaged ECG. The signal-averaged QRS complex was significantly longer in dogs with inducible ventricular tachycardia or fibrillation (61 +/- 5 versus 57 +/- 3 ms, p = 0.02), had a lower terminal QRS amplitude (24 +/- 20 versus 46 +/- 33 microV, p = 0.04) and a longer late potential duration (19 +/- 4 versus 15 +/- 3 ms, p = 0.003) compared with that in animals with no inducible ventricular arrhythmia. Late potentials were defined as a total QRS duration greater than 58 ms, a terminal QRS amplitude less than 20 microV and a late potential duration greater than 18 ms. Using this definition, late potentials were seen in two distinct phases--immediately after coronary ligation and then beyond the first 72 h after infarction. The appearance of late potentials coincided with a change in arrhythmia inducibility from no ventricular arrhythmia to initiation of sustained monomorphic ventricular tachycardia. There is a close relation between inducibility of ventricular tachycardia in experimental canine myocardial infarction and the appearance of late potentials on the surface ECG.(ABSTRACT TRUNCATED AT 250 WORDS)

A comparison of T-wave alternans, signal averaged electrocardiography and programmed ventricular stimulation for arrhythmia risk stratification.

OBJECTIVES: The goal of this study was to compare T-wave alternans (TWA), signal-averaged electrocardiography (SAECG) and programmed ventricular stimulation (EPS) for arrhythmia risk stratification in patients undergoing electrophysiology study. BACKGROUND: Accurate identification of patients at increased risk for sustained ventricular arrhythmias is critical to prevent sudden cardiac death. T-wave alternans is a heart rate dependent measure of repolarization that correlates with arrhythmia vulnerability in animal and human studies. Signal-averaged electrocardiography and EPS are more established tests used for risk stratification. METHODS: This was a prospective, multicenter trial of 313 patients in sinus rhythm who were undergoing electrophysiologic study. T-wave alternans, assessed with bicycle ergometry, and SAECG were measured before EPS. The primary end point was sudden cardiac death, sustained ventricular tachycardia, ventricular fibrillation or appropriate implantable defibrillator (ICD) therapy, and the secondary end point was any of these arrhythmias or all-cause mortality. RESULTS: Kaplan-Meier survival analysis of the primary end point showed that TWA predicted events with a relative risk of 10.9, EPS had a relative risk of 7.1 and SAECG had a relative risk of 4.5. The relative risks for the secondary end point were 13.9, 4.7 and 3.3, respectively (p < 0.05). Multivariate analysis of 11 clinical parameters identified only TWA and EPS as independent predictors of events. In the prespecified subgroup with known or suspected ventricular arrhythmias, TWA predicted primary end points with a relative risk of 6.1 and secondary end points with a relative risk of 8.0. CONCLUSIONS: T-wave alternans is a strong independent predictor of spontaneous ventricular arrhythmias or death. It performed as well as programmed stimulation and better than SAECG in risk stratifying patients for life-threatening arrhythmias.

Local activation variability during monomorphic ventricular tachycardia in the dog.

OBJECTIVE: The aim was to determine the beat to beat variability in local activation time during sustained monomorphic ventricular tachycardia in a canine model of experimental myocardial infarction. METHODS: A digital template matching algorithm was developed for detecting subtle beat to beat variability in local activation timing at each of multiple ventricular sites. Ten electrically induced sustained ventricular tachycardia episodes, mean cycle length 211 (SD 40) ms, were endocardially and epicardially mapped in mongrel dogs weighing 15-20 kg. Digitised data were analysed for beat to beat local activation time variability. Similar data recorded during ventricular pacing at comparable rates and during sinus rhythm served as controls. RESULTS: The overall mean variability of local activation time for all 10 ventricular tachycardias was 3.2(1.6) ms, range 1.8(1.1) ms to 4.7(2.8) ms, in contrast to the overall mean variability of 0.2(0.4) ms (p = 0.0001) for ventricular pacing and 0.7(0.6) ms (p = 0.0001) for sinus rhythm. Oscillations in local activation time manifested alternans type periodicity during seven of 10 ventricular tachycardias independent of any alternans in local electrogram morphology. CONCLUSIONS: During sustained, monomorphic ventricular tachycardia, beat to beat variability and alternans type oscillations in local activation time are common and may be an intrinsic property of re-entry since they are negligibly small during ventricular pacing.

