Volume 7, Issue 2 (5-2020)                   J. Res. Orthop. Sci. 2020, 7(2): 61-66 | Back to browse issues page

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Omojola A, Akpochafor M, Adeneye S. A Simulation Study With Electronic Dosimeter to Estimate Patient and Personnel Dose in Orthopedic Surgery. J. Res. Orthop. Sci.. 2020; 7 (2) :61-66
URL: http://jros.iums.ac.ir/article-1-2057-en.html
1- Radiology Department, Federal Medical Centre Asaba, Asaba, Nigeria.
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1. Introduction
Orthopedic reconstructive or replacement surgeries have evolved and improved over the years with the advent of sophisticated imaging modalities like the mini C-arms with real-time imaging (Figure 1). With this recent development, many surgeries could be operated with greater ease, less time, and fewer patient complications. The outcomes are enhancing the technical proficiency of the surgeon with good results and better management of their patients [1-4]. At present, over 4000 x-ray units are used in Nigeria. Also, there is a hand full of orthopedic units in federal and state teaching hospitals, as well as private centers across the country where either a large or mini C-arm is used [5]. Besides, the number of medical specialists in other areas of medicine using fluoroscopy is immerging. However, studies indicate poor knowledge about exposure to radiation, its detrimental effect, and associated long-term risk, using C-arm fluoroscopy [6-8].
Generally, the primary beam from the tube head of the x-ray unit reaches the patient directly, with higher intensity compared with the scattered radiation reaching the personnel. For most orthopedic surgeries, the chances of deterministic effects of radiation are low compared with high dose procedures like cardiac studies. A lot of investigations on the impact of radiation to orthopedic surgeons and support staff using the C-arm have revealed that radiation doses incurred are far lower than the International Commission on Radiological Protection (ICRP) allowed limits. 
Reported doses during various orthopedic procedures are usually below international standards, either as dose equivalent (which is a measure of biological damage that is calculated by multiplying absorbed radiation dose by a quality factor for the type of radiation involved) and effective dose (which represent the stochastic health effects of a low level of ionizing radiation on the human body, which represents the probability of radiation-induced cancer and genetic damage). Orthopedic surgeons receive radiation arising from primary (direct) and scatter radiation. The hands are most likely exposed directly to ionizing radiation during fluoroscopy screening [9-11]. Other organs with high radiosensitivity that are exposed to scatter radiation are the eye lens, thyroid, and gonads [12].
2. Methods
This retrospective study was carried for one month using the main hall of the hospital where the C-arm was located. The purpose is to enhance the technical proficiency of the orthopedic surgeons during their operations with a real-time imaging system. Personnel recruited for this study involved orthopedic surgeons, scrub nurses, and a medical physicist for dose measurements. A Philips BV Endura R2.3 single-phase and mobile fluoroscopic unit was used for this study. A phantom was locally designed to mimic the patient’s position on the operating table as demonstrated in Figure 2. Various positions are assumed by personnel to estimate radiation dose by positioning the detector at various points. The points were assumed to be where the patients lie and personnel stand.
The Source To Patient Distance (SPD) was 0.5 m, central-axis to anesthetist (CA) was 0.75 m, central-axis to scrub nurse (CS n) was 0.87 m and central-axis to the surgeon (CS g) was 0.5 m. Similarly, the beam-on time was assumed to be the actual time exposure. An inspector USB survey meter and an NT6200 Electronic Dosimeter were used for radiation measurements. The inspector is a health and safety instrument to detect low levels of radiation. It is designed to measure alpha (α) and beta particles (β), gamma rays (γ), and x-ray radiation (ionizing radiation only). It can work in milliroentgen per hour (mR/h) and count per minute (cpm) or SI unit of microsievert per hour (μSv/h) and count per seconds (cps). Also, the technical parameters for the NT6200 Electronic Dosimeter can measure x-ray, γ, and β particles. The equivalent dose rate is calibrated to work from 0.01 μSv/h to 100 mSv/h. Similarly, the radiation equivalent dose is 0.01 μSv to 9999 Sv. The energy ranged from 40 KeV to 3.0 MeV. Since x-ray quality factor=1, then microsievert and microGrays units can be used interchangeably. The average technical factor used was 43 kVp and 4 mAs.
