Cost-effective approach to lung cancer risk for a radiological dispersal device (RDD) scenario-Reference-Cited by-同舟云学术

Cost-effective approach to lung cancer risk for a radiological dispersal device (RDD) scenario

Published:2019-12-01 Issue:4 Volume:64 Page:123-129
ISSN:0029-5922
Container-title:Nukleonika
language:en
Short-container-title:

Author:

Costa Karolina P. S.¹,Lima Sergio X.²,Brum Tercio²,Lima Zelmo R.¹,Amorim Jose C. C.²,Healy Matthew J. F.³,Vital Helio C.⁴,Prah Matjaž⁵,Andrade Edson R.⁶

Affiliation:

1. Institute of Nuclear Engineering Graduate Program , CNEN, Rio de Janeiro , Brazil

2. Defense Engineering Graduate Program , Military Engineering Institute , Rio de Janeiro , Brazil

3. Cranfield Forensic Institute , Cranfield University Defence Academy of the United Kingdom Shrivenham , SN6 8LA , UK

4. Nuclear Defense Section, IDQBRN/CTEx Rio de Janeiro , Brazil

5. Department for Nuclear Power Plant, in Croatian National Electric Utility – HEP d.d., Zagreb , Croatia

6. Institute of Nuclear Engineering Graduate Program , CNEN, Rio de Janeiro , Brazil and Defense Engineering Graduate Program, Military Engineering Institute , Praça General Tibúrcio 80, Rio de Janeiro , Brazil

Abstract

Abstract A release of radioactive material into the environment can lead to hazardous exposure of the population and serious future concerns about health issues such as an increased incidence of cancer. In this context, a practical methodology capable of providing useful basic information from the scenario can be valuable for immediate decisions and future risk assessment. For this work, the simulation of a radiological dispersal device (RDD) filled with americium-241 was considered. The radiation dose simulated by the HotSpot code was used as an input to the epidemiological equations from BEIR V producing the data used to assess the risk of lung cancer development. The methodology could be useful in providing training for responders aimed to the initial support addressed to decision-making for emergency response at the early phase of an RDD scenario. The results from the simulation allow estimating (a) the size of the potentially affected population, (b) the type of protection action considering gender and location of the individuals, (c) the absorbed doses, (d) the matrix of lung cancer incidence predictions over a period of 5 years, and (e) the cost-effectiveness in the initial decision environment.

Publisher

Walter de Gruyter GmbH

Subject

Waste Management and Disposal,Condensed Matter Physics,Safety, Risk, Reliability and Quality,Instrumentation,Nuclear Energy and Engineering,Nuclear and High Energy Physics

Link

https://www.sciendo.com/pdf/10.2478/nuka-2019-0016

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