A Theoretical and Experimental Analysis of Radiofrequency Ablation with a Multielectrode, Phased, Duty-Cycled System

  1. MICHAEL LAU M.Eng.1,
  2. BETTY HU M.S.1,
  3. RANDY WERNETH M.S.1,
  4. MARSHALL SHERMAN B.S.E.E.1,
  5. HAKAN ORAL M.D.2,
  6. FRED MORADY M.D.2,
  7. PETR KRYSL Ph.D.3

Article first published online: 10 JUN 2010

DOI: 10.1111/j.1540-8159.2010.02801.x

Issue

Pacing and Clinical Electrophysiology

Pacing and Clinical Electrophysiology

Volume 33, Issue 9, pages 1089–1100, September 2010

Additional Information

How to Cite

LAU, M., HU, B., WERNETH, R., SHERMAN, M., ORAL, H., MORADY, F. and KRYSL, P. (2010), A Theoretical and Experimental Analysis of Radiofrequency Ablation with a Multielectrode, Phased, Duty-Cycled System. Pacing and Clinical Electrophysiology, 33: 1089–1100. doi: 10.1111/j.1540-8159.2010.02801.x

Author Information

  1. 1

    Medtronic Ablation Frontiers, Carlsbad, California

  2. 2

    University of Michigan Health System, Ann Arbor, Michigan

  3. 3

    University of California, San Diego, California

*Address for reprints: Michael Lau, M.Eng., 2210 Faraday Ave. Suite 100, Carlsbad, CA 92008. Fax: 760-827-0131; e-mail: michael.t.lau@medtronic.com

Publication History

  1. Issue published online: 1 SEP 2010
  2. Article first published online: 10 JUN 2010
  3. Received October 21, 2009; revised March 10, 2010; accepted March 29, 2010.

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Keywords:

  • ablation;
  • multielectrode;
  • radiofrequency;
  • phasing;
  • duty-cycle;
  • finite element

Background:The development of a unique radiofrequency (RF) cardiac ablation system, for the treatment of cardiac arrhythmias, is driven by the clinical need to safely create large uniform lesions while controlling lesion depth. Computational analysis of a finite element model of a three-dimensional, multielectrode, cardiac ablation catheter, powered by a temperature-controlled, multiphase, duty-cycled RF generator, is presented.

Methods:The computational model for each of the five operating modes offered by the generator is compared to independent tissue temperature measurements taken during in vitro ablation experiments performed on bovine myocardium.

Results:The results of the model agree with experimental temperature measurements very closely—the average values for mean error, root mean square difference, and correlation coefficient were 1.9°C, 13.3%, and 0.97, respectively. Lesions are shown to be contiguous and no significant edge effects are observed.

Conclusions:Both the in vitro and computational model results demonstrate that lesion depth decreases consistently as the bipolar-to-unipolar ratio increases—suggesting a clinical application to potentially control lesion depth with higher fidelity than is currently available. The effect of variable design parameters and clinical conditions on RF ablation can now be expeditiously studied with this validated model. (PACE 2010; 33:1089–1100)

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