One treatment for cervical cancer is to use radioactive sources that directly target the cancer cell called brachytherapy. This study is aimed to determine dose distribution at phantom pelvis using the DOSXYZnrc Monte Carlo code. The phantom was derived from a CT scan image of the DICOM-type pelvis with a size of 50 × 50 × 28.8 cm obtained from Santosa Kopo Hospital. The source used was Ir-192, which makes an asymmetrical beam with a size of 0.45 × 0.09 × 0.09 cm. Monte Carlo simulation was performed to determine the dose distribution of the Ir-192 source on cervical cancer CT images based on the Manchester system. The Monte Carlo simulation was divided into two models with distance variations on the applicator. Model A used TPS data with a distance between sources of 0.9 cm, while model B had a distance between sources of 0.5 cm. The distribution of dose resulting from the Monte Carlo simulation was analyzed and compared with TPS data. The results showed that at the range of 50 %, dose distribution in model A reaches the end of 3.9 cm. When compared to the range of 50 % dose distribution at the TPS results that reaches the point of 4 cm, it produces a deviation value of 2.5 %, which is still within the tolerance range. Model A and Model B provide different dose distribution. In model B, it reaches 3.86 cm, resulting in a deviation of 1.02 %, which is still within the tolerance range. The resulting γ-index value for the 50 % dose distribution was 2.26, while the whole area's GPR value was 94.13 %. This indicates a difference in dose distribution between the two models. Therefore, the smaller the distance between the sources, the shorter the dose distribution range with relatively more uniform dose distribution. 

Brachytherapy; CT image; Ir-192 source; Manchester system; Monte carlo simulation

F. Bray, J. Ferlay, I. Soerjomataram et al., CA Cancer J. Clin. 68 (2018) 394.

E. B. Podgorsak, Radiation Oncology Physics: A Handbook for Teachers and Students, International Atomic Energy Agency, Vienna (2005) 210.

Junios, Sainstek: Jurnal Sains dan Teknologi 4 (2012) 26. (in Indonesian)

Junios and D. Kariman, Jurnal Iptek Terapan 10 (2016) 155. (in Indonesian)

F. P. Krisna, S. Yani, Junios et al., J. Phys. Conf. Ser. 1505 (2020) 012051.

S. S. O. Fonseca-Rodrigues, M. Begalli, P. P. Q. Filho et al., Monte Carlo simulation of an Ir-192 brachytherapy source spectra, geometry and anysotropy factors using Geant4 Code, Proceedings of the 2009 IEEE Nuclear Science Symposium Conference Record (NSS/MIC) (2009) 544.

A. Sharma, Manchester System For Gynecological Applications (2018).

N. Papanikolaou, J. J. Battista, A. L. Boyer et al., Tissue Inhomogeneity Corrections for Megavoltage Photon Beams, in: AAPM Report No. 85, Medical Physics Publishing, U.S.A. (2004) 1.

M. Saito, Radiol. Phys. Technol. 12 (2019) 105.

A. Manikandan, B. Sarkar, V. T. Rajendran et al., J. Med. Phys. 38 (2013) 148.

N. P. Patel, B. Majumdar, P. K. Hota et al., J. Cancer Res. Ther. 1 (2005) 84.

Junios, I. Irhas, N. Novitrian et al., Radiol. Phys. Technol. 13 (2020) 398.

B. Walters, I. Kawrakow, and D.W.O. Rogers, DOSXYZnrc Users Manual, in: NRCC Report PIRS-794revB, Ionizing Radiation Standards National Research Council of Canada, Ottawa (2011) 130.

J. E. Gentle, Statistic and Computing, in: Random Number Generation and Monte Carlo Methods, 2nd ed., Springer Science Business Media Inc, U.S.A. (2003) 25.

I. Kawrakow, E. Mainegra-Hing, D. W. O. Rogers et al., The EGSnrc Code System: Monte Carlo Simulation of Electron and Photon Transport, in: NRCC Report PIRS-701, NRC Canada, Ottawa (2011) 125.

H. Moseley, NCRP report no. 119. A practical guide to the determination of human exposure to radiofrequency fields: National Council on Radiation Protection and Measurements, Bethesda, U.S.A. (1993) 397.