Modal and temporal analysis of head mathematical models

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Willinger, R.¹; Taleb, L.¹; Kopp, C-M.¹

Modal and temporal analysis of head mathematical models

J Neurotrauma. August 1995;12(4):743-754

© Mary Ann Liebert, Inc.

Affiliations

¹University Strasbourg-LSBM, IMF, CNRS 854, Strasbourg, France
Abstract and keywords

The basic hypotheses used during these investigations were based on the vibration analysis of the head, which demonstrated that the head is not a solid nondeformable body, but a complex structure including deformable elements. Laboratoire des Systèmes Biomécanique (LSBM) has recently proposed three mathematical models: a lumped model, a finite element model of the head in its sagittal plane, and a three-dimensional finite element model. These models were validated by their modal behavior and enabled the lesion mechanisms to be distinguished as a function of the spectral characteristics of the shock. The objective of this study is to complete these modal results by temporal analysis of the models by calculating the evolution of the intracranian mechanical parameters under shock conditions. To describe the head's dynamic behavior in the temporal domain, constant energy shocks of variable duration were simulated to evaluate their influence on different quantities as the intracerebral stresses in terms of compression, tensile, and shearing stresses, the relative brain–skull displacement, and the skull deformation. The importance of modal behavior of the head is illustrated by analyzing its temporal response to variable duration impacts, thus exciting very different frequencies. For a triangular shock, the critical duration times are between 10 and 15 × 10⁻³ s, which correspond to impacts that excite the first resonance frequency of the head. Taking modal behavior into consideration in developing the finite element model leads to a harmonization of the calculated intracerebral stresses, even for short duration shocks. So, when the head is considered as a complex structure made up of several deformable elements, risk limitation is conditioned by an impact energy reduction for frequencies close to the natural frequencies of the structure. In the time field, the objective will be to avoid a number of impact shapes and durations. Therefore, the aim will not be to dampen the impact at any cost, but to damper it in an "intelligent" manner. In the future, this will allow the reduction of an injury mechanism-related risk, without increasing the risk of an injury generated by another mechanism.

Keywords: head biomechanics; modal analysis; temporal analysis; lumped model; finite element models; injury mechanisms
Links

DOI: 10.1089/neu.1995.12.743

PubMed: 8683626

WoS: A1995RY92000026

Cited Works (19)

