Response of Post-Mortem Human Head Under Primary Blast Loading Conditions: Effect of Blast Overpressures

2013 ◽  
Author(s):  
Shailesh Ganpule ◽  
Robert Salzar ◽  
Namas Chandra
Keyword(s):  
Brain Injury ◽  
Blast Loading ◽  
Human Head ◽  
Severe Injury ◽  
Post Mortem ◽  
Loading Conditions ◽  
Primary Blast ◽  
Blast Overpressure ◽  
Moderate Traumatic Brain Injury ◽  
The Brain

Blast induced neurotrauma (BINT), and posttraumatic stress disorder (PTSD) are identified as the “signature injuries” of recent conflicts in Iraq and Afghanistan. The occurrence of mild to moderate traumatic brain injury (TBI) in blasts is controversial in the medical and scientific communities because the manifesting symptoms occur without visible injuries. Whether the primary blast waves alone can cause TBI is still an open question, and this work is aimed to address this issue. We hypothesize that if a significant level of intracranial pressure (ICP) pulse occurs within the brain parenchyma when the head is subjected to pure primary blast, then blast induced TBI is likely to occur. In order to test this hypothesis, three post mortem human heads are subjected to simulated primary blast loading conditions of varying intensities (70 kPa, 140 kPa and 200 kPa) at the Trauma Mechanics Research Facility (TMRF), University of Nebraska-Lincoln. The specimens are placed inside the 711 mm × 711 mm square shock tube at a section where known profiles of incident primary blast (Friedlander waveform in this case) are obtained. These profiles correspond to specific field conditions (explosive strength and stand-off distance). The specimen is filled with a brain simulant prior to experiments. ICPs, surface pressures, and surface strains are measured at 11 different locations on each post mortem human head. A total of 27 experiments are included in the analysis. Experimental results show that significant levels of ICP occur throughout the brain simulant. The maximum peak ICP is measured at the coup site (nearest to the blast) and gradually decreases towards the countercoup site. When the incident blast intensity is increased, there is a statistically significant increase in the peak ICP and total impulse (p<0.05). Even after five decades of research, the brain injury threshold values for blunt impact cases are based on limited experiments and extensive numerical simulations; these are still evolving for sports-related concussion injuries. Ward in 1980 suggested that no brain injury will occur when the ICP<173 kPa, moderate to severe injury will occur when 173 kPa<ICP<235 kPa and severe injury will occur when ICP>235 kPa for blunt impacts. Based on these criteria, no injury will occur at incident blast overpressure level of 70 kPa, moderate to severe injuries will occur at 140 kPa and severe head injury will occur at the incident blast overpressure intensity of 200 kPa. However, more work is needed to confirm this finding since peak ICP alone may not be sufficient to predict the injury outcome.

scholarly journals Guidelines to inform the generation of clinically relevant and realistic blast loading conditions for primary blast injury research

2021 ◽  
pp. bmjmilitary-2021-001796
Author(s):  
J W Denny ◽  
A S Dickinson ◽  
G S Langdon
Keyword(s):  
Blast Wave ◽  
Blast Loading ◽  
Wave Interaction ◽  
Blast Waves ◽  
Experimental Investigations ◽  
Loading Conditions ◽  
Primary Blast ◽  
Blast Overpressure ◽  
Engineering Theory ◽  
Blast Traumatic Brain Injury

‘Primary’ blast injuries (PBIs) are caused by direct blast wave interaction with the human body, particularly affecting air-containing organs. With continued experimental focus on PBI mechanisms, recently on blast traumatic brain injury, meaningful test outcomes rely on appropriate simulated conditions. Selected PBI predictive criteria (grouped into those affecting the auditory system, pulmonary injuries and brain trauma) are combined and plotted to provide rationale for generating clinically relevant loading conditions. Using blast engineering theory, explosion characteristics including blast wave parameters and fireball dimensions were calculated for a range of charge masses assuming hemispherical surface detonations and compared with PBI criteria. While many experimental loading conditions are achievable, this analysis demonstrated limits that should be observed to ensure loading is clinically relevant, realistic and practical. For PBI outcomes sensitive only to blast overpressure, blast scaled distance was demonstrated to be a useful parameter for guiding experimental design as it permits flexibility for different experimental set-ups. This analysis revealed that blast waves should correspond to blast scaled distances of 1.75<Z<6.0 to generate loading conditions found outside the fireball and of clinical relevance to a range of PBIs. Blast waves with positive phase durations (2–10 ms) are more practical to achieve through experimental approaches, while representing realistic threats such as improvised explosive devices (ie, 1–50 kg trinitrotoluene equivalent). These guidelines can be used by researchers to inform the design of appropriate blast loading conditions in PBI experimental investigations.

