Measurement and monitoring of electrocardiogram belt tension in premature infants for assessment of respiratory function

BACKGROUND

Monitoring of the electrocardiogram (ECG) in premature infants with conventional adhesive-backed electrodes can harm their sensitive skin. Use of an electrode belt prevents skin irritation, but the effect of belt pressure on respiratory function is unknown. A strain gauge sensor is described which measures applied belt tension.

METHOD

The device frame was comprised of an aluminum housing and slide to minimize the device weight. Velcro tabs connected housing and slide to opposite tabs located at the electrode belt ends. The slide was connected to a leaf spring, to which were bonded two piezoresistive transducers in a half-bridge circuit configuration. The device was tested for linearity and calibrated. The effect on infant respiratory function of constant belt tension in the normal range (30 g-90 g) was determined.

RESULTS

The mechanical response to a step input was second order (fn = 401 Hz, zeta = 0.08). The relationship between applied tension and output voltage was linear in the range 25-225 gm of applied tension (r2 = 0.99). Measured device sensitivity was 2.18 mV/gm tension using a 5 V bridge excitation voltage. When belt tension was increased in the normal range from 30 gm to 90 gm, there was no significant change in heart rate and most respiratory functions during monitoring. At an intermediate level of tension of 50 gm, pulmonary resistance and work of breathing significantly decreased.

CONCLUSION

The mechanical and electrical design of a device for monitoring electrocardiogram electrode belt tension is described. Within the typical range of application tension, cardiovascular and respiratory function are not substantially negatively affected by electrode belt force.

Development of gradient descent adaptive algorithms to remove common mode artifact for improvement of cardiovascular signal quality

BACKGROUND

Common-mode noise degrades cardiovascular signal quality and diminishes measurement accuracy. Filtering to remove noise components in the frequency domain often distorts the signal.

METHOD

Two adaptive noise canceling (ANC) algorithms were tested to adjust weighted reference signals for optimal subtraction from a primary signal. Update of weight w was based upon the gradient term of the steepest descent equation: [see text], where the error epsilon is the difference between primary and weighted reference signals. nabla was estimated from Deltaepsilon(2) and Deltaw without using a variable Deltaw in the denominator which can cause instability. The Parallel Comparison (PC) algorithm computed Deltaepsilon(2) using fixed finite differences +/- Deltaw in parallel during each discrete time k. The ALOPEX algorithm computed Deltaepsilon(2)x Deltaw from time k to k + 1 to estimate nabla, with a random number added to account for Deltaepsilon(2) . Deltaw--> 0 near the optimal weighting.

RESULTS

Using simulated data, both algorithms stably converged to the optimal weighting within 50-2000 discrete sample points k even with a SNR = 1:8 and weights which were initialized far from the optimal. Using a sharply pulsatile cardiac electrogram signal with added noise so that the SNR = 1:5, both algorithms exhibited stable convergence within 100 ms (100 sample points). Fourier spectral analysis revealed minimal distortion when comparing the signal without added noise to the ANC restored signal.

CONCLUSIONS

ANC algorithms based upon difference calculations can rapidly and stably converge to the optimal weighting in simulated and real cardiovascular data. Signal quality is restored with minimal distortion, increasing the accuracy of biophysical measurement.

Heterogeneous gap junction remodeling in reentrant circuits in the epicardial border zone of the healing canine infarct☆

BACKGROUND

The epicardial border zone (EBZ) of surviving myocytes in the healing, 4- to 5-day-old canine infarct is an arrhythmogenic substrate characterized by both structural and functional remodeling of Cx43. Unknown is whether the remodeling of gap junction conductance is heterogeneous in the EBZ like that of sarcolemmal ion channel remodeling and how remodeling of the gap junction influences conduction and anisotropy.

METHODS AND RESULTS

Ventricular tachycardia was initiated by programmed stimulation in healing canine infarcted hearts. Reentrant circuits were mapped and the central common pathway (CCP) and outer pathway (OP) regions localized. Epimyocardium removed from the CCP was disaggregated to generate myocyte pairs for conductance measurements. Cx43 distribution was determined by immunofluorescent confocal microscopy. While transverse coupling (gap junction conductance) was markedly decreased in OP cells, CCP cells with lateralized Cx43 gap junctions showed normal conductance. Longitudinal coupling in both OP and CCP was no different than normal. Consistent with conductance measurements, the anisotropic ratio in the CCP was similar to that of normal tissue. In the OP it was increased. Despite normal longitudinal and transverse conductance and anisotropic ratio, longitudinal and transverse conduction velocities were decreased in the CCP with respect to normal epicardium, possibly as a result of the remodeling of sarcolemmal ion channels in this region.

