突发性剧烈头痛患者黄染检测中肉眼观察与分光光度法的对比--诊断准确性研究。

IF 5.4 2区 医学 Q1 CLINICAL NEUROLOGY
Headache Pub Date : 2024-08-01 DOI:10.1111/head.14802
Ane Skaare Sjulstad, Ole-Lars Brekke, Karl B Alstadhaug
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引用次数: 0

摘要

目的:关于是否应常规使用分光光度法检测脑脊液(CSF)中的黄原色素,或者目测是否足够,目前仍存在分歧。我们旨在评估这些方法在检测突发剧烈头痛患者动脉瘤性蛛网膜下腔出血方面的诊断准确性:背景:当患者因头痛到急诊科就诊并被怀疑为蛛网膜下腔出血时,如果入院时头颅非对比计算机断层扫描(CT)结果为阴性,则排除这一可能性的金标准是通过或不通过分光光度法对CSF进行黄染分析。如果头颅 CT 被解释为阳性、出现血性 CSF 或无法获得 CSF 的视觉评估数据,则排除患者。我们仔细检查了患者的病历,并评估了分光光度法与目测法相比的优势。支持蛛网膜下腔出血的净胆红素吸光度临界值设定为 >0.007 吸光度单位。如果净胆红素吸光度≤0.007,净氧合血红蛋白吸光度≥0.1个吸光度单位,则分光光度法也被视为阳性。我们计算并比较了脑脊液分光光度法和目测脑脊液的敏感性和特异性:共纳入 769 名患者,平均年龄为 42.3 ± (标准差 [SD] = 17.3) 岁。41.5%的患者发病时头痛如雷贯耳,4.7%的患者突然失去知觉。15名患者(2%)最终被诊断为蛛网膜下腔出血,6名(0.8%)为动脉瘤性蛛网膜下腔出血,7名(0.9%)为脑周出血,1名(0.1%)为皮质脑窦静脉血栓,1名(0.1%)为脊髓硬膜外血肿。有四名患者(0.5%)的蛛网膜下腔出血无法通过肉眼检查发现,其中两名患者的出血是由动脉瘤破裂引起的。这两名患者中,一名在介入治疗前死亡,另一名因前交通动脉瘤接受了盘绕治疗。腰椎穿刺检测蛛网膜下腔出血所需的人数为 51 人,而检测动脉瘤出血所需的人数为 128 人。相应的 CSF 分光光度分析所需人数分别为 192 人和 385 人。分光光度法呈阳性的患者有 31 人(4.0%),其中 18 人(2.3%)也有肉眼检测到的黄染(11 人为真阳性)。在 13 份肉眼清晰的 CSF 样本中,平均净胆红素吸光度为 0.0111 ± (SD = 0.0103) 个吸光度单位,而在分光光度法呈阴性的 CSF 样本中,平均净胆红素吸光度为 0.0017 ± (SD = 0.0013)个吸光度单位。净氧血红蛋白吸光度的相应数字为 0.0391 ± (SD = 0.0522) 与 0.0057 ± (SD = 0.0081)。分光光度法检测黄染的灵敏度为 100%(95% 置信区间 [CI],78-100),而目测黄染的灵敏度为 73%(95% 置信区间 [CI],45-92)。分光光度法检测黄染的特异性为 98%(95% CI,97-99),而肉眼黄染的特异性为 99%(95% CI,98-100)。两种方法的阴性预测值都很高:100%(95% CI,99.5-100)与 99.5%(95% CI,98.6-99.9):目测法和分光光度法检测 CSF 黄染的诊断准确率都很高,但目测法的灵敏度较低,因此并不可靠,我们建议在临床实践中使用分光光度法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Visual inspection versus spectrophotometry for xanthochromia detection in patients with sudden onset severe headache-A diagnostic accuracy study.

Objective: There is still disagreement about whether to routinely use spectrophotometry to detect xanthochromia in cerebrospinal fluid (CSF) or whether visual inspection is adequate. We aimed to evaluate the diagnostic accuracy of these methods in detecting an aneurysmal subarachnoid hemorrhage in patients with sudden onset severe headache.

