A Cryoinjury Model Using Engineered Tissue Equivalents for Cryosurgical Applications

Cryosurgery is emerging as a promising treatment modality for various cancers, but there are still challenges to be addressed to improve its efficacy. Two primary challenges are determining thermal injury thresholds for various types of cell/tissue, and understanding of the mechanisms of freezing induced cell/tissue injury within a cryolesion. To address these challenges, various model systems ranging from cell suspensions to three-dimensional in vivo tissues have been developed and used. However, these models are either oversimplifications of in vivo tissues or difficult to control and extract precise experimental conditions from. Therefore, a more readily controllable model system with tissue-like characteristics is needed. In this study, a cryoinjury model was developed using tissue engineering technology, and the capabilities of the model were demonstrated. Engineered tissue equivalents (TEs) were constructed by seeding and culturing cells in a type I collagen matrix. Two different cell lines were used in this study, AT-1 rat prostate tumor cells and LNCaP human prostate cancer cells. The constructed TEs underwent a freeze/thaw cycle imitating in vivo cryosurgery. Thermal conditions within TEs during freeze/thaw cycles were characterized, and the responses of TEs to these thermal conditions including freezing induced cellular injury and extracellular matrix damage were investigated at three different time points. The results illustrate the feasibility to establish thermal thresholds of cryoinjury for different cell/tissue types using the presently developed model, and its potential capabilities to study cell death mechanisms, cell proliferation or migration, and extracellular matrix structural damage after a freeze/thaw cycle.

[1]  N E Hoffmann,et al.  Cryosurgery of normal and tumor tissue in the dorsal skin flap chamber: Part II--injury response. , 2001, Journal of biomechanical engineering.

[2]  J. Bischof,et al.  In vitro model systems for evaluation of smooth muscle cell response to cryoplasty. , 2005, Cryobiology.

[3]  J. Bischof,et al.  A parametric study of freezing injury in AT-1 rat prostate tumor cells. , 1999, Cryobiology.

[4]  Y Rabin,et al.  Long-term follow-up post-cryosurgery in a sheep breast model. , 1999, Cryobiology.

[5]  Baust,et al.  Cryosurgical Modeling: Sequence of Freezing and Cytotoxic Agent Application Affects Cell Death. , 1999, Molecular urology.

[6]  M. Toner,et al.  Cellular response of mouse oocytes to freezing stress: prediction of intracellular ice formation. , 1993, Journal of biomechanical engineering.

[7]  John C Bischof,et al.  The cryobiology of cryosurgical injury. , 2002, Urology.

[8]  J. Lovelock,et al.  The haemolysis of human red blood-cells by freezing and thawing. , 1953, Biochimica et biophysica acta.

[9]  J C Bischof,et al.  Cryosurgery of dunning AT-1 rat prostate tumor: thermal, biophysical, and viability response at the cellular and tissue level. , 1997, Cryobiology.

[10]  B Rubinsky,et al.  A morphological study of cooling rate response in normal and neoplastic human liver tissue: cryosurgical implications. , 1993, Cryobiology.

[11]  P. Mazur Cryobiology: the freezing of biological systems. , 1970, Science.

[12]  J. Bischof,et al.  Investigation of the mechanism and the effect of cryoimmunology in the Copenhagen rat. , 2001, Cryobiology.

[13]  John C. Bischof,et al.  Enhancement of cell and tissue destruction in cryosurgery by use of eutectic freezing , 2003, SPIE BiOS.

[14]  B Rubinsky,et al.  Effect of thermal variables on frozen human primary prostatic adenocarcinoma cells. , 1996, Urology.

[15]  P. Mazur,et al.  Contributions of unfrozen fraction and of salt concentration to the survival of slowly frozen human erythrocytes: influence of warming rate. , 1983, Cryobiology.

[16]  A. Gage,et al.  Mechanisms of tissue injury in cryosurgery. , 1998, Cryobiology.

[17]  Bumsoo Han,et al.  Direct cell injury associated with eutectic crystallization during freezing. , 2004, Cryobiology.

[18]  S. A. Zacarian The observation of freeze-thaw cycles upon cancer-cell suspensions. , 1977, The Journal of dermatologic surgery and oncology.

[19]  A. D. Solomon,et al.  Mathematical Modeling Of Melting And Freezing Processes , 1992 .

[20]  J. Hulbert,et al.  BIOCHEMICAL ALTERATIONS AND TISSUE VIABILITY IN AT-1 PROSTATE TUMOR TISSUEAFTER IN VITRO CRYODESTRUCTION , 1997 .

[21]  D. Pegg,et al.  The "unfrozen fraction" hypothesis of freezing injury to human erythrocytes: a critical examination of the evidence. , 1989, Cryobiology.

[22]  N E Hoffmann,et al.  Cryosurgery of normal and tumor tissue in the dorsal skin flap chamber: Part I--thermal response. , 2001, Journal of biomechanical engineering.

[23]  L. Mir,et al.  Treatment of cancer with cryochemotherapy , 2002, British Journal of Cancer.

[24]  W H Yang,et al.  An in vitro monitoring system for simulated thermal process in cryosurgery. , 2000, Cryobiology.

[25]  B. Rubinsky,et al.  Chemical adjuvant cryosurgery with antifreeze proteins , 1997, Journal of surgical oncology.