CONCLUSIONS

Gap junction conductance and distribution is heterogeneous in different regions of reentrant circuits. Lateralization of Cx43 gap junctions in CCP of reentrant circuits is associated with normal transverse conductance between cell pairs. In contrast, absence of lateralization in OP is associated with reduced transverse conductance. Despite normal anisotropic ratio, conduction velocity in CCP region remains slower than normal. This suggests that the effects of Cx43 remodeling in the infarcted heart should be interpreted in conjunction with other types of remodeling occurring in the EBZ (i.e. sarcolemmal ion channels).

Multichannel data acquisition system for mapping the electrical activity of the heart

BACKGROUND

Details of the electrical conduction pattern of the heart are revealed to the electrophysiologist when multichannel data are used for activation mapping. Commercial electronic systems are available for simultaneous acquisition of many surface electrograms; however, the cost of these systems may be prohibitive and they can be mostly inflexible for adaptation to other research projects. Furthermore, the hardware and software design is often proprietary. In this article we describe the in-house design and implementation of a 320-multichannel acquisition system for animal electrophysiologic research.

METHOD AND RESULTS

Several modules comprise this system. The multichannel data are first preprocessed by amplification, filtering, and analog multiplexing. An algorithm for automatic adjustment of signal gains is implemented to maximize the voltage resolution and minimize noise pickup. Signals are then digitized, and sequenced to order the multichannel data and to add markers required for analysis. The digital data are streamed to archival storage media. Additionally, the electrocardiogram (ECG), blood pressure, and stimulus channel signals are stored simultaneously. Selected signals are then displayed in real-time for measurement and analysis and as a check of the system integrity. Examples of multielectrode arrays and surface recordings are provided. Costs for building such a system are estimated.

CONCLUSIONS

Multichannel data acquisition systems that are designed and constructed in-house have several advantages over turnkey commercial systems, including the potential for considerable cost savings, flexibility in acquiring data, and the ability to subsequently add additional components.

Method to Predict Isthmus Location in Ventricular Tachycardia Caused by Reentry with a Double-Loop Pattern

BACKGROUND

During electrophysiologic study, induction and mapping of clinical reentrant ventricular tachycardia can be difficult. Hence, analysis of sinus-rhythm electrograms for reentry localization is of potential clinical relevance. Herein is described a method of sinus-rhythm electrogram shape analysis, that does not require arbitrary threshold values, for localization of double-loop reentrant circuits that drive clinical tachycardias.

METHODS AND RESULTS

Reentrant ventricular tachycardia was induced by premature stimulation in 23 postinfarction canine hearts 4-5 days after left anterior descending (LAD) ligation. Sinus-rhythm activation maps were constructed from bipolar electrograms acquired at 196-312 sites in the epicardial border zone. The timing of all electrogram peak deflections during one cycle of sinus rhythm was determined, and the mean (MPD) and deviation (DPD) were taken, respectively, as estimates of the time of activation wavefront crossing, and the duration of local electrical activity. These variables were then mapped on a computerized grid. The line of most uniform and sharp MPD gradient predicted the propagation direction through the double-loop reentrant circuit isthmus that would occur upon tachycardia induction. The sharpest transitions in DPD bounding this line predicted the positions of arcs of block that would border the reentrant circuit isthmus during tachycardia. The actual and estimated isthmuses overlapped by a mean of 84.1 +/- 3.8%. In six experiments lacking inducible reentrant tachycardia, no line of sharp MPD gradient was present in the MPD maps.

CONCLUSIONS

Analysis of multiple sinus-rhythm deflections can localize the reentrant ventricular tachycardia isthmus without introduction of arbitrary threshold points and peak choices that may lead to error.

