Evaluating Simulant Materials for Understanding Cranial Backspatter from a Ballistic Projectile

Das, Raj; Collins, Boyce; Verma, Bhupesh; Fernandez, Justin; Taylor, Michael

doi:10.1111/1556-4029.12701

Cited by 15 publications

(5 citation statements)

References 57 publications

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“…Das et al [ 29 ] also used PC to simulate skull bone for ballistic projectile evaluation. They consider PC to be too ductile for this application, which confirms the need to carry out mechanical tests specific to the chosen application.…”

Section: Discussionmentioning

confidence: 99%

Geometric and mechanical evaluation of 3D-printing materials for skull base anatomical education and endoscopic surgery simulation – A first step to create reliable customized simulators

et al. 2017

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IntroductionEndoscopic skull base surgery allows minimal invasive therapy through the nostrils to treat infectious or tumorous diseases. Surgical and anatomical education in this field is limited by the lack of validated training models in terms of geometric and mechanical accuracy. We choose to evaluate several consumer-grade materials to create a patient-specific 3D-printed skull base model for anatomical learning and surgical training.MethodsFour 3D-printed consumer-grade materials were compared to human cadaver bone: calcium sulfate hemihydrate (named Multicolor), polyamide, resin and polycarbonate. We compared the geometric accuracy, forces required to break thin walls of materials and forces required during drilling.ResultsAll materials had an acceptable global geometric accuracy (from 0.083mm to 0.203mm of global error). Local accuracy was better in polycarbonate (0.09mm) and polyamide (0.15mm) than in Multicolor (0.90mm) and resin (0.86mm). Resin and polyamide thin walls were not broken at 200N. Forces needed to break Multicolor thin walls were 1.6–3.5 times higher than in bone. For polycarbonate, forces applied were 1.6–2.5 times higher. Polycarbonate had a mode of fracture similar to the cadaver bone. Forces applied on materials during drilling followed a normal distribution except for the polyamide which was melted. Energy spent during drilling was respectively 1.6 and 2.6 times higher on bone than on PC and Multicolor.ConclusionPolycarbonate is a good substitute of human cadaver bone for skull base surgery simulation. Thanks to short lead times and reasonable production costs, patient-specific 3D printed models can be used in clinical practice for pre-operative training, improving patient safety.

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Section: Discussionmentioning

confidence: 99%

Geometric and mechanical evaluation of 3D-printing materials for skull base anatomical education and endoscopic surgery simulation – A first step to create reliable customized simulators

et al. 2017

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“…Easy handling due to spheric form, difficult to replicate Polyethylene Grabmüller et al [ 20 , 21 ], Schyma et al [ 51 ] Polyethylene bottles, easy to obtain and handle, stable, but different mechanical properties Skin Chamois leather Euteneuer et al [ 81 ] Used and recommended by the German Federal Criminal Police Office Semi-finished chrome tanned upholstery “crust” cowhide Jusilla et al [ 82 ] Best skin simulant in a comparison study with 13 materials. Still partly natural product and thus prone to variation Silicon with artificial fibers Thali et al [ 71 ] Results comparable to real cases Dental silicon Falland-Cheung et al [ 83 ] Suitable material with mechanical properties comparable to fresh porcine skin Lorica leather Das et al [ 84 ] Better skin simulant for backspatter compared to natural rubber, at shots with 9 mm Luger Roebuck 1518 synthetic chamois Pullen et al [ 85 ] Suitable skin simulant for tests with non-deforming bullets. Silicon Misc.…”

Section: Research Guidementioning

confidence: 99%

“…The skin simulant used in the “skin-skull-brain” model by Thali et al consists of silicon with artificial fibers and produced results comparable to real cases [ 71 ], while Felland-Cheung et al described dental silicon as an alternative for skin in a study comparing dental materials as simulants to fresh porcine skin [ 83 ]. Das et al evaluated simulant materials for cranial backspatter and while only employing very limited materials, they concluded that lorica leather is a better skin simulant than natural rubber for backspatter testing [ 84 ]. In a recent study, Pullen et al evaluated Roebuck 1518 synthetic chamois (RBK) backed by 10% gelatin for ballistic and forensic use and confirmed this material’s suitability as skin simulant with test using non-deforming projectiles [ 85 ].…”

