32nd Annual International Conference of the IEEE EMBS Buenos Aires, Argentina, August 31 - September 4, 2010 Analytical Validation of COMSOL Multiphysics for Theoretical Models of Radiofrequency Ablation Including the Hyperbolic Bioheat Transfer Equation Maria J. Rivera, Juan A. López Molina, Macarena Trujillo, Vicente Romero-García, and Enrique J. Berjano Abstract—In this paper we outline our main findings about the differences between the use of the Bioheat Equation and the Hyperbolic Bioheat Equation in theoretical models for Radiofrequency (RF) ablation. At the moment, we have been working on the analytical approach to solve both equations, but more recently, we have considered numerical models based on the Finite Element Method (FEM). As a first step to use FEM, we conducted a comparative study between the temperature profiles obtained from the analytical solutions and those obtained from FEM. Regarding the differences between both methods, we obtain agreement in less than 5% of relative differences. Then FEM is a good alternative to model heating of biological tissues using BE and HBE in, for example, more complex and realistic geometries. I. INTRODUCTION R adiofrequency (RF) heating of biological tissues is currently employed in many surgical and therapeutic procedures such as the elimination of cardiac arrhythmias, the destruction of tumors, the treatment of gastroesophageal reflux disease, and the heating of the cornea for refractive surgery. In order to investigate and develop new RF ablation techniques, besides understanding the complex electrical and thermal phenomena involved in the heating process, numerous theoretical models have been employed [1]. To date, all these models have employed the Bioheat Equation (BE) proposed by Pennes [2], in which the heat conduction term is based on Fourier’s theory (i.e. they have employed a parabolic heat transfer equation). r Therefore, it related to heat flux ( q ) in the following way: r r r r q (r , t ) = −k∇T (r , t ) (1) r where k is the thermal conductivity (W/m⋅K) and T (r , t ) the r temperature at point r at time t. This approach assumes an infinite thermal energy propagation speed, and although it Manuscript received March 31, 2010. This work was supported in part by the Spanish Government by means of the following Grants: TEC200801369/TEC, MTM2007-64222, MTM2010-14909 and MAT2009-09438, and by Valencia Government by means of the Grant ACOMP/2010/008. M. J. Rivera, J. A. López Molina and M. Trujillo are with the Departamento de Matemática Aplicada, Instituto de Matemática Pura y Aplicada, Universidad Politécnica de Valencia, Valencia, Spain (e-mails: mjrivera@mat.upv.es, jalopez@mat.upv.es , matrugui@mat.upv.es). V. García-Romero is with the Centro de Tecnologías Físicas: Acústica, Universidad Politécnica de Valencia, Valencia, Spain (e-mail: virogar1@upvnet.upv.es). E. J. Berjano is with the Electronic Engineering Department, Universidad Politécnica de Valencia, Valencia, Spain (e-mail: eberjano@eln.upv.es). 978-1-4244-4124-2/10/$25.00 ©2010 IEEE might be suitable for most RF ablation procedures, it has been suggested that under certain conditions (such as very short heating times), a non-Fourier model should be considered by means of the Hyperbolic Bioheat Equation (HBE), i.e. considering a nonzero thermal relaxation time (τ) in the tissue [3]. It is known that heat is always found to propagate at a finite speed [4], and in fact Cattaneo [5] and Vernotte [6] simultaneously suggested a modified heat flux model in the form: r r r r (2) q (r , t + τ ) = −k∇T (r , t ) where τ is the thermal relaxation time of the biological tissue. Equation (2) assumes that the effect (heat flux) and the cause (temperature gradient) occur at different times and that the delay between heat flux and temperature gradient is τ. The particular case of considering τ = 0 obviously corresponds to the BE. In order to study how the temperature profiles could be altered when HBE is considered in place of BE, we have conducted different theoretical studies based on onedimensional analytical models [7-9]. In these models, we solved both BE and HBE under different circumstances. Obviously, since the analytical approach does not allow easily to consider complex geometries or to solve non-linear equations, recently we are using a complementary approach based on numerical techniques, specifically the Finite Element Method (FEM). However the use of non standard equations like the HBE and non standard functions as the Heaviside function and the Dirac’s Delta function can add new problems in the use of numerical methods. The aim of this paper is the validation of COMSOL Multiphysics in the solution of the HBE in models for RF ablation by the analytical solution. For this reason the geometry we have to consider must be simple enough so that the exact solution can be attained. II. ANALYTICAL APPROACH Briefly, we considered a r0 radius spherical electrode completely imbedded in the biological tissue (see Fig. 1), which had an infinite