Ventricular Tachycardia Duration and Form Are Associated with Electrical Discontinuities Bounding the Core of the Reentrant Circuit

BACKGROUND

Successful prediction of reentrant ventricular tachycardia duration and form from sinus-rhythm electrogram signals in canine hearts is relevant to clinical studies, to potentially improve catheter ablation treatment during EP study.

METHODS/RESULTS

Following LAD ligation of canine hearts, activation maps were constructed from 312 border zone sites 4-5 days postinfarction. When reentrant ventricular tachycardia was inducible via programmed stimulation, the core of the circuit was defined on the maps as the enclosed area formed by the adjoining lines of slowest conduction and block bounding the protected region of the reentrant circuit. The number, location, and width of points of entrance or exit of the activation wavefront about the core were determined. Core perimeter location was then marked on the sinus-rhythm activation map, and the difference in activation time at opposite recording sites along the core perimeter was measured. Mean sinus-rhythm activation was highly discontinuous along the core perimeter in 10 transient reentry experiments (30.1 +/- 4.4 ms), moderately discontinuous in 13 sustained experiments (16.7 +/- 1.8 ms), and only slightly discontinuous in 5 noninducible experiments (9.7 +/- 1.7 ms). For transient versus sustained experiments, the entrance/exit points were narrower (mean: 6.5 +/- 1.0 mm vs 9.5 +/- 1.8 mm) with larger sinus-rhythm discontinuity across them (mean: 23.8 +/- 6.0 ms vs 11.8 +/- 2.1 ms). As core size increased, so did the number of entrance/exits present during reentry (P < 0.001). With increasing core size, four-loop (quatrefoil) reentry was frequently observed.

CONCLUSIONS

Whether reentrant ventricular tachycardia will be inducible in the canine infarct border zone, and its duration and form, is associated with the characteristics of electrical discontinuities present about the core perimeter.

Sinus Rhythm Electrogram Shape Measurements are Predictive of the Origins and Characteristics of Multiple Reentrant Ventricular Tachycardia Morphologies

INTRODUCTION

During clinical electrophysiologic study, multiple clinical tachycardia morphologies often can be induced in the infarct border zone, and all morphologies must be targeted for ablation therapy to be successful. Analysis of sinus rhythm electrogram shape for localizing figure-of-eight reentrant circuits in cases of multiple morphologies is proposed.

METHODS AND RESULTS

Sinus rhythm activation maps were constructed from bipolar electrograms acquired at 196 to 312 sites in the epicardial border zone in 10 postinfarction canine hearts. In each heart, at least two distinct figure-of-eight reentrant ventricular tachycardia morphologies were inducible by premature electrical stimulation, as determined by activation maps of sustained tachycardias. Sinus rhythm maps were used to predict the location of the isthmus (central common pathway [CCP]), which is the protected region of the circuit bounded by arcs of block (mean accuracy 76.7 +/- 4%). Although reentrant circuits differed, the positions of the entrance point of each CCP were common. The location of the line that would span the CCP at its narrowest width also was estimated (mean accuracy 91.3 +/- 5%). Ablation at this line is expected to prevent reentry recurrence. In one test experiment, ablation prevented recurrence of both sustained reentrant tachycardia morphologies.

CONCLUSION

Sinus rhythm electrogram analyses are useful for (1) localizing multiple reentrant circuits with differences in morphology that are inducible by premature stimulation in the infarct border zone, and (2) locating and orienting the position of a linear lesion for preventing recurrence of all morphologies with minimal damage to the heart.

Localization of the isthmus in reentrant circuits by analysis of electrograms derived from clinical noncontact mapping during sinus rhythm and ventricular tachycardia

INTRODUCTION

New methods for electrogram analysis accurately estimated reentrant circuit isthmus location and shape in a canine model. It was hypothesized that these methods also would locate reentrant circuits causing clinical ventricular tachycardia (VT).

