评估急诊科使用 CT 扫描和 T2-星形加权图像核磁共振成像进行脑损伤分类的准确性

Hadeel Zaidan Khlaif Almamoori, Vahid Changizi, Fahimeh Zeinalkhani, Ahmed Faaz Nasser
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The population of this study were100 patients the population of this study were patients with brain trauma that have been indicated for CT and MRI test in emergency department period of sampling which was during September 2023 to February 2024. Epidemiological data were collected at admission: age, sex, TBI mechanism, presence of m TBI, moderate and severe extra-cranial injury, post-resuscitation level of consciousness expressed by GCS and its motor subscale, and pupil examination. Findings from the admission CT scan were recorded following the Traumatic Coma Data Bank classification and MRI had been done through 72h week and 2week depending on stability of patients. questionnaire was designed and copied by the researcher. Examination had done on CT scan (Philips Multiva System 64 slice) in a supine position using a standard brain protocol, as part of the initial clinical assessment, according to the Scandinavian Guidelines for Head Injury Management. MRI examinations was performed using MRI 1. 5 T scanner (Philips MULTIVA systems) using a phase array head coil at the radiology department. The data had encoded and then entered into the statistical program (SSPS version 26). Results: A total 100 were patients with brain trauma that have been indicated for CT and MRI investigated in emergency department radiographically. The age of each study samples was normally distributed and ranged from 6 to 60, 7 to 55, and 10 to 60 years with a mean of 34. 6±17 for mild group, 30. 05±13. 7 for moderate group and 10 to 60 for sever group respectively after the inclusion and exclusion criteria, without significant differences between them (P-value= 0. 454) which reflecting the matching purpose of samples collection. All the 100 participants who completed, CT identified radiographic TBI in were true positive diagnostic accuracy (60%) while missed diagnostic were 40case. 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Using CT as the criterion standard in severe TBI, after brain injury through 24h the sensitivity (100%) and Specificity (57%). MRI 1 were sensitivity (0. 8%) and Specificity (75. 2%). MRI 2 were sensitivity (0. 6%) and Specificity (30%). MRI 3 were sensitivity (100%) and Specificity (100%). Conclusion: MRI is a reasonable alternative to CT to identify radiographically evident TBI in clinically stable patients. MRI is a very sensitive technique for diagnosing DAI and ATI in moderate and severe TBI. 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引用次数: 0

摘要

背景:虽然创伤性脑损伤(TBI)的诊断由临床决定,但神经影像学检查对于在确定颅内病理情况的基础上指导治疗仍然至关重要。CT 是急性 TBI 初步分诊和随访的主要成像手段,因为它在检测需要神经外科干预的原发性和继发性损伤方面快速准确,但在检测非出血性病变和位于后窝的病变方面分辨率有限。核磁共振成像对检测某些颅内损伤(如轴索损伤)和损伤后 24-48 小时的血液制品更为敏感,但也有局限性(如速度、可及性、对运动的敏感性和成本)。证据主要支持在 CT 检查结果正常且存在持续性不明原因的神经系统检查结果或在亚急性和慢性期使用 MRI。放射科医生应了解常规磁共振成像方案的作用和最佳成像方式,以最少的序列减少研究时间,从而能够与患者一起快速完成检查。在急诊科使用 CT 检查和由 T1、T2、FALIR 和 T2* 组成的 MRI 方案组合,有助于脑外伤分类治疗计划的良好诊断和治疗反应的评估。目的:螺旋 CT 扫描和 MRI T2 星形加权图像在脑损伤分类中的作用。方法:本项目采用横断面设计。研究对象为 100 名急诊科有 CT 和 MRI 检查指征的脑外伤患者,取样时间为 2023 年 9 月至 2024 年 2 月。入院时收集的流行病学数据包括:年龄、性别、创伤性脑损伤机制、是否存在多发性创伤性脑损伤、中度和重度颅外损伤、复苏后的意识水平(以 GCS 及其运动分量表表示)以及瞳孔检查。