利用辐照的蛋白质组生物标志物建立器官特异性生物模拟模型

IF 2.5 3区 医学 Q2 BIOLOGY
M Sproull, Y Fan, Q Chen, D Meerzaman, K Camphausen
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引用次数: 0

摘要

在未来涉及辐射伤害的大规模伤亡医疗管理情景中,将需要医疗诊断来确定受照射者和受照射程度。由于现场几乎所有的辐照都是不同的,因此确定辐照程度和哪些重要器官受到辐照对于有效的医疗管理至关重要。在目前的研究中,我们试图描述辐射照射的新型蛋白质组生物标志物,并为各种照射范例开发照射和剂量预测算法,包括均匀的全身照射,以及只照射大脑、肠道和肺部的器官特异性部分全身照射。C57BL6 雌性小鼠接受 2、4 或 8 Gy 的单次全身辐照 (TBI),肺部或肠道辐照为 2 和 8 Gy,仅脑部辐照为 2、8 或 16 Gy。然后使用 SomaScan v4.1 分析法对血浆中的 7,000 ∼ 种蛋白质分析物进行筛选。对辐照后表达发生显著变化(FDR0.2)的蛋白质生物标志物子集进行特征分析。所有蛋白质都被用于特征选择,利用不同的样本队列组合建立 7 种不同的辐照预测模型。这些模型的结构是根据现场实际情况设计的,除了识别器官特异性辐照外,还可区分辐照水平。使用独特的样本队列建立的每个模型算法都经过了样本训练集的验证,并使用单独的新样本系列进行了测试。在模型训练水平上,所有模型的总体预测准确率均为 100%。在使用保留样本进行测试时,模型 1 比较了 "暴露 "组(包括研究中的所有创伤性脑损伤和器官特异性部分身体暴露)与对照组,模型 2 区分了对照组、创伤性脑损伤和部分身体暴露(所有器官特异性部分身体暴露),结果预测准确率分别为 92.3% 和 95.4%。为了识别器官特异性暴露与对照组的比较,建立了模型 3(仅脑部)、模型 4(仅肠道)和模型 5(仅肺部),预测准确率分别为 78.3%、88.9% 和 94.4%。最后,模型 6 和模型 7 区分了创伤性脑损伤和单独的器官特异性部分身体组群,其测试预测准确率分别为 83.1%和 92.3%。这些模型代表了辐射反应蛋白组生物标志物的新型预测面板,说明了开发生物模拟算法的可行性,该算法可用于同时对全身、部分全身和器官特异性辐射照射进行分类。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Organ-specific Biodosimetry Modeling Using Proteomic Biomarkers of Radiation Exposure.

In future mass casualty medical management scenarios involving radiation injury, medical diagnostics to both identify those who have been exposed and the level of exposure will be needed. As almost all exposures in the field are heterogeneous, determination of degree of exposure and which vital organs have been exposed will be essential for effective medical management. In the current study we sought to characterize novel proteomic biomarkers of radiation exposure and develop exposure and dose prediction algorithms for a variety of exposure paradigms to include uniform total-body exposures, and organ-specific partial-body exposures to only the brain, only the gut and only the lung. C57BL6 female mice received a single total-body irradiation (TBI) of 2, 4 or 8 Gy, 2 and 8 Gy for lung or gut exposures, and 2, 8 or 16 Gy for exposure to only the brain. Plasma was then screened using the SomaScan v4.1 assay for ∼7,000 protein analytes. A subset panel of protein biomarkers demonstrating significant (FDR<0.05 and |logFC|>0.2) changes in expression after radiation exposure was characterized. All proteins were used for feature selection to build 7 different predictive models of radiation exposure using different sample cohort combinations. These models were structured according to practical field considerations to differentiate level of exposure, in addition to identification of organ-specific exposures. Each model algorithm built using a unique sample cohort was validated with a training set of samples and tested with a separate new sample series. The overall predictive accuracy for all models was 100% at the model training level. When tested with reserved samples Model 1 which compared an "exposure" group inclusive of all TBI and organ-specific partial-body exposures in the study vs. control, and Model 2 which differentiated between control, TBI and partials (all organ-specific partial-body exposures) the resulting prediction accuracy was 92.3% and 95.4%, respectively. For identification of organ-specific exposures vs. control, Model 3 (only brain), Model 4 (only gut) and Model 5 (only lung) were developed with predictive accuracies of 78.3%, 88.9% and 94.4%, respectively. Finally, for Models 6 and 7, which differentiated between TBI and separate organ-specific partial-body cohorts, the testing predictive accuracy was 83.1% and 92.3%, respectively. These models represent novel predictive panels of radiation responsive proteomic biomarkers and illustrate the feasibility of development of biodosimetry algorithms with utility for simultaneous classification of total-body, partial-body and organ-specific radiation exposures.

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来源期刊
Radiation research
Radiation research 医学-核医学
CiteScore
5.10
自引率
8.80%
发文量
179
审稿时长
1 months
期刊介绍: Radiation Research publishes original articles dealing with radiation effects and related subjects in the areas of physics, chemistry, biology and medicine, including epidemiology and translational research. The term radiation is used in its broadest sense and includes specifically ionizing radiation and ultraviolet, visible and infrared light as well as microwaves, ultrasound and heat. Effects may be physical, chemical or biological. Related subjects include (but are not limited to) dosimetry methods and instrumentation, isotope techniques and studies with chemical agents contributing to the understanding of radiation effects.
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