Uranium Body Clearance Kinetics-A Long-term Follow-up Study of Retired Nuclear Fuel Workers.

IF 1 4区 医学 Q4 ENVIRONMENTAL SCIENCES Health physics Pub Date : 2024-10-01 Epub Date: 2024-07-24 DOI:10.1097/HP.0000000000001861
Ibtisam Yusuf, Edvin Hansson, Mats Eriksson, Patric Lindahl, Håkan B L Pettersson
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In this study, two workers, previously working for >20 y at a nuclear fuel fabrication plant, provided urine samples regularly for up to 6 y. One individual had worked at the pelletizing workshop with the known presence of uranium dioxide (UO 2 ) and triuranium octoxide (U 3 O 8 ). The second individual worked at the conversion workshop where multiple compounds, including uranium hexafluoride (UF 6 ), uranium dioxide (UO 2 ), ammonium uranyl carbonate, and AUC [UO 2 CO 3 ·2(NH 4 ) 2 CO 3 ], are present. Data on uranium concentration in urine during working years were also available for both workers. The daily excretion of uranium by urine was characterized by applying non-linear least square regression fitting to the urinary data. Material-specific parameters, such as the activity median aerodynamic diameter (AMAD), the respiratory tract absorption parameters, rapid fraction ( f r ,), rapid dissolution rate ( s r , d -1 ), and slow dissolution rate ( s s , d -1 ) and alimentary tract transfer factor ( f A ) acquired from previous work along with default absorption types, were applied to urine data, and the goodness of fit was evaluated. Thereafter intake estimates and dose calculations were performed. For the ex-pelletizing worker, a one-compartment model with a clearance half-time of 662 ± 100 d ( s s = 0.0010 d -1 ) best represented the urinary data. For the ex-conversion worker, a two-compartment model with a major [93% of the initial urinary excretion (A 0 )] fast compartment with a clearance half-time of 1.3 ± 0.4 d ( s r = 0.5 d -1 ) and a minor (7% of A 0 ) slow compartment with a half-time of 394 ± 241 d ( s s = 0.002 d -1 ) provided the best fit. 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引用次数: 0

Abstract

Abstract: Nuclear industry workers exposed to uranium aerosols may risk kidney damage and radiation-induced cancer. This warrants the need for well-established dose and risk assessments, which can be greatly improved by using material-specific absorption parameters in the ICRP Human Respiratory Tract Model. The present study focuses on the evaluation of the slow dissolution rate ( s s , d -1 ), a parameter that is difficult to quantify with in vitro dissolution studies, especially for more insoluble uranium compounds. A long-term follow-up of urinary excretion after the cessation of chronic inhalation exposure can provide a better estimate of the slow-rate dissolution. In this study, two workers, previously working for >20 y at a nuclear fuel fabrication plant, provided urine samples regularly for up to 6 y. One individual had worked at the pelletizing workshop with the known presence of uranium dioxide (UO 2 ) and triuranium octoxide (U 3 O 8 ). The second individual worked at the conversion workshop where multiple compounds, including uranium hexafluoride (UF 6 ), uranium dioxide (UO 2 ), ammonium uranyl carbonate, and AUC [UO 2 CO 3 ·2(NH 4 ) 2 CO 3 ], are present. Data on uranium concentration in urine during working years were also available for both workers. The daily excretion of uranium by urine was characterized by applying non-linear least square regression fitting to the urinary data. Material-specific parameters, such as the activity median aerodynamic diameter (AMAD), the respiratory tract absorption parameters, rapid fraction ( f r ,), rapid dissolution rate ( s r , d -1 ), and slow dissolution rate ( s s , d -1 ) and alimentary tract transfer factor ( f A ) acquired from previous work along with default absorption types, were applied to urine data, and the goodness of fit was evaluated. Thereafter intake estimates and dose calculations were performed. For the ex-pelletizing worker, a one-compartment model with a clearance half-time of 662 ± 100 d ( s s = 0.0010 d -1 ) best represented the urinary data. For the ex-conversion worker, a two-compartment model with a major [93% of the initial urinary excretion (A 0 )] fast compartment with a clearance half-time of 1.3 ± 0.4 d ( s r = 0.5 d -1 ) and a minor (7% of A 0 ) slow compartment with a half-time of 394 ± 241 d ( s s = 0.002 d -1 ) provided the best fit. The results from the data-fitting of urinary data to biokinetic models for the ex-conversion worker demonstrated that in vitro derived experimental parameters (AMAD = 20 μm, f r = 0.32, s r = 27 d -1 , s s = 0.0008 d -1 , f A = 0.005) from our previous work best represented the urinary data. This resulted in an estimated intake rate of 0.66 Bq d -1 . The results from the data-fitting of urinary data to biokinetic models for the ex-pelletizing worker indicated that the experimental parameters (AMAD = 10 μm and 20 μm, f r = 0.008, s r = 12 d -1 , f A = 0.00019) from our previous dissolution studies with the slow rate parameter step-wise optimized to urine-data ( s s = 0.0008 d -1 ) gave the best fit. This resulted in an estimated intake rate of 5 Bq d -1 . Experimental parameters derived from in vitro dissolution studies provided the best fit for the subject retired from work at the conversion workshop, where inhalation exposure to a mix of soluble (e.g., AUC, UF 6 ) and relatively insoluble aerosol (e.g., UO 2 ) can be assumed. For the subject retired from work at the pelletizing workshop, which involved exposure to relatively insoluble aerosols (UO 2 and U 3 O 8 ), a considerably higher s s than obtained in dissolution studies provided a better representation of the urinary data and was comparable to reported s s values for UO 2 and U 3 O 8 in other studies. This implies that in vitro dissolution studies of insoluble material can be uncertain. When evaluating the results from the retrospective fitting of urine data, it is evident that the urine samples acquired after cessation of exposure provide less fluctuation. Long-term follow-up of uranium excretion after cessation of exposure is a good alternative for determining absorption parameters and can be considered the most viable way for determining the slow rate for more insoluble material.

