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Concussion in Professional Football: Brain Responses by Finite Element Analysis: Part 9

Viano, David C. Dr. med, Ph.D.; Casson, Ira R. M.D.; Pellman, Elliot J. M.D.; Zhang, Liying Ph.D.; King, Albert I. Ph.D.; Yang, King H. Ph.D.

Neurosurgery:
doi: 10.1227/01.NEU.0000186950.54075.3B
Clinical Studies: Sports: Trauma
Abstract

OBJECTIVE: Brain responses from concussive impacts in National Football League football games were simulated by finite element analysis using a detailed anatomic model of the brain and head accelerations from laboratory reconstructions of game impacts. This study compares brain responses with physician determined signs and symptoms of concussion to investigate tissue-level injury mechanisms.

METHODS: The Wayne State University Head Injury Model (Version 2001) was used because it has fine anatomic detail of the cranium and brain with more than 300,000 elements. It has 15 different material properties for brain and surrounding tissues. The model includes viscoelastic gray and white brain matter, membranes, ventricles, cranium and facial bones, soft tissues, and slip interface conditions between the brain and dura. The cranium of the finite element model was loaded by translational and rotational accelerations measured in Hybrid III dummies from 28 laboratory reconstructions of NFL impacts involving 22 concussions. Brain responses were determined using a nonlinear, finite element code to simulate the large deformation response of white and gray matter. Strain responses occurring early (during impact) and mid-late (after impact) were compared with the signs and symptoms of concussion.

RESULTS: Strain concentration “hot spots” migrate through the brain with time. In 9 of 22 concussions, the early strain “hot spots” occur in the temporal lobe adjacent to the impact and migrate to the far temporal lobe after head acceleration. In all cases, the largest strains occur later in the fornix, midbrain, and corpus callosum. They significantly correlated with removal from play, cognitive and memory problems, and loss of consciousness. Dizziness correlated with early strain in the orbital-frontal cortex and temporal lobe. The strain migration helps explain coup-contrecoup injuries.

CONCLUSION: Finite element modeling showed the largest brain deformations occurred after the primary head acceleration. Midbrain strain correlated with memory and cognitive problems and removal from play after concussion. Concussion injuries happen during the rapid displacement and rotation of the cranium, after peak head acceleration and momentum transfer in helmet impacts.

Author Information

ProBiomechanics, LLC, Bloomfield Hills, Michigan, Bioengineering Center, Wayne State University, Detroit, Michigan (Viano)

Department of Neurology, Long Island Jewish Medical Center, New Hyde Park, New York, and Department of Neurology, Albert Einstein College of Medicine, Bronx, New York (Casson)

ProHEALTH Care Associates, LLP Lake Success, New York (Pellman)

Bioengineering Center, Wayne State University, Detroit, Michigan (Zhang, King, Yang)

Reprint requests: David C. Viano, Dr. med, Ph.D, ProBiomechanics, LLC, 265 Warrington Road, Bloomfield Hills, MI 48304–2952.

Email: dviano@comcast.net

Received, March 3, 2005.

Accepted, September 8, 2005.

Copyright © by the Congress of Neurological Surgeons