在癌症筛查模拟中使用辐射风险模型:重要假设及其对结果预测的影响。
Using radiation risk models in cancer screening simulations: important assumptions and effects on outcome projections.
机构信息
Institute for Technology Assessment, Massachusetts General Hospital, 101 Merrimac St, 10th Floor, Boston, MA 02114, USA.
出版信息
Radiology. 2012 Mar;262(3):977-84. doi: 10.1148/radiol.11110352.
PURPOSE
To evaluate the effect of incorporating radiation risk into microsimulation (first-order Monte Carlo) models for breast and lung cancer screening to illustrate effects of including radiation risk on patient outcome projections.
MATERIALS AND METHODS
All data used in this study were derived from publicly available or deidentified human subject data. Institutional review board approval was not required. The challenges of incorporating radiation risk into simulation models are illustrated with two cancer screening models (Breast Cancer Model and Lung Cancer Policy Model) adapted to include radiation exposure effects from mammography and chest computed tomography (CT), respectively. The primary outcome projected by the breast model was life expectancy (LE) for BRCA1 mutation carriers. Digital mammographic screening beginning at ages 25, 30, 35, and 40 years was evaluated in the context of screenings with false-positive results and radiation exposure effects. The primary outcome of the lung model was lung cancer-specific mortality reduction due to annual screening, comparing two diagnostic CT protocols for lung nodule evaluation. The Metropolis-Hastings algorithm was used to estimate the mean values of the results with 95% uncertainty intervals (UIs).
RESULTS
Without radiation exposure effects, the breast model indicated that annual digital mammography starting at age 25 years maximized LE (72.03 years; 95% UI: 72.01 years, 72.05 years) and had the highest number of screenings with false-positive results (2.0 per woman). When radiation effects were included, annual digital mammography beginning at age 30 years maximized LE (71.90 years; 95% UI: 71.87 years, 71.94 years) with a lower number of screenings with false-positive results (1.4 per woman). For annual chest CT screening of 50-year-old females with no follow-up for nodules smaller than 4 mm in diameter, the lung model predicted lung cancer-specific mortality reduction of 21.50% (95% UI: 20.90%, 22.10%) without radiation risk and 17.75% (95% UI: 16.97%, 18.41%) with radiation risk.
CONCLUSION
Because including radiation exposure risk can influence long-term projections from simulation models, it is important to include these risks when conducting modeling-based assessments of diagnostic imaging.
目的
评估将放射风险纳入乳腺和肺癌筛查的微观模拟(一阶蒙特卡罗)模型中的效果,以说明包括放射风险对患者预后预测的影响。
材料与方法
本研究中使用的所有数据均源自公开或去识别的人体研究数据。本研究无需获得机构审查委员会的批准。通过对分别用于纳入乳房 X 线摄影和胸部计算机断层扫描(CT)放射暴露效应的两种癌症筛查模型(乳腺癌模型和肺癌政策模型)进行适应性修改,展示了将放射风险纳入模拟模型的挑战。乳房模型预测的主要结果是 BRCA1 突变携带者的预期寿命(LE)。在存在假阳性结果和放射暴露效应的情况下,评估从 25、30、35 和 40 岁开始的数字乳房 X 线筛查对 BRCA1 突变携带者的影响。肺模型的主要结果是由于每年筛查而导致的肺癌特异性死亡率降低,比较两种用于肺结节评估的年度诊断 CT 方案。使用 metropolis-hastings 算法来估计结果的平均值及其 95%置信区间(UI)。
结果
在不考虑放射暴露效应的情况下,乳房模型表明,从 25 岁开始每年进行数字乳房 X 线筛查可使 LE 最大化(72.03 岁;95%UI:72.01 岁,72.05 岁),并且假阳性结果的筛查次数最多(每位女性 2.0 次)。当纳入放射效应时,从 30 岁开始的每年数字乳房 X 线筛查可使 LE 最大化(71.90 岁;95%UI:71.87 岁,71.94 岁),且假阳性结果的筛查次数更少(每位女性 1.4 次)。对于直径小于 4 毫米的结节不进行随访的 50 岁女性,每年进行胸部 CT 筛查,肺部模型预测在不考虑放射风险的情况下,肺癌特异性死亡率降低 21.50%(95%UI:20.90%,22.10%),而考虑放射风险时降低 17.75%(95%UI:16.97%,18.41%)。
结论
由于纳入放射暴露风险会影响模拟模型的长期预测,因此在进行基于模型的诊断影像学评估时,纳入这些风险非常重要。
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