Your search keyword '"Rafaels KA"' showing total 12 results

1. Primary blast survival and injury risk assessment for repeated blast exposures.

Author

Panzer MB, Bass CR, Rafaels KA, Shridharani J, Capehart BP, Panzer, Matthew B, Bass, Cameron R Dale, Rafaels, Karin A, Shridharani, Jay, and Capehart, Bruce P

Published

2012

2. The temperature-dependent viscoelasticity of porcine lumbar spine ligaments.

Author

Bass CR, Planchak CJ, Salzar RS, Lucas SR, Rafaels KA, Shender BS, and Paskoff G

Published

2007

3. Shear behavior of human skull bones.

Author

Brown AD, Rafaels KA, and Weerasooriya T

Subjects

Finite Element Analysis, Frontal Bone, Humans, Porosity, Shear Strength, Stress, Mechanical, Bone and Bones, Skull diagnostic imaging

Abstract

A shear-punch test (SPT) experimental method was developed to address the lack of shear deformation and failure response data for the human skull as a function of local bone microarchitecture. Improved understanding of skull deformation and fracture under varying stress-states helps implement mechanism-based, multi-axial material models for finite element analysis for optimizing protection strategies. Shear-punch coupons (N = 47 specimens) were extracted from right-parietal and frontal bones of three fresh-frozen-thawed human skulls. The specimens were kept as full through-thickness or segmented into the three skull constituent layers: the inner and outer cortical tables and the middle porous diploë. Micro-computed x-ray tomography (μCT) before and after SPT provided the bone volume fraction (BVF) as a function of depth for correlation to shear mechanisms in the punched volumes. Digital image correlation was used to track displacement of the punch above the upper die to minimize compliance error. Five full-thickness specimens were subjected to partial indentation loading to investigate the process of damage development as a function of BVF and depth. It was determined that BVF dominates the shear yield and ultimate strength of human skull bone, but the imposed uniaxial loading rate (0.001 and 0.1 s -1 ) did not have as strong a contribution (p = 0.181-0.806 > 0.05) for the shear yield and ultimate strength of the skull bone layer specimens. Shear yield and ultimate strength data were highly correlated to power law relationships of BVF (R 2  = 0.917-0.949). Full-thickness and partial loaded SPT experiments indicate the diploë primarily dictates the shear strength of the intact structure., (Published by Elsevier Ltd.)

Published

2021

4. Assessment of Thorax Finite Element Model Response for Behind Armor Blunt Trauma Impact Loading Using an Epidemiological Database.

Author

Cronin DS, Bustamante MC, Barker J, Singh D, Rafaels KA, and Bir C

Subjects

Humans, Biomechanical Phenomena, Models, Biological, Mechanical Phenomena, Male, Finite Element Analysis, Wounds, Nonpenetrating physiopathology, Wounds, Nonpenetrating epidemiology, Thorax physiopathology, Databases, Factual, Thoracic Injuries epidemiology, Thoracic Injuries physiopathology

Abstract

Nonperforating ballistic impacts on thoracic armor can cause blunt injuries, known as behind-armor blunt trauma (BABT). To evaluate the potential for this injury, the back face deformation (BFD) imprinted into a clay backing is measured; however, the link between BFD and potential for injury is uncertain. Computational human body models (HBMs) have the potential to provide an improved understanding of BABT injury risk to inform armor design but require assessment with relevant loading scenarios. In this study, a methodology was developed to apply BABT loading to a computational thorax model, enhanced with refined finite element mesh and high-deformation rate mechanical properties. The model was assessed using an epidemiological BABT survivor database. BABT impact boundary conditions for 10 cases from the database were recreated using experimentally measured deformation for specific armor/projectile combinations, and applied to the thorax model using a novel prescribed displacement methodology. The computational thorax model demonstrated numerical stability under BABT impact conditions. The predicted number of rib fractures, the magnitude of pulmonary contusion, and injury rank, increased with armor BFD, back face velocity, and input energy to the thorax. In three of the 10 cases, the model overpredicted the number of rib fractures, attributed to impact location positional sensitivity and limited details from the database. The integration of an HBM with the BABT loading method predicted rib fractures and injury ranks that were in good agreement with available medical records, providing a potential tool for future armor evaluation and injury assessment., (Copyright © 2021 by ASME.)

