Merchant-Borna Kian, Asselin Patrick, Narayan Darren, Abar Beau, Jones Courtney M C, Bazarian Jeffrey J
Department of Emergency Medicine, University of Rochester School of Medicine and Dentistry, 265 Crittenden Blvd, Box 655C, Rochester, NY, 14642, USA.
School of Mathematical Sciences, Rochester Institute of Technology, Rochester, NY, USA.
Ann Biomed Eng. 2016 Dec;44(12):3679-3692. doi: 10.1007/s10439-016-1680-9. Epub 2016 Jun 27.
One football season of sub-concussive head blows has been shown to be associated with subclinical white matter (WM) changes on diffusion tensor imaging (DTI). Prior research analyses of helmet-based impact metrics using mean and peak linear and rotational acceleration showed relatively weak correlations to these WM changes; however, these analyses failed to account for the emerging concept that neuronal vulnerability to successive hits is inversely related to the time between hits (TBH). To develop a novel method for quantifying the cumulative effects of sub-concussive head blows during a single season of collegiate football by weighting helmet-based impact measures for time between helmet impacts. We further aim to compare correlations to changes in DTI after one season of collegiate football using weighted cumulative helmet-based impact measures to correlations using non-weighted cumulative helmet-based impact measures and non-cumulative measures. We performed a secondary analysis of DTI and helmet impact data collected on ten Division III collegiate football players during the 2011 season. All subjects underwent diffusion MR imaging before the start of the football season and within 1 week of the end of the football season. Helmet impacts were recorded at each practice and game using helmet-mounted accelerometers, which computed five helmet-based impact measures for each hit: linear acceleration (LA), rotational acceleration (RA), Gadd Severity Index (GSI), Head Injury Criterion (HIC), and Head Impact Technology severity profile (HITsp). All helmet-based impact measures were analyzed using five methods of summary: peak and mean (non-cumulative measures), season sum-totals (cumulative unweighted measures), and season sum-totals weighted for time between hits (TBH), the interval of time from hit to post-season DTI assessment (TUA), and both TBH and TUA combined. Summarized helmet-based impact measures were correlated to statistically significant changes in fractional anisotropy (FA) using bivariate and multivariable correlation analyses. The resulting R values were averaged in each of the five summary method groups and compared using one-way ANOVA followed by Tukey post hoc tests for multiple comparisons. Total head hits for the season ranged from 431 to 1850. None of the athletes suffered a clinically evident concussion during the study period. The mean R value for the correlations using cumulative helmet-based impact measures weighted for both TUA and TBH combined (0.51 ± 0.03) was significantly greater than the mean R value for correlations using non-cumulative HIMs (vs. 0.19 ± 0.04, p < 0.0001), unweighted cumulative helmet-based impact measures (vs. 0.27 + 0.03, p < 0.0001), and cumulative helmet-based impact measures weighted for TBH alone (vs. 0.34 ± 0.02, p < 0.001). R values for weighted cumulative helmet-based impact measures ranged from 0.32 to 0.77, with 60% of correlations being statistically significant. Cumulative GSI weighted for TBH and TUA explained 77% of the variance in the percent of white matter voxels with statistically significant (PWMVSS) increase in FA from pre-season to post-season, while both cumulative GSI and cumulative HIC weighted for TUA accounted for 75% of the variance in PWMVSS decrease in FA. A novel method for weighting cumulative helmet-based impact measures summed over the course of a football season resulted in a marked improvement in the correlation to brain WM changes observed after a single football season of sub-concussive head blows. Our results lend support to the emerging concept that sub-concussive head blows can result in sub-clinical brain injury, and this may be influenced by the time between hits. If confirmed in an independent data set, our novel method for quantifying the cumulative effects of sub-concussive head blows could be used to develop threshold-based countermeasures to prevent the accumulation of WM changes with multiple seasons of play.
一个橄榄球赛季的次脑震荡头部撞击已被证明与扩散张量成像(DTI)上的亚临床白质(WM)变化有关。先前使用平均和峰值线性及旋转加速度对基于头盔的撞击指标进行的研究分析显示,与这些WM变化的相关性相对较弱;然而,这些分析未能考虑到一个新出现的概念,即神经元对连续撞击的易损性与撞击间隔时间(TBH)成反比。本研究旨在开发一种新方法,通过对基于头盔的撞击测量结果按头盔撞击间隔时间进行加权,来量化大学橄榄球单个赛季中亚脑震荡头部撞击的累积效应。我们还旨在比较使用加权累积头盔撞击测量结果与使用非加权累积头盔撞击测量结果及非累积测量结果,在一个大学橄榄球赛季后与DTI变化的相关性。我们对2011赛季收集的10名第三分区大学橄榄球运动员的DTI和头盔撞击数据进行了二次分析。所有受试者在橄榄球赛季开始前和赛季结束后1周内接受了扩散磁共振成像检查。在每次训练和比赛中使用头盔安装的加速度计记录头盔撞击情况,每次撞击计算五个基于头盔的撞击指标:线性加速度(LA)、旋转加速度(RA)、加德严重度指数(GSI)、头部损伤标准(HIC)和头部撞击技术严重度概况(HITsp)。所有基于头盔的撞击测量结果使用五种汇总方法进行分析:峰值和平均值(非累积测量)、赛季总和(累积未加权测量),以及按撞击间隔时间(TBH)、从撞击到赛季后DTI评估的时间间隔(TUA)以及TBH和TUA两者结合进行加权的赛季总和。使用双变量和多变量相关分析,将汇总的基于头盔的撞击测量结果与分数各向异性(FA)的统计学显著变化进行相关分析。在五个汇总方法组中分别对得到的R值进行平均,并使用单因素方差分析,随后进行Tukey事后检验进行多重比较。该赛季的总头部撞击次数在431次至1850次之间。在研究期间,没有运动员遭受临床明显的脑震荡。使用同时按TUA和TBH加权的累积头盔撞击测量结果进行相关性分析的平均R值(0.51±0.03)显著大于使用非累积HIMs(对比0.19±0.04,p<0.0001)、未加权累积头盔撞击测量结果(对比0.27 + 0.03,p<0.0001)以及仅按TBH加权的累积头盔撞击测量结果(对比0.34±0.02,p<0.001)进行相关性分析的平均R值。基于头盔的加权累积撞击测量结果的R值范围为0.32至0.77,其中60%的相关性具有统计学意义。按TBH和TUA加权的累积GSI解释了从赛季前到赛季后FA有统计学显著增加的白质体素百分比(PWMVSS)变化的77%的方差,而按TUA加权的累积GSI和累积HIC两者则占PWMVSS中FA减少方差的75%。一种对橄榄球赛季过程中基于头盔的累积撞击测量结果进行加权的新方法,显著改善了与亚脑震荡头部撞击单个橄榄球赛季后观察到的脑WM变化的相关性。我们的结果支持了新出现的概念,即亚脑震荡头部撞击可导致亚临床脑损伤,并且这可能受撞击间隔时间的影响。如果在独立数据集中得到证实,我们用于量化亚脑震荡头部撞击累积效应的新方法可用于制定基于阈值的对策,以防止多个赛季比赛中WM变化的累积。