High resolution optical mapping reveals conduction slowing in connexin43 deficient mice.

UNLABELLED: Analysis of mice with genetically altered expression of cardiac connexins can provide insights into the role of individual gap junction channel proteins in cell-to-cell communication, impulse propagation, and arrhythmias. However, conflicting results have been reported regarding conduction velocity slowing in mice heterozygous for a null mutation in the gene encoding connexin43 (Cx43). METHODS: High-resolution optical mapping was used to record action potentials from 256 sites, simultaneously, on the ventricular surface of Langendorff perfused hearts from 15 heterozygous (Cx43+/-) and 8 wildtype (Cx43+/+) mice (controls). A sensitive method for measuring epicardial conduction velocity was developed to minimize confounding influences of subepicardial breakthrough and virtual electrode effects. RESULTS: Epicardial conduction velocity was significantly slower (23 to 35%, P<0.01) in Cx43+/- mice compared to wildtype. There was no change in conduction patterns or anisotropic ratio (Cx43+/- 1.54+/-0.33; Cx43+/+ 1.57+/-0.17) suggesting that Cx43 expression was reduced uniformly throughout myocardium. The magnitude of reductions in conduction velocity and Cx43 protein expression (45%) were similar in mice in which the null allele occurred in a pure C57BL/6J genetic background versus a mixed (C57BL/6J X 129) background. Action potential duration did not differ between mice of different genotypes. CONCLUSIONS: A approximately 50% reduction of Cx43 expression causes significant conduction velocity slowing in the Cx43+/- mouse heart. The apparent lack of conduction velocity changes reported in previous studies may be related to technical factors rather than variations in genetic background. High-resolution optical mapping is a powerful tool for investigating molecular determinants of propagation and arrhythmias in genetically engineered mice.

Electrical alternans during rest and exercise as predictors of vulnerability to ventricular arrhythmias.

This investigation was performed to evaluate the feasibility of detecting repolarization alternans with the heart rate elevated with a bicycle exercise protocol. Sensitive spectral signal-processing techniques are able to detect beat-to-beat alternation of the amplitude of the T wave, which is not visible on standard electrocardiogram. Previous animal and human investigations using atrial or ventricular pacing have demonstrated that T-wave alternans is a marker of vulnerability to ventricular arrhythmias. Using a spectral analysis technique incorporating noise reduction signal-processing software, we evaluated electrical alternans at rest and with the heart rate elevated during a bicycle exercise protocol. In this study we defined optimal criteria for electrical alternans to separate patients from those without inducible arrhythmias. Alternans and signal-averaged electrocardiographic results were compared with the results of vulnerability to ventricular arrhythmias as defined by induction of sustained ventricular tachycardia or fibrillation at electrophysiologic evaluation. In 27 patients alternans recorded at rest and with exercise had a sensitivity of 89%, specificity of 75%, and overall clinical accuracy of 80% (p <0.003). In this patient population the signal-averaged electrocardiogram was not a significant predictor of arrhythmia vulnerability. This is the first study to report that repolarization alternans can be detected with heart rate elevated with a bicycle exercise protocol. Alternans measured using this technique is an accurate predictor of arrhythmia inducibility.

T-wave alternans and dispersion of the QT interval as risk stratification markers in patients susceptible to sustained ventricular arrhythmias.

T-wave alternans and QT dispersion were compared as predictors of the outcome of electrophysiologic study and arrhythmia-free survival in patients undergoing electrophysiologic evaluation. T-wave alternans was a highly significant predictor of these 2 outcome variables, whereas QT dispersion was not.

Platelet deposition after surgically induced myocardial ischemia. An etiologic factor for reperfusion injury.