Development of a Human Head Physical Surrogate Model for Investigating Blast Injury

2009 ◽  
Author(s):  
A. C. Merkle ◽  
I. D. Wing ◽  
R. A. Armiger ◽  
B. G. Carkhuff ◽  
J. C. Roberts
Keyword(s):  
Blast Loading ◽  
Human Head ◽  
Head Model ◽  
Loading Conditions ◽  
Pressure Loading ◽  
Spatial Response ◽  
Displacement Sensors ◽  
Hybrid Iii ◽  
Intracranial Pressures ◽  
The Brain

The objective of this effort was to develop a Human Surrogate Head Model (HSHM) and measure its response to pressure loading conditions representative of a blast environment. The HSHM consists of skin, face, skull, and brain fabricated using biosimulant materials and mounted to the neck of a Hybrid III Anthropomorphic Test Device to allow head motion during loading. The HSHM instrumentation includes pressure and displacement sensors embedded in the anterior and posterior areas of the brain along the saggital plane. The displacement sensors are a custom solution developed for this particular application. A series of shock tube tests at three varying load levels were conducted with the HSHM to simulate blast loading conditions. As pressure loading levels increased, the intracranial pressures and brain displacements increased as well. However, the spatial response of the displacement sensors varied with location in the brain. The results of this test series provide the first instance of intracranial pressure and directly measured brain displacements recorded from an anatomically correct head surrogate exposed to conditions representative of blast loading.

scholarly journals Mild traumatic brain injury induced by primary blast overpressure produces dynamic regional changes in [18F]FDG uptake

2019 ◽  
Vol 1723 ◽  
pp. 146400 ◽  
Author(s):  
Shalini Jaiswal ◽  
Andrew K. Knutsen ◽  
Colin M. Wilson ◽  
Amanda H. Fu ◽  
Laura B. Tucker ◽  
...  
Keyword(s):  
Traumatic Brain Injury ◽  
Brain Injury ◽  
Mild Traumatic Brain Injury ◽  
Primary Blast ◽  
Fdg Uptake ◽  
Blast Overpressure ◽  
18F Fdg

Traumatic Brain Injury Caused by +Gz Acceleration

2016 ◽  
Author(s):  
Abbas Shafiee ◽  
Mohammad Taghi Ahmadian ◽  
Maryam Hoviattalab
Keyword(s):  
Traumatic Brain Injury ◽  
Brain Injury ◽  
Damage Threshold ◽  
Human Head ◽  
Loss Of Consciousness ◽  
Time Duration ◽  
University Of Technology ◽  
Trauma Model ◽  
The Brain ◽  
Brain Pressure

Traumatic brain injury (TBI) has long been known as one of the most anonymous reasons for death around the world. This phenomenon has been under study for many years and yet it remains a question due to physiological, geometrical and computational complexity. Although the modeling facilities for soft tissue have improved, the precise CT-imaging of human head has revealed novel details of the brain, skull and meninges. In this study a 3D human head including the brain, skull, and meninges is modeled using CT-scan and MRI data of a 30-year old human. This model is named “Sharif University of Technology Head Trauma Model (SUTHTM)”. By validating SUTHTM, the model is then used to study the effect of +Gz acceleration on the human brain. Damage threshold based on loss of consciousness in terms of acceleration and time duration is developed using Maximum Brain Pressure criteria. Results revealed that the Max. Brain Pressure ≥3.1 are representation of loss of consciousness. 3D domains for the loss of consciousness are based on Max. Brain Pressure is developed.

scholarly journals The influence of heterogeneous meninges on the brain mechanics under primary blast loading

2012 ◽  
Vol 43 (8) ◽  
pp. 3160-3166 ◽  
Author(s):  
Linxia Gu ◽  
Mehdi S. Chafi ◽  
Shailesh Ganpule ◽  
Namas Chandra
Keyword(s):  
Blast Loading ◽  
Primary Blast ◽  
The Brain