Background: When a patient presents to the emergency department with a headache for which there is suspicion of a subarachnoid hemorrhage, the gold standard to rule this out is to perform a CSF analysis for xanthochromia with or without spectrophotometry if the cranial non-contrast computed tomography (CT) upon admission is negative.

Methods: Having applied the gold standard, we retrospectively included patients with acute headache who underwent both CT scan and CSF spectrophotometry at our hospital in the period 2002-2020. Patients were excluded if the cranial CT was interpreted as positive, there was a bloody CSF, or if visual assessment data of the CSF was unavailable. We scrutinized the patients' medical records and evaluated the benefit of spectrophotometry compared to visual inspection. The net bilirubin absorbance cut-off for support of subarachnoid hemorrhage was set at >0.007 absorbance units. The spectrophotometry was also considered positive if the net bilirubin absorbance was ≤0.007 and net oxyhemoglobin absorbance was ≥0.1 absorbance units. We calculated and compared the sensitivity and specificity of CSF spectrophotometry and visual inspection of the CSF.

Results: In total, 769 patients, with a mean age of 42.3 ± (standard deviation [SD] = 17.3) years, were included. The headache onset was classified as a thunderclap headache in 41.5%, and 4.7% had a sudden loss of consciousness. Fifteen patients (2%) were finally diagnosed with a subarachnoid hemorrhage, six (0.8%) had an aneurysmal subarachnoid hemorrhage, seven (0.9%) had a perimesencephalic hemorrhage, one (0.1%) had a cortical cerebral sinus venous thrombosis, and one (0.1%) had a spinal epidural hematoma. Four patients (0.5%) had a subarachnoid hemorrhage that was not detected by visual inspection, and two were caused by an aneurysmal rupture. One of these two patients died just before intervention, and the other underwent coiling for an anterior communicating aneurysm. The number needed for lumbar puncture to detect a subarachnoid hemorrhage was 51, but 128 to detect an aneurysmal hemorrhage. The corresponding numbers needed for CSF spectrophotometric analysis were 192 and 385, respectively. Spectrophotometry was positive in 31 patients (4.0%), of whom 18 (2.3%) also had visually detected xanthochromia (11 true positive). The mean net bilirubin absorbance in the 13 samples with visually clear CSF was 0.0111 ± (SD = 0.0103) absorbance units, compared to 0.0017 ± (SD = 0.0013) in the CSF with negative spectrophotometry. The corresponding figures for net oxyhemoglobin absorbance were 0.0391 ± (SD = 0.0522) versus 0.0057 ± (SD = 0.0081). The sensitivity of spectrophotometric xanthochromia detection was 100% (95% confidence interval [CI], 78-100), compared to 73% (95% CI, 45-92) for visual xanthochromia detection. The specificity of spectrophotometric xanthochromia detection was 98% (95% CI, 97-99) compared to 99% (95% CI, 98-100) for visual xanthochromia detection. Both methods had high negative predictive values: 100% (95% CI, 99.5-100) versus 99.5% (95% CI, 98.6-99.9), respectively.

Conclusions: Both visual inspection and spectrophotometry have high diagnostic accuracy for detecting CSF xanthochromia, but the lower sensitivity of visual assessment makes it unreliable, and we recommend the use of spectrophotometry in clinical practice.

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来源期刊
Headache
Headache 医学-临床神经学
CiteScore
9.40
自引率
10.00%
发文量
172
审稿时长
3-8 weeks
期刊介绍: Headache publishes original articles on all aspects of head and face pain including communications on clinical and basic research, diagnosis and management, epidemiology, genetics, and pathophysiology of primary and secondary headaches, cranial neuralgias, and pains referred to the head and face. Monthly issues feature case reports, short communications, review articles, letters to the editor, and news items regarding AHS plus medicolegal and socioeconomic aspects of head pain. This is the official journal of the American Headache Society.
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