Despite meticulous adherence to presently known principles of myocardial preservation, reperfusion after aortic cross-clamping results in a unique injury manifested by decreasing high-energy phosphate levels and increased coronary resistance. We hypothesize that platelet deposition into the coronary microvasculature is a major factor in reperfusion injury. To differentiate platelet deposition due to subendocardial hemorrhage from deposition due to vascular entrapment, we infused 111In-labeled platelets together with 51Cr-labeled erythrocytes into 15 dogs that were on normothermic bypass and subjected to 60 minutes of global ischemia followed by 30 minutes of reperfusion. Platelet deposition is indicated only when the proportion of platelets to erythrocytes in tissue exceeds that measured by peripheral blood. Myocardial biopsy specimens were obtained after 10 minutes of bypass, 120 minutes of continuous bypass (Group I), and at the end of reperfusion after global ischemia (Group II). In five dogs (Group III), dipyridamole (1 mg/kg), an antiplatelet activation agent, was administered in the preischemic period. Platelet deposition was expressed as the number of radioactive-labeled platelets deposited per gram of tissue. Bypass for 120 minutes resulted in only a minimal increase in platelet deposition. However, normothermic ischemia followed by reperfusion resulted in over a twofold increase in platelet deposition compared to controls. Pretreatment with dipyridamole appeared to avoid platelet deposition. These data indicate that platelet deposition in the coronary microcirculation following surgically induced myocardial ischemia may be associated with reperfusion injury and that antiplatelet drugs after this sequence.

Prognostic significance of electrical alternans versus signal averaged electrocardiography in predicting the outcome of electrophysiological testing and arrhythmia-free survival.

OBJECTIVE: To investigate the accuracy of signal averaged electrocardiography (SAECG) and measurement of microvolt level T wave alternans as predictors of susceptibility to ventricular arrhythmias. DESIGN: Analysis of new data from a previously published prospective investigation. SETTING: Electrophysiology laboratory of a major referral hospital. PATIENTS AND INTERVENTIONS: 43 patients, not on class I or class III antiarrhythmic drug treatment, undergoing invasive electrophysiological testing had SAECG and T wave alternans measurements. The SAECG was considered positive in the presence of one (SAECG-I) or two (SAECG-II) of three standard criteria. T wave alternans was considered positive if the alternans ratio exceeded 3.0. MAIN OUTCOME MEASURES: Inducibility of sustained ventricular tachycardia or fibrillation during electrophysiological testing, and 20 month arrhythmia-free survival. RESULTS: The accuracy of T wave alternans in predicting the outcome of electrophysiological testing was 84% (p < 0.0001). Neither SAECG-I (accuracy 60%; p < 0.29) nor SAECG-II (accuracy 71%; p < 0.10) was a statistically significant predictor of electrophysiological testing. SAECG, T wave alternans, electrophysiological testing, and follow up data were available in 36 patients while not on class I or III antiarrhythmic agents. The accuracy of T wave alternans in predicting the outcome of arrhythmia-free survival was 86% (p < 0.030). Neither SAECG-I (accuracy 65%; p < 0.21) nor SAECG-II (accuracy 71%; p < 0.48) was a statistically significant predictor of arrhythmia-free survival. CONCLUSIONS: T wave alternans was a highly significant predictor of the outcome of electrophysiological testing and arrhythmia-free survival, while SAECG was not a statistically significant predictor. Although these results need to be confirmed in prospective clinical studies, they suggest that T wave alternans may serve as a non-invasive probe for screening high risk populations for malignant ventricular arrhythmias.

Implications of ion channel diversity to ventricular repolarization and arrhythmogenesis: insights from high resolution optical mapping.

Recent evidence from experiments in isolated cells suggests that substantial ion channel diversity exists throughout the heart. However, due to limitations of conventional electrophysiological recording techniques, the influence of ion channel diversity on ventricular repolarization and arrhythmia vulnerability at the level of the intact heart are poorly understood. High resolution optical mapping with voltage-sensitive dye was used to measure significant heterogeneity in the kinetics of cellular repolarization between cells across the epicardial surface (1 x 1 cm) of the intact guinea-pig heart. Such diversity of repolarization kinetics modulates dispersion of repolarization in a biphasic fashion as premature coupling interval is shortened. Moreover, evidence is provided that modulation of repolarization by a premature stimulus in a coupling interval-dependent manner also modulates arrhythmia vulnerability in parallel, ie, 'modulated dispersion' hypothesis. Therefore, due to diversity of repolarization kinetics between epicardial cells, a premature stimulus serves not only as a 'trigger' of arrhythmias, but also importantly modulates spatial dispersion of repolarization and the arrhythmogenic substrate for reentry.

Minimum Information about a Cardiac Electrophysiology Experiment (MICEE): standardised reporting for model reproducibility, interoperability, and data sharing.

