Skip to main content
Key Specialties
Cardiology Diabetology Endocrinology Gastroenterology Geriatrics and Gerontology Gynecology and Obstetrics Hematology Infectious Disease Internal Medicine Nephrology Neurology Oncology Pediatrics Respiratory Medicine Rheumatology Surgery
Congress Coverage
2024 ACC Congress 2023 ESMO Congress 2023 EASD Congress 2023 ERS Congress 2023 ESC Congress
Clinical Collections
Advances in Alzheimer’s

Keynote webinar | Spotlight on medication adherence

LIVE: Thursday 27th June 2024, 18:00-19:30 (CEST)
Join our expert panel to discover why you need to understand the drivers of non-adherence in your patients, and how you can optimize medication adherence in your clinics to drastically improve patient outcomes.
ADVANCED SEARCH
Log in
Top
International Journal of Legal Medicine
Published in: International Journal of Legal Medicine 2/2019

01-03-2019 | Original Article

A novel hypothesis for the formation of conoidal projectile wounds in sandwich bones

Authors: John M. Rickman, James Shackel

Published in: International Journal of Legal Medicine | Issue 2/2019

Login to get access

Abstract

When perforated by a projectile, sandwich bones typically exhibit wounds with a distinct conoidal morphology that is widely utilised both in wound diagnosis and trajectory determinations. However, the dynamic fracture mechanisms underlying this intriguing wound type have yet to be experimentally verified. The most frequently quoted hypothesis for their formation, plug and spall, is difficult to reconcile with the conoidal morphology exhibited by such wounds. The present article carries out a high-speed videographic and micro-computerised tomographic (μ-CT) analysis of perpendicularly produced projectile wounds induced from 139.15 to 896.84 metres per second (m/s) in pig scapulae. Fundamental data on energy absorption, wound shape and bevel symmetry are presented. Cross-sectional fracture morphology revealed by μ-CT raises the novel hypothesis that tensile stresses induced by the projectile in the outer cortex elicit cone crack formation and that this cone crack then propagates catastrophically through the entire sandwich structure. This process results in the momentary formation of a bioceramic conoid, a conoidal volume of bone consisting of all three sandwich bone layers separated from the parent bone by the internal bevel. Fragmentation of the separated volume leaves the conoidal wound behind as its counterpart. The significance of this hypothesis in terms of differential diagnosis and interpretation of bevel shape is discussed.
Literature
1.
2.
Aarabi B, Tofighi B, Kufera JA, Hadley J, Ahn ES, Cooper C, Malik JM, Naff NJ, Chang L, Radley M, Kheder A, Uscinski RH (2014) Predictors of outcome in civilian gunshot wounds to the head. J Neurosurg 120:1138–1146PubMed
3.
4.
Snell RS (1995) Clinical anatomy. Lipincott Williams and Wilkins, Maryland
5.
Berryman HE, Symes SA (1998) Recognising gunshot and cranial trauma through fracture interpretation. In: Reichs KJ (ed) Forensic osteology: advances in the identification of human remains. Charles C Thomas Publishers, Springfield, pp 333–352
6.
Rhine and Curran (1990) Multiple gunshot wounds to the head: an anthropological review. J Forensic Sci 35(3):1236–1245PubMed
7.
Spitz WU (2006) Injuries by gunfire. In: Spitz WU, Spitz DJ, Clark R (eds) Spitz and Fisher’s medicolegal investigation of death: guidelines for the application of pathology to crime investigation. Charles C Thomas Publishers, Springfield Available from: Proquest Ebook Central. Accessed 9.11.17
8.
Hull D (1999) Fractography: observing, measuring and interpreting fracture surface topography. Cambridge University Press, Cambridge
9.
Komar DA, Buikstra JE (2008) Forensic anthropology: contemporary theory and practice. Oxford University Press Inc., New York
10.
