Background: The human body's anatomical structure may be seen in radiological image findings. The proper exposure factor must be given in order to produce radiographic findings. The amperage value times the exposure period is equal to mAs. A darker image will result from a larger mA factor or longer exposure time. However, by choosing the appropriate exposure factor, an optimal radiograph density can be produced that can clearly display the difference in thickness and density between organs. The purpose of this study is to determine the results of how density affects the results of radiographs of the os femur.

Methods: This research is quantitative using experimental methods to find out how the effect of mAs variations and how much the range of changes in value on density in AP projection femur examinations using mAs variations namely mAs 4, 8, 10, 12, 20, 25, and 32 with a fixed kV of 70 kV.

Results: The results of this study indicate that there is a change in the effect of density quality on the variation of mAs on the radiograph results of the femoral os using the Friedman test p-value <0.001 which means less than 0.05. And the range of changes in density values at the caput femur, collum femur, collum femur, and greater trochanter there are changes in each mAs variation. The value of density variation against 7 mAs variations in radiograph results at variations of 4 to 32 mAs shows the density value increases by 0.14, for the range of increase in each variation it is ± from 0.02 to 0.05.

Conclusions: The purpose of this study is to determine the results of how density is affected and the results of how the range of changes in density values on femur radiographs.

mAs Variation; Density; Femur Radiograph

Finzia, P. Z., & Ichwanisa, N. (2017). GAMBARAN PENGETAHUAN RADIO GRAFER TENTANG KESEHATAN DAN KESELAMATAN KERJA DI INSTALASI RADIOLOGI RSUD dr. ZAINOEL ABIDIN BANDA ACEH. Jurnal Aceh Medika, 1(2).

Lampignano, J. P., & E.Kendrick, L. (2018). Bontrager’s Textbook of Radiographic Positioning and Related Anatomy. ELSEVIER.

Lestari, S., & Aditya, A. C. (2019). Teknik Radiografi Medis . Andi.

Ningtias, D. R., Suryono, S., & Susilo, S. (2016). PENGUKURAN KUALITAS CITRA DIGITAL COMPUTED RADIOGRAPHY MENGGUNAKAN PROGRAM PENGOLAH CITRA. Jurnal Pendidikan Fisika Indonesia, 12(2), 161–168. https://doi.org/10.15294/jpfi.v12i2.5950

Nuramdiani, D. (2021). Tinjauan Densitas Radiograf Pada Berbagai Ketebalan Step Wedge Berbasis Variasi Arus Tabung (2nd ed., Vol. 3).

Ofori, E. K., Gawugah, J. N. K., & Nathan, J. A. (2016). Relationship between Patient Anatomical Thickness and Radiographic Exposure Factors for Selected Radiologic Examinations. In An International Peer-reviewed Journal (Vol. 23). www.iiste.org

Rasad, S. (2005). Radiologi Diagnostik. Balai Penerbit FKUI.

Sari, A. W., & Fransiska, E. (2018). Pengaruh Faktor Eksposi dengan Ketebalan Objek pada Pemeriksaan Foto Thorax terhadap Gambaran Radiografi. Journal of Health Guna Bangsa, 5(1).

Sparzinanda, E., & Nurhidayah, dan. (2017). PENGARUH FAKTOR EKSPOSI TERHADAP KUALITAS CITRA RADIOGRAFI. JoP, 3, 14–22.

Terri L. Fauber. (2013). Radiographic Imaging and Exposure (4th ed.). Elsevier Mosby.

Utami .W.M.S, N., Nyoman Ratini, N., Putu Eka Juliantara, I., Teknik Radiodiagnostik dan Radioterapi Bali, A., & Tukang Batanghari VII No, J. (2022). Pengaruh Kombinasi Arus Tabung Sinar-X dan Waktu Eksposi Terhadap Contrast to Noise Ratio (CNR) dengan menggunakan Computed Radiography.