Thermo-elastic Response of Cutaneous and Subcutaneous Tissues to Noninvasive Radiofrequency Heating

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Thermo-elastic Response of Cutaneous and Subcutaneous Tissues to Noninvasive Radiofrequency Heating Joel N. Jiménez Lozano, Paulino Vacas-Jacques, Walfre Franco. Excerpt from the Proceedings of the 2012 COMSOL Conference in Boston Wellman Center for Photomedicine Harvard Medical School Massachusetts General Hospital

Outline 1. Introduction 2. Problem definition 3. Mathematical modeling and solution 4. Results 5. Significance 6. Conclusions

Outline 1. Introduction 2. Problem definition 3. Mathematical modeling and solution 4. Results 5. Significance 6. Conclusions

1 Introduction Radiofrequency (RF) heating uses frequencies in the range of 30kHz 1GHz. RF energy is used for generating heat,. which can be used to cut, or induce metabolic processes in the body target tissue. RF technology offers unique advantages for non-invasive selective heating of. relatively large volumes of tissue. RF applicator

1 Introduction The skin-fat structure: An outer cellular layer, the epidermis. (~0.1 mm) A dense connective tissue layer perfused. with microvessels, the dermis. (~1 mm) A thick fatty layer, the hypodermis or subcutaneous tissue. (1 cm to 10 cm) MacNeil S., Nature vol.445 (2007).

1 Introduction Anatomy: Subcutaneous tissue Subcutaneous structure: clusters of adipocytes interlaced by a fine collagen fiber mesh (fiber septa).. Micro-MRI clearly shows thickness and structural alterations of connective tissues that correlate with abnormalities of skin. Chavarcode,Co. High-resolution in vivo MRI of the skin of a female. Dark filaments correspond to fiber septa within the subcutaneous fat. Mirrashed, F., et al., Skin Research and Technology, 10 (2004).

1 Introduction Objectives: i. Present a mathematical model for selective, non-invasive, nonablative RF heating of cutaneous and subcutaneous tissue including their thermo-elastic responses; ii. iii. Investigate the effect of fiber septa networks interlaced between fat clusters in the RF energy deposition; Illustrate the electric, thermal and elastic response of tissues.

Outline 1. Introduction 2. Problem definition 3. Mathematical modeling and solution 4. Results 5. Discussion 6. Conclusions

2 Problem definition Domain Geometry High-resolution in vivo MRI of the skin of a female. Dark filaments correspond to fiber septa within the subcutaneous fat.

2 Problem definition RF applicator in contact to the skin surface Electric B.C. at the surface defined from Voltage measurements. Tissue physical parameters: Electric conductivity, s, (ability to transport electric current) Relative permittivity, e, (ability to concentrate electric flux) Thermal conductivity,k, (ability to conduct. heat) Blood perfusion, w, (ability to dissipate heat) Elastic modulus,e, (ability to be deformed) Thermal expansion coefficient, a, (ability to expand by increasing temperature).

Outline 1. Introduction 2. Problem definition 3. Mathematical modeling and solution 4. Results 5. Significance 6. Conclusions

3 Mathematical modeling and solution Governing Equations (i = skin, hypodermis, muscle, septa) 1 (i) (ii) (iii) (iv) (v) 2 (I) (II) (III) 3 1 Electric Potential 3 2 Heat Transfer i. change in heat storage, ii. thermo-elastic coupling, iii. heat conduction, iv. blood perfusion, v. electric power absorption,, Solid Mechanics I. rate increase momentum, II. divergence of stress, III. external forces.

3 Mathematical modeling and solution Main physical assumptions: Tissues are homogeneous and have isotropic electric and thermal properties Electromagnetic propagation is very fast compared to heat diffusion Distribution of blood vessels is isotropic Blood flow enters at arterial temperature but reaches local tissue temperature before leaving Fourier conduction Linear elasticity

3 Mathematical modeling and solution Boundary conditions (a) Electric: i. a voltage source distribution at the skin surface, ii. a zero voltage condition at the muscle bottom, iii. no electric flux at the lateral boundaries; (b) Thermal: i. a cooling plate below the applicator, ii. air convection at the top of skin, iii. a core temperature at the muscle bottom, iv. no thermal flux at the lateral boundaries, (c) Elastic: i. fixed at the skin upper surface and muscle bottom, ii. lateral boundaries are assumed to move freely. As initial conditions at t=0 s, we assume V=0, T 0 =310 K and no initial strain.