METHODS AND RESULTS

Intracardiac electrogram recordings, obtained with a noncontact mapping system, were analyzed retrospectively from 14 patients with reentrant VT who had undergone successful radiofrequency ablation for prevention of VT initiation. Unipolar electrograms from 256 uniformly distributed endocardial sites were reconstructed by mathematical transformation. Twenty-seven tachycardias were mapped; 15 (in 11 patients) had a complete endocardial reentrant circuit with a figure-of-eight conduction pattern. During sinus rhythm, the location and axis of the slowest and most uniform conduction in the region of latest endocardial activation (the primary axis), the limits of which were defined as boundaries with >15 ms difference in electrogram duration between contiguous recordings, identified the location and shape of the reentrant circuit isthmus with a mean sensitivity compared with activation mapping of 79.3% and a mean specificity of 97.6%. The midpoint of a theoretical "estimated best ablation line" drawn perpendicular to the primary axis of activation, spanning the estimated isthmus location was within 1.3 +/- 0.2 cm (mean distance +/- SD) of the actual ablation site that terminated tachycardia. Analysis of VT electrograms, based on time shifts in the far-field component of the local electrogram when cycle length changed (piecewise linear adaptive template matching [PLATM] method) in 5 of the cases, accurately estimated the time interval between activation at the recording site and the circuit isthmus slow conduction zone where the effective ablation lesion had been placed, which is proportional to the distance between the two locations (mean difference compared with activation mapping: +/-37.3 ms).

CONCLUSION

In selected patients with VT who have a complete endocardial circuit, isthmus location and shape can be discerned by analysis of sinus rhythm or tachycardia electrograms, and an effective ablation site can be predicted without the need to construct activation maps of reentrant circuits.

Optimized region finding and edge detection of knee cartilage surfaces from magnetic resonance images

Expert hand-drawing of magnetic resonance image (MRI) features can be tedious and time consuming. MRI of the knee were acquired from eight subjects to develop an automated segmentation approach. The regions of interest (ROI) were femur, tibia, and patella cartilage. The Karhunen-Loeve transformation was used to construct prototypical ROI with accentuated features and reduced noise level. Adaptive template matching was then used to translate the prototypical ROI locations for detection and optimal overlap of ROI in test images. Cartilage boundaries at the optimal overlap area were computed based on standard gradient methods.

Isochronal difference mapping: an approach for mapping dynamic changes during reentrant ventricular tachycardia

During clinical electrophysiological study for treatment of reentrant ventricular tachycardia, activation maps constructed from the acquired electrophysiological data can be difficult to interpret when the reentrant circuit is changing from one cardiac cycle to the next. Reduction of complexity would be beneficial but has been difficult. A new technical method termed isochronal difference mapping (IDM) was devised to reduce complexity and enhance distinctive conduction patterns present in the data. Electrograms were acquired from 196 sites using a canine model of a reentrant ventricular tachycardia circuit with a figure eight conduction pattern occurring in the epicardial border zone. Activation maps were constructed for all cardiac cycles during episodes of tachycardia in five experiments. IDM maps were then created, which are subtractive comparisons of the activation maps from two different cardiac cycles during a given tachycardia episode. In each map the electrical activation occurring for only one or for both of the cardiac cycles was separately highlighted in distinct spatial areas of the border zone during an isochronal interval. Based on the mappings, areas of conduction velocity change, regions of breakthrough of the wavefront across functional lines of block, regions with coherent activation, and regions with irregular activation became readily apparent. IDM maps showed that when cycle length prolonged due to deceleration of conduction within the reentrant circuit isthmus, conduction velocity increased elsewhere in the circuit. IDM accentuates cycle-to-cycle differences in multi-channel electrophysiological data and can be used to reduce complexity and enhance distinctive conduction patterns.

Premature excitation and onset of reentrant ventricular tachycardia

It was hypothesized that quantitative sinus rhythm electrogram measurements could be used to predict conduction events that result from premature stimulation and reentrant ventricular tachycardia inducibility. Sinus rhythm activation and electrogram-duration maps were constructed from bipolar electrograms acquired at 196-312 sites in the epicardial border zone of 43 canine hearts (25 with and 18 without reentrant ventricular tachycardia inducible by premature stimulation). From these maps, lines of electrical discontinuity, where blocks would occur during premature excitation, were estimated. The mean error in distance between the estimated and actual block lines of premature excitation was 0.97 +/- 0.49 cm. Based on the quantitative characteristics of the activation and electrogram-duration maps and the longest block line that formed during premature excitation, it was possible to predict whether reentry would occur (sensitivity, 94.7%; specificity, 79.6%). In reentry experiments, the breakthrough-point location along the unidirectional arc of the block that initiated reentry was also predictable (mean error, 0.79 +/- 0.19 cm). Sinus rhythm measurements are useful to predict conduction events that result from premature stimulation and reentry inducibility.