Published

2021

5. Injuries of the head from backface deformation of ballistic protective helmets under ballistic impact.

Author

Rafaels KA, Cutcliffe HC, Salzar RS, Davis M, Boggess B, Bush B, Harris R, Rountree MS, Sanderson E, Campman S, Koch S, and Dale Bass CR

Subjects

Aged, Aged, 80 and over, Biomechanical Phenomena, Cadaver, Contusions pathology, Equipment Design, Forensic Ballistics, Forensic Pathology, Humans, Male, Middle Aged, Radiography, Head Protective Devices, Skull Fracture, Depressed diagnostic imaging, Skull Fracture, Depressed pathology, Skull Fractures diagnostic imaging, Skull Fractures pathology, Wounds, Gunshot pathology

Abstract

Modern ballistic helmets defeat penetrating bullets by energy transfer from the projectile to the helmet, producing helmet deformation. This deformation may cause severe injuries without completely perforating the helmet, termed "behind armor blunt trauma" (BABT). As helmets become lighter, the likelihood of larger helmet backface deformation under ballistic impact increases. To characterize the potential for BABT, seven postmortem human head/neck specimens wearing a ballistic protective helmet were exposed to nonperforating impact, using a 9 mm, full metal jacket, 124 grain bullet with velocities of 400-460 m/s. An increasing trend of injury severity was observed, ranging from simple linear fractures to combinations of linear and depressed fractures. Overall, the ability to identify skull fractures resulting from BABT can be used in forensic investigations. Our results demonstrate a high risk of skull fracture due to BABT and necessitate the prevention of BABT as a design factor in future generations of protective gear., (© 2014 American Academy of Forensic Sciences.)

Published

2015

6. Brain injury risk from primary blast.

Author

Rafaels KA, Bass CR, Panzer MB, Salzar RS, Woods WA, Feldman SH, Walilko T, Kent RW, Capehart BP, Foster JB, Derkunt B, and Toman A

Subjects

Animals, Blast Injuries diagnosis, Brain Injuries diagnosis, Disease Models, Animal, Ferrets, Male, Trauma Severity Indices, Blast Injuries complications, Brain pathology, Brain Injuries etiology, Explosions

Abstract

Background: Military service members are often exposed to at least one explosive event, and many blast-exposed veterans present with symptoms of traumatic brain injury. However, there is little information on the intensity and duration of blast necessary to cause brain injury., Methods: Varying intensity shock tube blasts were focused on the head of anesthetized ferrets, whose thorax and abdomen were protected. Injury evaluations included physiologic consequences, gross necropsy, and histologic diagnosis. The resulting apnea, meningeal bleeding, and fatality were analyzed using logistic regressions to determine injury risk functions., Results: Increasing severity of blast exposure demonstrated increasing apnea immediately after the blast. Gross necropsy revealed hemorrhages, frequently near the brain stem, at the highest blast intensities. Apnea, bleeding, and fatality risk functions from blast exposure to the head were determined for peak overpressure and positive-phase duration. The 50% risk of apnea and moderate hemorrhage were similar, whereas the 50% risk of mild hemorrhage was independent of duration and required lower overpressures (144 kPa). Another fatality risk function was determined with existing data for scaled positive-phase durations from 1 millisecond to 20 milliseconds., Conclusion: The first primary blast brain injury risk assessments for mild and moderate/severe injuries in a gyrencephalic animal model were determined. The blast level needed to cause a mild/moderate brain injury may be similar to or less than that needed for pulmonary injury. The risk functions can be used in future research for blast brain injury by providing realistic injury risks to guide the design of protection or evaluate injury.

Published

2012

7. Brain injuries from blast.

Author

Bass CR, Panzer MB, Rafaels KA, Wood G, Shridharani J, and Capehart B

Subjects

Animals, Disease Models, Animal, Humans, Stress Disorders, Post-Traumatic diagnosis, Stress Disorders, Post-Traumatic epidemiology, Blast Injuries diagnosis, Blast Injuries epidemiology, Brain Injuries diagnosis, Brain Injuries epidemiology

Abstract

Traumatic brain injury (TBI) from blast produces a number of conundrums. This review focuses on five fundamental questions including: (1) What are the physical correlates for blast TBI in humans? (2) Why is there limited evidence of traditional pulmonary injury from blast in current military field epidemiology? (3) What are the primary blast brain injury mechanisms in humans? (4) If TBI can present with clinical symptoms similar to those of Post-Traumatic Stress Disorder (PTSD), how do we clinically differentiate blast TBI from PTSD and other psychiatric conditions? (5) How do we scale experimental animal models to human response? The preponderance of the evidence from a combination of clinical practice and experimental models suggests that blast TBI from direct blast exposure occurs on the modern battlefield. Progress has been made in establishing injury risk functions in terms of blast overpressure time histories, and there is strong experimental evidence in animal models that mild brain injuries occur at blast intensities that are similar to the pulmonary injury threshold. Enhanced thoracic protection from ballistic protective body armor likely plays a role in the occurrence of blast TBI by preventing lung injuries at blast intensities that could cause TBI. Principal areas of uncertainty include the need for a more comprehensive injury assessment for mild blast injuries in humans, an improved understanding of blast TBI pathophysiology of blast TBI in animal models and humans, the relationship between clinical manifestations of PTSD and mild TBI from blunt or blast trauma including possible synergistic effects, and scaling between animals models and human exposure to blasts in wartime and terrorist attacks. Experimental methodologies, including location of the animal model relative to the shock or blast source, should be carefully designed to provide a realistic blast experiment with conditions comparable to blasts on humans. If traditional blast scaling is appropriate between species, many reported rodent blast TBI experiments using air shock tubes have blast overpressure conditions that are similar to human long-duration nuclear blasts, not high explosive blasts.

