Analysis of head impact exposure and brain microstructure response in a season-long application of a jugular vein compression collar: a prospective, neuroimaging investigation in American football

Myer, Gregory D.; Yuan, Weihong; Foss, Kim D. Barber; Thomas, Staci; Smith, David W.; Leach, James; Kiefer, Adam W.; DiCesare, Christopher A.; Adams, Janet; Gubanich, Paul; Kitchen, Katie; Schneider, Denis; Braswell, Daniel; Krueger, Darcy A.; Altaye, Mekibib

doi:10.1136/bjsports-2016-096134

Cited by 73 publications

(75 citation statements)

References 53 publications

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“…This novel prophylaxis through venous engorgement is intriguing in its capacity to address the multiple different mechanisms of TBI on microscopic (diffuse axonal injury) and macroscopic (hemorrhage) level that lead to morbidity and mortality. 4,5,12,13 Due to the absence of acceleration injury in the CCI model, our results contest an additional mechanism elucidated by IJV compression besides slosh mitigation through venous structural alterations. A quantitative mathematical model of the complex venous network is a substantial technical challenge and is beyond the scope of this paper; however, studies of simpler geometries and loading conditions have reported that increased internal pressure, volume, and diameter increases load bearing capacity in cylindrical fluid-filled vessels.…”

Section: Discussionsupporting

confidence: 58%

“…IJV compression and, presumably its effect on brain turgor, size, and resultant slosh mitigation, has been shown in pre-clinical and clinical studies to significantly reduce microstructural axonal damage from concussive impacts and acceleration forces. 12,13,22,23 This appealing approach as a prophylactic measure to TBI can only be considered for therapeutic use if mild venous congestion is shown to not intensify hemorrhagic injury. In this experiment, we have demonstrated that IJV compression prior to injury did not increase the propensity for hemorrhagic extension; and more significantly, actually reduced hemorrhage (both subarachnoid and intraparenchymal hemorrhage) in the porcine CCI model.…”

Section: Discussionmentioning

confidence: 99%

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Effect of Internal Jugular Vein Compression on Intracranial Hemorrhage in a Porcine Controlled Cortical Impact Model

Sindelar

Bailes

Sherman

et al. 2017

Journal of Neurotrauma

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Internal jugular vein (IJV) compression has been shown to reduce axonal injury in pre-clinical traumatic brain injury (TBI) models and clinical concussion studies. However, this novel approach to prophylactically mitigating TBI through venous congestion raises concerns of increasing the propensity for hemorrhage and hemorrhagic propagation. This study aims to test the safety of IJV compression in a large animal controlled cortical impact (CCI) injury model and the resultant effects on hemorrhage. Twelve swine were randomized to placement of a bilateral IJV compression collar (CCI+collar) or control/no collar (CCI) prior to CCI injury. A histological grading of the extent of hemorrhage, both subarachnoid (SAH) and intraparenchymal (IPH), was conducted in a blinded manner by two neuropathologists. Other various measures of TBI histology were also analyzed including: β-amyloid precursor protein (β-APP) expression, presence of degenerating neurons, extent of cerebral edema, and inflammatory infiltrates. Euthanized 5 h after injury, the CCI+collar animals exhibited a significant reduction in total SAH (p = 0.024-0.026) and IPH scores (p = 0.03-0.05) compared with the CCI animals. There was no statistically significant difference in scoring for the other markers of TBI (β-APP, neuronal degeneration, cerebral edema, or inflammatory infiltration). In conclusion, IJV compression was shown to reduce hemorrhage (SAH and IPH) in the porcine CCI model when applied prior to injury. These results suggest the role of IJV compression for mitigation of not only axonal, but also hemorrhagic injury following TBI.

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Section: Discussionsupporting

confidence: 58%

Section: Discussionmentioning

confidence: 99%

Effect of Internal Jugular Vein Compression on Intracranial Hemorrhage in a Porcine Controlled Cortical Impact Model

Sindelar

Bailes

Sherman

et al. 2017

Journal of Neurotrauma

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“…The effects of cumulative head impacts on young athletes over their entire careers are still unknown. Emerging neuroimaging investigations have generated evidence that suggests that the brain network may be affected, both structurally and functionally, during one season of contact sports, even with only nonclinical, subconcussive head impacts being tracked [Bahrami et al, ; Bazarian et al, ; Davenport et al, ; Lao et al, ; Koerte et al, ; Merchant‐Borna et al, ; Myer et al, ; Yuan et al, in press). When taken in aggregate over the career of the athlete, repetitive SCI could potentially increase the risk of season (or career) ending injuries, neurological impairments, and WM alterations [Bahrami et al, ; Myer et al, ].…”

Section: Introductionmentioning

confidence: 99%

“…Even in later adolescence, WM connectivity supporting executive control of behavior is still immature. Therefore, any compromise in WM integrity in youth or adolescence may have significant developmental implications [Asato et al, ; Bahrami et al, ; Davenport et al, ; Merchant‐Borna et al, ; Myer et al, ; Steinberg, ; ).…”

