Microwave ablation of myocardial tissue: the effect of element design, tissue coupling, blood flow, power, and duration of exposure on lesion size

Irrigated Microwave Catheter Ablation Can Create Deep Ventricular Lesions Through Epicardial Fat With Relative Sparing of Adjacent Coronary Arteries

BACKGROUND

Radiofrequency ablation depth can be inadequate to reach intramural or epicardial substrate, and energy delivery in the pericardium is limited by penetration through epicardial fat and coronary anatomy. We hypothesized that open irrigated microwave catheter ablation can create deep myocardial lesions endocardially and epicardially though fat while acutely sparing nearby the coronary arteries.

METHODS

In-house designed and constructed irrigated microwave catheters were tested in in vitro phantom models and in 15 sheep. Endocardial ablations were performed at 140 to 180 W for 4 minutes; epicardial ablations via subxiphoid access were performed at 90 to 100 W for 4 minutes at sites near coronary arteries.

RESULTS

Epicardial ablations at 90 to 100 W produced mean lesion depth of 10±4 mm, width 18±10 mm, and length 29±8 mm through median epicardial fat thickness of 1.2 mm. Endocardial ablations at 180 W reached depths of 10.7±3.3 mm, width of 16.6±5 mm, and length of 20±5 mm. Acute coronary occlusion or spasm was not observed at a median separation distance of 2.7 mm (IQR, 1.2-3.4 mm). Saline electrodes recorded unipolar and bipolar electrograms; microwave ablation caused reductions in voltage and changes in electrogram morphology with loss of pace-capture. In vitro models demonstrated the heat sink effect of coronary flow, as well as preferential microwave coupling to myocardium and blood as opposed to lung and epicardial fat phantoms.

CONCLUSIONS

Irrigated microwave catheter ablation may be an effective ablation modality for deep ventricular lesion creation with capacity for fat penetration and sparing of nearby coronary arteries because of cooling endoluminal flow. Clinical translation could improve the treatment of ventricular tachycardia arising from mid myocardial or epicardial substrates.

Electrical homogenization of ventricular scar by application of collagenase: a novel strategy for arrhythmia therapy

BACKGROUND

Radiofrequency ablation for ventricular tachycardia is an established therapy. Use of chemical agents for scar homogenization represents an alternative approach. The purpose of this study was to characterize the efficacy of collagenase (CLG) application on epicardial ventricular scar homogenization.

METHODS AND RESULTS

Myocardial infarcts were created in Yorkshire pigs (n=6) by intracoronary microsphere injection. After 46.6±4.3 days, CLG type 2, type 4, and purified CLG were applied in vitro (n=1) to myocardial tissue blocks containing normal myocardium, border zone, and dense scar. Histopathologic studies were performed to identify the optimal CLG subtype. In vivo high-density electroanatomic mapping of the epicardium was also performed, and border zone and dense scar surface area and late potentials were quantified before and after CLG-4 application (n=5). Of the CLG subtypes tested in vitro, CLG-4 provided the best scar modification and least damage to normal myocardium. During in vivo testing, CLG-4 application decreased border zone area (21.3±14.3 to 17.1±11.1 mm(2), P=0.043) and increased dense scar area (9.1±10.3 to 22.0±20.6 mm(2), P=0.043). The total scar area before and after CLG application was 30.4±23.4 and 39.2±29.5 mm(2), respectively (P=0.08). Late potentials were reduced by CLG-4 application (28.8±21.8 to 13.8±13.1, P=0.043). During CLG-4 application (50.0±15.5 minutes), systolic blood pressure and heart rate were not significantly changed (68.0±7.7 versus 61.8±5.3 mmHg, P=0.08; 77.4±7.3 versus 78.8±6.0 beats per minute, P=0.50, respectively).

CONCLUSIONS

Ventricular epicardial scar homogenization by CLG-4 application is feasible and effective. This represents the first report on bioenzymatic ablation of arrhythmogenic tissue as an alternative strategy for lesion formation.

Evaluation of epicardial microwave lesions in the pig model using an electroanatomic mapping system

BACKGROUND

Surgical ablation techniques using microwave energy are an alternative to catheter-based ablation therapy in the treatment of atrial fibrillation. We investigate electrical conduction properties of linear lesions after epicardial ablation in a pig model by using an electroanatomic mapping system.

METHODS

After medial sternotomy in eight pigs epicardial pacing wires were placed on the anterior and posterolateral wall of the right atrium. Endocardial electroanatomical mapping was performed during pacing from anterior and posterolateral. Epicardial ablation was implemented in between the superior and inferior caval vein using microwave energy. Mapping was repeated to demonstrate conduction block or gap across the ablation line. When conduction gap was present the ablation procedure was repeated. Hearts were removed for histologic evaluation.

