Department of Neurosurgery, University of Cincinnati College of Medicine, Cincinnati, Ohio.
Department of Neurology and Rehabilitation Medicine, University of Cincinnati College of Medicine, Cincinnati, Ohio.
JAMA Neurol. 2020 Apr 1;77(4):489-499. doi: 10.1001/jamaneurol.2019.4476.
Advances in treatment of traumatic brain injury are hindered by the inability to monitor pathological mechanisms in individual patients for targeted neuroprotective treatment. Spreading depolarizations, a mechanism of lesion development in animal models, are a novel candidate for clinical monitoring in patients with brain trauma who need surgery.
To test the null hypothesis that spreading depolarizations are not associated with worse neurologic outcomes.
DESIGN, SETTING, AND PARTICIPANTS: This prospective, observational, multicenter cohort study was conducted from February 2009 to August 2013 in 5 level 1 trauma centers. Consecutive patients who required neurological surgery for treatment of acute brain trauma and for whom research consent could be obtained were enrolled; participants were excluded because of technical problems in data quality, patient withdrawal, or loss to follow-up. Primary statistical analysis took place from April to December 2018. Evaluators of outcome assessments were blinded to other measures.
A 6-contact electrode strip was placed on the brain surface during surgery for continuous electrocorticography during intensive care.
Electrocorticography was scored for depolarizations, following international consensus procedures. Six-month outcomes were assessed by the Glasgow Outcome Scale-Extended score.
A total of 157 patients were initially enrolled; 19 were subsequently excluded. The 138 remaining patients (104 men [75%]; median [interquartile range] age, 45 [29-64] years) underwent a median (interquartile range) of 75.5 (42.2-117.1) hours of electrocorticography. A total of 2837 spreading depolarizations occurred in 83 of 138 patients (60.1% incidence) who, compared with patients who did not have spreading depolarizations, had lower prehospital systolic blood pressure levels (mean [SD], 133 [31] mm Hg vs 146 [33] mm Hg; P = .03), more traumatic subarachnoid hemorrhage (depolarization incidences of 17 of 37 [46%], 18 of 32 [56%], 22 of 33 [67%], and 23 of 30 patients [77%] for Morris-Marshall Grades 0, 1, 2, and 3/4, respectively; P = .047), and worse radiographic pathology (in 38 of 73 patients [52%] and 42 of 60 patients [70%] for Rotterdam Scores 2-4 vs 5-6, respectively; P = .04). Of patients with depolarizations, 32 of 83 (39%) had only sporadic events that induced cortical spreading depression of spontaneous electrical activity, whereas 51 of 83 patients (61%) exhibited temporal clusters of depolarizations (≥3 in a 2-hour span). Nearly half of those with clusters (23 of 51 [45%]) also had depolarizations in an electrically silent area of the cortex (isoelectric spreading depolarization). Patients with clusters did not improve in motor neurologic examinations from presurgery to postelectrocorticography, while other patients did improve. In multivariate ordinal regression adjusting for baseline prognostic variables, the occurrence of depolarization clusters had an odds ratio of 2.29 (95% CI, 1.13-4.65; P = .02) for worse outcomes.
In this cohort study of patients with acute brain trauma, spreading depolarizations were predominant but heterogeneous and independently associated with poor neurologic recovery. Monitoring the occurrence of spreading depolarizations may identify patients most likely to benefit from targeted management strategies.
创伤性脑损伤治疗的进展受到阻碍,因为无法针对需要手术的患者进行靶向神经保护治疗来监测病理机制。在动物模型中,播散性去极化是病变发展的一种机制,是颅脑创伤患者需要手术时进行临床监测的一个新的候选方案。
检验播散性去极化与神经功能预后不良无关的零假设。
设计、设置和参与者:这是一项前瞻性、观察性、多中心队列研究,于 2009 年 2 月至 2013 年 8 月在 5 个 1 级创伤中心进行。连续纳入需要神经外科手术治疗急性颅脑创伤且可获得研究同意的患者;因数据质量、患者退出或随访丢失等技术问题而排除参与者。主要统计分析于 2018 年 4 月至 12 月进行。结局评估人员对其他措施不了解。
在手术期间,将 6 接触电极条置于脑表面,用于重症监护期间的连续皮质脑电图监测。
根据国际共识程序对脑电图进行去极化评分。通过格拉斯哥结局量表-扩展评分评估 6 个月的结局。
共有 157 名患者最初入组,19 名患者随后被排除。其余 138 名患者(104 名男性[75%];中位[四分位间距]年龄,45[29-64]岁)接受了中位数(四分位间距)75.5(42.2-117.1)小时的皮质脑电图监测。在 138 名患者中,有 83 名(60.1%的发生率)发生了 2837 次播散性去极化,与未发生播散性去极化的患者相比,这些患者的院前收缩压水平较低(平均[标准差],133[31]mmHg 比 146[33]mmHg;P = .03),创伤性蛛网膜下腔出血更多(去极化发生率分别为 17/37[46%]、18/32[56%]、22/33[67%]和 23/30 例患者[77%],Morris-Marshall 分级分别为 0、1、2 和 3/4;P = .047),影像学病理更严重(38/73 例患者[52%]和 42/60 例患者[70%]的 Rotterdam 评分分别为 2-4 分和 5-6 分;P = .04)。在有去极化的患者中,32/83(39%)仅有诱导皮质扩散性抑制自发电活动的散发性事件,而 51/83 例患者(61%)表现为去极化的时间簇(2 小时内≥3 次)。这些簇中的近一半(23/51[45%])患者也存在皮质静息区的去极化(等电扩散性去极化)。有簇的患者从术前到皮质脑电图检查后,其运动神经检查并没有改善,而其他患者则有改善。在调整基线预后变量的多变量有序回归中,去极化簇的发生具有 2.29(95%置信区间,1.13-4.65;P = .02)的优势比,与较差的结局相关。
在这项急性颅脑创伤患者的队列研究中,播散性去极化是主要的,但具有异质性,与神经功能恢复不良独立相关。监测播散性去极化的发生可能有助于确定最有可能从靶向治疗中获益的患者。