Sensitivity analysis and inverse problems in bio-heat transfer modelling

Majchrzak, E.; Mochnacki, B.

Artykuł - szczegóły

Tytuł artykułu

Sensitivity analysis and inverse problems in bio-heat transfer modelling

Autorzy

Majchrzak E. , Mochnacki B.

Wybrane pełne teksty z tego czasopisma

http://cames.ippt.gov.pl/

Identyfikatory

Warianty tytułu

Języki publikacji

Abstrakty

In the paper the problems connected with numerical modelling of bio-heat transfer processes are discussed. The mathematical model of phenomena discussed bases on the Pennes equation, at the same time the steady and transient tasks are considered. The basic equation is supplemented by the adequate geometrical, physical, boundary and (in the case of transient heat transfer) initial conditions. In the first part of the paper the examples of direct solutions are discussed. Next the possibilities of sensitivity analysis applications in the domain of bio-heat transfer are presented. In the final part the selected solutions of inverse problems are shown. On the stage of numerical simulations both in the case of direct and inverse problems, as a rule, the different variants of the boundary element method have been used.

Słowa kluczowe

numerical modelling bio-heat transfer

wymiana ciepła modelowanie numeryczne

Wydawca

Instytut Podstawowych Problemów Techniki PAN

Czasopismo

Computer Assisted Mechanics and Engineering Sciences

Rocznik

2006

Tom

Vol. 13, No. 1

Strony

85--108

Opis fizyczny

Bibliogr. 62 poz., rys., wykr.

Twórcy

autor

Majchrzak E.

autor

Mochnacki B.

Department for Strength of Materials and Computational Mechanics Silesian University of Technology, Konarskiego 18a, 44-100 Gliwice, Poland