入院 CT 扫描结果按照创伤性昏迷数据库的分类进行记录,核磁共振成像则根据患者病情的稳定程度在 72 小时周和 2 周内进行。根据《斯堪的纳维亚头部损伤管理指南》,作为初步临床评估的一部分,采用标准脑部方案对仰卧位患者进行 CT 扫描(飞利浦 Multiva 系统 64 片)检查。核磁共振成像检查由放射科使用相位阵列头部线圈的核磁共振成像 1.5 T 扫描仪(飞利浦 MULTIVA 系统)进行。数据经编码后输入统计程序(SSPS 26 版)。结果共有 100 名脑外伤患者在急诊科接受了 CT 和 MRI 检查。各研究样本的年龄呈正态分布,分别为 6 至 60 岁、7 至 55 岁和 10 至 60 岁,轻度组的平均年龄为(34.6±17)岁,中度组的平均年龄为(30.05±13)岁。05±13.中度组为 30.05±13.7 岁,重度组为 10 至 60 岁。在所有 100 名完成检查的参与者中,CT 确定放射性创伤性脑损伤的诊断准确率为真阳性(60%),而漏诊为 40 例。核磁共振成像的诊断准确率为92%,而漏诊为8例,最常见的损伤为颅骨骨折、脑震荡、颅内出血、硬膜下血肿、蛛网膜下腔出血、弥漫性轴索损伤、外伤性轴索损伤。将 CT 作为轻度创伤性脑损伤的标准,24 小时内的敏感性(0.7%)和特异性(29.6%)。核磁共振成像在创伤性脑损伤后 1 至 72 小时内的敏感性(86.7%)和特异性(100%)。创伤性脑损伤后第2周至第1周的磁共振成像的灵敏度为6.7%,特异性为43.5%。创伤性脑损伤后3至2周的磁共振成像的灵敏度(25.1%)和特异度(64.7%)。将 CT 作为中度创伤性脑损伤的标准,脑损伤后 24 小时内的敏感性(54.5%)和特异性(33.4%)。磁共振成像 1 的灵敏度(0.9%)和特异性(24.1%)。磁共振成像 2 的敏感性(87.3%)和特异性(97.8%)。磁共振成像 3 的灵敏度为 0.5%,特异性为 33.4%。将 CT 作为严重创伤性脑损伤的标准,脑损伤 24 小时后的敏感性(100%)和特异性(57%)。MRI 1 的灵敏度(0.8%)和特异性(75.2%)。磁共振成像 2 的灵敏度(0.6%)和特异性(30%)。磁共振成像 3 的灵敏度(100%)和特异性(100%)。结论:核磁共振成像是一种合理的替代 CT 的方法,可用于识别临床稳定的患者中影像学上明显的创伤性脑损伤。磁共振成像是诊断中度和重度 TBI 的 DAI 和 ATI 的非常敏感的技术。 为了正确诊断,我们建议在亚急性期(创伤后 4 周内)进行常规 MRI 检查,其中至少包括不同切片平面的 T1、T2、FLAIR 和梯度回波序列,以缩短检查时间,从而能够在 TBI 患者接受 MRI 检查后尽快完成检查。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Evaluation of Brain Injury Classifications Accuracy by Using CT scan and T2 - Star Weighted Image MRI in the Emergency Department
Background: While the diagnosis of traumatic brain injury (TBI) is a clinical decision, neuroimaging remains vital for guiding management on the basis of identification of intracranial pathologic conditions. CT is the mainstay of imaging of acute TBI for both initial triage and follow-up, as it is fast and accurate in detecting both primary and secondary injuries that require neurosurgical intervention, also has a limited resolution capacity in detecting non-hemorrhagic lesions and those lesions located in the posterior fossa. MRI is more sensitive for the detection of certain intracranial injuries (e.g., axonal injuries) and blood products 24-48 hours after injury, but it has limitations (e.g., speed, accessibility, sensitivity to motion, and cost). The evidence primarily supports the use of MRI when CT findings are normal and there are persistent unexplained neurologic findings or at sub-acute and chronic periods. Radiologists should understand the role and optimal imaging modality to a conventional MRI protocol with minimum sequences that reduces study time in order to be able to complete examination fast with patient. The use of examination CT and a combination of MRI protocols consisting of T1, T2, FALIR and T2* in emergency department to help with the good diagnosis of brain trauma classification treatment planning and assessing response to treatment. Objective: The role of helical CT scan and MRI T2 star weighted image to classification brain injury. Method: This project is based on cross-sectional design. The population of this study were100 patients the population of this study were patients with brain trauma that have been indicated for CT and MRI test in emergency department period of sampling which was during September 2023 to February 2024. Epidemiological data were collected at admission: age, sex, TBI mechanism, presence of m TBI, moderate and severe extra-cranial injury, post-resuscitation level of