Year	Entry
1975	Ward CC, Thompson RB. The development of a detailed finite element brain model. In: Proceedings of the 19th Stapp Car Crash Conference. November 17-19, 1975; San Diego, CA. Warrendale, PA: Society of Automotive Engineers:641-674. SAE 751163.
1991	Willinger R, Kopp CM, Cesari D. Cerebral motion and head tolerance. In: 35th Annual Proceedings, Association for the Advancement of Automotive Medicine (AAAM). October 7, 1991; Toronto, Canada.387-404.
1990	Thibault LE, Gennarelli TA, Margulies SS, Marcus J, Eppinger R. The strain dependent pathophysiological consequences of inertial loading on central nervous system tissue. In: Proceedings of the 1990 International IRCOBI Conference on the Biomechanics of Impact. September 12-14, 1990; Lyon, France.191-202.
1991	Willinger R, Césari D, Kopp CM. Brain tolerance in the frequency field. In: Proceedings of the 13th International Technical Conference on Experimental Safety Vehicles (ESV). November 4-7, 1991; Paris, France.940-947.
1989	Viano DC, King AI, Melvin JW, Weber K. Injury biomechanics research: an essential element in the prevention of trauma. J Biomech. 1989;22(5):403-417.
1993	Willinger R, Kopp CM, Ramet M, Bouquet R, Caire Y. Proposition of a new dummy head: the bimass 150 principle. In: Proceedings of the 1993 International IRCOBI Conference on the Biomechanics of Impact. September 8-10, 1993; Eindhoven, The Netherlands.229-240.
1971	Stalnaker RL, Fogle JL, McElhaney JH. Driving point impedance characteristics of the head. J Biomech. March 1971;4(2):127-139.
1970	Slattenschek A, Tauffkirchen W. Critical evaluation of assessment methods for head impact applied in appraisal of brain injury hazard, in particular in head impact on windshields. In: 1970 International Automobile Safety Conference Compendium. Society of Automotive Engineers; 1970:1084-1112. SAE 700426.
1991	Dimasi F, Marcus J, Eppinger R. 3-D anatomic brain model for relating cortical strains to automobile crash loading. In: Proceedings of the 13th International Technical Conference on Experimental Safety Vehicles (ESV). November 4-7, 1991; Paris, France.916-924.
1995	Willinger R, Taleb L, Pradoura P. Head biomechanics: from the finite element model to the physical model. In: Proceedings of the 1995 International IRCOBI Conference on the Biomechanics of Impact. September 13-15, 1995; Brunnen, Switzerland.245-259.
1966	Gadd CW. Use of a weighted-impulse criterion for estimating injury hazard. In: Proceedings of the 10th Stapp Car Crash Conference. November 8-9, 1966; Hollomon Air Force Base, NM. Warrendale, PA: Society of Automotive Engineers:164-174. SAE 660793.
1968	Hodgson VR, Patrick LM. Dynamic response of the human cadaver head compared to a simple mathematical model. In: Proceedings of the 12th Stapp Car Crash Conference. October 22-23, 1968; Detroit, MI. Warrendale, PA: Society of Automotive Engineers:280-301. SAE 680784.
1985	Stalnaker RL, Lin CA, Guenther DA. The application of the new mean strain criterion (NMSC). In: Proceedings of the 1985 International IRCOBI/AAAM Conference on the Biomechanics of Impact. September 24-26, 1985; Göteborg, Sweden.191-209.
1974	Alem NM. Simulation of head injury due to combined rotation and translation of the brain. In: Proceedings of the 18th Stapp Car Crash Conference. December 4-5, 1974; Ann Arbor, MI. Warrendale, PA: Society of Automotive Engineers:579-598. SAE 741192.
1980	Kallieris D, Schmidt G, Hausler E. Brain injuries under high speed loadings: a study with models and cadaver heads. In: Proceedings of the 1980 International IRCOBI Conference on the Biomechanics of Impact. September 9-11, 1980; Birmingham, England.229-240.
1976	McElhaney JH, Roberts VL, Hilyard JF. Handbook of Human Tolerance. Tokyo, Japan: Japan Automobile Research Institute (JARI) Inc; 1976.
1970	Brinn J, Staffeld SE. Evaluation of impact test accelerations: a damage index for the head and torso. In: Proceedings of the 14th Stapp Car Crash Conference. November 17-18, 1970; Ann Arbor, MI. Warrendale, PA: Society of Automotive Engineers:188-220. SAE 700902.
1968	Gadd CW, Patrick LM. System versus laboratory impact tests for estimating injury hazard. In: Proceedings of the SAE Automotive Engineering Congress and Exposition. January 8-12, 1968; Detroit, MI. Warrendale, PA: Society of Automotive Engineers. SAE 680053.
1992	Willinger R, Kopp CM, Césari D. New concept of contrecoup lesion mechanism: modal analysis of a finite element model of the head. In: Proceedings of the 1992 International IRCOBI Conference on the Biomechanics of Impact. September 9-11, 1992; Verona, Italy.283-297.