Autoregulation of cerebral blood flow after experimental fluid percussion injury of the brain

1980 ◽  
Vol 53 (4) ◽  
pp. 500-511 ◽  
Author(s):  
W. Lewelt ◽  
L. W. Jenkins ◽  
J. Douglas Miller
Keyword(s):  
Blood Flow ◽  
Cerebral Blood Flow ◽  
Brain Injury ◽  
Intracranial Pressure ◽  
Severe Injury ◽  
Content Type ◽  
Fluid Percussion ◽  
Arterial Blood ◽  
Fluid Percussion Injury ◽  
The Brain

✓ To test the hypothesis that concussive brain injury impairs autoregulation of cerebral blood flow (CBF), 24 cats were subjected to hemorrhagic hypotension in 10-mm Hg increments while measurements were made of arterial and intracranial pressure, CBF, and arterial blood gases. Eight cats served as controls, while eight were subjected to mild fluid percussion injury of the brain (1.5 to 2.2 atmospheres) and eight to severe injury (2.8 to 4.8 atmospheres). Injury produced only transient changes in arterial and intracranial pressure, and no change in resting CBF. Impairment of autoregulation was found in injured animals, more pronounced in the severe-injury group. This could not be explained on the basis of intracranial hypertension, hypoxemia, hypercarbia, or brain damage localized to the area of the blood flow electrodes. It is, therefore, concluded that concussive brain injury produces a generalized loss of autoregulation for at least several hours following injury.

scholarly journals Defining blast loading ‘zones of relevance’ for primary blast injury research: A consensus of injury criteria for idealised explosive scenarios

2021 ◽  
Author(s):  
Jack Denny ◽  
Alexander Dickinson ◽  
Genevieve Langdon
Keyword(s):  
Blast Wave ◽  
Blast Loading ◽  
Wave Interaction ◽  
Blast Injury ◽  
Blast Injuries ◽  
Loading Conditions ◽  
Primary Blast ◽  
Injury Criteria ◽  
The 1960S ◽  
Injury Research

Blast injuries remain a serious threat to defence and civilian populations around the world. ‘Primary’ blast injuries (PBIs) are caused by direct blast wave interaction with the human body, particularly affecting air-containing organs. Despite development of blast injury criteria since the 1960s, work to define blast loading conditions for safety limits, protective design and injury research has received relatively little attention. With a continued experimental focus on PBI mechanisms and idealised blast assumptions, meaningful test outcomes rely on appropriate simulated conditions. This paper critically evaluates existing predictive criteria for PBIs (grouped into those affecting the auditory system, pulmonary injuries and brain trauma) as a function of incident blast wave parameters, assuming idealised air blast scenarios. Analysis of the multi-injury criteria reveals new insights and understanding. It showed that blast conditions of relevance to realistic explosive threats are limited and they should be an important consideration in the design of clinical trials simulating blast injury. Zones of relevance for PBI research are proposed to guide experimental designs and compare future data. This work will prove valuable to blast protection engineers and clinical researchers seeking to determine blast loading conditions for safety limits, protective design requirements and injury investigations.

Test-Retest Reliability of the Brain Injury Vision Symptom Survey

2018 ◽  
pp. 177-185
Keyword(s):  
Brain Injury ◽  
Limits Of Agreement ◽  
Retest Reliability ◽  
Visual Symptoms ◽  
Significant Bias ◽  
Moderate Traumatic Brain Injury ◽  
Significant Difference ◽  
History Of ◽  
Test Retest Reliability ◽  
The Brain