Section: Introductionmentioning

confidence: 99%

White matter alterations over the course of two consecutive high‐school football seasons and the effect of a jugular compression collar: A preliminary longitudinal diffusion tensor imaging study

Yuan

Foss

Thomas

et al. 2017

Human Brain Mapping

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The cumulative effects of repetitive subclinical head impacts during sports may result in chronic white matter (WM) changes and possibly, neurodegenerative sequelae. In this pilot study, we investigated the longitudinal WM changes over the course of two consecutive high-school football seasons and explored the long-term effects of a jugular vein compression collar on these WM alterations. Diffusion tensor imaging data were prospectively collected both pre-and postseason in the two consecutive seasons. Participants were assigned into either collar or noncollar groups. Tract-based spatial statistics (TBSS) approach and region of interest-based approach were used to quantify changes in WM diffusion properties. Despite comparable exposure to repetitive head impacts, significant reductions in mean, axial, and/or radial diffusivity were identified in Season 1 in multiple WM regions in the Additional Supporting Information may be found in the online version of this article. noncollar group but not in the collar group. After an 8-to 9-month long off-season, these changes observed in the noncollar group partially and significantly reversed but also remained significantly different from the baseline. In Season 2, trend level WM alterations in the noncollar group were found but located in spatially different regions than Season 1. Last, the WM integrity in the collar group remained unchanged throughout the four time points. In conclusion, we quantitatively assessed the WM structural changes and partial reversal over the course of two consecutive high-school football seasons. In addition, the mitigated WM alterations in athletes in the collar group might indicate potential effect of the collar in ameliorating the changes against repetitive head impacts. Hum Brain Mapp 39: 491-508, 2018.

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“…Two clinical studies [6,7] have used a jugular compression collar to reduce cranial slosh. They both demonstrated marked protective effects in high school athletes during competitive fullcontact play with exposure to impacts resulting in accelerations up to 200 g. Initial animal studies also lent support to the physiology of using a small jugular compressive collar in rats by providing an 83% protective effect when the animals were exposed to a 900 x g impact model [8].…”

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confidence: 99%

Red Blood Cell Response to Blast Levels of Force Impartations Into Freely Moveable Fluid Surfaces Inside a Closed Container

et al. 2018

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Background: Blast waves have plagued mankind for centuries, yet their interaction with blood has been largely overlooked. Recent studies of ways to mitigate traumatic brain injury (TBI) in sport have utilized slosh-reducing techniques with varying success. However, hydrodynamic principles have not been used to assess the interaction of intense blast waves and the red blood cells themselves.Objective: To establish the benefits of slosh reduction by analyzing the degree of damaging effects from a blast wave imparted on human red blood cells both fully and partially contained by rigid surfaces.Methods: Approximately 40 mL of blood was collected from 13 males and 25 females ages 18-55 and aliquoted into three separate steel containers (5 cc-control, 15 cc-full and 10 cc -partially filled) in preparation for blast testing. An improvised explosive device (IED) blast level model (Vandenberg) was developed by using a nail gun plunger to impart approximately 150 kPa of pressure over a 4 to 6 µs timespan into a target container. Blood in steel containers, with and without IED blast exposure, was assayed for cell hemolysis products including serum free hemoglobin (HgB), lactate dehydrogenase (LDH), and potassium (K-ABL) when the containers were fully-filled or partially filled (no-slosh versus slosh). Hemolysis products were measured 1, 4, 24, 48, and 72 h after blast exposure.Results: In both the slosh and no-slosh groups, hemolysis increased significantly at each time point after IED blast energy impartation. However, the no-slosh blood samples had less hemolysis. Compared to the slosh group, blood from the no slosh group contained less extracellular HgB (p < 0.0001), lactate dehydrogenase (LDH) (p < 0.0001), and potassium (K + ) (p < 0.0001) at all time points.Conclusions: Damage to human blood resulting from the impartation of a force similar to an IED blast was mitigated by fully containing blood within a volume and thereby reducing fluid slosh.

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Analysis of head impact exposure and brain microstructure response in a season-long application of a jugular vein compression collar: a prospective, neuroimaging investigation in American football

Cited by 73 publications

References 53 publications

Effect of Internal Jugular Vein Compression on Intracranial Hemorrhage in a Porcine Controlled Cortical Impact Model

Effect of Internal Jugular Vein Compression on Intracranial Hemorrhage in a Porcine Controlled Cortical Impact Model

White matter alterations over the course of two consecutive high‐school football seasons and the effect of a jugular compression collar: A preliminary longitudinal diffusion tensor imaging study

Red Blood Cell Response to Blast Levels of Force Impartations Into Freely Moveable Fluid Surfaces Inside a Closed Container

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