RESULTS

Conduction block was observed in two pigs after the first ablation and in two additional pigs after the second ablation. Conduction gap was present in three pigs after the second ablation. One animal died during the second ablation. Histologic evaluation showed more severe transmural cellular damage in lesions with conduction gap. Complete lesions with conduction block more often showed moderate alterations.

CONCLUSIONS

Epicardial microwave ablation can induce bidirectional conduction block, which is believed to be essential for therapeutic efficacy. However, the intraoperative macroscopic visible lesion and histological findings are not reliable markers of bidirectional conduction block. The Carto-Qwik-Map-System is an effective system to evaluate epicardial microwave lesions and to locate conduction gap areas intraoperatively. This increased the success rate regarding acute bidirectional conduction block after ablation in our experimental setting.

Preliminary Results with Percutaneous Transcatheter Microwave Ablation of Typical Atrial Flutter

BACKGROUND

Linear microwave ablation has been shown to be effective for treatment of atrial fibrillation during open-heart surgery by producing transmural lesions in the atrium to isolate the pulmonary veins. However, the safety and efficacy of percutaneous, transcatheter, linear microwave ablation for atrial arrhythmias, while demonstrated in animal models, is unknown in humans. Therefore, we studied the safety and efficacy of linear microwave ablation of the cavotricuspid isthmus (CTI) in humans with typical atrial flutter, utilizing a 2-cm long microwave antenna mounted on a steerable 9-French catheter.

METHODS AND RESULTS

In seven consecutive patients, multielectrode catheters were positioned at the His bundle (quadripolar) and around the TV annulus (duo-decapolar) for pacing and recording atrial activation sequence before and after ablation. The microwave antenna was withdrawn gradually from tricuspid annulus towards inferior vena cava to ablate the CTI. Intracardiac ultrasound was used to ensure adequate endocardial contact of the microwave ablation catheter with the CTI. Microwave energy was applied at a power of 18 to 21 W at each ablation point for 120 seconds. Ablation was repeated until bidirectional CTI block was confirmed by demonstrating a descending activation wavefront in the contralateral atrial wall during pacing from the coronary sinus ostium or low lateral right atrium, respectively. Bidirectional isthmus block was achieved in all patients, after a mean number of 27.4 +/- 14.7 energy applications per patients. There were no acute procedural complications.

CONCLUSIONS

Percutaneous, transcatheter microwave ablation of CTI dependent atrial flutter was demonstrated to be safe and effective in this preliminary feasibility study.

ATX-II Effects on the Apparent Location of M Cells in a Computational Model of a Human Left Ventricular Wedge

INTRODUCTION

The apparent location of the myocytes (M cells) with the longest action potential duration (APD) in a canine left ventricular (LV) wedge have been reported to shift after application of a sea anemone toxin, ATX-II. This toxin slows inactivation of I(Na) and thus prolongs APD. Thus, M cells may exhibit dynamic functional states, rather than being a static, anatomically discrete, myocyte population. In this study, we attempted to further define and understand this phenomenon using a mathematical model of the human ventricular myocyte action potential incorporated into an in silico "wedge" preparation. Our simulations demonstrate that even under conditions of a fixed population and ratio of epicardial, M, and endocardial myocytes, the apparent anatomical position (transmural location) of the myocytes with the longest APD can shift following ATX-II treatment. This arises because the ATX-II effect, modeled as a small increase in the late or persistent Na(+) current, and consequent prolongation of APD significantly changes the electrotonic interactions between ventricular myocytes in this LV wedge preparation.

METHODS AND RESULTS

This LV wedge model is based on bidomain equations. It corresponds to a rectangular tissue immersed in a passive and isotropic medium that represents the superfusion bath. In this theoretical work, the three known different and discrete populations of myocytes in the human left ventricle have been included: the epicardial, M, and endocardial cells. The effects of ATX-II on I(Na) were simulated by altering the voltage-dependent steady-state inactivation of the parameters h (fast gate) and j (slow gate). As a result, in these ATX-II simulations a persistent late Na(+) current was generated in all three types of ventricular myocytes. However, the APDs were prolonged in a heterogeneous pattern. Our simulations demonstrate that after the ATX-II effects develop, alterations in transmural electrotonic interactions can produce changes in the transmural location of myocytes with the longest APD.

CONCLUSIONS

The combination of intercellular electrotonic interactions, which tend to reduce and smooth out the discrete transmural APD variations, and the heterogeneous effects of ATX-II, which preferentially prolong the APD of M cells, can shift the location of the ventricular myocytes. This shift results in significantly altered transmural patterns of action potential durations, which would be expected to change localized refractory period and excitability. These cellular changes give rise to alterations in the corresponding surface electrograms and may change the overall substrates for conduction and rhythm disturbances.