3 Mathematical modeling and solution RF Monopolar applicator (Franco, W. et al. LSM 42, 2010) The RF applicator consists of a multidimensional series of tightly spaced concentric rings that are energized at variable operational frequencies. Upper view Voltage B.C.

3 Mathematical modeling Parameters Parameter Value Reference Geometrical Dimensions [mm] l s l f l m L W 1.5 17 38 18.5 54.5 Permittivity e s e f e m e sp 1832.8 27.22 1836.4 1832.8 Electric conductivity [S/m] s s s f s m s s Density [kg/m 3 ] r s r f r m r sp r b 0.22 0.025 0.5 0.22 1200 850 1270 1200 1000 Thermal conductivity [W/m/K] k s 0.53 k f 0.16 k m 0.53 k sp 0.53 Assumption Assumption Assumption Assumption Parameter Value Reference Perfusion [kg/m 3 /s] w s w f w m 2 0.6 0.5 Young s Modulus [kpa] E s 35 E f 2 E m 80 0.009 E sp Thermal expansion coefficient [1/ o C] a s a f a m a sp 6E-5 2.76E-5 4.14E-5 6E-5 Fixed constants h 10 [W/m 2 /K] T 298 [K] T b 310 [K] T core 310[K] T plate 303[K] [9] [9] [9] [10] [11] [12] [12] Assumption

3 Mathematical modeling and solution COMSOL Solution The model was implemented using the electric currents, heat transfer and solid mechanics modules. Simulations were run in a Intel Core i5 at 3.1 GHz PC computer with 4 GB RAM memory. Model has 355,772 dof. Processing required about 134 min real time. The model mesh has 44380 elements. Skin, fat, muscle and septa central domains had a higher mesh density. The time dependent solution was set from 0-1200 seconds with a time-step of 0.1 seconds. We used COMSOL MUMPS direct solver.

Outline 1. Introduction 2. Problem definition 3. Mathematical modeling and solution 4. Results 5. Significance 6. Conclusions

4 Results Voltage distribution Voltage distribution within tissue, homogeneous fat tissue (no fiber septa). Voltage distribution within tissue, fat tissue with fiber septa.

4 Results Total electric power absorption (Q) and Electric field (arrows) Electric power absorption and Electric field within tissue for homogeneous fat tissue. Electric power absorption and Electric field within tissue for fat with fiber septa.

4 Results Temperature distribution Time to reach steady-state ~1200s

4 Results Temperature distribution Temperature map at 1200 seconds (steady-state) for homogeneous fat tissue. Temperature map at 1200 seconds (steady-state) for fat tissue with fiber septa. Difference in maximum temperature ~8 o C.

4 Results Volumetric strain

4 Results Volumetric strain Volumetric strain at 30 seconds. Volumetric strain at steady-state.

Outline 1. Introduction 2. Problem definition 3. Mathematical modeling and solution 4. Results 5. Significance 6. Conclusion

5 Significance A specific clinical application of our analysis is hyperthermic injury to adipocyte cells. Model developed for planning the. clinical treatment of subcutaneous fat related disorders; such as, lipomatosis, Madelung s disease, or lipedema*, studying the tissue response as a function of structure; such as, density of fibers, cellulite. * MRIs of lipedema show massive circumferential enlargement of the subcutaneous tissue occupied by fat lobules and a highly dense fibrous septa structure.

Outline 1. Introduction 2. Problem definition 3. Mathematical modeling and solution 4. Results 5. Significance 6. Conclusions

6 Conclusions Fiber septa structures in the subcutaneous fat tissue concentrate electric power and contribute to increase the bulk temperature. Subcutaneous tissue with septa reaches a higher maximum temperature when compared to homogenous tissue. Dermis and fat exhibit a volumetric expansion whereas fiber septa contracts. Accurate assessment of tissue thermal responses will benefit the design of thermal therapies in the field of clinical hyperthermia (38-45 o C).

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