Interhemispheric and intrahemispheric language reorganization in complex partial epilepsy.

OBJECTIVE: To investigate interhemispheric and intrahemispheric reorganization in patients with localization-related epilepsy. METHOD: We studied 50 patients with a left hemispheric focus and 20 normal right-handed controls with a 3T echoplanar imaging blood oxygen level dependent functional MRI auditory-based word definition decision task. Data were analyzed using SPM 2. Using region of interest for Broca and Wernicke areas and an asymmetry index (AI), patients were categorized as left language (LL; AI > or = 0.20) or atypical language (AL; AI <0.20) for region. The point maxima activation for normal controls (p <0.05 corrected FDR) was identified in Broca and midtemporal regions and then used as a point of reference for individual point maxima identified at p < 0.001, uncorrected. RESULTS: Patient groups showed increased frequency of having activation in right homologues. Activation in AL groups occurred in homologous right regions; distances for point maxima activation in homologous regions were the same as point maxima distances in normal control activation in left regions. Distances for LL patient in left regions showed a trend for differences for midtemporal gyrus (6 mm posterior, 3 mm superior) but variability around mean difference distance was significant. There was no effect of age at epilepsy onset, duration, or pathology on activation maxima. CONCLUSIONS: Right hemisphere language regions in patients with left hemispheric focus are homologues of left hemisphere Broca and broadly defined Wernicke areas. We found little evidence for intrahemispheric reorganization in patients with left hemisphere epilepsy who remain left language dominant by these methods.

Limitations to plasticity of language network reorganization in localization related epilepsy.

Neural networks for processing language often are reorganized in patients with epilepsy. However, the extent and location of within and between hemisphere re-organization are not established. We studied 45 patients, all with a left hemisphere seizure focus (mean age 22.8, seizure onset 13.3), and 19 normal controls (mean age 24.8) with an fMRI word definition language paradigm to assess the location of language processing regions. Individual patient SPM maps were compared to the normal group in a voxel-wise comparison; a voxel was considered to be significant if its z-value exceeded mid R:2mid R:. Subsequently, we used principal component analysis with hierarchical clustering of variance patterns from individual difference maps to identify four patient sub-groups. One did not differ from normal controls; one had increased left temporal activation on the margin of regions activated in controls; two others had recruitment in right inferior frontal gyrus, middle frontal gyrus and temporal cortex. Right hemisphere activation in these two groups occurred in homologues of left hemisphere regions that sustained task activation. Our study used novel data driven methods to find evidence for constraints on inter-hemispheric reorganization of language in recruitment of right homologues, and, in a subpopulation of patients, evidence for intra-hemispheric reorganization of language limited to the margins of typical left temporal regional activation. These methods may be applied to investigate both normal and pathological variance in other developmental disorders and cognitive domains.

Atypical language in lesional and nonlesional complex partial epilepsy.

OBJECTIVE: We investigated the relationship between partial epilepsy, MRI findings, and atypical language representation. METHODS: A total of 102 patients (4 to 55 years) with left hemisphere epileptogenic zones were evaluated using three fMRI language tasks obtained at 1.5 or 3T with EPI BOLD techniques: verbal fluency, reading comprehension, and auditory comprehension. fMRI maps were visually interpreted at a standard threshold and rated as left or atypical language. RESULTS: Atypical language dominance occurred in 30 patients (29%) and varied with MRI type (p < 0.01). Atypical language representation occurred in 36% (13/36) with normal MRI, 21% (6/29) with mesial temporal sclerosis, 14% (4/28) with focal cortical lesions (dysplasia, tumor, vascular malformation), and all (6/6) with a history of stroke. Multivariate logistic regression analysis found handedness, seizure onset, and MRI type accounted for much of the variance in language activation patterns (chi(2) = 24.09, p < 0.01). Atypical language was more prevalent in patients with early seizure onset (43.2%, p < 0.05) and atypical handedness (60%, p < 0.01). None of the three clinical factors were correlated with each other (p > 0.40). Patients with atypical language had lower verbal abilities (F = 6.96, p = 0.01) and a trend toward lower nonverbal abilities (F = 3.58, p = 0.06). There were no differences in rates of atypical language across time, age groups, or MRI scanner. CONCLUSION: Early seizure onset and atypical handedness, as well as the location and nature of pathologic substrate, are important factors in language reorganization.

Seizure focus affects regional language networks assessed by fMRI.