Static relationship of cycle length to reentrant circuit geometry

BACKGROUND

Knowledge of the pathway common to both wave fronts in figure-8 reentrant circuits (ie, the isthmus) is of importance for catheter ablation to stop reentrant ventricular tachycardia. It was hypothesized that quantitative measures of reentry isthmus geometry were interrelated and could be correlated with tachycardia cycle length.

METHODS AND RESULTS

A canine infarct model of reentrant ventricular tachycardia in the epicardial border zone with a figure-8 pattern of conduction was used for initial analysis (experiments in 20 canine hearts with monomorphic reentry). Sinus-rhythm and reentry activation maps were constructed, and quantitative (skeletonized) geometric parameters of the isthmus and border zone were measured from the maps. Regression equations were used to determine significant correlation relationships between skeletonized variables, which can be described as follows. Tachycardia cycle length, measured from the ECG R-R interval, increases with increasing isthmus length, width, narrowest width, angle with respect to muscle fibers, and circuit path length determined by use of sinus-rhythm measurements. After this procedure, in 5 test-set experiments, tachycardia cycle length measured from the R-R interval, in combination with regression coefficients calculated from initial experiments, correctly predicted isthmus geometry (mean estimated/actual isthmus overlap 70.5%). Also, the circuit path length determined with sinus-rhythm measurements correctly estimated the tachycardia cycle length (mean error 6.2+/-2.5 ms).

CONCLUSIONS

Correlation relationships derived from measurements using reentry and sinus-rhythm activation maps are useful to assess isthmus geometry on the basis of tachycardia cycle length. Such estimates may improve catheter ablation site targeting during clinical electrophysiological study.

Relationship between sinus rhythm activation and the reentrant ventricular tachycardia isthmus

BACKGROUND

In canine hearts with inducible reentry, the isthmus tends to form along an axis from the area of last to first activity during sinus rhythm. It was hypothesized that this phenomenon could be quantified to predict reentry and the isthmus location.

METHODS AND RESULTS

An in situ canine model of reentrant ventricular tachycardia occurring in the epicardial border zone was used in 54 experiments (25 canine hearts in which primarily long monomorphic runs of figure-8 reentry were inducible, 11 with short monomorphic or polymorphic runs, and 18 lacking inducible reentry). From the sinus rhythm activation map for each experiment, the linear regression coefficient and slope were calculated for the activation times along each of 8 rays extending from the area of last activation. The slope of the regression line for the ray with greatest regression coefficient (called the primary axis) was used to predict whether or not reentry would be inducible (correct prediction in 48 of 54 experiments). For all 36 experiments with reentry, isthmus location and shape were then estimated on the basis of site-to-site differences in sinus rhythm electrogram duration. For long and short runs of reentry, estimated isthmus location and shape partially overlapped the actual isthmus (mean overlap of 71.3% and 43.6%, respectively). On average for all reentry experiments, a linear ablation lesion positioned across the estimated isthmus would have spanned 78.2% of the actual isthmus width.

CONCLUSIONS

Parameters of sinus rhythm activation provide key information for prediction of reentry inducibility and isthmus location and shape.

Dynamic relationship of cycle length to reentrant circuit geometry and to the slow conduction zone during ventricular tachycardia

BACKGROUND

Knowledge of cycle-to-cycle changes in isthmus geometry is of potential importance for radiofrequency catheter ablation to stop reentrant ventricular tachycardia. It was hypothesized that isthmus geometry often undergoes continuous evolution throughout reentry and that cycle-length variability measurements could be used to segment reentry into distinct phases and to predict changes in isthmus geometry.

METHODS AND RESULTS

A canine infarct model of reentrant ventricular tachycardia in the epicardial border zone with a figure 8 pattern of conduction was used for analysis (25 monomorphic reentry episodes, 20 experiments). Tachycardias were segmented, on the basis of cycle-length variations, into 2 to 3 distinct phases corresponding to onset, maintenance, and spontaneous termination, when it occurred (6/25 episodes). Trends of linear cycle-length change occurred throughout the maintenance phase in all tachycardias. For each trend, quantitative geometric parameters of the isthmus were measured, and the following linear relationships were established. During a trend, the slow conduction zone activation interval and tachycardia cycle length increased, while isthmus length decreased. When isthmus length decreased, isthmus width decreased at its narrowed portion. Larger decreases in isthmus length corresponded to higher rates of linear cycle-length prolongation. Also, greater cycle-length variability tended to prolong tachycardia.

