Ionising radiation is a potential risk factor for the various healthcare worker [4]. The most exposed medical professionals include cardiologist, orthopaedic surgeons and radiologists [5]. There are potential side effects of radiation exposure hazards ranging from dermatitis to malignant diseases [6]. In this study, the knowledge among the orthopaedic surgeon is evaluated regarding the safety and consequences of radiation exposures. Similar studies [7] were performed but none regarding the Indian population involving such questions. The use of intra-operative fluoroscopy is indispensable in most of the orthopaedic surgeries and procedures. With the advent of more complex and minimal invasive surgeries, the use of fluoroscopy has increased many folds [8]. The surgeries like closed intramedullary nailing, MIPPO (Minimal Invasive Percutaneous Plate Osteosynthesis), Minimal invasive surgeries in the spine and so on has become standard and need of the hour. The 90% of the orthopaedic surgeons in this study agreed that closed femur nailing leads to more radiation exposure compared to open femur nailing technique (Question 14). There has been development in the fluoroscopy machines like C-Arm to provide 3D imaging intra-operatively. The Operating Room (OR) personnel including technicians and surgeons are exposed to such radiation risk on daily basis. But the surgeons, in particular, are unaware or ignore the radiation safety measures during surgical procedures. Although previous studies ascertained that the amount of occupational radiation exposure for surgeons who used C-arm fluoroscopy was below the safe limit determined by the International Commission on Radiation Protection [9, 10]. Still, it is important to have knowledge about radiation exposure and consequences.
In this study, we evaluated the knowledge of Indian orthopaedic surgeons regarding the protocols of radiation exposure, safety and consequences. The study involved various level of orthopaedic experts (trainees to professors) performing various types of surgeries in a different clinical setup. The surgeons in the study had varying operating days with different surgeries requiring C-Arm. Depending on the level of expertise as the type of surgery, the number of images taken by the C-Arm varies (Question1-5). The study correlated to the previous study [11] depicting the more experienced surgeon used a smaller number of fluoroscopy images thus reducing the radiation hazard.
The radiation exposure has both deterministic (dose-dependent) as well as stochastic (dose-independent) effects [12–14]. Although there is no deterministic effect seen among the orthopaedic surgeons but the stochastic effect can occur in the short or long term. The use of dosimeter for individuals exposed to a dose of > 6mSv annually is mandatory [9]. The study depicted no orthopaedic surgeon wore dosimeter while being exposed to the radiation (Question 10). It shows the lack of the surgeon as well as institutional support or aware regarding radiation safety. The dosimeter not only measures the level of exposure but also prevent the surgeon from overexposing. The study demonstrates that 25% of the surgeon took more than 200 C-Arm images per operating day. The surgeons are mostly exposed to the scattered radiation from the C-Arm. Thus, it is important to prevent this exposure rather than direct radiation exposure. This can be done using various methods.
Firstly, reducing the number of inappropriate images. Operating the C-Arm appropriately is important to reduce unwanted radiation exposure [15]. The trained personnel should operate the C-Arm to minimise inappropriate X-ray images. It not only helps to reduce the suboptimal exposed images but also inappropriate positioning of the C-arm. The study depicted that out of all the personnel operating the C-Arm only 20% are trained technicians whereas 65% are the doctors (Question 6). The scattered radiation from the C-Arm also depends upon the orientation of the machine. Mostly the C-Arm is oriented vertically with an X-ray tube below the operating table and image intensifier above the patient. This keeps the scattered radiation below the level of the operating table. The horizontal oriental orientation of the C-Arm produces more scattered radiation [16] and that too above the waist height of the surgeons. Thus, causing more radiation exposure to the persons in the operating room. Only 36% of the surgeons were aware of this fact and mostly (64%) surgeons had no correct knowledge regarding this (Question 11). The collimation of the C-Arm also affects the amount of radiation [17]. Actively collimating to the volume of interest reduces the overall integral dose to the patient and thus minimises the radiation risk. Less volume irradiated will result in less X-ray scatter on the detector. This was well known to 45% of the surgeon in the study (Question 9).
Secondly, the use of protective gears by surgeons [18]. Studies have shown that the use of proper protection reduces a doctor’s radiation exposure by 90% [19]. This study demonstrates 75% of the orthopaedic surgeons used some kind of protective gears always while doing the surgeries. Whereas 25% of the surgeon did use some protective gear occasionally (Question 12). This may be accounted to the specialised orthopaedic procedures not requiring much C-Arm images or ignorance on part of the surgeons. All the orthopaedic surgeons (100%) used lead apron as the protective gear whereas only 25% used thyroid shield and 3% used protective eye gear additionally (Question 13).
Thirdly, the knowledge of radiation safety and consequences is utmost important. It was interesting to note that only 5% of the orthopaedic surgeon was aware of ALARA/ALARP criteria (Question 7). The ALARA (As Low As Reasonably Achievable) radiation safety principle is based on the minimization of radiation doses and limiting the release of radioactive materials into the environment by employing all reasonable methods [20]. ALARP (As Low As Reasonably Practical) is a process where the onus is to carry out measures to reduce radiation risk unless it can be demonstrated that it is not reasonably practicable to do so. This depicts the lack of training as most of the study population consists of residents. A greater distance from the radiation source can reduce radiation exposure [21, 22]. The amount of radiation exposure is inversely proportional to the square of the distance [23]. Due to the obvious nature of the occupation, 60% of the orthopaedic surgeons were within 1 foot of the C-Arm whereas rest were within 2–5 feet distance (Question 8).
The study revealed a lack of training among the orthopaedic surgeons regarding the radiation safety protocols. The International Commission on Radiological Protection [24] has established the standards for radiation protection including the dosage limits. Only 45% of the surgeons were aware of the permissible radiation exposure limits (Question 15). Whereas only 45% of the surgeons in this study pointed gonads as the most exposed part to the scattered radiation followed by the thyroid (Question 16). Previous studies depicted hands as most exposed part to the radiation though thyroid and gonads are sensitive to the radiation [25]. Whereas only 5% of the orthopaedic surgeon had training in radiation safety protocols (Question 17).
The study depicted the lack of adequate and appropriate knowledge among the Indian orthopaedic surgeons regarding the proper radiation safety protocols and consequences.
Limiting factor of this study: Small study population, study population does not depict the whole of orthopaedic surgeon population and more elaborate studies are required. The radiation hazard and long-term follow-up were not included in the study.