3. Results
The maximum and minimum measured mean dose rates to the patient were 451.2 µSv/h and 272.4 µSv/h at 3.33 and 0.67 minutes exposure time, respectively. The mean scatter dose to the patient was estimated at 25.03 µSv/case and 3.04 µSv/case, respectively (Table 1). Similarly, the maximum and minimum measured scatter mean dose rates to the anesthetist was 67.6 µSv/h and 35.6 µSv/h at 3.33 and 0.67 minutes exposure time, respectively. The mean scatter dose reaching the anesthetist without protective apron was estimated at 3.75 µSv/case and 0.4 µSv/case, respectively (Table 2).
In the same vein, the total maximum and minimum measured scatter mean dose rates to the scrub nurse was 64.8 µSv/h and 26.4 µSv/h at 3.33 and 0.67 minutes exposure time, respectively. The mean scatter dose reaching the scrub nurse without a protective apron was estimated at 3.59 µSv/case and 0.29 µSv/case, respectively (Table 3).
The maximum and minimum total measured scatter mean dose rates to the surgeon was 139.2 µSv/h and 121.88 µSv/h at 3.33 and 0.67 minutes exposure time, respectively. The mean scatter dose reaching the surgeon was estimated at 7.72 µSv/case and 1.33 µSv/case (without protective apron), respectively (Table 4).
The average dose impacted a total of 104 patients per year for the average maximum time of 3.33 minutes was estimated as 2603 µSv/y. The estimated average dose values to the surgeon, anesthetist, and scrub nurse per year were 802, 390, and 373.36 µSv/y, respectively.
4. Discussion
Orthopedic interventional procedures result in unavoidable radiation exposure to patients and personnel due to fluoroscopy exposure. The use of Electronic Dosimeter (ED) has become more popular because of the display of dose in real-time compared with Thermoluminescent Dosimeters (TLDs), which involves the use of a thermal stimulator before dose can be determined. However, the latter still stands out as a “gold standard” for personal dosimetry [13, 15].
There were variations in personnel positions (surgeon, anesthetist, and scrub nurse) from the central-axis of the mini C-arm unit (0.5, 0.75, and 0.87 m). Mehlman et al., who used a fluoroscopy unit for personnel dose simulation, reported that the surgeon, anesthetist, and scrub nurse were at a distance of 0.305, 1.524, and 0.914 m away from the central axis. The anesthetist position was twice far than what was in our study. Also, results from Mehlman et al. study indicated that unprotected individuals working 36 inches (0.914 m) or far away from the beam axis would receive a much lower dose, which is in agreement with the inverse square law. The above result was in line with our study where the anesthetist and scrub nurse received 1.13 µSv/min and 1.08 µSv/min, respectively without protection [15]. Likewise, there was a slight difference in the distance from the central axis where the surgeon stands in this study (0.7 m) against the distance reported by Tasbas et al. study (0.9 m). 
Radiation reading from an anesthetic position from an orthopedic surgery at a distance of 1.5 m was zero [16]. Simulated radiation dose to anesthesiologist at 0.9 m from the source of the C-arm from this study was approximately 4 µSv/case. Alonso et al. used an electronic dosimeter and reported that for a Dynamic Hip Screw (DHS) fixation of the femur, the estimated dose to an anesthetist, standing 2 m away from the C-arm, was a maximum value of 1 µSv for two measurements. There was no evidence of radiation dose for most measurements made [17]. 
The position of the anesthetist in our study was 0.9 m away, which recorded a maximum dose of 3.75 µSv. Also according to the perspex phantom experiment by Lo et al., the radiation dose in orthopedic surgeries to the surgeon and operating personnel for a distance of 1 m to the head, waist, and feet ranged from 50 to 100 µSv/h. In our study, the distance was 0.7-1 m from the surgeon and operating theatre personnel, with a range of 64.8-139 µSv/h [18].