dimension. Although some RF ablation applications use wet and cooled electrodes, in our model we considered the simplest case, i.e. a dry electrode. This model presented radial symmetry and a onedimensional approach was possible. Regarding the electrical problem, we always modeled a constant-power protocol, i.e. the source term Qs(r,t) in W/m3 for the BE and HBE (i.e. the Joule heat produced per unit volume of tissue) was always: 3214 P ⋅ r0 (3) H (t ) 4 ⋅π ⋅ r4 where P is the total applied power (W), r0 the electrode radius (m), and H(t) is the Heaviside function. Although this temporal function have not been included in the previous study by Erez and Shitzer [10], later it was crucial to study the pulsed protocol in RF ablation for the case HBE [11]. Qs (r , t ) = Additionally, we consider the source term related with the blood perfusion which can be expressed as: Q p ( r , t ) = − ρ b cbωb (T ( r , t ) − T0 ) (4) where ρb is the blood density (kg/m3), cb (J/kg⋅K) the blood specific heat, ωb is the perfusion blood flux (s-1), and the T0 is the blood temperature (ºC). Both terms (Qp and Qs) are source terms and therefore the total source term is: ∂ 2T ( r , t ) 2 ∂T (r , t ) ∂T (r , t ) + ) +ζ ∂r 2 r ∂r ∂t (9) ∂T (r , t ) Pα r0 +τ = ( H (t ) + τ δ (t )) − B(T ( r , t ) − T0 ) ∂t 4π k r 4 where δ(t) is Dirac’s function, B = αρ bcbωb , and ζ = 1 + τ B . k To set the boundary condition in r = r0, we adopted a simplification assuming the thermal conductivity of the electrode to be much larger than that of the tissue (i.e. assuming that the boundary condition at the interface between electrode and tissue is mainly governed by the thermal inertia of the electrode). This obviously modeled a dry electrode. Other thermal boundary conditions should be considered for the case of internally cooled electrodes [13]. −α ( III. NUMERICAL APPROACH Q ( r , t ) = Qs ( r , t ) + Q p ( r , t ) (5) Fig. 1. Schematic diagram of the model geometry. A spherical electrode (white circle) of radius r0 is completely imbedded and in close contact with the biological tissue, which has an infinite dimension. As a result, the model presented a radial symmetry, and a one-dimensional approach is possible (dimensional variable is r). The HBE was obtained by combining the energy equation: − ∇q ( r , t ) + Q ( r , t ) = ρ c ∂T ( r , t ) ∂t (6) where ρ is the density (kg/m3) and c (J/kg⋅K) the specific heat, with the heat transfer model derived from Equation (2) and proposed by Özişik and Tzou [12]: q(r , t ) + τ ∂q(r , t ) = −k∇T (r , t ) ∂t (7) The result was: 1 ∂T (r , t ) ∂ 2T ( r , t ) ( +τ )= α ∂t ∂ 2t (8) 1 ∂Q (r , t ) (Q(r , t ) + τ ) k ∂t where α is the thermal diffusivity (m2/s). Finally, we − ∆T (r , t ) + combined (5) and (8) to obtain the HBE: The majority of heat transfer problems of real situations involve complex geometries, are non-linear problems or their initial and boundary conditions lead us to use numerical methods to solve them. This is absolutely true in RF ablation. Some widespread numerical methods to solve this kind of problems are the Finite Element Method (FEM) and the Finite Differences Method. There is abundant available software for building models, solving them by the mentioned methods and post-processing the results. We have chosen COMSOL Multiphysics (Burlington, MA, USA), which has been broadly employed in the study of the RF ablation of biological tissues. However, all of those previous studies considered the BE [14-16]. In this respect, our recent objective has focused on the validation of COMSOL Multiphysics for using the HBE in obtaining the temperature distribution during RF ablation. This issue is especially important by taking into account the cuspidal-type singularities found in the analytical solutions of the HBE, which are materialized as a temperature peak traveling through the medium at a finite speed [7]. In other words, it is necessary to know if this behavior will be accurately modeled by numerical methods in general, and by COMSOL in particular. For this reason, we build with COMSOL the same onedimensional model previously solved by analytical methods, and then we obtained the numerical solution. Our idea was to validate COMSOL by comparing the numerical and analytical solution. We used COMSOL Multiphysics software version 3.2b, which can virtually model and solve any physical phenomenon, which can be described with Partial Differential Equations (PDE) using the FEM. COMSOL presents several models to solve a wide range of PDEs. We have chosen a one-dimensional problem. We used the automatic mesh generated by COMSOL, and for this reason we conducted a sensibility analysis to check that a more refinished meshes do not produce results closer 3215 to the analytical ones. The control parameter used to conduct this sensibility analysis was the temperature reached at the interface electrode-tissue (r=r0), r=2r0, and r=3r0, after 60 s. These three different points were checked due to the different thermal behavior at each location, especially in the case of