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The aim of this paper is to review available results pertaining to various heat transfer problems of biomechanics. The present part is concerned with low-temperature phenomena, namely the issues of cryosurgery, cryopreservation and cryotherapy. The description of damage mechanisms is also discussed along with its possible applications.
Czasopismo
Rocznik
Tom
Strony
3--22
Opis fizyczny
Bibliogr. 46 poz., tab., wykr.
Twórcy
autor
- Polish Academy of Sciences, Institute of Fundamental Technological Research, Świętokrzyska 21, 00-049 Warsaw, Poland
autor
- Polish Academy of Sciences, Institute of Fundamental Technological Research, Świętokrzyska 21, 00-049 Warsaw, Poland
Bibliografia
- [1] BALDERSON D.D., CURREY J.D., PEGG D.E., Both freeze-drying and desiccation of cortical bone allografts preserve mechanical properties satisfactorily, Acta Bioengng. Biomech., 2002, 4, (suppl. 1), 427–428.
- [2] BARRON R.F., Cryogenic heat transfer, Taylor&Francis, Bristol PA, 1999.
- [3] BROWN N.J., BAYJOO P., REED M.W.R., Effect of cryosurgery on liver blood flow, Br. J. Cancer, 1993, 68, 10–12.
- [4] BROWN N.J., POLLOCK K.J., BAYJOO P., REED M.W.R., The effect of cryotherapy on the cremaster muscle microcirculation in vivo, Br. J. Cancer, 1994, 69, 706–710.
- [5] CARSLAW H.S., JAEGER J.C., Conduction of heat in solids, Oxford University Press, 1954.
- [6] COOPER T.E., PETROVIC W.K., An experimental investigation of the temperature field produced by a cryosurgical cannula, J. Heat Transfer, 1974, 96, 415–420.
- [7] DEVIREDDY R.V., BISCHOF J.C., Measurement of water transport during freezing in mammalian liver tissue. Part II. The use of differential scanning calorimetry, J. Biomech. Eng., 1998, 120, 559–569.
- [8] DEVIREDDY R.V., SMITH D.J., BISCHOF J.C., Effect of microscale mass transport and phase change on numerical prediction of freezing in biological tissues, J. Heat Transfer, 2002, 124, 365–374.
- [9] DILLER K.R., Modelling of bioheat transfer processes at high and low temperature, Advances in Heat Transfer, 1992, 22, 177–357.
- [10] FRÉMOND M., Non-smooth thermomechanics, Springer, Berlin, 2002.
- [11] FUNG Y.C., Foundation of solid mechanics, Prentice Hall, 1965.
- [12] HOFFMANN N.E., BISCHOF J.C., Cryosurgery of normal and tumor tissue in the dorsal skin flap chamber. Part I. Thermal response, J. Biomech. Eng., 2001, 123(4), 301–309.
- [13] HOFFMANN N.E., BISCHOF J.C., Cryosurgery of normal and tumor tissue in the dorsal skin flap chamber. Part II. Injury response, J. Biomech. Eng., 2001, 123(4), 310–316.
- [14] JUTTE L.S., MERKRICK M.A., INGERSOLL C.D., EDWARDS J.E., The relationship between intramuscular temperature, skin temperature, and adipose thickness during cryotherapy and rewarming, Arch. Phys. Med. Rehabil., 2001, 82, 845–850.
- [15] KSIĘŻOPOLSKA-PIETRZAK K., Cryotherapy use in osteoporosis treatment (in Polish), Pol. Mer. Lek., 1998, 5(28), 930–933.
- [16] KSIĘŻOPOLSKA-PIETRZAK K., GAJEWSKI M., POKRZYWNICKA-GAJEK I., JÓŹWICKA M., MAŁDYK P., MAŚLIŃSKI S., LESIAK A., The effect of cryotherapy on oxygenic stress in rheumatoid arthritis (in Polish), Reumatologia, 1999, 37(4), 353–359.
- [17] MAJCHRZAK E., Numerical modelling of bio-heat transfer using the boundary element method, J. Theor. Appl. Mech., 1998, 36(2), 437–455.
- [18] MARTIN R.B., SHARKEY N.A., Mechanical effects of postmortem change, preservation and allograft bone treatments, [in:] Bone mechanics handbook, S.C. Cowin, Ed. CRC Press, Boca Raton, 2001, pp. (20–1)–(20–24).
- [19] MAZUR P., Cryobiology – the freezing of biological systems, Science, 1970, 168, 939–949.
- [20] MOCHNACKI B., DZIEWOŃSKI M., Numerical analysis of cyclic freezing/thawing process of bio- logical tissue, Acta Bioengng. Biomech., 2001, 3, 361–368.
- [21] OSTROWSKA-MACIEJEWSKA J., Mechanics of deformable bodies (in Polish), Wydawnictwa Naukowe PWN, Warszawa, 1994.
