Evaluation of brain tissue responses because of the underwash overpressure of helmet and faceshield under blast loading

Sarvghad-Moghaddam, Hesam; Rezaei, Asghar; Ziejewski, Mariusz; Karami, G.

doi:10.1002/cnm.2782

Cited by 24 publications

(28 citation statements)

References 41 publications

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“…They also showed that the underwash overpressure occurred at the opposite side of the incoming waves in front and back directions. Moreover, in another study on the effects of underwash on the brain tissue response, they studied the same blast directions used here using a FEA approach and found similar results in terms of the location and intensity of the underwash overpressure (Sarvghad-Moghaddam et al 2016). The dependence of the underwash on the direction of the blast was also among their results.…”

Section: Disclosure Statementsupporting

confidence: 62%

“…This phenomenon may also affect the performance of these tools under blast compared to their high efficiency under impact (SarvghadMoghaddam et al 2015). Sarvghad-Moghaddam et al (2016) showed that underwash-induced overpressure on the head has the potential of imposing higher risk of brain injury. While parameters such as the blast intensity and direction, as well as the shockwave flow mechanics can affect underwash, the underlying cause for underwash is still a question.…”

Section: Introductionmentioning

confidence: 99%

“…In terms of assessing the brain injury risk in different blast theatres, many researchers have investigated the mechanical response of the human head and brain to dynamic loads such as blast (Moore et al 2009;Chafi et al 2010;Grujicic et al 2010;Nyein et al 2010;Grujicic et al 2011;SarvghadMoghaddam, Jazi, et al 2014). Sarvghad-Moghaddam et al (2016) performed a comprehensive FEA study on the development and effects of underwash on the dynamics response of the brain. They reported that based on different blast parameters such direction, the underwash-induced overpressure on the head can exceed the one imposed by the primary shockwaves.…”

Section: Introductionmentioning

confidence: 99%

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CFD modeling of the underwash effect of military helmets as a possible mechanism for blast-induced traumatic brain injury

Sarvghad-Moghaddam

Rezaei

Ziejewski

et al. 2016

Computer Methods in Biomechanics and Biomedical Engineering

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Underwash occurs as the incoming shockwaves enter the helmet subspace and develop a high pressure region at the opposite side of the head. The mechanism leading to the underwash is yet not well understood. To investigate this effect, the turbulent, supersonic flow of compressible air approaching the head-helmet assembly from different directions was studied through computational fluid dynamics simulations. The effects of different incident overpressures and helmet gap size on the underwash incidence were further evaluated. The backflow-induced pressure from the air traveling outside of the helmet on the outflow from the helmet, as well as the momentum change in the backside curve of the helmet were postulated as the main reasons for this effect. Side shockwaves predicted the highest underwash overpressures. The increase rate of the underwash reduced with increasing the incident shockwave intensity.

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Section: Disclosure Statementsupporting

confidence: 62%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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CFD modeling of the underwash effect of military helmets as a possible mechanism for blast-induced traumatic brain injury

Sarvghad-Moghaddam

Rezaei

Ziejewski

et al. 2016

Computer Methods in Biomechanics and Biomedical Engineering

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“…Experimental methods impose moral and technical issues before conducting any research. Many FE studies have been conducted to determine brain responses under dynamic loads to study TBIs [1][2][3][4][5][6][7][8][9][10]. Such studies have helped to e ciently develop TBI prediction tools based 1 on the current injury threshold criteria of kinematics, intracranial pressure (ICP), tissue strain, and tissue shear stress [11].…”

Section: Introductionmentioning

confidence: 99%

“…Such studies have helped to e ciently develop TBI prediction tools based 1 on the current injury threshold criteria of kinematics, intracranial pressure (ICP), tissue strain, and tissue shear stress [11]. Mechanical responses of human head brain and skull have been studied using multi-material FE simulations [5,12]. Representative FE head models, which include major components of the head such as brain, skull bones, and cerebrospinal uid (CSF), have been employed to study the response of the head under di erent loadings.…”

Section: Introductionmentioning

confidence: 99%

Brain Tissue Constitutive Material Models and the Finite Element Analysis of Blast-Induced Traumatic Brain Injury

et al. 2018

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Abstract. Traumatic Brain Injury (TBI) often occurs due to assaulting loads such as blast on the human head. Finite Elements (FEs) can approximately simulate blast interactions with the human head. An important parameter in the FE modelling procedures is the accuracy of constitutive formulation of the brain tissue. This paper focuses on implementation of three brain tissue constitutive relations to measure and compare the dynamic behaviour of the brain under identical blast loads. For the geometry, a simple spherical head model is employed to monitor the brain tissue response and examine the uncertainties in FE brain tissue constitutive modelling. The brain tissue is constitutively modelled as hyperelastic, viscoelastic, and hyperviscoelastic material types. Intracranial Pressures (ICP), strains, and shear stresses as the dynamic parameters are measured with time. These biomechanical parameters can be compared against the injury thresholds. Our analyses show that although the results of ICPs and strains are close for the three models, shear stresses are considerably di erent. The study will further provide a new insight into selecting a proper constitutive model of the brain tissue under dynamic conditions.

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Face shield design against blast‐induced head injuries

Tan

Tse

Tan

et al. 2017

Numer Methods Biomed Eng

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Blast-induced traumatic brain injury has been on the rise in recent years because of the increasing use of improvised explosive devices in conflict zones. Our study investigates the response of a helmeted human head subjected to a blast of 1 atm peak overpressure, for cases with and without a standard polycarbonate (PC) face shield and for face shields comprising of composite PC and aerogel materials and with lateral edge extension. The novel introduction of aerogel into the laminate face shield is explored and its wave-structure interaction mechanics and performance in blast mitigation is analysed. Our numerical results show that the face shield prevented direct exposure of the blast wave to the face and help delays the transmission of the blast to reduce the intracranial pressures (ICPs) at the parietal lobe. However, the blast wave can diffract and enter the midface region at the bottom and side edges of the face shield, resulting in traumatic brain injury. This suggests that the bottom and sides of the face shield are important regions to focus on to reduce wave ingress. The laminated PC/aerogel/PC face shield yielded higher peak positive and negative ICPs at the frontal lobe, than the original PC one. For the occipital and temporal brain regions, the laminated face shield performed better than the original. The composite face shield with extended edges reduced ICP at the temporal lobe but increases ICP significantly at the parietal lobe, which suggests that a greater coverage may not lead to better mitigating effects.

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Evaluation of brain tissue responses because of the underwash overpressure of helmet and faceshield under blast loading

Cited by 24 publications

References 41 publications

CFD modeling of the underwash effect of military helmets as a possible mechanism for blast-induced traumatic brain injury

CFD modeling of the underwash effect of military helmets as a possible mechanism for blast-induced traumatic brain injury

Brain Tissue Constitutive Material Models and the Finite Element Analysis of Blast-Induced Traumatic Brain Injury

Face shield design against blast‐induced head injuries

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