Published

2012

8. Pulmonary injury risk assessment for long-duration blasts: a meta-analysis.

Author

Rafaels KA, Bass CR, Panzer MB, and Salzar RS

Subjects

Animals, Biomechanical Phenomena, Blast Injuries pathology, Blast Injuries physiopathology, Cats, Cattle, Cohort Studies, Disease Models, Animal, Dogs, Environmental Exposure analysis, Goats, Haplorhini, Injury Severity Score, Linear Models, Lung Injury etiology, Lung Injury pathology, Lung Injury physiopathology, Pressure, Sheep, Species Specificity, Survival Analysis, Time Factors, Blast Injuries mortality, Environmental Exposure statistics & numerical data, Explosions, Logistic Models, Lung Injury mortality, Risk Assessment

Abstract

Background: Long-duration blasts are an increasing threat with the expanded use of thermobaric and other novel explosives. Other potential long-duration threats include large explosions from improvised explosive devices, weapons caches, and other explosives including nuclear explosives. However, there are very few long-duration pulmonary blast injury assessments, and use of short-duration exposure injury metrics is inappropriate as the injury mechanism for long-duration exposures is likely different from that of short-duration exposures., Methods: This study develops an injury model for long-duration (>10 milliseconds positive overpressure phase) blasts with sharp rising overpressures. For this study, data on more than 2,730 large animal experiments were collected from more than 55 experimental studies on blast. From this dataset, nearly 850 large animal experiments were selected with positive phase overpressure durations of 10 milliseconds or more. Various models were evaluated to determine the best fit of injury risk as a function of pressure and duration. A linear logistic regression was performed on the experimental data for threshold injury and lethality in terms of pressure and duration. The effects of mass, pressure, and duration scaling were all evaluated, and two goodness-of-fit indicators were used to assess the different models., Results and Conclusions: New injury risk assessment curves were determined for both incident and reflected pressure conditions for reflecting surface and free-field exposures. Position dependent injury risk curves were also determined. The resulting curves are an improvement to existing assessments, because they use actual data to demonstrate theoretical assumptions on the injury risk.

Published

2010

9. Drosophila melanogaster larvae as a model for blast lung injury.

Author

Bass CR, Meyerhoff KP, Damon AM, Bellizzi AM, Salzar RS, and Rafaels KA

Subjects

Animals, High-Energy Shock Waves, Humans, Larva anatomy & histology, Lung pathology, Acute Lung Injury pathology, Blast Injuries pathology, Disease Models, Animal, Drosophila melanogaster anatomy & histology

Abstract

Background: Primary blast injuries, specifically lung injuries, resulting from blast overpressure exposures are a major source of mortality for victims of blast events. However, existing pulmonary injury criteria are inappropriate for common exposure environments. This study uses Drosophila melanogaster larvae to develop a simple phenomenological model for human pulmonary injury from primary blast exposure., Methods: Drosophila larvae were exposed to blast overpressures generated by a 5.1-cm internal diameter shock tube and their mortality was observed after the exposure. To establish mortality thresholds, a survival analysis was conducted using survival data and peak incident pressures. In addition, a histologic analysis was performed on the larvae to establish the mechanisms of blast injury., Results: The results of the survival analysis suggest that blast overpressure for 50% Drosophila survival is greater than human threshold lung injury and is similar to human 50% survival levels, in the range of overpressure durations tested (1-5 ms). A "parallel" analysis of the Bass et al. 50% human survival curves indicates that 50% Drosophila survival is equivalent to a human injury resulting in a 69% chance of survival. Histologic analysis of the blast-exposed larvae failed to demonstrate damage to the dorsal trunk of the tracheal system; however, the presence of flocculent material in the larvae body cavities and tracheas suggests tissue damage., Conclusions: This study shows that D. melanogaster survival can be correlated with large animal injury models to approximate a human blast lung injury tolerance. Within the range of durations tested, Drosophila larvae may be used as a simple model for blast injury.