Bibliografia

[1] O.M. Alifanov. Inverse Heat Transfer Problems. Springer-Verlag, 1994.
[2] P.K. Banerjee. Boundary Element Methods in Engineering. McGraw-Hill Co., London, 1994.
[3] J.V. Beck, B. Blackwell. Inverse Problems. Handbook of Numerical Heat Transfer. Wiley Intersc., New York, 1988.
[4] J.V. Beck, B. Blackwell, Ch.R.S. Clair. Inverse Heat Conduction. Ill-Posed Problems. J. Wiley & Sons, 1985.
[5] CA. Brebbia, J. Dominguez. Boundary Elements. An Introductory Course. Computational Mechanics Publications, McGraw-Hill Co., London, 1992.
[6] H. Budman, A. Shitzer, J. Dayan. Analysis of the inverse problem of freezing and thawing of a binary solution during cryosurgical processes, Journal of Biomechanical Engineering, 117: 193-202, 1995.
[7] T. Burczyński. Sensitivity analysis, optimization and inverse problems. In: D. Beskos, G. Maier, eds., Boundary Element Advances in Solid Mechanics, 245-307, Springer, Wien and New York, 2003.
[8] K. Dems. Sensitivity analysis in thermal problems - I: variation of materiał parameters within fixed domain. Journal of Thermal Stresses, 9: 303-324, 1986.
[9] K. Dems. Sensitivity analysis in thermal problems - II: structure shape variation. Journal of Thermal Stresses, 10: 1-16, 1987.
[10] M. Dziewoński. Modelling of freezing process of the tissue subjected to the action of spherical cryoprobes. Scientific Research of the Institute of Mathematics and Computer Science, 1(3): 41-46, 2004.
[11] M. Dziewoński, E. Majchrzak, B. Mochnacki. Modelling of cyclic freezing process of the biological tissue using the BEM. In: E. Majchrzak, B. Mochnacki, R. Wyrzykowski, eds., 4th International Conference on Parallel Processing and Applied Mathematics, PPAM 2001, Workshop, 47-52, Częstochowa, 2001.
[12] M. Dziewoński, B. Mochnacki, R. Szopa. Numerical model of biological tissue freezing. Acta of Bioengineering and Biomechanics, 1: 139-142, 1999.
[13] F.C. Henriques Jr. Studies of Thermal Injuries V. Archives of Pathology, 43: 489-502, 1947.
[14] M. Jasiński, E. Majchrzak. Sensitivity analysis of burn integrals with respect to the thermophysical properties of the skin. In: E. Majchrzak, B. Mochnacki, R. Wyrzykowski, eds., 4th International Conference on Parallel Processing and Applied Mathematics, PPAM 2001, Workshop, 53-63, Częstochowa, 2001.
[15] M. Kleiber et al.. Parameter Sensitivity in Nonlinear Mechanics. J. Wiley &: Sons Ltd., London, 1997.
[16] K. Kurpisz, A.J. Nowak. Inverse Thermal Problems. Computational Mechanics Publications, Southampton, Boston, 1995.
[17] J. Liu, L.X. Xu. Boundary information based diagnostics on the thermal states of biological bodies. Int. Journal of Heat and Mass Transfer, 43: 2827-2839, 2000.
[18] E. Majchrzak. Numerical modelling of bioheat transfer using the boundary element method. Journal of Theoretical and Applied Mechanics, 36(2): 437-455, 1998.
[19] E. Majchrzak. Numerical modelling of biological tissue freezing. In: B. Sarler, CA. Brebbia, eds., Moving Boundaries VI, Computational Modelling of Free and Moving Boundary Problems, 153-162. WIT Press, Southampton, Boston, 2001.
[20] E. Majchrzak. Identification of internal heat source in domain of tissue with a tumor. In: H.A. Mang, F.G. Rammerstorfer, J. Ebershardsteiner, eds., Proceedings of the Fifth World Congress on Computational Mechanics (WCCM V), 1-10. Vienna University of Technology, Austria, 2002, http://wccm.tuwien.ac.at.
[21] E. Majchrzak. Boundary Element Method in Heat Transfer (in Polish). Publ. of the Techn. Univ. of Częstochowa, Częstochowa, 2001.
[22] E. Majchrzak, J. Drozdek, G. Kałuża. Application of the multiple reciprocity BEM for numerical solution of bioheat transfer equation. Scientific Research of the Institute of Mathematics and Computer Science, 1(1): 114-124, Częstochowa University of Technology, Częstochowa, 2002.
[23] E. Majchrzak, M. Dziewoński. Heat transfer in biological tissue subjected to the action of cylindrical cryoprobe, In: B. Sarler, CA. Brebbia, eds., Mouing Boundaries V, 29-36, Southampton, 1999.