consciousness expressed by GCS and its motor subscale, and pupil examination. Findings from the admission CT scan were recorded following the Traumatic Coma Data Bank classification and MRI had been done through 72h week and 2week depending on stability of patients. questionnaire was designed and copied by the researcher. Examination had done on CT scan (Philips Multiva System 64 slice) in a supine position using a standard brain protocol, as part of the initial clinical assessment, according to the Scandinavian Guidelines for Head Injury Management. MRI examinations was performed using MRI 1. 5 T scanner (Philips MULTIVA systems) using a phase array head coil at the radiology department. The data had encoded and then entered into the statistical program (SSPS version 26). Results: A total 100 were patients with brain trauma that have been indicated for CT and MRI investigated in emergency department radiographically. The age of each study samples was normally distributed and ranged from 6 to 60, 7 to 55, and 10 to 60 years with a mean of 34. 6±17 for mild group, 30. 05±13. 7 for moderate group and 10 to 60 for sever group respectively after the inclusion and exclusion criteria, without significant differences between them (P-value= 0. 454) which reflecting the matching purpose of samples collection. All the 100 participants who completed, CT identified radiographic TBI in were true positive diagnostic accuracy (60%) while missed diagnostic were 40case. In MRI were true positive diagnostic accuracy (92%) while missed in 8 cases with the most common injuries being skull fracture, concision, intracranial hemorrhage, subdural hematoma, and subarachnoid hemorrhage, diffuse axonal injury, trauma axonal injury. Using CT as the criterion standard in mild TBI, through 24h the sensitivity (0. 7%) and Specificity (29. 6%). MRI 1 through 72h after TBI had the sensitivity (86. 7%) and Specificity (100%). MRI 2 through week after TBI had the sensitivity (6. 7%) and Specificity (43. 5%). MRI 3 through 2 weeks after TBI had the sensitivity (25. 1%) and Specificity (64. 7%). Using CT as the criterion standard in moderate TBI, after brain injury through 24h the sensitivity (54. 5%) and Specificity (33. 4%). MRI1 were sensitivity (0. 9%) and Specificity (24. 1%). MRI 2 were sensitivity (87. 3%) and Specificity (97. 8%). MRI 3 were sensitivity (0. 5%) and Specificity (33. 4%). Using CT as the criterion standard in severe TBI, after brain injury through 24h the sensitivity (100%) and Specificity (57%). MRI 1 were sensitivity (0. 8%) and Specificity (75. 2%). MRI 2 were sensitivity (0. 6%) and Specificity (30%). MRI 3 were sensitivity (100%) and Specificity (100%). Conclusion: MRI is a reasonable alternative to CT to identify radiographically evident TBI in clinically stable patients. MRI is a very sensitive technique for diagnosing DAI and ATI in moderate and severe TBI. For proper diagnosis, we recommend performing a conventional MRI in the sub-acute phase (within the first 4 weeks of the trauma) that includes at least T1, T2, FLAIR and gradient echo sequences in the different slice planes that reduces study time in order to be able to complete examination fast as soon as an MRI in patients with TBI.
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