Symes SA, L’Abbé EN, Chapman EN, Wolff I, Dirkmaat DC (2012) Interpreting traumatic injuries to bone in medicolegal investigations. In: Dirkmaat DC (ed) A companion to forensic anthropology. Wiley-Blackwell Publishing, West Sussex
11.
Christensen AM, Passalacqua NV, Bartelink EJ (2014) Forensic anthropology: current methods and practice. Academic Press, Oxford
12.
Peterson BL (1991) External beveling of cranial gunshot entrance wounds. J Forensic Sci 36(5):1592–1595PubMed
13.
Kimmerle EH, Baraybar JP (2008) Skeletal trauma: identification of injuries resulting from human rights abuses and armed conflict. CRC Press, Florida
14.
15.
Murphy MS, Gaither C, Goycochea E, Verano JW, Cock G (2010) Violence and weapon-related trauma at Puruchuko-Huaquerones, Peru. Am J Phys Anthropol 142:636–649PubMed
16.
Murphy MS, Spatola B, Weathermon R (2014) Allies today, enemies tomorrow: a comparative analysis of perimortem injuries along the biomechanical continuum. In: Martin DL, Anderson CP (eds) Bioarchaeological and forensic perspectives on violence: how violent death is interpreted from skeletal remains. Cambridge University Press, Cambridge, pp 261–288
17.
Bird CE, Fleischman JM (2015) A rare case of an intact bone plug associated with a gunshot exit wound. J Forensic Sci 60(4):1074–1077PubMed
18.
Smith MJ, Brickley MB, Leach SL (2007) Experimental evidence for lithic projectile injuries: improving identification of an under-recognised phenomenon. J Archaeol Sci 34:540–553
19.
20.
Currey JD (2002) Bones: structure and mechanics. Princeton University Press, New Jersey
21.
Quatrehomme G, İşcan MY (1998) Analysis of bevelling in gunshot entrance wounds. Forensic Sci Int 93:45–60PubMed
22.
Zukas JA (1982) Penetration and perforation of solids. In: Zukas JA, Nicholas T, Swift HF, Greszczuk LB, Curran DR (eds) Impact dynamics. John Wiley and Sons, Inc., USA, pp 155–214
23.
Backman ME, Goldsmith W (1978) The mechanics of penetration of projectiles into targets. Int J Eng Sci 16:1–99
24.
Crouch IG (2016) An introduction to armour materials. In Crouch IG, Arthur J (eds) The science of armour materials, available from ProQuest Ebook central
25.
Hassan MZ, Cantwell WJ (2012) The influence of core properties on the perforation resistance of sandwich structures: an experimental study. Compos Part B 43:3231–3238
26.
Knight CG, Swain MV, Chaudhri (1977) Impact of small steel spheres on glass surfaces. J Mater Sci 12:1573–1586
27.
Chen SY, Farris TN, Chandrasekar S (1995) Contact mechanics of Hertzian cone cracking. Int J Solids Struct 2(3/4):329–340
28.
Lawn BR (1998) Indentation of ceramics with spheres: a century after Hertz. J Am Ceram Soc 81(8):1977–1994
29.
30.
Zaera R, Sánchez-Gálvez V (1998) Analytical modelling of normal and oblique ballistic impact on ceramic/metal lightweight armours. Int J Impact Eng 21(3):133–148
31.
Klepinger LL (2006) Fundamentals of forensic anthropology. John Wiley & Sons, New Jersey
32.
Olszta MJ, Cheng X, Jee SS, Kumar R, Kim YY, Kaufman MJ, Douglas EP, Gower LB (2007) Bone structure and formation: a new perspective. Mater Sci Eng R Rep 58:77–116
33.
Gibson LJ, Ashby MF (1988) Cellular solids: structure and properties. Pergamon press, Oxford
34.
Kaplan SL, Hayes WC, Stone JL (1985) Tensile strength of bovine trabecular bone. J Biomech 18(9):723–727PubMed
35.
Tomar V (2009) Insights into the effects of tensile and compressive loadings on microstructure dependent fracture of trabecular bone. Eng Fract Mech 76:884–897
36.
37.
Zimmermann EA, Gludovatz B, Schaible E, Busse B, Ritchie RO (2014) Fracture resistance of human cortical bone across multiple length scales at physiological strain rates. Biomaterials 35:5472–5481PubMed
38.
He M-Y, Hutchinson JW (1989) Crack deflection at an interface between dissimilar elastic materials. Int J Solids Struct 25(9):1053–1067
39.
Mencík J (2010) Mechanics of components with treated or coated surfaces. Klewer Academic Publishers, Netherlands