HBE. In order to compare analytical and numerical solution we plotted the progress of temperature from each solution. In the case of the analytical solution we used the software Mathematica 7.0 software (Wolfram Research, Champaign, IL, USA). To make graphics of the numerical solution we used the post-processing option of COMSOL. In order to plot the results we particularized the solutions for a specific case. We chose an electrode radius of r0=1.5 mm. As biological tissue we chose the liver with the following characteristics: density ρ of 1060 kg/m3, specific heat c of 3600 J/kg⋅K and thermal conductivity k of 0.502 W/m⋅K. The electrode characteristics were the density ρ of 21500 kg/m3 and the specific heat c of 132 J/kg⋅K. This corresponds with a platinum-iridium electrode such as used in RF ablation. The initial temperature of tissue was 37ºC. The applied power was of P = 1 W. This values was chosen in order to obtain tissue temperatures capable of producing thermal lesion (>50ºC) and below 80ºC (where non linear phenomena occur, such as vaporization and desiccation).l Moreover, we included the term of blood perfusion both in BE and HBE. Finally, these numerical solutions were compared to those obtained analytically in order to validate the FEM tool. IV. RESULTS AND DISCUSSION Regarding the analytical solutions, we found, from a mathematical point of view, that the HBE solution shows cuspidal-type singularities in the form of a temperature peak traveling through the medium at finite speed (see Fig. 2). This peak arises at the electrode surface, and clearly reflects the wave nature of the thermal problem. In [11] we tried to provide an explanation about this behavior which is based on the interaction of forward and reverse thermal waves. At the beginning of heating (i.e. when the considered time was comparable to or shorter than the thermal relaxation time), HBE provided temperature values lower than those provided by BE. In general, and for points far from the electrode surface, the speed of temperature change at the beginning of the heating in the case of HBE was slightly slower than BE. This can be explained due to the fact that when using HBE a period of time is needed for heat to travel to a particular location inside the tissue. When these conclusions were particularized for specific tissues, once more the differences between BE and HBE temperature profiles were greater for lower times and shorter distances. For this reason, our results suggested that the HBE should be considered in the case of RF heating of the cornea (heating time 0.6 s), and for short time ablation in cardiac tissue (less than 30 s) [8]. Although in this study we used the characteristics of the liver, these values are very similar to those found in the cornea [8], and for this reason, the temperatures obtained will be almost equal. Regarding the numerical results, Figure 3 shows the temperature progress for HBE and for two values of thermal relaxation time (1 and 16 s) and for two blood perfusion conditions (without perfusion ω=0, and perfusion ω=0.01 1/s). To obtain the numerical solution, we have meshed both the numerical and the temporal domains. On one hand, spatial domain has been meshed in 16 nodes using Lagrangequadratic elements, whereas the temporal domain has been analyzed form 0 s to 160 s in steps of 0.1 s. The mesh in both cases is equi-distributed, that means, every node present the same size. The solution has been obtained by the unsymmetric multifrontal sparse LU factorization package (UMFPACK), which is a set of routines for solving unsymmetric sparse linear systems using the Unsymmetric MultiFrontal method. The results obtained from analytical approach, both using BE and HBE, and from COMSOL were almost coincident. We have analyzed the relative differences between the numerical and analytical temperature profiles, using the next expression: ε (%) = TN − TA × 100 TA (10) Where, TN is the temperature profile obtained by FEM and TA is the analytical temperature profile. For all the cases analyzed in this work, the differences have been less 5%. These results suggest that COMSOL can be a suitable tool to model the heating of biological tissues using BE and HBE. Now, future work will be conducted to implement theoretical models based on FEM (COMSOL) with more realistic geometries. Fig. 2. Temperature progress obtained from analytical solution during 60 s of RF ablation using the HBE and for two values of thermal relaxation time (1 and 16 s) and for two blood perfusion conditions: without perfusion ωb=0 (solid line), and perfusion ωb =0.01 1/s (dashed line). The plots correspond with a location r = 2r0. V. CONCLUSION In this paper, we have outlined our main findings about the differences between the BE and HBE models for RF ablation. These differences encourage the use of the HBE approach for processes in which great amounts of heat are transferred to any material in very short times, e.g. RF 3216 heating in the cornea. 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