Section: Research Guidementioning

confidence: 99%

Ten years of molecular ballistics—a review and a field guide

Euteneuer

Courts

2021

Int J Legal Med

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Molecular ballistics combines molecular biological, forensic ballistic, and wound ballistic insights and approaches in the description, collection, objective investigation, and contextualization of the complex patterns of biological evidence that are generated by gunshots at biological targets. Setting out in 2010 with two seminal publications proving the principle that DNA from backspatter collected from inside surfaces of firearms can be retreived and successfully be analyzed, molecular ballistics covered a lot of ground until today. In this review, 10 years later, we begin with a comprehensive description and brief history of the field and lay out its intersections with other forensic disciplines like wound ballistics, forensic molecular biology, blood pattern analysis, and crime scene investigation. In an application guide section, we aim to raise consciousness to backspatter traces and the inside surfaces of firearms as sources of forensic evidence. Covering crime scene practical as well as forensic genetic aspects, we introduce operational requirements and lay out possible procedures, including forensic RNA analysis, when searching for, collecting, analyzing, and contextualizing such trace material. We discuss the intricacies and rationales of ballistic model building, employing different tissue, skin, and bone simulants and the advantages of the “triple-contrast” method in molecular ballistics and give advice on how to stage experimental shootings in molecular ballistic research. Finally, we take a look at future applications and prospects of molecular ballistics.

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“…However, the morphology of skin-penetrating gunshot wounds currently use human and animal cadaver skin for ballistic wound investigations [ 3 , 36 – 39 ]. Although several relevant studies on natural and synthetic skin simulants exist, their focus is predominantly on the biomechanical properties of the simulants, such as tensile strength and shore hardness [ 40 – 45 ].In 2005, Jussila argued that the properties of a tissue (skin) simulant do not have to exactly match those of comparable living tissue [ 40 ]. To the best of our knowledge, our study is the first to report exclusively on the macroscopic comparability of bullet entry wounds created in skin simulants to those in human skin.…”

Section: Introductionmentioning

confidence: 99%

Skin simulants for wound ballistic investigation – an experimental study

Fischer,

Rothschild,

Kneubuehl

et al. 2024

Int J Legal Med

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Gunshot wound analysis is an important part of medicolegal practice, in both autopsies and examinations of living persons. Well-established and studied simulants exist that exhibit both physical and biomechanical properties of soft-tissues and bones. Current research literature on ballistic wounds focuses on the biomechanical properties of skin simulants. In our extensive experimental study, we tested numerous synthetic and natural materials, regarding their macromorphological bullet impact characteristics, and compared these data with those from real bullet injuries gathered from medicolegal practice. Over thirty varieties of potential skin simulants were shot perpendicularly, and at 45°, at a distance of 10 m and 0.3 m, using full metal jacket (FMJ) projectiles (9 × 19 mm Luger). Simulants included ballistic gelatine at various concentrations, dental silicones with several degrees of hardness, alginates, latex, chamois leather, suture trainers for medical training purposes and various material compound models. In addition to complying to the general requirements for a synthetic simulant, results obtained from dental silicones shore hardness 70 (backed with 20 % by mass gelatine), were especially highly comparable to gunshot entry wounds in skin from real cases. Based on these results, particularly focusing on the macroscopically detectable criteria, we can strongly recommend dental silicone shore hardness 70 as a skin simulant for wound ballistics examinations.

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Evaluating Simulant Materials for Understanding Cranial Backspatter from a Ballistic Projectile

Cited by 15 publications

References 57 publications

Geometric and mechanical evaluation of 3D-printing materials for skull base anatomical education and endoscopic surgery simulation – A first step to create reliable customized simulators

Geometric and mechanical evaluation of 3D-printing materials for skull base anatomical education and endoscopic surgery simulation – A first step to create reliable customized simulators

Ten years of molecular ballistics—a review and a field guide

Skin simulants for wound ballistic investigation – an experimental study

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