OBJECTIVE: To investigate the degree of language dominance in patients with left and right hemisphere seizure foci compared to normal volunteers using a fMRI reading comprehension task. METHODS: Fifty patients with complex partial epilepsy, aged 8 to 56 years and 33 normal volunteers, aged 7 to 34 had fMRI (1.5 T) and neuropsychological testing. Participants silently named an object described by a sentence compared to a visual control. Data were analyzed with region of interest (ROI) analysis based on t maps for inferior frontal gyrus (IFG), midfrontal gyrus (MFG), and Wernicke area (WA). Regional asymmetry indices (AIs) were calculated [(L - R)/(L + R)]; AI > 0.20 was deemed left dominant and AI < 0.20 as atypical language. RESULTS: Left hemisphere focus patients had a higher likelihood of atypical language than right hemisphere focus patients (21% vs 0%, chi2 < 0.002). Left hemisphere focus patients, excluding those with atypical language, had lower regional AI in IFG, MFG, and WA than controls. Right hemisphere focus patients were all left language dominant and had a lower AI than controls in WA and MFG, but not for IFG. AI in MFG and WA were similar between left hemisphere focus/left language patients and right hemisphere focus patients. Patients activated more voxels than healthy volunteers. Lower AIs were attributable to greater activation in right homologous regions. Less activation in the right-side WA correlated with better verbal memory performance in right focus/left hemisphere-dominant patients, whereas less strongly lateralized activation in IFG correlated better with Verbal IQ in left focus/left hemisphere-dominant patients. CONCLUSIONS: Patients had lower asymmetry indices than healthy controls, reflecting increased recruitment of homologous right hemisphere areas for language processing. Greater right hemisphere activation may reflect greater cognitive effort in patient populations, the effect of epilepsy, or its treatment. Regional activation patterns reflect adaptive efforts at recruiting more widespread language processing networks that are differentially affected based on hemisphere of seizure focus.

Effects of acute global low-flow ischemia on triggered arrhythmias in d-sotalol-induced long Q-T intervals in perfused rabbit hearts.

Little information is available on how acute ischemia modifies the electrophysiologic substrate associated with long Q-T interval conditions. We studied the effects of low-flow ischemia (10 min at 5.0 ml/min followed by 10 min of 2.5 ml/min) in Langendorff perfused rabbit hearts during control and in hearts 20 min after the addition to the perfusate of 92 microM d-sotalol, which reliably produced triggered activity. Epicardial electrograms, a left ventricular endocardial monophasic action potential (MAP), and simulated X and Y lead electrocardiograms were used to characterize myocardial activation and recovery during ventricular pacing. In the control hearts, conduction velocity as indicated by the mean epicardial activation time accelerated for most of the period of ischemia (maximum decrease of -9.4 +/- 7.9%). The mean activation-recovery interval, MAP duration, and Q-T interval were moderately decreased (-4.9 +/- 8.6%, -7.5 +/- 4.4%, and -4.6 +/- 2.3%, respectively). The mean standard deviation of the activation-recovery interval (epicardial heterogeneity of recovery) was increased by 34.6 +/- 23.4%. d-Sotalol had no effect on conduction but prolonged myocardial recovery time, increased heterogeneity, and produced triggered arrhythmias in all hearts. Within 2 min of ischemia triggered activity was eliminated. With d-sotalol, ischemia slowed conduction and produced relatively larger decreases in the activation-recovery interval, MAP duration, and Q-T interval (-11.8 +/- 10.3%, -13.9 +/- 12.0%, and -15.8 +/- 11.2%). The increased epicardial heterogeneity seen with d-sotalol was attenuated by ischemia. Thus ischemia superimposed on long Q-T conditions had antiarrhythmic as well as arrhythmogenic effects.

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.

Modulation of arrhythmias by isoproterenol in a rabbit heart model of d-sotalol-induced long Q-T intervals.