[24] E. Majchrzak, M. Dziewoński. Numerical simulation of freezing process using the BEM. Computer Assisted Mechanics and Engineering Sciences, 7: 667-676, 2000.
[25] E. Majchrzak, M. Dziewoński. Numerical analysis of biological tissue freezing process. In: T. Burczyński, ed.,IUTAM/IACM/IABEM Symposium on Advanced Mathematical and Computational Mechanics Aspects of the Boundary Element Method, Cracow, Poland, 31 May-3 June 1999, 189-200. Kluwer Academic Publishers, Dordrech-Boston-London, 2001.
[26] E. Majchrzak, M. Dziewoński, B. Mochnacki. Numerical analysis of temperaturę field in the tissue around blood vessel. In: A. Garstecki, B. Mochnacki, N. Sczygiol, eds., 16th International Conference on Computer Methods in Mechanics CMM-2005, CD-ROM Proceedings, Częstochowa, 2005.
[27] E. Majchrzak, D. Janisz, G. Kałuża, K. Freus. Identification of the boundary condition on the skin surface subjected to external heat source. 9th Int. Conf. on Numerical Methods in Continuum Mechanics, CD-ROM Proceedings, 1-11, Zilina, 2003.
[28] E. Majchrzak, D. Janisz, B. Mochnacki. Identification of external heat flux on the basis of temperature distribution in domain of skin tissue. In: T. Burczyński, P. Fedeliński, E. Majchrzak, eds., 15th International Conference on Computer Methods in Mechanics CMM-2003, Short Papers, 237-238, Gliwice, 2003.
[29] E. Majchrzak, M. Jasiński. Sensitivity study of burn predictions to variations in thermophysical properties of skin. Advances in Boundary Element Techniques II, 273-280, Hoggar, Geneva, 2001.
[30] E. Majchrzak, M. Jasiński. Sensitivity analysis of bioheat transfer in 2D tissue domain subjected to an external heat source. Acta of Bioengineering and Biomechanics, 3: 329-336, 2001.
[31] E. Majchrzak, M. Jasiński. Numerical estimation of burn degree of skin tissue using the sensitivity analysis methods. Acta of Bioengineering and Biomechanics, 4: 464-465, 2002, 464-465.
[32] E. Majchrzak, M. Jasiński. Numerical estimation of burn degree of skin tissue using the sensitivity analysis methods. Acta of Bioengineering and Biomechanics, 5: 93-108, 2003.
[33] E. Majchrzak, M. Jasiński. Sensitivity analysis of burns integrals. Computer Assisted Mechanics and Engineering Sciences, 11: 125-136, 2004.
[34] E. Majchrzak, M. Jasiński, D. Janisz. Identification of thermal parameters of biological tissue. Acta of Bioengineering and Biomechanics, 6: 467-470, 2004.
[35] E. Majchrzak, M. Jasiński, A. Pownuk. A boudary element model of burns of a skin with interval thermophysical parameters. Acta of Bioengineering and Biomechanics, 1: 305-308, 1999.
[36] E. Majchrzak, G. Kałuża. Sensitivity analysis of biological tissue freezing process with respect to the radius of spherical cryoprobe. 16th International Conference on Computer Methods in Mechanics CMM-2005, CD-ROM Proceedings, Częstochowa, 2005.
[37] E. Majchrzak, B. Mochnacki. The model of ice-ball formation during the brain tissue freezing on the basis of the BEM. Proceedings of the Int. Symposium on Boundary Element Method IABEM'98, 151-152, Paris, France, 1998.
[38] E. Majchrzak, B. Mochnacki. Numerical model of heat transfer between blood vessel and biological tissue. Computer Assisted Mechanics and Engineering Sciences, 6: 439-447, 1999.
[39] E. Majchrzak, B. Mochnacki. Analysis of bioheat transfer in the system of blood vessel-biological tissue. In: T. Burczyński, ed., IUTAM/IACM/IABEM Symposium on Advanced Mathematical and Computational Mechanics Aspects of the Boundary Element Method, Cracow, Poland, 31 May-3 June 1999, 201-211. Kluwer Academic Publishers, Dordrech-Boston-London, 2001.
[40] E. Majchrzak, B. Mochnacki. Analysis of thermal processes occuring in tissue with a tumor region using the BEM. Journal of Theoretical and Applied Mechanics, 6: 101-112, 2002.
[41] E. Majchrzak, B. Mochnacki. The BEM application for numerical solution of non-steady and non-linear thermal diffusion problems. Computer Assisted Mechanics and Engineering Sciences, 3: 327-346, 1996.
[42] E. Majchrzak, B. Mochnacki, M. Jasiński. Numerical modelling of bioheat transfer in multi-layer skin tissue domain subjected to a flash fire. Computational Fluid and Solid Mechanics, 2: 1766-1770, Elsevier, 2003.