40.
Keaveny TM, Morgan EF, Yeh OC (2004) Bone biomechanics. In: Kutz M (ed) Standard handbook of biomedical engineering and design. McGraw-Hill Professional, USA, pp 8.1–8.23
41.
Bayraktar HH, Morgan EF, Niebur GL, Morris GE, Wong EK, Keaveny TM (2004) Comparison of elastic and yield properties of human femoral trabecular and cortical bone tissue. J Biomech 37:27–35PubMed
42.
Kaufmann C, Cronin D, Worswick M, Pageau G, Beth A (2003) Influence of material properties on the ballistic performance of ceramics for personal body armour. Shock Vib 10:51–58
43.
Madea B, Staak M (1988) Determination of the sequence of gunshot wounds of the skull. J Forensic Sci Soc 28:321–328PubMed
44.
Zimmermann EA, Launey ME, Barth HD, Ritchie RO (2009) Mixed mode fracture of human cortical bone. Biomaterials 30:5877–5884PubMed
45.
Zou Z, Reid SR, Tan PJ, Li S, Harrigan JJ (2009) Dynamic crushing of honeycombs and features of shock fronts. Int J Impact Eng 36:165–176
46.
Abrate S (1998) Impact on composite structures. Cambridge University Press, Cambridge
47.
Skvortsov V, Kepler J, Bozhevolnaya E (2003) Energy partition for ballistic penetration of sandwich panels. Int J Impact Eng 28:697–716
48.
Hou W, Zhu F, LU G, Fang D-N (2010) Ballistic impact experiments of metallic sandwich panels with aluminium foam core. Int J Impact Eng 37:1045–1055
49.
50.
Spatola BF (2015) Atypical gunshot and blunt force injuries: wounds along the biomechanical continuum. In: Passalacqua NV, Rainwater CW (eds) Skeletal trauma analysis: case studies in context. John Wiley & Sons, West Sussex, pp 7–26
51.
52.
Vermeij EJ, Zoon PD, Chang SBCG, Keereweer I, Pieterman R, Gerretsen RRR (2012) Analysis of microtraces in invasive traumas using SEM/EDS. Forensic Sci Int 214(1):96–104PubMed
53.
Nawrocki SP (2009) Forensic taphonomy. In: Blau S, Ubelaker DH (eds) Handbook of forensic anthropology and archaeology. Left Coast Press, California, pp 284–294
54.
Moraitis K, Spiliopoulou C (2010) Forensic implications of carnivore scavenging on human remains recovered from outdoor locations in Greece. J Forensic Legal Med 17:298–303
55.
Pope EJ, Smith O’BC (2004) Identification of traumatic injury in burned cranial bone: an experimental approach. J Forensic Sci 49(3):1–10
56.
Tümer AR, Karacaoğlu E, Keten A, Ünal M (2012) Postmortem burning of the corpses following homicide. J Forensic Legal Med 19:223–228
57.
Loe L (2009) Perimortem trauma. In: Blau S, Ubelaker DH (eds) Handbook of forensic anthropology and archaeology. Left Coast Press, California, pp 263–283
58.
59.
Cantwell WJ, Morton J (1989) Comparison of low and high velocity impact response of CFRP. Composites 20(6):545–551
Metadata
Title
A novel hypothesis for the formation of conoidal projectile wounds in sandwich bones
Authors
John M. Rickman
James Shackel
Publication date
01-03-2019
Publisher
Springer Berlin Heidelberg
Published in
International Journal of Legal Medicine / Issue 2/2019
Print ISSN: 0937-9827
Electronic ISSN: 1437-1596
DOI
https://doi.org/10.1007/s00414-018-1946-x

Other articles of this Issue 2/2019

International Journal of Legal Medicine 2/2019 Go to the issue

Population Data

Genetic polymorphisms of 32 Y-STR loci in Meizhou Hakka population

Original Article

Mitochondrial DNA control region diversity in a population from Parana state—increasing the Brazilian forensic database

Population Data

Autosomal short tandem repeat variations and population genetic data on 23 systems in seven major subpopulations from Lebanon

Original Article

Multiplex analysis of genetic polymorphisms within UGT1A9, a gene involved in phase II of Δ9-THC metabolism

Original Article

Sharp bone trauma diagnosis: a validation study using epifluorescence microscopy

Original Article

Predatory behavior of Synthesiomyia nudiseta larvae (Diptera: Muscidae) on several necrophagous blowfly species (Diptera: Calliphoridae)