Development of monitor unit calculation program for integration with radiation therapy information system

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Published: Jun 11, 2023
Keywords:
Clarkson’s integration method IAEA TECDOC 1540 monitor unit programing.

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Damrongsak Tippanya
Division of Radiation Therapy, Radiology Department, Faculty of Medicine, Chiang Mai University, Chiang Mai, Thailand
Ekasit Tharavichitkul
Division of Radiation Therapy, Radiology Department, Faculty of Medicine, Chiang Mai University, Chiang Mai, Thailand
Sumbhat Wanwilairat
Thai Petroleum exploration and Production Company, Thailand
Thanit Chaiwiang
Datasoft Computer Company Limited, Thailand
Somsak Wanwilairat
Division of Radiation Therapy, Radiology Department, Faculty of Medicine, Chiang Mai University, Chiang Mai, Thailand

Abstract

Introduction: Monitor unit (MU) calculation is the main process of 2D technique teletherapy planning. Using of monitor unit calculation program will increase the performance and reduce errors of 2D technique teletherapy.


Objectives: To develop a monitor unit (MU) calculation program for integration with an in-house radiation therapy information system (RTIS). The developed program was used for 6 MV photon MU calculation in 2D technique teletherapy.


Materials and methods: MU calculation program was based on the Clarkson’s integration method and divided into two parts. The first part was for scatter sector radius determination from 2D simulation images. This part was programmed based on JAVA language. The second part was MU calculation using Clarkson’s irregular field method. The latter part was programmed based on Microsoft Visual Foxpro language. Calculated MU was verified by dose measurement following the test cases (1a, 1b, 1c, 2a, 2b and 7) of IAEA TECDOC 1540. After dose difference between the calculation and the measurement was within acceptance criteria, the program was integrated to the RTIS.


Results: The scatter sector radius determination program workflow included selecting of the angle between each radius, calibrating of image distance, defining of isocenter, field size edge defining and equivalent square field. The program generated radius distance and exported to a text file. The MU calculation part workflow included input of prescription dose and tumor depth. Following TECDOC 1540, dose different ranging between calculation and measurement was -1.98% to 1.40% for Test case 1a, 1b, 1c, 2a and 2b, and -3.02% to 0.08% for Test case 7. The program was integrated to dosimetry menu in RTIS which could help calculate MU for each field size of each patient and record to patient database.


Conclusion: MU calculation computer program was developed, verified and integrated to RTIS. The program was used for 6 MV photon monitor unit calculation in 2D technique irradiation.


Journal of Associated Medical Sciences 2017; 50(1): 54-63. Doi: 10.14456/jams.2017.5

Article Details

How to Cite
Tippanya, D., Tharavichitkul, E., Wanwilairat, S., Chaiwiang, T., & Wanwilairat, S. (2023). Development of monitor unit calculation program for integration with radiation therapy information system. Journal of Associated Medical Sciences, 50(1), 54. Retrieved from https://he01.tci-thaijo.org/index.php/bulletinAMS/article/view/73579
Issue
Vol. 50 No. 1 (2017): January-April
Section
Research Articles
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This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.

Personal views expressed by the contributors in their articles are not necessarily those of the Journal of Associated Medical Sciences, Faculty of Associated Medical Sciences, Chiang Mai University.

References

1. Mandal A, Asthana AK, Aggarwal LM. Development of an electronic radiation oncology patient information management system. J Cancer Res Ther 2008; 4:178-85.

2. Gibbons JP. Monitor unit calculations for external photon and electron Beams, 2001.

3. Khan FM. The physics of radiation therapy. 2nd edition. William & Wilkins. Maryland. USA, 1994.

4. Bentel GC. Radiation therapy planning. 2nd edition. McGraw-Hill. USA, 1996.

5. International Atomic Energy Agency. Specification and acceptance testing of radiotherapy treatment planning systems. IAEA-TECDOC-1540. IAEA, Vienna, 2007.

6. Bukovitz AG. Computer program for central axis dose calculations for high energy photons. ActaRadiol 1977; 16: 427-32.

7. Cohen M., Jones DEA, Greene D. Central axis depth dose data for use in radiotherapy. Brit J Radiol, Suppl 1972; 11: 61-72.

8. Konrad WL, Peter BD. Independent corroboration of monitor unit calculations performed by a 3D computerized planning system. Am Coll Med Phys 2000; 1:120-5.

9. Zhu J, Yin FF, Kim JH. Point dose verification for intensity modulated radiosurgery using Clarkson’s method. Med Phys 2003; 30: 2218-21.

10. Kenny MB. A PC-based program for routine calculation of monitor units in radiotherapy. Australas Phys Eng Sci Med 1992; 15:153-4.

11. Cunningham JR, Shrivastava PN, Wilkinson JM. Program IRREG-Calculation of dose from irregularly shaped radiation beams. Comput Programs Biomed 1972; 2:192-9.

12. Steidley KD, Gamper C, Greener A, Caggiano A. A Clarkson’s sector integration routine for personal computers. Med Phys 1994; 21: 61-4.

13. Aird EGA, Burns JE, Day MJ, Duane S., Jordan TJ, Kacperek A. et al. Central axis depth dose data for use in radiotherapy. Brit J Radiol, Suppl 1996; 25: 62-109.

14. Gibbons JP, Khan FM. Calculation of dose in asymmetric photon fields. Med Phys 1995; 22(9): 1451-7.

15. Visual FoxPro. [cited2016Jul 1].Available from: https://en.wikipedia.org/wiki/Visual_FoxPro.

16. Sinrungriangkul K. Microsoft Visual Foxpro 6: building applications. Starcom. Thailand; 1999 (in Thai).

17. Microsoft Visual FoxPro Developer Center: System Requirements. [cited2016Jul 1].Available from: https://msdn.microsoft.com/en-us/vfoxpro/bb190292.aspx.

18. Doung Bawakotketsakul, Database development by FoxPro. SE-EDUCATION. Thailand; 1997 (in Thai).