An accumulated dose of as little as 65 µSv, which is frequently exceeded during most orthopedic procedures, over multiple exposures can statistically increase the incidence of thyroid cancer after many years [19]. It can be seen that an average of 17.3 cases would exceed the above value (65 µSv) over 2 months for a surgeon. Mesbahi et al., who investigated radiation dose to surgeon and staff, reported that entrance skin exposure to the surgeon’s hand, eye, and thyroid varied from 0.85-8036 µSv/min. This study was seen to be within this range based on our simulated value of 2.32 µSv/min [20].
The fluoroscopy times in commonly performed fracture of the femur in a study by Tsalafoutas et al. were 3.2, 1.5, and 6.3 min based on different types of surgery [12]. The maximum mean time from our simulated study was about 3.3 min, which was close to one of the quoted times above. Whittaker et al. study shows an average dose range of 0.1-2.4 min with intramedullary nailing having the highest time. The most seen orthopedic cases in the studied facility were Open Reduction Internal Fixation (ORIF) with an average time of 0.67 min. Based on Whittaker et al. study results, the average screening time for post ORIF was 0.16 min [21]. The patient dose in this study ranged from 3.04 to 25.03 µSv, with its maximum value close to a surgically-treated femoral fracture studied by Perisinakis et al. whose dose ranged from 11.6 to 21.7 µSv [22]. 
In most cases, discrepancies in effective doses are largely due to exposure time variation, size of the patient, and the point source of measurement. In another study, Suhm et al. reported an effective dose of 100 µSv to patients for lower extremity fractures, which was four times higher than our value (25.03 µSv) [23]. 
The estimated scatter radiation for a few commonly performed orthopedic surgeries like intramedullary nailing of pertrochanteric fracture ranged from 0.012-0.103 mSv/min [12]. The above results were higher than our study which was 0.00218 mSv/min on average. Surgeon dose (7.72 µSv/case) based on our study was lower compared with Osman et al. [24] who investigated surgeon dose to the thyroid in orthopedic surgeries. His study looked at two different kinds of orthopedic surgeries, which resulted in a mean thyroid dose of 71.6 µGy/case and 57.6 µGy/case. The relative dose difference was 161% and 150%, respectively. The mean estimated dose to personnel from this study was 5.02 µSv; this value was close to a study carried out by Zweers et al., who investigated patient and staff dose. The estimated dose to staff per procedure was 28 and 4 µSv from two different hospitals using an electronic dosimeter [25]. Henderson et al. studied the radiation exposure of anesthetists. They concluded that at 1.5 m distance from the radiation source, the unprotected average equivalent dose readings were undetectable from prospective case series over two months [26]. 
Compensation for staff movement within the room during the procedure was not possible because the phantom was static. In this regard, the dose may be slightly affected. Second, the average exposure time was based on commonly performed orthopedic surgeries. Procedures with a much longer time were not investigated in this study.
5. Conclusion
An investigation was conducted to estimate patient and personnel radiation dose values from a mini C-arm unit. The total exposure time was mostly dependent on the type of orthopedic surgery and the experience of the surgical team. Also, the exposure time and distance from the radiation source were directly proportional to the dose received by the personnel. Although radiation doses were generally small in magnitude, there must be strong regulation on the use of the protective device during these procedures. Studies have shown that with continual exposure to low ionizing radiation there might be a potential stochastic risk.
Ethical Considerations
Compliance with ethical guidelines
All ethical principles were considered in this article. 
This research did not receive any specific grant from funding agencies in the public, commercial, or not-for-profit sectors.
Authors' contributions
All authors contributed in preparing this article.
Conflict of interest
The authors declared no conflict of interest.

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Type of Study: Research Article | Subject: General
Received: 2019/07/13

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