Analysis of HIC and Hydrostatic Pressure in the Human Head during NOCSAE Tests of American Football Helmets

Analysis of HIC and Hydrostatic Pressure in the Human Head during NOCSAE Tests of American Football Helmets

Brain damage is a serious economic and social burden. Contact sports such as American football, are one of the most common sources of concussions. The biomechanical response of the head–helmet system caused by dynamic loading plays a major role. The literature has focused on measuring the resultant...

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Main Authors: Mateusz Dymek, Mariusz Ptak, Monika Ratajczak, Fábio A. O. Fernandes, Artur Kwiatkowski, Johannes Wilhelm
Format: Article
Language:English
Published: MDPI AG 2021-02-01
Series:Brain Sciences
Subjects:
brain injury
finite element head model
American football
helmet
helmet testing
biomechanics
Online Access:https://www.mdpi.com/2076-3425/11/3/287
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spelling doaj-5d45c855bd6540d9b3e0ccea1fbf2c3b2021-02-26T00:07:09ZengMDPI AGBrain Sciences2076-34252021-02-011128728710.3390/brainsci11030287Analysis of HIC and Hydrostatic Pressure in the Human Head during NOCSAE Tests of American Football HelmetsMateusz Dymek0Mariusz Ptak1Monika Ratajczak2Fábio A. O. Fernandes3Artur Kwiatkowski4Johannes Wilhelm5Faculty of Mechanical Engineering, Wroclaw University of Science and Technology, Lukasiewicza 7/9, 50-371 Wroclaw, PolandFaculty of Mechanical Engineering, Wroclaw University of Science and Technology, Lukasiewicza 7/9, 50-371 Wroclaw, PolandFaculty of Mechanical Engineering, University of Zielona Gora, ul. Prof. Szafrana 4, 65-516 Zielona Gora, PolandTEMA—Centre for Mechanical Technology and Automation, Department of Mechanical Engineering, University of Aveiro, Campus de Santiago, 3810-193 Aveiro, PortugalDepartment of Neurosurgery, Provincial Specialist Hospital in Legnica, ul. Iwaszkiewicza 5, 59-220 Legnica, PolandCFturbo GmbH, Unterer Kreuzweg 1, 01097 Dresden, GermanyBrain damage is a serious economic and social burden. Contact sports such as American football, are one of the most common sources of concussions. The biomechanical response of the head–helmet system caused by dynamic loading plays a major role. The literature has focused on measuring the resultant kinematics that act on the head and helmet during tackles. However, few studies have focused on helmet validation tests, supported by recent findings and emerging numerical approaches. The future of helmet standards could benefit from insights at the level of injury mechanisms, using numerical tools to assess the helmets. Therefore, in this work, a numerical approach is employed to investigate the influence of intracranial pressure (ICP) on brain pathophysiology during and after helmeted impacts, which are common in American football. The helmeted impacts were performed at several impact locations according to the NOCSAE standard (configurations A, AP, B, C, D, F, R, UT). In order to evaluate the ICP levels, the αHEAD finite element head and brain model was combined with a Hybrid III-neck structure and then coupled with an American football helmet to simulate the NOCSAE impacts. In addition, the ICP level was analyzed together with the resulting HIC value, since the latter is commonly used, in this application and others, as the injury criterion. The obtained results indicate that ICP values exceed the common threshold of head injury criteria and do not correlate with HIC values. Thus, this work raises concern about applying the HIC to predict brain injury in American football direct head impacts, since it does not correlate with ICP predicted with the FE head model.https://www.mdpi.com/2076-3425/11/3/287brain injuryfinite element head modelAmerican footballhelmethelmet testingbiomechanics
collection DOAJ
language English
format Article
sources DOAJ
author Mateusz Dymek
Mariusz Ptak
Monika Ratajczak
Fábio A. O. Fernandes
Artur Kwiatkowski
Johannes Wilhelm
spellingShingle Mateusz Dymek
Mariusz Ptak
Monika Ratajczak
Fábio A. O. Fernandes
Artur Kwiatkowski
Johannes Wilhelm
Analysis of HIC and Hydrostatic Pressure in the Human Head during NOCSAE Tests of American Football Helmets
Brain Sciences
brain injury
finite element head model
American football
helmet
helmet testing
biomechanics
author_facet Mateusz Dymek
Mariusz Ptak
Monika Ratajczak
Fábio A. O. Fernandes
Artur Kwiatkowski
Johannes Wilhelm
author_sort Mateusz Dymek
title Analysis of HIC and Hydrostatic Pressure in the Human Head during NOCSAE Tests of American Football Helmets
title_short Analysis of HIC and Hydrostatic Pressure in the Human Head during NOCSAE Tests of American Football Helmets
title_full Analysis of HIC and Hydrostatic Pressure in the Human Head during NOCSAE Tests of American Football Helmets
title_fullStr Analysis of HIC and Hydrostatic Pressure in the Human Head during NOCSAE Tests of American Football Helmets
title_full_unstemmed Analysis of HIC and Hydrostatic Pressure in the Human Head during NOCSAE Tests of American Football Helmets
title_sort analysis of hic and hydrostatic pressure in the human head during nocsae tests of american football helmets
publisher MDPI AG
series Brain Sciences
issn 2076-3425
publishDate 2021-02-01
description Brain damage is a serious economic and social burden. Contact sports such as American football, are one of the most common sources of concussions. The biomechanical response of the head–helmet system caused by dynamic loading plays a major role. The literature has focused on measuring the resultant kinematics that act on the head and helmet during tackles. However, few studies have focused on helmet validation tests, supported by recent findings and emerging numerical approaches. The future of helmet standards could benefit from insights at the level of injury mechanisms, using numerical tools to assess the helmets. Therefore, in this work, a numerical approach is employed to investigate the influence of intracranial pressure (ICP) on brain pathophysiology during and after helmeted impacts, which are common in American football. The helmeted impacts were performed at several impact locations according to the NOCSAE standard (configurations A, AP, B, C, D, F, R, UT). In order to evaluate the ICP levels, the αHEAD finite element head and brain model was combined with a Hybrid III-neck structure and then coupled with an American football helmet to simulate the NOCSAE impacts. In addition, the ICP level was analyzed together with the resulting HIC value, since the latter is commonly used, in this application and others, as the injury criterion. The obtained results indicate that ICP values exceed the common threshold of head injury criteria and do not correlate with HIC values. Thus, this work raises concern about applying the HIC to predict brain injury in American football direct head impacts, since it does not correlate with ICP predicted with the FE head model.
topic brain injury
finite element head model
American football
helmet
helmet testing
biomechanics
url https://www.mdpi.com/2076-3425/11/3/287
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