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铀体清除动力学--退休核燃料工人的长期跟踪研究。
摘要:暴露于铀气溶胶的核工业工人可能面临肾脏损伤和辐射诱发癌症的风险。因此,需要进行完善的剂量和风险评估,而在国际放射防护委员会人体呼吸道模型中使用特定材料的吸收参数,可以大大提高评估结果的准确性。本研究的重点是评估缓慢溶解速率(ss,d-1),这是一个很难通过体外溶解研究进行量化的参数,尤其是对于较难溶解的铀化合物。在停止慢性吸入接触后,对尿液排泄进行长期跟踪可以更好地估计缓慢溶解率。在这项研究中,两名曾在核燃料制造厂工作超过 20 年的工人定期提供了长达 6 年的尿样。其中一人曾在造粒车间工作,已知存在二氧化铀(UO2)和八氧化三铀(U3O8)。第二个人曾在转化车间工作,该车间存在多种化合物,包括六氟化铀 (UF6)、二氧化铀 (UO2)、碳酸铀铵和 AUC [UO2CO3-2(NH4)2CO3]。这两名工人在工作期间尿液中铀浓度的数据也已获得。通过对尿液数据进行非线性最小平方回归拟合,确定了尿液中铀的日排泄量。将特定材料参数,如活动中值空气动力学直径 (AMAD)、呼吸道吸收参数、快速组分 (fr,)、快速溶解率 (sr, d-1) 和慢速溶解率 (ss, d-1) 以及消化道转移因子 (fA) 与默认吸收类型一起应用于尿液数据,并评估拟合的良好性。然后进行摄入量估计和剂量计算。对于前造粒工人,清除半衰期为 662 ± 100 d(ss = 0.0010 d-1)的单室模型最能体现尿液数据。对于前转化工人,二室模型的拟合效果最好,其中主要的快速室(占初始尿排泄量(A0)的 93%)的清除半衰期为 1.3 ± 0.4 d(ssr = 0.5 d-1),次要的慢速室(占 A0 的 7%)的清除半衰期为 394 ± 241 d(ss = 0.002 d-1)。将尿液数据与前转化工人的生物动力学模型进行数据拟合的结果表明,我们以前工作中得出的体外实验参数(AMAD = 20 μm,fr = 0.32,sr = 27 d-1,ss = 0.0008 d-1,f A = 0.005)最能代表尿液数据。因此,估计摄入率为 0.66 Bq d-1。将尿液数据与生物动力学模型进行拟合的结果表明,先前溶解研究中的实验参数(AMAD = 10 μm 和 20 μm,fr = 0.008,sr = 12 d-1,fA = 0.00019)与根据尿液数据逐步优化的慢速率参数(ss = 0.0008 d-1)的拟合效果最佳。因此,估计摄入率为 5 Bq d-1。从体外溶解研究中得出的实验参数为从转炉车间退休的受试者提供了最佳拟合参数,可以假定他吸入的是可溶气溶胶(如AUC、UF6)和相对不溶气溶胶(如二氧化铀)的混合物。对于在造粒车间工作而退休的受试者,由于其暴露于相对不溶性的气溶胶(二 氧化铀和八氧化三铀),ss 值比溶解度研究中获得的要高得多,这更好地反映了尿液 数据,并且与其他研究中报告的二氧化铀和八氧化三铀的ss 值相当。这意味着不溶性材料的体外溶解研究可能存在不确定性。在评估尿液数据的回顾性拟合结果时,停止接触后获得的尿液样本显然波动较小。停止接触后对铀排泄的长期跟踪是确定吸收参数的一个很好的替代方法,可被视为确定较难溶解物质缓慢吸收率的最可行方法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Health physics
Health physics 医学-公共卫生、环境卫生与职业卫生
CiteScore
4.20
自引率
0.00%
发文量
324
审稿时长
3-8 weeks
期刊介绍: Health Physics, first published in 1958, provides the latest research to a wide variety of radiation safety professionals including health physicists, nuclear chemists, medical physicists, and radiation safety officers with interests in nuclear and radiation science. The Journal allows professionals in these and other disciplines in science and engineering to stay on the cutting edge of scientific and technological advances in the field of radiation safety. The Journal publishes original papers, technical notes, articles on advances in practical applications, editorials, and correspondence. Journal articles report on the latest findings in theoretical, practical, and applied disciplines of epidemiology and radiation effects, radiation biology and radiation science, radiation ecology, and related fields.
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