Treffer: Extremity radiation dose reduction in radiosynoviorthesis procedures by development of 3D printed finger protection ring.

Title:
Extremity radiation dose reduction in radiosynoviorthesis procedures by development of 3D printed finger protection ring.
Authors:
Daniel M; Medical Physics Department, Portsmouth Hospitals University NHS Trust, Portsmouth, United Kingdom.; Alliance Manchester Business School, University of Manchester, Manchester, United Kingdom., Edwards M; Rheumatology Department, Portsmouth Hospitals University NHS Trust, Portsmouth, United Kingdom., Harrison C; Medical Physics Department, Portsmouth Hospitals University NHS Trust, Portsmouth, United Kingdom., Davis A; Medical Physics Department, Portsmouth Hospitals University NHS Trust, Portsmouth, United Kingdom.
Source:
Journal of radiological protection : official journal of the Society for Radiological Protection [J Radiol Prot] 2025 Dec 04; Vol. 45 (4). Date of Electronic Publication: 2025 Dec 04.
Publication Type:
Journal Article
Language:
English
Journal Info:
Publisher: IOP Pub. Ltd Country of Publication: England NLM ID: 8809257 Publication Model: Electronic Cited Medium: Internet ISSN: 1361-6498 (Electronic) Linking ISSN: 09524746 NLM ISO Abbreviation: J Radiol Prot Subsets: MEDLINE
Imprint Name(s):
Original Publication: [Bristol, UK] : IOP Pub. Ltd., [c1988-
MeSH Terms:
Radiation Protection*/instrumentation , Printing, Three-Dimensional* , Fingers*/radiation effects , Occupational Exposure*/prevention & control, Humans ; Radiation Dosage ; Equipment Design
Contributed Indexing:
Keywords: 3D printing; finger dose; radiation protection; radiosynovectomy; radiosynoviorthesis; syringe shield; yttrium-90
Entry Date(s):
Date Created: 20251118 Date Completed: 20251204 Latest Revision: 20251204
Update Code:
20251204
DOI:
10.1088/1361-6498/ae20a0
PMID:
41252750
Database:
MEDLINE

Weitere Informationen

Radiation exposure to the fingers of clinicians carrying out radiosynoviorthesis with yttrium citrate ( <sup>90</sup> Y) can be an area of concern if equipment or practice is sub-optimal, with contact dose rates in the mSv·s <sup>-1</sup> range around the syringe and needle neck. Syringe shields reduce potential exposure around the syringe but offer no protection around the needle neck. There are no commercially available protection products in the United Kingdom to address this deficiency. Clinical safety requires that the clinician is able to feel the position of the needle and limit the amount of needle movement at critical times. Although direct handling of the needle neck presents the easiest solution, radiation protection concerns make this unacceptable, and leave forceps the only established alternative to minimise finger doses. We present a further method to address these issues-a locally designed infection control compliant finger protection ring which has been 3D printed and used at the authors' hospital. Potential extremity doses have been measured for three methods. 1, direct finger contact with the needle neck, 2, forceps, and 3, use of a 3D printed ring. Finger dose coefficients with the first method (direct contact) have been demonstrated experimentally to be as high as 33 µ Sv·MBq <sup>-1</sup> , with even higher results recorded in clinical practice at 79.5 µ Sv·MBq <sup>-1</sup> . The second method (forceps) reduces the potential skin dose coefficient to less than 1 µ Sv·MBq <sup>-1</sup> . The third method (finger protection ring) achieves a similar dose coefficient to forceps. Forceps are more technically demanding for the clinician. This new finger protection ring ensures that patient safety is maintained, the procedure is technically easier for the clinician, finger doses are as low as Reasonably Practicable, and contamination risk is reduced.
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