Sympathetic influences have been implicated in arrhythmias associated with both congenital and acquired long Q-T intervals. We recorded epicardial electrograms, a left ventricular endocardial monophasic action potential (MAP), and a bipolar electrocardiogram in 23 isolated rabbit hearts. Spontaneous focal arrhythmias appeared within 8-18 min following 92 microM d-sotalol in 15 of 23 hearts. The epicardial activation-recovery interval was shorter at baseline and increased to a significantly greater degree after d-sotalol administration in the hearts that developed focal activity. The standard deviation of the activation-recovery interval of the epicardial sites also increased. With the addition of 0.01 microM isoproterenol, the incidence of focal activity increased, and its mean cycle length was shortened by 7%. Also, myocardial recovery time in the epicardium was shortened to a greater degree than the endocardial MAP duration. It did not alter local epicardial heterogeneity of recovery but did increase the regional dispersion between epicardial recovery times, and the endocardial MAP duration. Therefore, beta-adrenergic stimulation in the presence of d-sotalol favors the appearance of arrhythmias by increasing the propensity for closely coupled focal activity and the temporal dispersion of recovery.

Modulation of quinidine-induced arrhythmias by temperature in perfused rabbit heart.

We used low temperature to slow ion channel kinetics and studied the electrophysiological effects of quinidine at different pacing rates in isolated rabbit hearts. Fifteen epicardial electrograms together with an endocardial monophasic action potential were recorded. Epicardial activation and local recovery times were measured. Arrhythmias together with the characteristics of their mode of induction and rate were analyzed by epicardial activation sequence mapping. In the presence of quinidine, arrhythmias consistent with both triggered activity and reentry were observed. At baseline, triggered activity was not inducible, even though at 25 degrees C the recovery time was greater than that in the presence of quinidine at 36 degrees C. Also, with quinidine, the incidence of triggered activity decreased at 30 and 25 degrees C. Therefore prolongation of the recovery time per se does not cause triggered activity. Quinidine's use-dependent effects on conduction and reverse use-dependent effects on recovery time were amplified by low temperatures. These findings can be understood in terms of the known temperature sensitivities of the kinetics of the membrane ion channels responsible for activation and recovery. The results demonstrate that temperature can be used as a tool to elucidate mechanisms of drug action.

Modulation of procainamide's effect on conduction by cellular uncoupling in perfused rabbit hearts.

INTRODUCTION: How cell-to-cell electrical coupling influences an antiarrhythmic agent's effect on conduction is largely unknown. To investigate this, we evaluated the effects of procainamide on myocardial conduction at decreasing degrees of cell-to-cell electrical coupling induced by graded doses of heptanol. METHODS AND RESULTS: Electrograms were recorded from 50 ventricular epicardial sites in a 1 cm x 0.5 cm area during pacing to produce conduction longitudinal or transverse to myocardial fiber orientation in Langendorff-perfused rabbit hearts. The effects of procainamide (15 mg/L) on conduction velocity were determined in the presence of increasing doses of heptanol (0.2, 0.5, and 1.0 mM). In addition, using standard microelectrode techniques in isolated superfused rabbit myocardium, intracellular potentials were recorded in the presence of 15 mg/L procainamide and heptanol (1.0 mM). In the absence of heptanol, procainamide slowed conduction velocity. In the presence of increasing doses of heptanol, procainamide's contribution to the depressant effect on conduction velocity was attenuated and reversed at the highest dose. The latter effect was preferentially seen for conduction longitudinal to myocardial fiber orientation. Heptanol had no effect on action potential amplitude or maximum rate of depolarization in the presence of procainamide. CONCLUSIONS: Procainamide's effect on conduction velocity is influenced by the underlying degree of cell-to-cell electrical coupling. The present model should be useful in evaluating the relative ability of other pharmacologic agents to modulate conduction under conditions of changing cell coupling.

Effect of coronary perfusion of heptanol on conduction and ventricular arrhythmias in infarcted canine myocardium.

INTRODUCTION: Abnormal cellular coupling is a major constituent of the slow, dissociated conduction that supports ventricular tachycardia (VT) following myocardial infarction. Agents that modulate cellular coupling may exert either proarrhythmic or antiarrhythmic effects. METHODS AND RESULTS: The effects of modulating cellular coupling on conduction and susceptibility to inducible VT were studied in 11 dogs with healed left anterior descending (LAD) infarction. The LAD circulation was isolated and supplied with arterial blood via a constant-flow bypass system. Localized intracoronary infusion of heptanol, an agent with relatively specific effects on intracellular coupling, was performed using this bypass system. Heptanol produced dose-dependent changes in cardiac conduction, assessed by delayed local activation times in sinus rhythm (0.5 mM: 11.9% +/- 11.0% change, P = 0.005; 1.0 mM: 45.8% +/- 25.5% change, P = 0.0004) and slowed conduction velocity both transverse and longitudinal to fiber orientation. Sustained VT was not induced in any of the control animals. During infusion of 0.5 mM heptanol, uniform sustained VT was inducible in 4 of 11 animals (P = 0.027). During infusion of 1.0 mM heptanol, sustained VT was induced in only 1 of 9 animals. CONCLUSIONS: In the canine model of healed myocardial infarction, heptanol had a bimodal effect on susceptibility to inducible VT. Low-dose heptanol facilitated the induction of sustained VT, and high-dose heptanol had an antiarrhythmic effect. This suggests that agents that modulate coupling may significantly modify susceptibility to VT following myocardial infarction.