Background: Assessment of the test-retest reliability of the Brain Injury Vision Symptom Survey (BIVSS), a self-administered survey for visual symptoms following mild to moderate traumatic brain injury (TBI). Methods: Subjects (n=130, mean age 37 +/- 17.6, range 19 to 55) with mild-to-moderate TBI completed the 28-item BIVSS questionnaire two times (1-hr to 4-month separation interval). 25 subjects reported a history of medically diagnosed TBI, 5 an undiagnosed TBI, and 14 no history of injury. 87 subjects did not select a type of TBI diagnosis and were analyzed in the ‘not specified’ group. A scoring algorithm was developed for the BIVSS,1 and Rasch and Likert analyses performed. Bland-Altman charts illustrating methods of analyses were created and limits of agreement calculated. Results: A one sample t-test performed on both analyses for each patient group revealed no significant bias in scoring higher or lower on retest for any group with the exception of the ‘not specified’ group and Rasch analysis (n=87, t=3.41, p=0.01). When time between survey administrations is restricted to two weeks or less however, we see no significant difference for any group. Bland-Altman charts with 95% limits of agreement (+/- 0.40) revealed no significant change in direction of bias (Likert: p=0.92; Rasch: p=0.52) and consistency in distribution of values on retest (Likert: r=0.91; Rasch: r=0.25); the first administration accounting for 82.6% (r2) of variance at the second administration. Conclusions: The BIVSS has very good test retest reliability, and can serve as a suitable tool for assessing and quantifying visual symptoms associated with mild to moderate TBI. There is no significant bias in total BIVSS score between test administrations for either patients who have experienced TBI or non-injured patients. Future analysis of change in BIVSS subset scores concurrent with intervention could potentially reveal relationships between improvement in objective measurements and specific subjective subset scores.

Mechanical Response of the Brain Under Blast: The Effect of Blast Direction and the Head Protection

2016 ◽  
Author(s):  
Hesam Sarvghad-Moghaddam ◽  
Asghar Rezaei ◽  
Ashkan Eslaminejad ◽  
Mariusz Ziejewski ◽  
Ghodrat Karami
Keyword(s):  
Brain Injury ◽  
Mechanical Response ◽  
Experimental Studies ◽  
Human Head ◽  
Blast Waves ◽  
Arbitrary Lagrangian Eulerian ◽  
Explosion Pressure ◽  
Head Protection ◽  
Coupling Algorithm ◽  
The Brain

Blast-induced traumatic brain injury (bTBI), is defined as a type of acquired brain injury that occurs upon the interaction of the human head with blast-generated high-pressure shockwaves. Lack of experimental studies due to moral issues, have motivated the researchers to employ computational methods to study the bTBI mechanisms. Accordingly, a nonlinear finite element (FE) analysis was employed to study the interaction of both unprotected and protected head models with explosion pressure waves. The head was exposed to the incoming shockwaves from front, back, and side directions. The main goal was to examine the effects of head protection tools and the direction of blast waves on the tissue and kinematical responses of the brain. Generation, propagation, and interactions of blast waves with the head were modeled using an arbitrary Lagrangian-Eulerian (ALE) method and a fluid-structure interaction (FSI) coupling algorithm. The FE simulations were performed using Ls-Dyna, a transient, nonlinear FE code. Side blast predicted the highest mechanical responses for the brain. Moreover, the protection assemblies showed to significantly alter the blast flow mechanics. Use of faceshield was also observed to be highly effective in the front blast due to hindering of shockwaves.

Development and validation of a biofidelic head form model to assess blast-induced traumatic brain injury

2017 ◽  
Vol 15 (3) ◽  
pp. 257-267
Author(s):  
Devon Downes ◽  
Amal Bouamoul ◽  
Simon Ouellet ◽  
Manouchehr Nejad Ensan
Keyword(s):  
Finite Element ◽  
Brain Injury ◽  
Blast Wave ◽  
Skull Fracture ◽  
Free Field ◽  
Blast Loading ◽  
Human Head ◽  
Arbitrary Lagrangian Eulerian ◽  
Element Analysis ◽  
Head Form

Traumatic Blast Injury (TBI) associated with the human head is caused by exposure to a blast loading, resulting in decreased level of consciousness, skull fracture, lesions, or death. This paper presents the simulation of blast loading of a human head form from a free-field blast with the end goal of providing insight into how TBI develops in the human head. The developed numerical model contains all the major components of the human head, the skull, and brain, including the tentorium, cerebral falx, and gray and white matter. A nonlinear finite element analysis was employed to perform the simulation using the Arbitrary Lagrangian–Eulerian finite element method. The simulation captures the propagation of the blast wave through the air, its interaction with the skull, and its transition into the brain matter. The model quantifies the pressure histories of the blast wave from the explosive source to the overpressure on the skull and the intracranial pressure. This paper discusses the technical approach used to model the head, the outcome from the analysis, and the implication of the results on brain injury.

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