Cardiac experimental electrophysiology is in need of a well-defined Minimum Information Standard for recording, annotating, and reporting experimental data. As a step towards establishing this, we present a draft standard, called Minimum Information about a Cardiac Electrophysiology Experiment (MICEE). The ultimate goal is to develop a useful tool for cardiac electrophysiologists which facilitates and improves dissemination of the minimum information necessary for reproduction of cardiac electrophysiology research, allowing for easier comparison and utilisation of findings by others. It is hoped that this will enhance the integration of individual results into experimental, computational, and conceptual models. In its present form, this draft is intended for assessment and development by the research community. We invite the reader to join this effort, and, if deemed productive, implement the Minimum Information about a Cardiac Electrophysiology Experiment standard in their own work.

Role of wavelength adaptation in the initiation, maintenance, and pharmacologic suppression of reentry.

INTRODUCTION: The stability of reentry is thought to depend on a critical balance between the spatial extent of refractory tissue in a reentrant wave (i.e., wavelength lambda) and the reentrant path length. Because considerable evidence suggests that lambda changes continuously in space and time during abrupt rate changes associated with the onset of tachycardia, we hypothesized that beat-by-beat adaptation of A to the dimensions of the reentrant path plays a central role in the mechanism of initiation of reentry. METHODS AND RESULTS: To investigate the dynamic relationship between lambda and path length during initiation of reentry, optical mapping with voltage-sensitive dyes was used in a guinea pig model of reentrant ventricular tachycardia (VT). In this model, a computer-guided laser obstacle precisely controlled the position and dimensions of the reentrant path. Under control perfusion and after addition of 15 microM d-sotalol, lambda was monitored during steady-state pacing, premature stimulation, and the initiating beats leading to nonsustained and sustained VT. During control perfusion, reentrant VT was reproducibly induced in 8 of 8 hearts, whereas in the presence of d-sotalol, reentry could only be initiated in 1 of 8 hearts due primarily to the failure of lambda to adapt to the reentrant path length. During successful initiation of VT, a consistent sequence was observed. The sequence was characterized by antidromic and orthodromic propagation around both sides of the anatomic obstacle, followed by unidirectional block of the antidromic impulse and persistence of reentry only if the A of the orthodromic impulse adapted to the reentrant path (lambda < path length). d-Sotalol prevented initiation of VT by altering lambda adaptation of the orthodromic wave; however, it failed to terminate ongoing VT because reverse use-dependence developed after several beats of tachycardia. CONCLUSION: In an experimental model where lambda, path length, and cellular action potentials were monitored during initiation of reentry, we found that, in contrast to termination, the initiation of reentry and the transition from nonsustained to sustained VT is strongly dependent on beat-to-beat adaptation of lambda to the dimensions of the reentrant path.

Variability in surface ECG morphology: signal or noise?

Using data collected from canine models of acute myocardial ischemia, we investigated two issues of major relevance to electrocardiographic signal averaging: ECG epoch alignment, and the spectral characteristics of the beat-to-beat variability in ECG morphology. With initial digitization rates of 1 kHz, an iterative a posteriori matched filtering alignment scheme, and linear interpolation, we demonstrated that there is sufficient information in the body surface ECG to merit alignment to a precision of 0.1 msecs. Applying this technique to align QRS complexes and atrial pacing artifacts independently, we demonstrated that the conduction delay from atrial stimulus to ventricular activation may be so variable as to preclude using atrial pacing as an alignment mechanism, and that this variability in conduction time be modulated at the frequency of respiration and at a much lower frequency (0.02-0.03Hz). Using a multidimensional spectral technique, we investigated the beat-to-beat variability in ECG morphology, demonstrating that the frequency spectrum of ECG morphological variation reveals a readily discernable modulation at the frequency of respiration. In addition, this technique detects a subtle beat-to-beat alternation in surface ECG morphology which accompanies transient coronary artery occlusion. We conclude that physiologically important information may be stored in the variability in the surface electrocardiogram, and that this information is lost by conventional averaging techniques.

Cellular basis for dispersion of repolarization underlying reentrant arrhythmias.