Mechanisms and models to predict a QTc effect.

Prolongation of the QT interval with consequent ventricular tachyarrhythmias may arise in the context of bradycardia (pause dependent) or may reflect sympathetic imbalances (adrenergic dependent). The normal repolarization process of ventricular myocardial cells is not entirely synchronous; some cells recover early and some later, resulting in a normal heterogeneity in refractoriness among ventricular cells during the inscription of the T wave. If the normal heterogeneity in ventricular repolarization is increased, as can occur following administration of some class IA and class III antiarrhythmic agents, then the QT interval will be prolonged. All-or-none action potentials can be evoked only in cells that have repolarized to a critical membrane potential of about -60 mV. Thus, the late-recovering cells (which terminate the T wave) may still be refractory and incapable of generating propagated action potentials while the early-recovering cells (which initiate the T wave) are fully excitable. In normal hearts, the period between repolarization of the earliest and the latest cells is insufficient to allow even very premature ventricular beats that occur early during the T wave (R-on-T phenomenon) to precipitate a sustained tachyarrhythmia. When the recovery process among ventricular cells becomes more inhomogeneous, however, as in the prolonged QT syndrome, the accompanying increased heterogeneity in ventricular repolarization and refractoriness can lead to the development of malignant ventricular arrhythmias, including torsades de pointes. Any drug that increases the dispersion of the repolarization process may prolong the QT interval and raise the potential for arrhythmias.(ABSTRACT TRUNCATED AT 250 WORDS)

"Supernormal" conduction and excitability.

Electrocardiographic manifestation of "supernormal" conduction is defined as conduction that is more rapid than expected or presence of conduction when block is anticipated. It is not supernormal in the sense or being more rapid than normal. Therefore, the term relative supernormality or "supernormality" is more appropriate. The mechanism of "supernormal" conduction is conduction during a period of supernormal excitability and conduction associated with altered membrane potential. Some of the more common phenomena that are not dependent on conduction during the supernormal period but manifest better than expected conduction, thus simulating "supernormal" conduction, include dual AV nodal conduction, the "gap" phenomenon, "peeling back" of the refractory period, summation of subthreshold responses, diastolic phase 4 depolarization, and phasic autonomic influences.

Electrophysiologic recovery in postischemic, stunned myocardium despite persistent systolic dysfunction.

Previous investigators have hypothesized that myocardial "stunning" may result either from a primary impairment in excitation or from electromechanical dissociation. Thrombolytic therapy and angioplasty have increased the importance of understanding the electrophysiologic effects of brief ischemia followed by reperfusion. We investigated the electrophysiologic properties of mechanically dysfunctional stunned myocardium in 18 dogs anesthetized with pentobarbital (30 mg/kg, intravenously administered). After thoracotomy, the proximal anterior descending coronary artery was occluded for 15 minutes, which was followed by 20 minutes of reperfusion. At baseline, peak ischemia, and 20 minutes of reperfusion, local electrogram durations, activation times, and refractory periods were measured from 12 standardized sites within the ischemic and border zones. Echocardiographic percentage of systolic wall thickening confirmed normal preischemic and markedly reduced postischemic function in the investigated region. Despite the marked electrophysiologic abnormalities observed in the ischemic zone during ischemia, mean electrogram duration, calculated conduction velocity, and mean effective refractory period after 20 minutes of reperfusion had returned almost to baseline values 39.2 +/- 11.5 msec versus 37.2 +/- 12.1 msec, 0.65 +/- 0.15 m/sec versus 0.68 +/- 0.15 m/sec, and 134 +/- 14 msec versus 131 +/- 8 msec, respectively. Corresponding mean values within the ischemic border zone were similarly close to baseline values after reperfusion. There was no significant difference in local heterogeneity (coefficient of variation) within the ischemic or border zone after reperfusion versus baseline values. Although the postischemic electrophysiologic status returned to normal, systolic thinning and dyskinesis persisted in the region of measurement. The contractile dysfunction that results from reperfusion-induced injury can thus occur in the setting of apparent excitation-contraction uncoupling.