Published

2010

10. Re-evaluating the neck injury index (NII) using experimental PMHS tests.

Author

Bass CR, Salzar RS, Lucas SR, Rafaels KA, Damon AM, and Crandall JR

Subjects

Algorithms, Humans, Least-Squares Analysis, Normal Distribution, Survival Analysis, Accidents, Traffic, Cervical Vertebrae injuries, Motorcycles, Neck Injuries, Risk Assessment methods, Trauma Severity Indices

Abstract

Objective: The neck injury index, NII, developed in ISO 13232 (2005) as a testing and evaluation procedure for assessing the risk of injury to the AO/C1/C2 region of the cervical spine in motorcycle riders is reevaluated using an existing postmortem human subjects (PMHS) data set and resulting in a reformulated NII criterion applicable to PMHS tests., Methods: A recent series of 36 PMHS head/neck component tests was used to examine the risk of neck injury in frontal impacts and to assess the predictive capability of NII for impacts of various orientations. Using force and moment load cell PMHS experimental data, injury risk was assessed using NII evaluated with the ISO 13232-5 algorithms., Results: The injury risk predictions are compared with the injury outcomes from the head/neck PMHS. The NII criterion underestimated the injury incidence of the PMHS experimental group. The average predicted risk of injuries for the experimental injury tests based on NII across the MAIS levels was 0.7 percent, though there were 11 AIS 3+ injuries observed in the actual testing (30.6%). Using the experimental injury outcomes and the experimental force and moment time histories, the normalizing coefficients from NII are reevaluated to minimize the difference between NII risk assessment and the experimental injury outcome in the least squares (L(2)) basis. This reanalysis is compared with existing human and PMHS neck injury criteria., Conclusions: By reanalyzing the NII formulation using an existing PMHS injury data set with known forces and moments and known injury outcomes, a new NII(PMHS) is developed that uses PMHS loads to predict injury. This reformulation removes the dependency of the original NII formulation on the forces and moments from motorcyclist anthropomorphic test device (MATD) experiments and simulations yet retains the advantages of the multi-axial neck injury criterion.

Published

2010

11. Pulmonary injury risk assessment for short-duration blasts.

Author

Bass CR, Rafaels KA, and Salzar RS

Subjects

Animals, Body Size, Disease Models, Animal, Humans, Logistic Models, Pressure, ROC Curve, Risk Assessment, Survival Analysis, Time Factors, Blast Injuries etiology, Lung Injury

Abstract

Background: Blast injuries are becoming more common in modern war and terrorist action. This increasing threat underscores the importance of understanding and evaluating blast effects., Methods: For this study, data on more than 2,550 large animal experiments were collected from more than 50 experimental studies on blast. From this dataset, over 1,100 large animal experiments were selected with positive phase overpressure durations of 30 milliseconds or less. A two variable nonlinear logistic regression was performed on the experimental data for threshold injury and lethality in terms of pressure and duration. The effects of mass, pressure, and duration scaling were all evaluated., Results: New injury risk assessment curves were analyzed for both incident and reflected pressure conditions. Position dependent injury risk curves were also analyzed and were found to be unnecessary, at least for prone and side on conditions., Conclusions: The injury risk assessment showed good correlation to some of the existing injury assessments. It also showed good correspondence to a reported human case of blast exposure. Pressure scaling was analyzed to be unnecessary for these short duration exposures. Recommended injury assessments for various orientations relative to the incoming blast wave are included.

Published

2008

12. Thoracic and lumbar spinal impact tolerance.

Author

Bass CR, Rafaels KA, Salzar RS, Carboni M, Kent RW, Lloyd MD, Lucas S, Meyerhoff K, Planchak C, Damon A, and Bass GT

Subjects

Animals, Anthropometry, Cadaver, Lumbar Vertebrae pathology, Models, Animal, Risk Assessment, Swine, Thoracic Vertebrae pathology, Accidents, Traffic, Back Injuries etiology, Lumbar Vertebrae injuries, Spinal Fractures etiology, Thoracic Vertebrae injuries

Abstract

Introduction: Thoracolumbar injuries resulting from motor vehicle accidents, falls, and assaults have a high risk of morbidity and mortality. However, there are no biomechanically based standards that address this problem., Methods: This study used four cadaveric porcine specimens as a model for direct spinal impact injuries to humans to determine an appropriate injury tolerance value. The anthropometric parameters of these specimens are compared with values found in a large human cadaveric dataset. Each specimen was subjected to five impacts on the dorsal surface of the lower thorax and abdomen., Results: The injuries ranged from mild spinous process fractures to endplate fractures with anterior longitudinal ligament (ALL) transactions with a maximum AIS=3. The average peak reaction force for the thoracic failure tests was 4720+/-1340 N, and the average peak reaction force for the lumbar failure tests was 4650+/-1590 N., Discussion: When scaled to human values using anthropometric parameters determined in this study, the force at which there is a 50% risk of injury is 10,200+/-3900 N. This value favorably compares to that found in the existing literature on isolated vertebral segments., Summary: After demonstrating that the porcine model can be used as a spinal impact model for the human, the resulting injury risk value can be used in determining new standards for human injury risk or in guiding the design of safety equipment for the back.

Published

2008