Bogsrud T V, Herold T J, Mahoney D W, Hung J C
Department of Diagnostic Radiology, Mayo Clinic, Rochester, MN 55905, USA.
Nucl Med Commun. 1999 Aug;20(8):761-7. doi: 10.1097/00006231-199908000-00011.
In the performance of conventional nuclear pharmacy work, personnel usually receive the highest hand radiation dose during reconstitution of 99Tcm-labelled radiopharmaceuticals. This study was conducted to compare the hand radiation doses incurred during the preparation of 99Tcm-labelled radiopharmaceuticals using three different reconstitution procedures: (1) the standard reconstitution method (i.e. withdrawing 99Tcm activity and normal saline [NS] into the same syringe before adding to the cold kit) (standard); (2) an alternative reconstitution procedure using two syringes to add normal saline separately before 99Tcm activity to the cold kit (NS/Tc); and (3) a standard reconstitution procedure using a robotic system (Amercare Syringe Fill Station, model NuMed SFS 3a, Amercare Ltd, Oxon, UK) (robot). Radiation doses were monitored by thermoluminescent dosimeters (Landauer Inc., Glenwood, IL, USA) on the base of the fourth finger (i.e. ring finger) of the non-dominant hand and on the mid-portion of the second finger (i.e. index finger) of the dominant hand. Three sets of ring badges were measured for each procedure, with 10 stimulated or real reconstitutions per set. Two different radiopharmaceutical kits were evaluated: 99Tcm-MDP, as it is the most frequently used radiopharmaceutical in the majority of nuclear medicine departments (all three reconstitution methods; i.e. standard, NS/Tc and robot), and 99Tcm-sestamibi, as it is not only reconstituted with the highest amount of radioactivity but is also the most frequently dispensed radiopharmaceutical in our laboratory (standard and robot). All kits were prepared from an elution vial containing a standardized amount of 99Tcm activity (i.e. 104.4 +/- 3.6 GBq). To each of the cold MDP and sestamibi kits, 20.7 +/- 1.2 GBq and 44.2 +/- 0.7 GBq of 99Tcm activity were added, respectively. Average accumulated radiation doses for 10 reconstitutions to the fingers (non-dominant/dominant) for the preparations of 99Tcm-MDP were as follows: 14.2 +/- 0.9 mSv/2.8 +/- 0.8 mSv (standard), 10.0 +/- 0.6 mSv/2.7 +/- 0.2 mSv (NS/Tc), and 0.6 +/- 0.1 mSv/1.3 +/- 0.1 mSv (robot). For 99Tcm-sestamibi, the average accumulated radiation doses for 10 reconstitutions to the fingers (non-dominant/dominant) were 6.7 +/- 0.7 mSv/4.6 +/- 0.5 mSv (standard) and 1.1 +/- 0.1 mSv/3.1 +/- 0.4 mSv (robot). When compared to the standard reconstitution method, our results show that the NS/Tc method slightly reduced radiation dose to the non-dominant hand, without any significant reduction for the dominant hand. However, the robot has proved to be the most effective method to considerably reduce radiation dose to both hands. A robotic system should be a useful ALARA (as low as reasonably achievable) tool to prepare other high-activity 99Tcm-labelled radiopharmaceuticals, as well as therapeutic and PET radiopharmaceuticals.
在进行常规核药房工作时,工作人员通常在99Tcm标记放射性药物的复溶过程中接受最高的手部辐射剂量。本研究旨在比较使用三种不同复溶程序制备99Tcm标记放射性药物时所产生的手部辐射剂量:(1)标准复溶方法(即在加入冷试剂盒之前,将99Tcm活度和生理盐水[NS]吸入同一注射器中)(标准方法);(2)一种替代复溶程序,在将99Tcm活度加入冷试剂盒之前,使用两个注射器分别加入生理盐水(NS/Tc);(3)使用机器人系统(Amercare注射器灌装站,型号NuMed SFS 3a,Amercare有限公司,英国牛津)的标准复溶程序(机器人方法)。通过热释光剂量计(Landauer公司,美国伊利诺伊州格伦伍德)在非优势手的第四指(即无名指)基部和优势手的第二指(即食指)中部监测辐射剂量。每种程序测量三组环形徽章,每组进行10次模拟或实际复溶。评估了两种不同的放射性药物试剂盒:99Tcm-MDP,因为它是大多数核医学科室最常用的放射性药物(所有三种复溶方法;即标准方法、NS/Tc和机器人方法);99Tcm-司他米比,因为它不仅以最高的放射性活度进行复溶,而且是我们实验室最常分发的放射性药物(标准方法和机器人方法)。所有试剂盒均由含有标准化量99Tcm活度(即104.4±3.6 GBq)的洗脱瓶制备。分别向每个冷的MDP和司他米比试剂盒中加入20.7±1.2 GBq和44.2±0.7 GBq的99Tcm活度。99Tcm-MDP制剂10次复溶对手指(非优势手/优势手)的平均累积辐射剂量如下:14.2±0.9 mSv/2.8±0.8 mSv(标准方法),10.0±0.6 mSv/2.7±0.2 mSv(NS/Tc),以及0.6±0.1 mSv/1.3±0.1 mSv(机器人方法)。对于99Tcm-司他米比,10次复溶对手指(非优势手/优势手)的平均累积辐射剂量为6.7±0.7 mSv/4.6±0.5 mSv(标准方法)和1.1±0.1 mSv/3.1±0.4 mSv(机器人方法)。与标准复溶方法相比,我们的结果表明,NS/Tc方法略微降低了非优势手的辐射剂量,而优势手的辐射剂量没有显著降低。然而,事实证明机器人方法是大幅降低双手辐射剂量的最有效方法。机器人系统应该是一种有用的“尽可能合理达到的最低水平”(ALARA)工具,可用于制备其他高活度的99Tcm标记放射性药物以及治疗性和PET放射性药物。
