Firefighters' Burn and Surgical Research Laboratory, MedStar Health Research Institute, Washington, DC 20010.
Integrative Systems Biology Program, U.S. Army Center for Environmental Health Research, Fort Detrick, Maryland 21702.
Radiat Res. 2020 Jun 1;193(6):543-551. doi: 10.1667/RR15527.1.
In the event of a mass casualty radiation scenario, rapid assessment of patients' health and triage is required for optimal resource utilization. Identifying the level and extent of exposure as well as prioritization of care is extremely challenging under such disaster conditions. Blood-based biomarkers, such as RNA integrity numbers (RIN), could help healthcare personnel quickly and efficiently determine the extent and effect of multiple injuries on patients' health. Evaluation of the effect of different radiation doses, alone or in combination with burn injury, on total RNA integrity over multiple time points was performed. Total RNA integrity was tallied in blood samples for potential application as a marker of radiation exposure and survival. Groups of aged mice (3-6 mice/group, 13-18 months old) received 0.5, 1, 5, 10 or 20 Gy ionizing radiation. Two additional mouse groups received low-dose irradiation (0.5 or 1 Gy) with a 15% total body surface area (TBSA) burn injury. Animals were euthanized at 2 or 12 h and at day 1, 2, 3, 7 or 14 postirradiation, or when injury-mediated mortality occurred. Total RNA was isolated from blood. The quality of RNA was evaluated and RNA RIN were obtained. Analysis of RIN indicated that blood showed the clearest radiation effect. There was a time- and radiation-dose-dependent reduction in RIN that was first detectable at 12 h postirradiation for all doses in animals receiving irradiation alone. This effect was reversible in lower-dose groups (i.e., 0.5, 1 and 5 Gy) that survived to the end of the study (14 days). In contrast, the effect persisted for 10 and 20 Gy groups, which showed suppression of RIN values <4.5 with high mortalities. Radiation doses of 20 Gy were lethal and required euthanasia by day 6. A low RIN (<2.5) at any time point was associated with 100% mortality. Combined radiation-burn injury produced significantly increased mortality such that no dually-injured animals survived beyond day 3, and no radiation dose >1 Gy resulted in survival past day 1. More modest suppression of RIN was observed in the surviving dually challenged mice, and no statistically significant changes were identified in RIN values of burn-only mice at any time point. In this study of an animal model, a proof of concept is presented for a simple and accurate method of assessing radiation dose exposure in blood which potentially predicts lethality. RIN assessment of blood-derived RNA could form the basis for a clinical decision-support tool to guide healthcare providers under the strenuous conditions of a radiation-based mass casualty event.
在大规模人员伤亡辐射场景中,需要快速评估患者的健康状况并进行分诊,以实现最佳资源利用。在这种灾难条件下,确定暴露程度和范围以及确定护理优先级极具挑战性。血液生物标志物,如 RNA 完整性数量 (RIN),可以帮助医护人员快速有效地确定患者健康的多个损伤程度和影响。评估不同剂量的辐射,单独或与烧伤结合,对多个时间点的总 RNA 完整性的影响。在血液样本中计算总 RNA 完整性,以作为辐射暴露和存活的标志物。一组老年小鼠(每组 3-6 只,13-18 个月大)接受 0.5、1、5、10 或 20 Gy 电离辐射。另外两组小鼠接受低剂量照射(0.5 或 1 Gy),全身表面积(TBSA)烧伤 15%。动物在照射后 2 或 12 小时以及 1、2、3、7 或 14 天处死,或因损伤导致死亡。从血液中分离总 RNA。评估 RNA 的质量并获得 RNA RIN。RIN 分析表明,血液显示出最明显的辐射效应。在单独接受照射的动物中,所有剂量在照射后 12 小时首先可检测到 RIN 随时间和辐射剂量呈下降趋势。在存活至研究结束(14 天)的较低剂量组(即 0.5、1 和 5 Gy)中,这种效应是可逆的。相比之下,10 和 20 Gy 组的效应持续存在,RIN 值抑制至<4.5,死亡率较高。20 Gy 的辐射剂量是致命的,需要在第 6 天进行安乐死。任何时间点的 RIN 较低(<2.5)都与 100%的死亡率相关。联合辐射-烧伤损伤导致死亡率显著增加,以至于没有双重损伤的动物存活超过第 3 天,没有任何剂量大于 1 Gy 的动物存活超过第 1 天。在幸存的双重挑战的小鼠中观察到 RIN 更适度的抑制,并且在任何时间点都没有在单纯烧伤的小鼠中发现 RIN 值的统计学显著变化。在这项动物模型研究中,提出了一种简单准确的方法来评估血液中的辐射剂量暴露,该方法可能预测致死率。血液衍生 RNA 的 RIN 评估可以为临床决策支持工具奠定基础,以在基于辐射的大规模伤亡事件的紧张条件下指导医护人员。