Effect of coronary perfusion of heptanol or potassium on conduction and ventricular arrhythmias.

Abnormalities in cellular coupling, modulated in part by intracellular gap junctions, have an important role in the genesis of reentrant arrhythmias in the setting of chronic myocardial infarction. The effects of heptanol, which has a relatively selective action on gap junctional resistance at low concentrations, and potassium, which primarily affects active membrane properties, were assessed using a localized intracoronary infusion system in 11 normal dogs in vivo. Both agents caused a dose-related slowing of conduction. Programmed stimulation during potassium infusion resulted in ventricular fibrillation in two of six animals treated with a low dose (5.0-5.5 meq/l) and five of six animals treated with a high dose (7.0-7.5 meq/l). During the infusion of 1.0 mM heptanol, uniform ventricular tachycardia was induced in four of eight animals. Infusion of heptanol, but not potassium, increased the susceptibility to presumably reentrant ventricular tachycardia in normal myocardium. This suggests that agents that affect cellular coupling may have markedly different arrhythmogenic consequences than agents that primarily alter active membrane properties.

Gap junctional conductance in ventricular myocyte pairs isolated from postischemic rabbit myocardium.

Abnormalities of myocardial gap junction-mediated cell coupling have been implicated in cardiac arrhythmogenesis. The potential role of gap junctional dysfunction in the generation of reperfusion-induced arrhythmias is uncertain. The purpose of this study was to measure the effects of myocardial ischemia and reperfusion on gap junctional conductance (gj) between isolated ventricular myocytes. By using a new experimental model, myocyte pairs were isolated from Langendorff-perfused rabbit hearts 1) after 30 minutes of global normothermic ischemia followed by 30 minutes of reperfusion, 2) after 75 minutes of control perfusion, or 3) immediately after removal of the heart. Myocytes and myocyte pairs were studied using whole-cell recording techniques. Action potential characteristics of cells in all three groups were normal. Despite similar mean gj in all three groups (0.88 +/- 0.27, 1.15 +/- 0.18, and 1.24 +/- 0.25 microS, respectively; p greater than 0.05), the postischemic group was more widely distributed and had a significantly greater proportion of poorly communicating cell pairs than either control group (gj less than 25% of mean in eight of 15 myocyte pairs versus zero of 15 and one of 13, respectively; p less than 0.02). Thus, postischemic myocyte pairs represent a heterogeneous population of electrically coupled cells in which individual deficits in coupling are masked by a normal mean value. In the reperfused intact heart, local disturbances of cell coupling, similarly undetected by gross measures of conduction, could disrupt myocardial conduction and activation on a microscopic scale and thus enhance arrhythmogenicity.

Effect of cellular uncoupling by heptanol on conduction in infarcted myocardium.

Experiments were performed in vitro on six normal thin ventricular epicardial tissue strips and 10 strips removed from the infarcted regions of dogs 21-60 days after experimental myocardial infarction. Conduction was evaluated by mapping activation sequences at 40-45 sites over an area of 1 x 2 cm during pacing at a basic cycle length of 2,000 msec. The amplitude and length of recorded electrograms were also determined at each site. After control recordings, heptanol, which increases gap junctional resistance, was added to the tissue bath at concentrations ranging between 0.2 and 1.0 mM. In contrast to its effect on normal tissues, heptanol caused 75 of 260 previously active sites in the infarcted tissues to become inactive. The affected sites were located in areas of very slow conduction and/or adjacent to areas of preexisting conduction block. In addition, heptanol decreased the length and degree of fractionation of electrograms recorded in slowly conducting regions of the infarcted tissues. The magnitude of the decrease in electrogram length following heptanol was related to the degree of electrogram abnormality during control as reflected in the ratio of electrogram length to amplitude. Heptanol shortened electrograms by causing local conduction block, which eliminated some components of the fractionated electrograms. In an additional eight epicardial strips removed from the infarcted region, 0.5 mM heptanol had only a slight effect (10.7% decrease) on the maximum rate of membrane depolarization. Thus, heptanol does not act primarily by way of depressing the fast inward current. We conclude from heptanol's effects on conduction and electrogram characteristics that slow and dissociated conduction in the infarcted region is due to an abnormality in gap junctional distribution between surviving cells and/or an abnormality in individual gap junctional function.