- [22] PAZHAYANNUR P.V., BISCHOF J.C., Measurement and simulation of water transport during freezing in mammalian liver tissue, J. Biomech. Eng., 1997, 119(4), 269–277.
- [23] RABIN Y., OLSON P., TAYLOR M.J., STEIF P.S., JULIAN T.B., WOLMARK N., Gross damage accumulation in frozen rabbit liver due to mechanical stresses at cryogenic temperatures, Cryobiology, 1997, 34, 394–405.
- [24] RABIN Y., SHITZER A., Numerical solution of the multidimensional freezing problem during cryosurgery, J. Biomech. Eng., 1998, 120(1), 32–37.
- [25] RABIN Y., STEIF P.S., Analysis of thermal stresses around a cryosurgical probe, Cryobiology, 1996, 33, 276–290.
- [26] RABIN Y., STEIF P.S., Thermal stresses in a freezing sphere and its application to cryobiology, J. Appl. Mech., 1998, 65, 328–333.
- [27] RABIN Y., STEIF P.S., Thermal stress modeling of the freezing of biological tissue, Advances in Heat and Mass Transfer in Biotechnology, 1999, 183–187.
- [28] RABIN Y., STEIF P.S., Thermal stress modeling in cryosurgery, Int. J. Solids Structures, 2000, 37, 2363–2375.
- [29] RABIN Y., STEIF P.S., TAYLOR M.J., JULIAN T.B., WOLMARK N., An experimental study of the mechanical reponse of frozen biological tissues at cryogenic temperatures, Cryobiology, 1996, 33, 472–482.
- [30] RABIN Y., TAYLOR M.J., WOLMARK N., Thermal expansion measurements of frozen biological tissues at cryogenic temperatures, J. Biomech. Eng., 1998, 120(2), 259–266.
- [31] RINCÒN L., SCHATZMANN L., BRUNNER P., STÄUBLI H.U., FERGUSON S.J., OXLAND T.R., NOLTE L.P., Design and evaluation of a cryogenic soft tissue fixation device – load tolerances and thermal aspects, J. Biomech., 2001, 34, 393–397.
- [32] RODRIGUES J.F., The variational inequality aproach to the one-phase Stefan problem, preprint, Centro de matemática e aplicaçoes fundamentais das universidades de Lisboa.
- [33] ROGERS J., BERGER A., CIMENT M., Alternating phase truncation method for a Stefan problem, SIAM Journal of Numerical Analysis, 1979, 16, 562–587.
- [34] RUBINSKY B., SHITZER A., Analysis of Stefan-like problem in a biological tissue around a cryo- surgical probe, J. Heat Transfer, 1976, 98, 514–519.
- [35] SHI X., DATTA A.K., MUKHERJEE S., Thermal fracture in a biomaterial during rapid freezing, J. Therm. Stress, 1999, 22, 275–292.
- [36] SHI X., DATTA A.K., MUKHERJEE Y., Thermal stresses from large volumetric expansion during freezing of biomaterials, J. Biomech. Eng., 1998, 120(6), 720–726.
- [37] SMITH D.J., SCHULTE M., BISCHOF J.C., The effect of dimethylsoxide on the water transport response of rat hepatocytes during freezing, J. Biomech. Eng., 1998, 120(5), 549–558.
- [38] STAŃCZYK M., TELEGA J.J., Modelling of heat transfer in biomechanics – a review. Part II. Orthopaedics, Acta Bioengng. Biomech., 2002, 4(2), 3–31.
- [39] STAŃCZYK M., TELEGA J.J., Modelling of heat transfer in biomechanics – a review. Part I. Soft tissues, Acta Bioengng. Biomech., 2002, 4, (1), 31–61.
- [40] STEFAN J., Ann. Phys. Chem., 1891, 42, 269–286.
- [41] TATSUTANI K., RUBINSKY B., A method to study intracellular ice nucleation, J. Biomech. Eng., 1998, 120(1), 27–31.
- [42] TONER M., CRAVALHO E.G., KAREL M., Thermodynamics and kinetics of intracellular ice formation during freezing of biological cells, J. Appl. Phys., 1990, 67, 1582–1593.
- [43] VOLLER V.R., SWAMINATHAN C.R., Treatment of discontinuous thermal conductivity in control- volume solutions of phase change problems, Numerical Heat Transfer, 1993, 24, 161–180.
- [44] WINZELL B., Finite element Galerkin methods for multi-phase Stefan problems, Appl. Math. Modelling, 1983, 7, 329–344.
- [45] YAMAUCHI T., The cryogenic therapy and the 24 hours rehabilitation, [in:] IX European Congress of Reumatology, Wiesbaden, 1979, p. 1025.
- [46] ZDROJEWICZ Z., ŁASISZ B., STRYCHALSKI J., DUL W., Cryotherapy of rheumatoid arthritis (in Polish), Wiad. Lek., 1988, 41, 930–933.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-BPB1-0016-0001