DETERMINATION OF FRACTIONATION SCHEME BASED ON REPAIR EFFECT USING EQUIVALENT UNIFORM DOSE (EUD) MODEL
Radiotherapy treatment planning is required to obtain an optimal balance between delivering a high dose to target volume and a low dose to organ at risks. In this planning, it is also necessary to determine the appropriate fractionation scheme for each patient. One of the commonly used methods to...
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| Format: | Final Project |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/78066 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Radiotherapy treatment planning is required to obtain an optimal balance between delivering a
high dose to target volume and a low dose to organ at risks. In this planning, it is also necessary
to determine the appropriate fractionation scheme for each patient. One of the commonly used
methods to determine the fractionation scheme is calculating the Normal Tissue Complication
Probability (NTCP) and Tumor Control Probability (TCP) parameters. In this study, the
Equivalent Uniform Dose (EUD) model is used to calculate NTCP and TCP. This model is
based on a non-uniform dose distribution that is sensitive to the biological factors of cells. The
biological factor examined in this research is the repair effect, which is the ability of cells to
repair themselves after being radiated. Thus, the objective of this research is to determine the
fractionation scheme based on NTCP calculations using the EUD model while taking into
account the repair effect. The data used in this study were obtained from 10 patients with
glioblastoma brain cancer in the form of cumulative DVH (dose-volume histogram) and total
time of radiation. Based on the NTCP calculations, the average risk of organ complication for
each patient appears to be close to zero, with a range of values from 2 x 10-6% to 1 x 10-1%.
These results indicate that the treatment planning conducted is proven to be safe and there are
no complications for the patients. Furthermore, based on the NTCP and TCP calculations, the
best fractionation scheme is hypofractionation, which remains safe while considering the dose
limit for each normal organ surrounding the target. |
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