Microwave Ablation of an Ischemic Sustained Ventricular Tachycardia During Aortocoronary Bypass, Mitral Valve and Tricuspid Valve Surgery Guided by a Three-Dimensional Nonfluoroscopic Mapping System (CARTO)

Postinfarct patients with malignant ventricular tachyarrhythmias (VTs) are prone to an increased risk for sudden cardiac death and implantation of an internal cardioverter-defibrillator (ICD) often is recommended. In cases where the VTs are incessant or refractory to medical treatment, disruption of the macro-reentry circuit, which represents the arrhythmogenic substrate for postinfarct VTs, is a major therapeutical goal for electro-physiologists. The precise identification of this underlying macro-reentrant circuit depends on conventional mapping techniques (i.e. diastolic potentials, entrainment) and more recently by a three-dimensional non-fluoroscopic electro-anatomical mapping system (CARTO), which integrates anatomical and electrophysiological information to reconstruct a three-dimensional activation and propagation map of the relevant VT. This reports describes on a patient with recurrent, drug-refractory, hemodynamically stable monomorphic VTs on the basis of a 2-vessel coronary artery disease, reduced left ventricular ejection fraction, who was scheduled for coronary artery bypass graft operation combined with mitral valve replacement and reconstruction of the tricuspid valve. Preoperatively, the underlying mechanism of the VT was identified by CARTO mapping with a slow conduction zone and a wide exit site at the inferoapico-basal portion of the left ventricle. In close cooperation between the cardiologists and the surgeons the decision for a simultaneous ablation approach during the subsequent operation was made. Successful ablation of the VT using microwave energy was confirmed by non-inducibility of the VT in the perioperative electrophysiologic study. This case report highlights the use of CARTO mapping to identify postinfarct VTs as well as the application of microwave energy as a useful tool to cure postinfarct ventricular arrhythmias.

Early morphologic changes following microwave endocardial ablation for treatment of chronic atrial fibrillation during mitral valve surgery

INTRODUCTION

The aim of this study was to investigate the early qualitative and quantitative structural changes in the left atrial wall after endocardial microwave ablation in patients with chronic atrial fibrillation (AF) undergoing mitral surgery.

METHODS AND RESULTS

Seven patients with chronic AF of for at least 6 months underwent surgical microwave energy ablation. Linear isolation of pulmonary veins was performed in all patients by microwave energy applications to the endocardial surface delivered by catheter at 65-W constant power for 45 seconds. Biopsies were obtained from a selected site (below the right lower pulmonary vein) of the left atrial posterior wall before and after the ablation procedure in all patients. Control tissues from the same sites were obtained at autopsy from patients with noncardiac causes of death. Light and electron microscopy was used to examine qualitative and quantitative changes in tissue morphology. Tissues after endocardial ablation procedure showed significantly increased loss of contractile material. Electron microscopy of atrial tissue demonstrated loss of profile of perinuclear and plasma membranes of myocytes, disruption of the endothelial cells of capillary vessels, and presence of macrophages.

CONCLUSION

Lesions created by endocardial microwave energy ablation revealed a transmural effect on the left atrial wall without a significant reduction in thickness but a significant increase in the myolytic areas involving the entire cytosol and occlusion of the small intramyocardial vessels within the ablative lesion.

The Completely Endoscopic Treatment of Atrial Fibrillation: Report on the First 14 Patients with Early Results

We report the early results of a new completely endoscopic technique for the treatment of atrial fibrillation (AF).

METHODS

Fourteen patients underwent surgery solely for the treatment of AF. The thoracoscopic technique delivered microwave energy to the epicardial surface of the beating heart. Access was obtained through 3 right-sided and 3 left-sided thoracic ports. The AFx/Guidant Flex-10 catheter was employed to produce a box lesion around the pulmonary veins along with additional right- and left-sided lesions. The left atrial appendage was amputated.

RESULTS

Ten patients had paroxysmal fibrillation, 1 had persistent fibrillation, and 3 were in permanent AF. Mean age of the group was 60 years, and their mean duration of AF was 74 months. Half had undergone unsuccessful attempts at chemical and/or electrical cardioversion. There were no deaths. Two patients required conversion to open procedure to control bleeding from the left atrial appendage. Average procedure time was 221 minutes, with the last 2 procedures taking less than 2 hours. Median length of hospital stay was 6 days, with 7 patients staying less than 3 days. Seventy-one percent of patients were in sinus rhythm at discharge, 100% at 6 months follow-up, and 67% at 12 months.

CONCLUSION

Totally endoscopic microwave ablation of atrial fibrillation appears to be safe and truly minimally invasive. It is associated with a short length of stay, short procedure time, and acceptable rhythm results. This procedure has the potential to greatly expand the indications for surgery in patients suffering from AF and deserves longer-term investigation.