Substantial heterogeneity in ion channel density and expression exists in cells isolated from various regions of the heart. Cell-to-cell coupling in the intact heart, however, is expected to attenuate the functional expression of the ion channel heterogeneities. Due to limitations of conventional electrophysiological recording techniques, the extent to which cellular electrical heterogeneities are functionally present in intact myocardium remains unknown. High-resolution optical mapping with voltage-sensitive dyes was used to measure transepicardial and transmural repolarization gradients in the Langendorff perfused guinea pig ventricle and the canine wedge preperation, respectively. Diversity of repolarization kinetics in the transepicardial direction modulated dispersion of repolarization in a biphasic fashion as premature coupling interval was shortened. Moreover, modulation of repolarization paralleled arrhythmia vulnerability in a predictable fashion. Transmural optical mapping revealed significant gradients of repolarization across the ventricular wall that were markedly increased in a surrogate model of LQTS. Transmural gradients of repolarization in LQTS were associated with an enhanced susceptibility to TdP. Therefore, despite strong cell-to-cell coupling in the normal heart, heterogeneities in the ionic make-up of cells across the epicardial and transmural surfaces result in functional heterogeneities of repolarization leading to arrhythmias.

Optical measurement of cell-to-cell coupling in intact heart using subthreshold electrical stimulation.

Electrical coupling between myocytes plays a critical role in propagation, repolarization, and arrhythmias. On the basis of predictions from cable theory, we hypothesized that the cardiac space constant (lambda) measured from the decay of subthreshold transmembrane potential (ST-Vm) in space would provide an index of regional cell-to-cell coupling in the intact heart. With the use of voltage-sensitive dyes, the distribution of ST-Vm was measured from hundreds of sites in close proximity to the site of subthreshold stimulation. lambda was calculated from the exponential decay of ST-Vm in space. Consistent with known directional differences in axial resistance, the spatial distribution of ST-Vm was strongly dependent on fiber orientation, because lambda was significantly (P < 0.001) longer along (1.5 +/- 0.1 mm) compared with across (0.8 +/- 0.1 mm) fibers. There was a close linear relationship (P < 0.001) between conduction velocity (CV) and lambda along all fiber angles tested. Reducing gap junctional conductance by heptanol reversibly decreased CV and lambda in parallel by approximately 50%. In contrast, sodium channel blockade by flecainide slowed CV by 40% but had no effect on lambda, reaffirming that lambda was an index of passive but not active membrane properties. These data establish the feasibility of measuring lambda as an index of cell-to-cell coupling in the intact heart, and indicate strong dependency of lambda on fiber orientation and pharmacological alterations of gap junction conductance.

Modulation of ventricular repolarization by a premature stimulus. Role of epicardial dispersion of repolarization kinetics demonstrated by optical mapping of the intact guinea pig heart.

Recent evidence suggests that ion channels governing the response of action potential duration (APD) to a premature stimulus (ie, APD restitution) are heterogeneously dispersed throughout the heart. However, because of limitations of conventional electrophysiological recording techniques, the effects of restitution in single cells on ventricular repolarization at the level of the intact heart are poorly understood. Using high-resolution optical mapping with voltage-sensitive dyes, we measured APD restitution kinetics at 128 simultaneous sites on the epicardial surface (1 cm2) of intact guinea pig hearts (n = 15). During steady state baseline pacing, APD gradients that produced a spatial dispersion of repolarization were observed. Mean APD was shortened monotonically from 186 +/- 19 ms during baseline pacing (S1-S1 cycle length, 393 +/- 19 ms) to 120 +/- 4 ms as single premature stimuli were introduced at progressively shorter coupling intervals (shortest S1-S2, 190 +/- 15 ms). In contrast, premature stimuli caused biphasic modulation of APD dispersion (defined as the variance of APD measured throughout the mapping field). Over a broad range of increasingly premature coupling intervals, APD dispersion decreased from 70 +/- 29 ms2 to a minimum of 10 +/- 7 ms2 at a critical S1-S2 interval (216 +/- 18 ms), and then, at shorter premature coupling intervals, APD dispersion increased sharply to 66 +/- 25 ms2. Modulation of APD dispersion by premature stimuli was attributed to coupling interval-dependent changes in the magnitude and direction of ventricular APD gradients, which, in turn, were explained by systematic heterogeneities of APD restitution across the epicardial surface. There was a characteristic pattern in the spatial distribution of cellular restitution such that faster restitution kinetics were closely associated with longer baseline APD. This relationship explained the reversal of APD between single cells, inversion of APD gradients across the heart, and ECG T-wave inversion during closely coupled premature stimulation. Therefore, because of the heterogeneous distribution of cellular restitution kinetics across the epicardial surface, a single premature stimulus profoundly altered the pattern and synchronization of ventricular repolarization in the intact ventricle. This response has important mechanistic implications in the initiation of arrhythmias that are dependent on dispersion of repolarization.