CONCLUSIONS

Cycle-length alterations occur throughout reentry in this canine model and are predictive of isthmus geometry changes. Because similar reentry dynamics, which affect catheter ablation efficacy, have been observed clinically, estimation of changes in geometry during electrophysiological study may help target ablation sites.

Localization of the slow conduction zone during reentrant ventricular tachycardia

BACKGROUND

Reentrant ventricular tachycardia is sometimes difficult to treat effectively because localizing the slow conduction zone (SCZ) for catheter ablation may be problematic. It was hypothesized that a linear relationship exists between activating wave-front acceleration and deceleration in the SCZ and, respectively, contractions and expansions of the far-field extracellular signal, which could be used for SCZ localization.

METHODS AND RESULTS

To test the hypothesis, a model was developed to approximate SCZ location on the basis of the time interval between activation at the recording site and shifts in electrogram far-field deflections. Electrograms were recorded during reentry from 196 to 312 epicardial sites (canine model, 8 episodes). Activation maps of reentry were constructed to determine wave-front velocity, and piecewise linear adaptive template matching (PLATM) measured time shifts in far-field electrogram deflections. Linear trends of cycle length change often occurred during tachycardia (mean trend, +15 ms/96.8 cardiac cycles; r(2)=0.92). Alteration in the time interval for activation through the SCZ approximated the change in tachycardia cycle length (mean correspondence, 75.7%). The beginning and end times of far-field extracellular waveform time shifts measured by PLATM predicted the time from recording site activation to activation at the SCZ proximal and distal edges, respectively (mean absolute error with respect to activation mapping, 20.3 ms).

CONCLUSIONS

During reentry, PLATM estimates the time interval from activation at any recording site near the circuit to SCZ activation. PLATM time intervals are convertible to arc lengths along the circuit for potentially more rapid and accurate update of a hand-held probe toward the SCZ for catheter ablation.

Relationship of specific electrogram characteristics during sinus rhythm and ventricular pacing determined by adaptive template matching to the location of functional reentrant circuits that cause ventricular tachycardia in the infarcted canine heart

INTRODUCTION

It would be advantageous, for ablation therapy, to localize reentrant circuits causing ventricular tachycardia by quantifying electrograms obtained during sinus rhythm (SR) or ventricular pacing (VP). In this study, adaptive template matching (ATM) was used to localize reentrant circuits by measuring dynamic electrogram shape using SR and VP data.

METHODS AND RESULTS

Four days after coronary occlusion, reentrant ventricular tachycardia was induced in the epicardial border zone of canine hearts by programmed electrical stimulation. Activation maps of circuits were constructed using electrograms recorded from a multichannel array to ascertain block line location. Electrogram recordings obtained during SR/VP then were used for ATM analysis. A template electrogram was matched with electrograms on subsequent cycles by weighting amplitude, vertical shift, duration, and phase lag for optimal overlap. Sites of largest cycle-to-cycle variance in the optimal ATM weights were found to be adjacent to block lines bounding the central isthmus during reentry (mean 61.1% during SR; 63.9% during VP). The distance between the mean center of mass of the ten highest ATM variance peaks and the narrowest isthmus width was determined. For all VP data, the center of mass resided in the isthmus region occurring during reentry.

CONCLUSION

ATM high variance measured from SR/VP data localizes functional block lines forming during reentry. The center of mass of the high variance peaks localizes the narrowest width of the isthmus. Therefore, ATM methodology may guide ablation catheter position without resorting to reentry induction.

Dynamic changes in electrogram morphology at functional lines of block in reentrant circuits during ventricular tachycardia in the infarcted canine heart: a new method to localize reentrant circuits from electrogram features using adaptive template matching

INTRODUCTION

Fractionated, low-amplitude or long-duration electrograms have limited specificity for locating reentrant circuits causing ventricular tachycardia (VT). In this study a new method is described, adaptive template matching (ATM), based on the quantification of beat-to-beat changes in electrograms, for locating functional reentrant circuits that are relatively stable and cause monomorphic VT.