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Year	Entry
2012	Tse KM, Tan LB, Lee HP, Lim SP. Characterization of human head-brain-neck vibration behavior using modal analysis. In: Proceedings of the 4th American Conference on Human Vibration. June 13-15, 2012; Farmington, CT.19-20.
2000	Willinger R, Baumgartner D, Chinn B, Neale M. Head tolerance limits derived from numerical replication of real world accidents. In: Proceedings of the 2000 International IRCOBI Conference on the Biomechanics of Impact. September 20-22, 2000; Montpellier, France.209-221.
2003	King AI, Yang KH, Zhang L, Hardy W, Viano DC. Is head injury caused by linear or angular acceleration? In: Proceedings of the 2003 International IRCOBI Conference on the Biomechanics of Impact. September 25, 2003; Lisbon, Portugal.1-12.
2012	Post A, Oeur A, Hoshizaki B, Gilchrist MD. The influence of centric and non‐centric impacts to American football helmets on the correlation between commonly used metrics in brain injury research. In: Proceedings of the 2012 International IRCOBI Conference on the Biomechanics of Injury. September 12-14, 2012; Dublin, Ireland.419-429.
2012	Kendall M, Post A, Rousseau P, Oeur A, Gilchrist MD, Hoshizaki B. A comparison of dynamic impact response and brain deformation metrics within the cerebrum of head impact reconstructions representing three mechanisms of head injury in ice hockey. In: Proceedings of the 2012 International IRCOBI Conference on the Biomechanics of Injury. September 12-14, 2012; Dublin, Ireland.430-440.
2013	Kendall M, Post A, Zanetti K, Hoshizaki TB, Gilchrist MD. Comparison of dynamic versus static head impact reconstruction methodology by means of dynamic impact response and brain deformation metrics. In: Proceedings of the 2013 International IRCOBI Conference on the Biomechanics of Injury. September 11-13, 2013; Gothenburg, Sweden.536-546.
2016	Post A, De Grau S, Ignacy T, Meehan A, Zemek R, Hoshizaki B, Gilchrist MD. Comparison of helmeted head impact in youth and adult ice hockey. In: Proceedings of the 2016 International IRCOBI Conference on the Biomechanics of Injury. September 14-16, 2016; Malaga, Spain.194-204.
2011	Li Z, Hu J, Zhang J. Development, validation and application of a parametric pediatric head finite element model for impact simulations. In: Proceedings of the 7th Ohio State University Injury Biomechanics Symposium. May 22-24, 2011; Columbus, OH.
2001	Zhang L, Yang KH, Dwarampudi R, Omori K, Li T, Chang K, Hardy WN, Khalil TB, King AI. Recent advances in brain injury research: a new human head model development and validation. Stapp Car Crash J. 2001;45:369-394. SAE 2001-22-0017.
1999	Willinger R, Kang H-S, Diaw B. Three-dimensional human head finite-element model validation against two experimental impacts. Ann Biomed Eng. May–June 1999;27(3):403-410.
2010	Chafi MS, Karami G, Ziejewski M. Biomechanical assessment of brain dynamic responses due to blast pressure waves. Ann Biomed Eng. February 2010;38(2):490-504.
2011	Li Z, Hu J, Reed MP, Rupp JD, Hoff CN, Zhang J, Cheng B. Development, validation, and application of a parametric pediatric head finite element model for impact simulations. Ann Biomed Eng. December 2011;39(12):2984-2997.
2015	Tabacu S. Numerical model (switchable/dual model) of the human head for rigid body and finite elements. Comput Methods Biomech Biomed Eng. 2015;18(7):769-781.
2008	Roth S, Raul J-S, Willinger R. Biofidelic child head FE model to simulate real world trauma. Comput Methods Prog Biomed. June 2008;90(3):262-274.
2010	Roth S, Raul J-S, Willinger R. Finite element modelling of paediatric head impact: global validation against experimental data. Comput Methods Prog Biomed. July 2010;99(1):25-33.
2003	Horgan TJ, Gilchrist MD. The creation of three-dimensional finite element models for simulating head impact biomechanics. Int J Crashworthiness. 2003;8(4):353-366.
2003	Willinger R, Baumgartner D. Human head tolerance limits to specific injury mechanisms. Int J Crashworthiness. 2003;8(6):605-617.
2003	Willinger R, Baumgartner D. Numerical and physical modelling of the human head under impact: towards new injury criteria. Int J Veh Des. January 2003;32(1-2):94-115.
2005	Viano DC, Casson IR, Pellman EJ, Zhang L, King AI, Yang KH. Concussion in professional football: brain responses by finite element analysis: part 9. Neurosurgery. November 2005;57(5):891-916.
2020	Karton C, Hoshizaki TB, Gilchrist MD. A novel repetitive head impact exposure measurement tool differentiates player position in National Football League. Sci Rep. 2020;10:1200.
2009	Verschueren P. Biomechanical Analysis of Head Injuries Related to Bicycle Accidents and a New Bicycle Helmet Concept [PhD thesis]. Leuven, Belgium: Katholieke Universiteit Leuven; July 2009.
2018	Kuo C. Measurement and Modeling of Head Impact Kinematics [PhD thesis]. Stanford University; May 2018.
2014	Patton DA. The Biomechanical Determinants of Sports-Related Concussion: Finite Element Simulations of Unhelmeted Head Impacts to Evaluate Kinematic and Tissue-Level Predictors of Injury and Investigate the Design Implications for Soft-Shell Headgear [PhD thesis]. University of New South Wales; March 2014.
2012	Karton C. The Effect of Inbound Mass on the Dynamic Response of the Hybrid III Headform and Brain Tissue Deformation [Master's thesis]. Ottawa, ON: University of Ottawa; November 2012.
2012	Oeur A. An Analysis of Head Impact Angle on the Dynamic Response of a Hybrid III Headform and Brain Tissue Deformation [Master's thesis]. Ottawa, ON: University of Ottawa; December 2012.
2016	Kendall M. Comparison and Characterization of Different Concussive Brain Injury Events [PhD thesis]. University of Ottawa; 2016.
2018	Oeur RA. The Effects of Reconstructed Head Impact Event Parameters on Risk of Sport Related Concussions [PhD thesis]. Ottawa, ON: University of Ottawa; 2018.
2019	Karton C. Profiling Brain Trauma in Professional American-Style Football and the Implications to Developing Neurological Injury [PhD thesis]. Ottawa, ON: University of Ottawa; 2019.
2020	Gabrieli DJ. Multiscale Predictions of Mechanical Response and Computational Circuit Dynamics After Traumatic Brain Injury [PhD thesis]. Philadelphia, PA: University of Pennsylvania; 2020.