Radiation protection measures during endourological therapies

doi:10.1016/j.ajur.2022.12.001

Asian Journal of Urology, 2023, 10 (3): 215-225 doi: 10.1016/j.ajur.2022.12.001

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Radiation protection measures during endourological therapies

Lazaros Tzelves^a,b,*(

),Patrick Juliebø-Jones^b,c,Ioannis Manolitsis^a,Themistoklis Bellos^a,Ioannis Mykoniatis^b,d,Marinos Berdempes^a,Titos Markopoulos^a,Michael Lardas^a,Belthangady M. Zeeshan Hameed^b,e,Panagiotis Angelopoulos^a,Amelia Pietropaolo^f,Bhaskar Somani^f,Ioannis Varkarakis^a,Andreas Skolarikos^a

^a 2nd Department of Urology, National and Kapodistrian University of Athens, Sismanogleion Hospital, Athens, Greece
^b Young Academic Urologists (YAU), Urolithiasis & Endourology Working Party, 6846 Arnhem, the Netherlands
^c Department of Urology, Haukeland University Hospital, N-5021 Bergen, Norway
^d Department of Urology, Faculty of Health Sciences, School of Medicine, Aristotle University of Thessaloniki, 54124 Thessaloniki, Greece
^e Department of Urology, Kasturba Medical College Manipal, Manipal Academy of Higher Education, Manipal 576104, India
^f Department of Urology, University Hospital Southampton NHS Trust, Southampton, UK

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Abstract

Objective The objective of this narrative review was to search the existing literature for studies reporting measures to minimize radiation use during endoscopic management of stone disease and present ways of reducing the exposure of both patients and operating room staff.
Methods A literature review in PubMed was performed to identify studies describing protocols or measures to reduce radiation received during endourological procedures from January 1970 to August 2022. Eligible studies were those that reported outcomes for ureteroscopy or percutaneous nephrolithotripsy regarding measures to minimize radiation doses used intraoperatively, performed either in real-life theatres or using phantoms. Both comparative and non-comparative studies were deemed eligible.
Results Protection can be achieved initially at the level of diagnosis and follow-up of patients, which should be done following an algorithm and choice of more conservative imaging methods. Certain protocols, which follow principles for minimized fluoroscopy use should be implemented and urologists as well as operating room staff should be continuously trained regarding radiation damage and protection measures. Wearing protective lead equipment remains a cornerstone for personnel protection, while configuration of the operating room and adjusting X-ray machine settings can also significantly reduce radiation energy.
Conclusion There are specific measures, which can be implemented to reduce radiation exposure. These include avoiding excessive use of computed tomography scans and X-rays during diagnosis and follow-up of urolithiasis patients. Intraoperative protocols with minimal fluoroscopy use can be employed. Staff training regarding dangers of radiation plays also a major role. Use and maintenance of protective equipment and setting up the operating room properly also serve towards this goal. Machine settings can be customized appropriately and finally continuously monitoring of exposure with dosimeters can be adopted.

Key words： Endourology Radiation Fluoroless ureteroscopy Percutaneous nephrolithotripsy As low as reasonably achievable

Received: 26 September 2022 Available online:

Corresponding Authors: Lazaros Tzelves E-mail: lazarostzelves@gmail.com

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	Lazaros Tzelves
	Patrick Juliebø-Jones
	Ioannis Manolitsis
	Themistoklis Bellos
	Ioannis Mykoniatis
	Marinos Berdempes
	Titos Markopoulos
	Michael Lardas
	Belthangady M. Zeeshan Hameed
	Panagiotis Angelopoulos
	Amelia Pietropaolo
	Bhaskar Somani
	Ioannis Varkarakis
	Andreas Skolarikos

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Cite this article:

Lazaros Tzelves,Patrick Juliebø-Jones,Ioannis Manolitsis, et al. Radiation protection measures during endourological therapies[J]. Asian Journal of Urology, 2023, 10(3): 215-225.

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http://www.ajurology.com/EN/10.1016/j.ajur.2022.12.001 OR http://www.ajurology.com/EN/Y2023/V10/I3/215

Setting	Specific steps to follow
Diagnosis and follow-up of urolithiasis patients	·- Use of low-dose CT protocols, especially for patients with BMI of <30 kg/m² ·- Follow-up patients according to their risk for recurrence and residual stone burden; consider European Association of Urology follow-up algorithm
Ureteroscopy	·- Estimate stone and kidney location by C-arm laser and avoid use of fluoroscopy ·- Place guidewires and double-J stents using anatomic landmarks and tactile feedback ·- Use hydrophilic, soft-tip guidewires ·- Synchronize use of fluoroscopy with patient respiration ·- Assess preoperative imaging in detail to delineate patient anatomy and stone characteristics ·- Choose ureteric access sheath according to patient height ·- Confirm guidewire placement using a semirigid ureteroscope in case of doubt ·- Assess stone clearance visually when possible
Percutaneous nephrolithotripsy	·- Estimate stone and kidney location by C-arm laser and avoid use of fluoroscopy ·- Use hydrophilic, soft-tip guidewires ·- Synchronize use of fluoroscopy with patient respiration ·- Assess preoperative imaging in detail to delineate patient anatomy and stone characteristics ·- Use ultrasound for renal puncture either as the only guidance or at least adjunctively to X-ray ·- Take advantage of direct visual feedback with flexible ureteroscope in cases of ECIRS to guide renal puncture with minimal fluoroscopy ·- Consider use of balloon instead of serial dilators to minimize fluoroscopy time
Setting of operating room	·- Monitor use of fluoroscopy ·- Use alarms ·- Use protective equipment (aprons, thyroid shields, glasses) ·- Ensure proper protective equipment maintenance and storage ·- Cooperate with technician if possible ·- Ensure proper positioning of patient and avoid interference between target area and X-ray beam ·- Staff should stand as far as possible from X-ray source
·X-ray machine settings	·- Use pulsed instead of continuous fluoroscopy ·- Make use of last-image hold option ·- Avoid using pre-established settings of mAs and kVps and lower the settings, especially in patients with normal BMI ·- Use collimation to minimize scattered energy ·- Use image magnification when suitable

Summary of measures to be implemented in order to reduce radiation exposure.

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