[43] E. Majchrzak, B. Mochnacki, R. Szopa. Numerical analysis of temperature distribution in the skin tissue with a tumor. Annales Academiae Medicae Silesiensis, 32: 135-142, 2001.
[44] E. Majchrzak, M. Paruch. Estimation of internal heat source in a tumor region on the basis of skin surface temperature. Acta of Bioengineering and Biomechanics. 6: 471-475, 2004.
[45] E. Majchrzak, M. Paruch. Localization of tumor region using the information concerning skin surface temperature. In: H. Rodrigues et. al., eds., II Int. Conf. on computational Bioengineering, 1078-1087, Lisbon, 2005.
[46] E. Majchrzak, M. Paruch, T. Burczyński. A comparison of different techniques of inverse problem solution for identification of tumor thermal parameters. In: A. Garstecki, B. Mochnacki, N. Sczygiol, eds., 16th International Conference on Computer Methods in Mechanics CMM-2005, CD-ROM Proceedings, Częstochowa, 2005.
[47] B. Mochnacki, M. Dziewoński. Numerical analysis of cyclic freezing/thawing process of biological tissue. Acta of Bioengineering and Biomechanics. 3: 361-368, 2001.
[48] B. Mochnacki, M. Dziewoński. Numerical analysis of cyclic freezing, Acta of Bioengineering and Biomechanics, 6: 476-479, 2004.
[49] B. Mochnacki, S. Preus. Numerical modeling of frost-bite process. 9th Int. Conf. on Numerical Methods in Continuum Mechanics, CD-ROM Proceedings, 1-7, Zilina, 2003.
[50] B. Mochnacki, G. Kałuża, Modelling of biological tissue freezing process with regard to the shape sensitivity analysis. In: H. Rodrigues et. al. eds., II Int. Conf. on computational Bioengineering, 781-792, Lisbon, 2005.
[51] B. Mochnacki, S. Lara. The enthalpy approach in numerical modelling of skin tissue frostbite. In: T. Burczyński, P. Fedeliński, E. Majchrzak eds., 15th International Conference on Computer Methods in Mechanics CMM-2003, 1-4, CD-ROM Proceedings, 2003.
[52] B. Mochnacki, E. Majchrzak. Sensitivity of the skin tissue on the activity of external heat sources. Computer Modeling in Engineering and Sciences, 4: 431-438, 2003.
[53] B. Mochnacki, E. Majchrzak, G. Kałuża. Modelling of biological tissue freezing process with regard to sensitivity analysis. Acta of Bioengineering and Biomechanics, 6: 480-484, 2004.
[54] B. Mochnacki, E. Majchrzak, M. Lupa. Coupled model of thermal processes in the system blood vessel-biological tissue. In: W. Wunderlich, ed., Proceedings of the European Conference on Computational Mechanics 1999, 1-12. Munich, Germany, 1999.
[55] B. Mochnacki, E. Majchrzak, R. Szopa. Application of the BEM for numerical analysis of temperature field in the skin tissue with a tumor. In: Z. Yao, M.H. Aliabadi, eds., Proceedings of the Third International Conference on Boundary Element Techniques, 399-404. Tsinghua University Press, Springer, 2002.
[56] B. Mochnacki, E. Pawlak, S. Lara. Application of generalized finite difference method in numerical modelling of bioheat transfer processes. Acta of Bioengineering and Biomechanics, 4: 478-479, 2002.
[57] A.J. Nowak, CA. Brebbia. The multiple reciprocity method — a new approach for transforming BEM domain integrals to the boundary. Engineering Analysis with Boundary Elements, 6: 164-167, 1989.
[58] A.J. Nowak, CA. Brebbia. Numerical verification of the multiple reciprocity method for linear potential problems with body forces. Engineering Analysis with Boundary Elements, 10: 259-266, 1992.
[59] M.N. Ozisik, H.R.B. Orlande. Inverse Heat Transfer: Fundamentals and Applications. Taylor and Francis, Pennsylvania, 1999.
[60] H.H. Pennes. Analysis of tissue and arterial blood temperatures in the resting human forearm, Journal of Applied Physiology, 1: 93-122, 1948.
[61] J. Rogers, A. Berger, M. Ciment. The alternating phase truncation method for a Stefan problem. SIAM Journal of Numerical Analysis, 16: 562-587, 1979.
[62] D.A. Torvi, J.D. Dale. A finite element model of skin subjected to a flash fire. Journal of Mechanical Engineering, 116: 250-255, 1994.

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-article-BPB2-0017-0005