METHODS AND RESULTS

Monomorphic VTs were induced in 4-day-old infarcted canine hearts by programmed stimulation and reentrant circuits mapped in the epicardial border zone with a 196 or 312 bipolar electrode array. For ATM analysis, a template electrogram from each electrode, during an early cycle, was matched with all subsequent (input) electrograms at the same site by weighting the inputs of amplitude, duration, average baseline, and phase lag. The mean square error (MSE) between template and input was the criterion used to adapt the weights, and was also a measure of changes in electrogram shape that occur from cycle to cycle. The variance of each of the weighting parameters at all electrode sites were plotted on a representation of the electrode array, and the location of the functional lines of block bounding the central common pathway of reentrant circuits with figure-of-eight characteristics, overlaid on the ATM map. Peaks of high variance were found to be coincident with functional lines of block during all tachycardia episodes.

CONCLUSION

Specific beat-to-beat changes in electrograms occur at functional lines of block in reentrant circuits that can be quantified by ATM analysis, suggesting that these regions might be located without activation mapping. The method might be useful to guide ablation catheter position.

Knee cartilage topography, thickness, and contact areas from MRI: in-vitro calibration and in-vivo measurements

OBJECTIVE

This study assessed the three-dimensional accuracy of magnetic resonance imaging (MRI) for measuring articular surface topographies and cartilage thicknesses of human cadaveric knee joints, by comparison with the calibrated stereophotogrammetric (SPG) method.

METHODS

Six fresh frozen cadaveric knees and the knees of four volunteers were imaged with a three-dimensional spoiled gradient-recalled acquisition with fat suppression using a linear extremity coil in a 1.5 T superconducting magnet. The imaging voxel size was 0.47 x 0.47 x 1.0 mm. Both a manual and a semi-automated segmentation method were employed to extract topographic measurements from MRI. Following MRI, each of the six cadaveric knees was dissected and its articular surfaces quantified using stereophotogrammetry. The MRI surface measurements were compared numerically with the SPG measurements.

RESULTS

For six cadaveric knees, the average accuracies of cartilage and subchondral bone surface measurements were found to be 0.22 mm and 0.14 mm respectively and the thickness measurements demonstrated an average accuracy of 0.31 mm. It was found that while most of the error may be attributed to random measurement error, the accuracy was somewhat affected by systematic errors. For each bone of the knee, accuracies were most favorable in the patella, followed by the femur and then the tibia. The more efficient semi-automated method provided equally good and sometimes better accuracies than manual segmentation.

CONCLUSIONS

This study demonstrates that clinical MRI can provide accurate measurements of cartilage topography, thickness, contact areas and surface curvatures of the knee.

Mechanisms causing sustained ventricular tachycardia with multiple QRS morphologies: results of mapping studies in the infarcted canine heart

BACKGROUND

Sustained reentrant ventricular tachycardias (VTs) with different QRS morphologies have been observed to occur spontaneously and during programmed stimulation in human hearts. We determined mechanisms that can cause tachycardias with multiple morphologies in a canine model of myocardial infarction by mapping reentrant circuits.

METHODS AND RESULTS

Reentrant VT with multiple QRS morphologies was induced in 11 canine hearts with 4-day-old infarcts. Comparison of activation maps of the reentrant circuits in the epicardial border zone associated with each morphology indicated two basic mechanisms. Less frequently, VTs of different morphologies in the same heart were caused by reentrant circuits in different regions of the infarct. Most commonly, the reentrant circuits associated with different morphologies were in the same region. Three different factors caused different exit routes from circuits in the same region, leading to the multiple morphologies. (1) The reentrant wave front for each morphology rotated around the same line of block but in different directions. (2) Reentrant circuits associated with each morphology were similar, but there were small changes in the extent of the central line of block. (3) Reentrant circuits with completely different sizes and shapes caused different morphologies.

CONCLUSIONS

In this canine model, tachycardias with multiple morphologies most commonly arise from reentrant circuits in the same region of the infarct, suggesting that most often only one area has electrophysiological properties necessary to sustain reentry.

