Optimizing heat shock protein expression induced by prostate cancer laser therapy through predictive computational models

Thermal therapy efficacy can be diminished due to heat shock protein (HSP) induction in regions of a tumor where temperatures are insufficient to coagulate proteins. HSP expression enhances tumor cell viability and imparts resistance to chemotherapy and radiation treatments, which are generally empl...

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Bibliographic Details
Published in:Journal of Biomedical Optics 2006-07, Vol.11 (4), p.041113-0411116
Main Authors: Rylander, Marissa Nichole, Feng, Yusheng, Zhang, Yongjie, Bass, Jon, Jason Stafford, R, Volgin, Andrei, Hazle, John D, Diller, Kenneth R
Format: Article
Language:English
Subjects:
Animals
Biomarkers, Tumor - metabolism
Computer Simulation
damage
Gene Expression Regulation, Neoplastic - radiation effects
heat shock proteins
hyperthermia
Laser Coagulation - methods
Male
Mice
Models, Biological
Neoplasm Proteins - metabolism
Prognosis
prostate cancer
Prostatic Neoplasms - metabolism
Prostatic Neoplasms - therapy
Therapy, Computer-Assisted - methods
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Summary:Thermal therapy efficacy can be diminished due to heat shock protein (HSP) induction in regions of a tumor where temperatures are insufficient to coagulate proteins. HSP expression enhances tumor cell viability and imparts resistance to chemotherapy and radiation treatments, which are generally employed in conjunction with hyperthermia. Therefore, an understanding of the thermally induced HSP expression within the targeted tumor must be incorporated into the treatment plan to optimize the thermal dose delivery and permit prediction of the overall tissue response. A treatment planning computational model capable of predicting the temperature, HSP27 and HSP70 expression, and damage fraction distributions associated with laser heating in healthy prostate tissue and tumors is presented. Measured thermally induced HSP27 and HSP70 expression kinetics and injury data for normal and cancerous prostate cells and prostate tumors are employed to create the first HSP expression predictive model and formulate an Arrhenius damage model. The correlation coefficients between measured and model predicted temperature, HSP27, and HSP70 were 0.98, 0.99, and 0.99, respectively, confirming the accuracy of the model. Utilization of the treatment planning model in the design of prostate cancer thermal therapies can enable optimization of the treatment outcome by controlling HSP expression and injury.
ISSN:1083-3668
1560-2281
DOI:10.1117/1.2241310