Microwave, irrigated, pulsed, or conventional radiofrequency energy source: which energy source for which catheter ablation?

The aim of the study was to compare the diameter of endomyocardial lesions induced with the delivery of microwave, cooled, or pulsed energy versus conventional RF energy. In vitro tests were performed in fresh endomyocardial preparations of pig hearts in a 10-L bath of NaCl 0.9% solution at 37 degrees C and constant 1.5 L/min flow. Ablation 7 Fr catheters with 4-mm tip electrodes were used, except for the delivery of microwave energy. Energy delivery time was set to 60 s/50 W in all experiments. Cooled energy delivery was performed with a closed irrigation catheter. Pulsed energy delivery was performed using a special controller with a duty-cycle of 5 ms. Microwave energy was delivered with a 2.5-GHz generator and 10-mm antenna. Electrode temperature and impedance were measured simultaneously. After ablation, lesion length, width, and depth were measured with microcalipers, and volume calculated by a formula for ellipsoid bodies. Each energy delivery mode was tested in ten experiments. The deepest lesions were created with cooled energy delivery, and the largest volume by microwave energy delivery. Pulsed RF produced significantly deeper lesions than conventional RF energy delivery. Cooled or pulsed RF energy delivery created deeper transmural lesions than conventional RF. To create linear lesions at anatomically complex sites (isthmus), microwave energy seemed superior by rapidly creating deep and long lesions.

Production of narrow but deep lesions suitable for ablation of atrial fibrillation using a saline-cooled narrow beam Nd:YAG laser catheter

BACKGROUND AND OBJECTIVE

Lines of radiofrequency ablation for cure of atrial fibrillation are broad, and the consequent loss of atrial mass may impair atrial function and contribute to the risk of stroke. We studied whether Nd:YAG laser could produce deep but narrower lesions.

STUDY DESIGN/MATERIALS AND METHODS

Laser lesions were made in ventricular myocardium of nonperfused ovine hearts and at thoracotomy in dogs.

RESULTS

Lesions were well demarcated, deep, and narrow. Saline irrigation prevented crater formation for energy levels below 200 J. Lesion depth increased with increasing duration of ablation (maximum 5.3 +/- 0.8mm, P < 0.01). The depth to width ratio was >1 in all cases (maximum 2.5 +/- 1.6). The narrowest lesions were made by using high power, short duration of exposure, and intermittent delivery.

CONCLUSIONS

Irrigated Nd:YAG laser can be used to make deep narrow myocardial lesions without crater formation. Laser ablation may be more suitable than radiofrequency ablation for intraoperative or catheter-based cure of atrial fibrillation.

Linear lesions in myocardium created by Nd:YAG laser using diffusing optical fibers: in vitro and in vivo results

BACKGROUND AND OBJECTIVE

Linear lesions may be necessary for successful catheter ablation of cardiac arrhythmias such as atrial fibrillation. This study uses laser energy delivered through diffusing optical fibers as an alternative to radiofrequency energy for the creation of linear lesions in cardiac tissue in a single application.

STUDY DESIGN/MATERIALS AND METHODS

Samples of canine myocardium were placed in a heated, circulating saline bath and irradiated with a 1.06-microm, continuous-wave Nd:YAG laser during in vitro studies. Laser ablation was then performed in vivo on the epicardial surface of the right ventricle during an open-chest procedure by using similar ablation parameters. Laser energy was delivered to the tissue by being diffused radially through flexible optical fiber tips oriented parallel to the tissue surface. Histology and temperature measurements verified transmurality, continuity, and linearity of the lesions.

RESULTS

Peak tissue temperatures measured in vitro remained low (51 +/- 1 degrees C at the endocardial surface, 61 +/- 6 degrees C in the mid-myocardium, and 55 +/- 6 degrees C at the epicardial surface) with no evidence of tissue charring or vaporization. Lesion dimensions produced in vitro and in vivo were similar (depth, 6 mm; width, 8-10 mm; length, 16-22 mm), demonstrating that tissue perfusion in vivo did not significantly alter the heating.

CONCLUSION

Long linear lesions, necessary for duplication of the surgical maze procedure during catheter ablation of atrial fibrillation, may be created by using laser radiation delivered through flexible diffusing optical fiber tips. Further development of steerable catheters for endocardial atrial ablation and studies correlating thermal damage zones with electrophysiologic indicators of irreversible conduction block are warranted.

Alternate energy sources for catheter ablation

Because of the limitations of conventional radiofrequency ablation in creating large or linear lesions, alternative energy sources have been used as possible methods of catheter ablation. Modified radiofrequency energy, cryoablation, and microwave, laser, and ultrasound technologies may be able to create longer, deeper, and more controlled lesions and may be particularly suited for the treatment of ventricular tachycardias and for linear atrial ablation. Future studies will establish the efficacy of these new and promising technologies.