Prediction of the location and time of spontaneous termination of reentrant ventricular tachycardia for radiofrequency catheter ablation therapy

Ventricular tachycardia caused by reentrant excitation can lead to cardiac arrest and sudden death. Drug treatment and surgical procedures have been used with limited effectiveness. Catheter ablation methods are more promising because they are less invasive than surgery. Although ablation has come to be highly effective in the treatment of supraventricular tachycardias, the overall success rate remains low for ventricular tachycardias, which may be due in part to an inaccurate localization of the reentrant pathway. The authors hypothesize that a site in the myocardium exists that is critical for the maintenance or reentry and that when ablated, will result in permanent cessation of the tachycardia. The authors also hypothesize that this is the same site where the reentrant impulse blocks during spontaneous termination of tachycardia. A series of experiments has been designed to determine if there are specific properties of extracellular electrograms recorded from reentrant circuits that would enable the circuits to be identified without activation maps and, more specifically, allow the site of block causing spontaneous termination to be localized. For quantitative analysis of electrograms, a paradigm is developed to characterize electrogram morphology using a canine infarct model. Changes in morphology (shape, size, and location of signal deflections) can be considered (1) motions of a coordinate system and/or (2) conformational changes of shape. To a first approximation, stationarity over short time segments is assumed so that the motions and conformations can be parameterized. These parameters were extracted for 50 cardiac cycles during an episode of nonsustained ventricular tachycardia, in which 196-bipolar electrode pairs were positioned in an array format across the epicardial surface of the heart. The results of these studies of changes in electrogram morphology suggest that during cycles 5 to 49 of ventricular tachycardia, in many electrograms near the circuit, the cycle length increases linearly, the amplitude increases, and the duration of activation decreases. During cycles 50 to 54, the cycle length increases much more markedly, the amplitude decreases, and the duration of activation increases. These observations suggest that cycle lengthening may be an important property of some spontaneous terminations, and moreover that other morphologic characteristics are affected differently at different stages of cycle lengthening. Further, all motion parameters tended to oscillate from cycle to cycle in either an alternans pattern or longer oscillation. The variations in morphology were typically only a few percent from cycle to cycle. Such variability would not be evident using only ruler-and-caliper measurements made by hand because of the lack of precision and the sheer volume of data. It is expected that this approach for characterization of electrogram morphology will be extremely useful clinically to (1) increase speed and accuracy of ablation site selection and (2) reduce multichannel electrogram recording complexity during ablation site selection.

Localized spatial discrimination of epicardial conduction paths after linear transformation of variant information

We present a method for the localized statistical discrimination of class populations based on the Karhunen-Loève and Fukunaga-Koontz transforms. These transforms provide features that model the variance of a sample distribution. The spatial series of a 196 channel epicardial electrogram recording from an arrythmogenic postinfarct canine were analyzed. For each type of rhythm studied, Karhunen-Loève and Fukunaga-Koontz expansions were computed from five training sets of spatial data, corresponding to five locations across the surface of the heart. Nonparametric statistical tests were then used for discriminant analysis to compare properties representative of the distribution from each proposed class. In a comparison of properties from sinus rhythm to those of two ventricular tachycardias, several spatial regions exhibited statistically significantly different propagation characteristics. These areas were observed by visual inspection of electrogram activation maps to be characterized by conductive gradients, which differed in magnitude and direction from one rhythm to another. The regions in which the propagation characteristics are of greatest difference in each tachycardia were centered upon sites of conduction block, manifested by reentrant circuit rhythms. Therefore, the importance of the technique for the localization of specific electrophysiologic events is demonstrated. This study extends previous work of our group on biosignal pattern recognition to encompass localized spatial data.

Pattern recognition and interpretation of electromyogram data from cat jaw muscle

This study investigates the effect of emotional behavior on the masseteric muscle EMG response patterns. Two experimental protocols are utilized: (1) does not elicit emotional behavior (stick chewing) and (2) elicits emotional behavior (hypothalamic stimulation). The Karhunen-Loève transform is used to compute features which exactly represent the correlated patterns of mean-zero observations, with data compression and noise immunity. Using nonparametric tests, it is found that the populations of biting and hissing features are significantly different (p < 0.05), with increased statistical significance as the size of the training set is increased. No statistically significant difference is seen in a test of the two biting populations.