Activation patterns in healed experimental myocardial infarction.

The maximum amplitude of vector loops formed by summing orthogonally recorded bipolar electrograms has been shown to reflect the direction of activation in cardiac muscle. To investigate whether components of vector loops could provide information about different activation directions in local areas of myocardium, we correlated "instantaneous vectors" with isochronal activation patterns in an in vitro preparation of experimental myocardial infarction. In thirteen 3 mm x 3 mm regions studied (from 11 tissues), at least 16 microelectrode impalements with a minimum density of 0.8 mm between sites were made. In seven situations in which notched, irregular, and prolonged duration electrograms were present, vector loops pointed in the same general direction throughout their entire time course. In these preparations, microelectrode impalements demonstrated only a single major direction of activation. In five of six areas in which multidirectional vector loops were present, two or more separate local directions of activation corresponded to the directions of the vector loop. Instantaneous vectors were then used to analyze propagation patterns in vivo in 10 animals with 2-4-week-old experimental myocardial infarction. Of 150 sites in the 10 animals, 13% contained more than one major local direction of activation. In 11 markedly abnormal sites, electrograms were recorded during pacing from four sites around the recording probe. When comparing electrogram characteristics from the four sites, a mean difference of 5.9 mV in electrogram amplitude and 19.1 msec in electrogram duration (coefficient of variation, 27% for amplitude and 22% for duration) was found. In only two of the 11 sites was it found that the same number of activation directions occurred from all pacing sites. We conclude: 1) Instantaneous components of vector loops accurately represent local directions of cardiac activation at differing times. 2) Most areas of experimental myocardial infarction have only one major direction of activation despite the presence of abnormal electrograms. 3) In some regions, however, two major local directions of activation can be identified within a relatively local area. 4) Geometric activation patterns in experimental myocardial infarction are markedly dependent on initial activation direction.

Electrophysiological studies on cardiac catheter ablation.

Clinical and animal investigations have pointed out that high energy electrical shocks are associated with the development of cardiac arrhythmias and with variable success in permanent ablation. The effects of electrode configuration and location on the size of the recorded electrogram was investigated to help explain variable catheter ablation results. We analyzed the cellular effects of catheter ablation shocks and found depression of resting potential, action potential amplitude, dV/dt and action potential duration. The most severe effects were noted with high current densities in tissues located between the cathode and anode. Damage was worse nearest the cathode. Similar cellular studies were completed using argon laser photoablation. Again, there was a decrease in resting potential, action potential amplitude and dV/dt. Laser energy led to a more focal region of myocardium void of action potentials and the border zone of injury was smaller. We also investigated the effects of lower energy shocks (1 to 10 joule) on cardiac tissues. Using microelectrodes, we observed that the membrane potential can "hang up" at the depolarized levels for varying periods of time and that conduction is altered during this membrane "hang-up" period. The duration and membrane hang-up level correlated with shock intensity and shock duration. Sequential shocks resulted in additive membrane "hang-up". We believe that membrane hang-up may be associated with brief arrhythmias observed following catheter ablation since conduction, refractoriness and excitability are all altered.

Interaction of fiber orientation and direction of impulse propagation with anatomic barriers in anisotropic canine myocardium.

We developed a computer model of the interaction of impulse propagation with anatomic barriers in uniformly anisotropic tissue. Its predictions were confirmed experimentally by using an in vitro cut to create a 6 X 1-mm anatomic barrier in 12 canine epicardial strips. The model predicted that long, thin barriers located parallel to the direction of impulse propagation would have little effect in delaying conduction regardless of the arrangement of cardiac fibers. In this situation, the mean experimental ratio of postcut to control conduction times across the barrier was 1.05:1.00 in 10 tissues. When impulses were proceeding perpendicular to an anatomic barrier, significant distal conduction delay was predicted and found to occur only when the conduction from pacing to recording sites was initially longitudinal to fiber orientation (mean experimental ratio, 2.34:1.00 in five tissues) but not transverse to fiber orientation (ratio, 1.08:1.00 in five tissues). We conclude that the direction of initial impulse propagation and the orientation of myocardial fibers have large effects on the degree to which anatomic barriers delay activation in cardiac tissue. These findings may have implications for the participation of anatomic barriers in reentrant circuits.