Interventional cardiology is a minimally-invasive imaging procedure that allows medical doctor to evaluate and treat structural heart diseases. Due to its main advantages of avoidance of the scars and pain, as well as long post-operative recovery, interventional cardiology procedures have rapidly been growing. However, the increasingly complex and time-consuming procedures in interventional cardiology may increase the radiation exposure received by patients. This paper describes a study to measure patient radiation doses in terms of air kerma and kerma air-product (KAP) for various types of interventional cardiology procedures conducted in Indonesia. The measurements were performed at the interventional cardiology or cardiac catheterization facilities in sixteen hospitals in ten cities in Indonesia during the years of 2015 to 2019. A total of 147 procedures conducted on adult patients were used in this study. The type of procedure, total KAP, and air kerma were recorded after each procedure was completed. The demographic data of the patients were also recorded. The results showed that the mean air kerma and KAP measured for CA (coronary angiography) procedure were 680.73±57.85 mGy and 12.52±5.86 Gy cm², respectively, while the values for PCI (percutaneous coronary intervention) procedure were 890.66±38.76 mGy and 20.18±9.37 Gy cm², respectively. These results are well within the ranges reported by other previous studies. The results are somewhat affected by the     body mass index of patients, while the fatal cancer risks among patients of CA and PCI procedures are comparable with those among interventional radiology procedures patients.

D. P. Faxon and D. O. Williams, Circ. Cardiovasc. Interv. 5 (2012) 325.

J. Järvinen, J. Sierpowska, T. Siiskonen et al., Radiat. Protect. Dos. 185 (2019) 483.

E. Barbato, M. Noc, A. Baumbach et al., Eur. Heart J. 41 (2020) 2579.

A. B. C. Alvarez, O. R. Leor, R. Moreno et al., Rev. Esp. Cardiol. 71 (2018) 1036.

C. Rizk, G. Fares, F. Vanhavere et al., Radiat. Protect. Dos. 183 (2019) 375.

J. E. Ngaile, P. K. Msaki, R. Mvungi et al., Radiat. Protect. Dos. 181 (2018) 317.

F. A. Mettler, M. Mahesh, M. Bhargavan-Chatfield et al., Radiology 295 (2020) 418.

I. Firdaus, Heart Disease Data, Financing and Indonesian Heart Association’s Strategy for Facing Health Insurance Program. (in Indonesian). https://web.persi.or.id/images /2019/data/materi_fgd_medverify/materi_drisman.pdf. Retrieved in February (2022)

M. K. Saeed, Radiat. Protect. Dos. 174 (2017) 109.

M. G. Andreassi, E. Piccaluga, G. Guagliumi, et al., Circ. Cardiovasc. Interv. 9 (2016) e003273.

Z. Valuckiene, M. Jurenas and I. Cibulskaite, J. Radiol. Prot. 36 (2016) 695.

K. Riabroi, K. Khanungwanitkul, P. Wattanapongpitak et al., Neurointervention 13 (2018) 110.

A. Karambatsakidou, Radiation Dose and Related Risk in Interventional Cardiology, Ph.D. Thesis, Karolinska Institutet, Sweden (2021).

Anonymous, UNSCEAR’s Global Survey of Radiation Exposure: Medical Exposure. http://www.survey.unscear.org/lib/exe/fetch.php/unscear_medical_exposure_survey _manual_ v2.pdf. Retrieved in March (2019)

Anonymous, 2018 National Report on Research of Basic Health, Research and Development Agency of the Ministry of Health, Jakarta (2019) 580.

S. J. M. Alqahtani, R. Welbourn, J. R. Meakin, et al., J. Radiol. Prot. 39 (2019) 38.

A. Brindhaban, Radiat. Protect Dos. 184 (2019) 1.

B. Osei, L. Xu, A. Johnston et al., Br. J. Radiol. 92 (2019) 20181021.

R. N. Uppot, Br. J. Radiol. 91 (2018) 20170931.

R. D. Madder, S. VanOosterhout, A. Mulder et al., Circ. Cardiovasc. Interv. 12 (2019) e006823.

E. Hiswara, K. H. Ng, H. Sofyan et al., Atom Indones. 45 (2019) 37.

Anonymous, The 2007 Recommendations of the International Commission on Radiological Protection, ICRP Publication 103, Ann. ICRP 37 (2007) 53.

L. Ukkola, H. Oikarinen, A. Henner et al., Eur. Radiol. 26 (2016) 436.

M. Alkhorayef, E. Babikir, A. Alrushoud et al, Saudi. J. Biol. Sci. 24 (2017) 235.

A. Sulieman, O. Serhan, H. I. Al-Mohammed et al., Saudi. J. Biol. Sci. 26 (2019) 1107.