John A. Feagin Jr. Sports Medicine Fellowship Department of Orthopaedic Surgery, Keller Army Community Hospital, West Point, NY 10996-1197, USA.
Division of Neurosurgery, Walter Reed National Military Medical Center, Bethesda, MD 20814, USA.
Mil Med. 2024 Jul 3;189(7-8):1593-1602. doi: 10.1093/milmed/usad271.
Assessments of the pupil's response to light have long been an integral part of neurologic examinations. More recently, the pupillary light reflex (PLR) has shown promise as a potential biomarker for the diagnosis of mild traumatic brain injury. However, to date, few large-scale normative data are available for comparison and reference, particularly, in military service members. The purpose of this study was to report normative values for eight PLR measurements among healthy service academy cadets based on sex, age, sleep, race, ethnicity, anisocoria, and concussion history.
Freshmen entering a U.S. Service Academy completed a quantitative pupillometric assessment in conjunction with baseline concussion testing. PLR measurements were conducted using a Neuroptics PLR-3000 with a 121 µW light stimulus. The device measured maximum and minimum pupil diameter (mm), latency (time to maximum pupil constriction post-light stimulus [s]), peak and average constriction velocity (mm/s), average dilation velocity (mm/s), percentage pupil constriction, and T75 (time for pupil re-dilation from minimum pupil diameter to 75% maximum diameter [s]). During baseline testing, cadets also reported concussion history (yes and no) and hours slept the night before (<5.5 and ≥5.5). Normative values for each PLR measurement were calculated as mean ± SD, percentiles, and interquartile range. Mann-Whitney U tests were used to assess differences based on sex, concussion history, ethnicity, and hours slept for each PLR measurement. Kruskall-Wallis testing was used to assess differences based on age, race, and anisocoria. Alpha was set at .05 and nonparametric effect sizes (r) were calculated for statistically significant results. Effect sizes were interpreted as no effect (r < .1), small (r ≥.1-<.3), medium (r ≥.3-<.5), or large (r ≥ .5). All procedures were reviewed and approved by the local institutional review board and the U.S. Army Human Research Protection Office before the study was conducted. Each subject provided informed consent to participate in the study before data collection.
Of the 1,197 participants baselined, 514 cadets (131 female; 18.91 ± 0.96 years) consented and completed a valid baseline pupillometric assessment. Eighty participants reported at least one previous concussion and participants reported an average of 5.88 ± 1.63 h slept the previous night. Mann-Whitney U results suggest females had larger initial (z = -3.240; P = .001; r = .10) and end pupil diameter (z = -3.080; P = .002; r = .10), slower average dilation velocity (z = 3.254; P = .001; r = .11) and faster T75 values (z = -3.342; P = .001; r = .11). Age, sleep, and race stratified by sex, also displayed a significant impact on specific PLR metrics with effect sizes ranging from small to medium, while ethnicity, anisocoria, and concussion history did not display an impact on PLR metrics.
This study provides the largest population-specific normative values for eight PLR measurements. Initial and end pupil diameter, dilation velocity, and the T75 metrics differed by sex; however, these differences may not be clinically significant as small effect size was detected for all metrics. Sex, age, sleep, and race may impact specific PLR metrics and are worth consideration when performing PLR assessments for mild traumatic brain injury management.
评估瞳孔对光的反应一直是神经检查的一个重要组成部分。最近,瞳孔光反射(PLR)已显示出作为轻度创伤性脑损伤诊断的潜在生物标志物的潜力。然而,迄今为止,几乎没有大规模的规范数据可供比较和参考,特别是在军事服役人员中。本研究的目的是报告根据性别、年龄、睡眠、种族、民族、瞳孔不等和脑震荡史,健康的军校学员的八项 PLR 测量的正常值。
进入美国服务学院的新生在基线脑震荡测试的同时完成了一项定量瞳孔测量评估。使用 Neuroptics PLR-3000 用 121µW 光刺激进行 PLR 测量。该设备测量最大和最小瞳孔直径(mm)、潜伏期(从光刺激后最大瞳孔收缩的时间 [s])、峰值和平均收缩速度(mm/s)、平均扩张速度(mm/s)、瞳孔收缩百分比和 T75(从最小瞳孔直径到最大瞳孔直径的 75%重新扩张的时间 [s])。在基线测试期间,学员还报告了脑震荡史(是和否)和前一天晚上的睡眠时间(<5.5 和≥5.5)。为每个 PLR 测量计算了正常值,包括平均值±标准差、百分位数和四分位间距。Mann-Whitney U 检验用于评估性别、脑震荡史、民族和睡眠时间对每个 PLR 测量的差异。Kruskal-Wallis 检验用于评估年龄、种族和瞳孔不等对 PLR 测量的差异。设定α为.05,对于统计学上显著的结果计算非参数效应大小(r)。效应大小被解释为无效应(r < .1)、小效应(r ≥.1-<.3)、中效应(r ≥.3-<.5)或大效应(r ≥ .5)。在进行研究之前,所有程序都经过了当地机构审查委员会和美国陆军人类研究保护办公室的审查和批准。在收集数据之前,每位受试者都同意参与研究并提供了知情同意书。
在 1197 名基线参与者中,有 514 名学员(131 名女性;18.91±0.96 岁)同意并完成了有效的基线瞳孔测量评估。80 名学员报告至少有一次脑震荡,学员报告前一天晚上平均睡眠 5.88±1.63 小时。Mann-Whitney U 结果表明,女性的初始(z = -3.240;P = .001;r = .10)和终末瞳孔直径(z = -3.080;P = .002;r = .10)更大,平均扩张速度(z = 3.254;P = .001;r = .11)较慢,T75 值(z = -3.342;P = .001;r = .11)更快。按性别分层的年龄、睡眠和种族也对特定的 PLR 指标有显著影响,效应大小从小到大不等,而民族、瞳孔不等和脑震荡史对 PLR 指标没有影响。
本研究提供了最大的特定于人口的八项 PLR 测量正常值。初始和终末瞳孔直径、扩张速度和 T75 指标因性别而异;然而,由于所有指标均检测到小效应大小,这些差异可能不具有临床意义。性别、年龄、睡眠和种族可能会影响特定的 PLR 指标,在进行轻度创伤性脑损伤管理的 PLR 评估时值得考虑。
