nach oben

Forensic Science, Medicine and Pathology

Erschienen in:

14.09.2022 | Original Article

Surface wave analysis of the skin for penetrating and non-penetrating projectile impact in porcine legs

verfasst von: Joseph LeSueur, Carolyn Hampton, Jared Koser, Sajal Chirvi, Frank A. Pintar

Erschienen in: Forensic Science, Medicine and Pathology | Ausgabe 1/2023

Einloggen, um Zugang zu erhalten

Abstract

Secondary blast injuries may result from high-velocity projectile fragments which ultimately increase medical costs, reduce active work time, and decrease quality of life. The role of skin penetration requires more investigation in energy absorption and surface mechanics for implementation in computational ballistic models. High-speed ballistic penetration studies have not considered penetrating and non-penetrating biomechanical properties of the skin, including radial wave displacement, resultant surface wave speed, or projectile material influence. A helium-pressurized launcher was used to accelerate 3/8″ (9.525 mm) diameter spherical projectiles toward seventeen whole porcine legs from seven pigs (39.53 ± 7.28 kg) at projectile velocities below and above V₅₀. Projectiles included a mix of materials: stainless steel (n = 26), Si₃N₄ (n = 24), and acetal plastic (n = 24). Tracker video analysis software was used to determine projectile velocity at impact from the perpendicular view and motion of the tissue displacement wave from the in-line view. Average radial wave displacement and surface wave speed were calculated for each projectile material and categorized by penetrating or non-penetrating impacts. Two-sample t-tests determined that non-penetrating projectiles resulted in significantly faster surface wave speeds in porcine skin for stainless steel (p = 0.002), plastic (p = 0.004), and Si₃N₄ ball bearings (p = 0.014), while ANOVA determined significant differences in radial wave displacement and surface wave speed between projectile materials. Surface wave speed was used to quantify mechanical properties of the skin including elastic modulus, shear modulus, and bulk modulus during ballistic impact, which may be implemented to simulate accurate deformation behavior in computational impact models.

Brinsfield KH. Bombings: injury patterns and care. American college of emergency physicians. Cent Dis Control Prevent. 2006;45–9.

Rankin IA, Nguyen TT, McMenemy L, Clasper JC, Masouros SD. The injury mechanism of traumatic amputation. Front Bioeng Biotechnol. Frontiers Media S.A. 2021;9.

Moxnes JF, Frøyland Ø, Skriudalen S, Prytz AK, Teland JA, Friis E, et al. On the study of ricochet and penetration in sand, water and gelatin by spheres, 7.62 mm APM2, and 25 mm projectiles. Def Technol. China Ordnance Soc. 2016;12:159–70.

Breeze J, Sedman AJ, James GR, Newbery TW, Hepper AE. Determining the wounding effects of ballistic projectiles to inform future injury models: a systematic review. J R Army Med Corps. BMJ Publishing Group. 2014;160:273–8.

Wang QS, Sun RJ, Tian X, Yao M, Feng Y. Quasi-static puncture resistance behaviors of high-strength polyester fabric for soft body armor. Res Phys Elsevier. 2016;6:554–60.

Dwivedi AK, Dalzell MW, Fossey SA, Slusarski KA, Long LR, Wetzel ED. Low velocity ballistic behavior of continuous filament knit aramid. Int J Impact Eng. Elsevier Ltd. 2016;96:23–34.

Breeze J, James GR, Hepper AE. Perforation of fragment simulating projectiles into goat skin and muscle. J R Army Med Corps. BMJ Publishing Group. 2013;159:84–9.

Yazdi SJM, Baqersad J. Mechanical modeling and characterization of human skin: a review. J Biomech. Elsevier Ltd. 2022;130.

Mahoney P, Carr D, Arm R, Gibb I, Hunt N, Delaney RJ. Ballistic impacts on an anatomically correct synthetic skull with a surrogate skin/soft tissue layer. Int JLegal Med. Springer Verlag. 2018;132:519–30.

10.

Pailler-Mattei C, Bec S, Zahouani H. In vivo measurements of the elastic mechanical properties of human skin by indentation tests. Med Eng Phys. 2008;30:599–606.CrossRefPubMed

11.

Jee T, Komvopoulos K. In vitro measurement of the mechanical properties of skin by nano/microindentation methods. J Biomech Elsevier Ltd. 2014;47:1186–92.CrossRef

12.

Lamers E, van Kempen THS, Baaijens FPT, Peters GWM, Oomens CWJ. Large amplitude oscillatory shear properties of human skin. J Mech Behav Biomed Mater. 2013;28:462–70.CrossRef

13.

Pereira JM, Mansour JM, Davis BR. Analysis of shear wave propagation in skin; application to an experimental procedure. J Biomech. 1990;3:745–51.CrossRef

14.

Meliga SC, Coffey JW, Crichton ML, Flaim C, Veidt M, Kendall MAF. The hyperelastic and failure behaviors of skin in relation to the dynamic application of microscopic penetrators in a murine model. Acta Biomater Elsevier Ltd. 2017;48:341–56.CrossRef

15.

Delalleau A, Josse G, Lagarde JM, Zahouani H, Bergheau JM. A nonlinear elastic behavior to identify the mechanical parameters of human skin in vivo. Skin Res Technol. 2008;14:152–64.CrossRefPubMed

16.

Santucci RA, Chang YJ. Ballistics for physicians: myths about wound ballistics and gunshot injuries. J Urol. Lippincott Williams and Wilkins. 2004;171:1408–14.

17.

Whittle K, Kieser J, Ichim I, Swain M, Waddell N, Livingstone V, et al. The biomechanical modeling of non-ballistic skin wounding: blunt-force injury. Forensic Sci Med Pathol. 2008;4:33–9.CrossRefPubMed

18.

Jin Y, Mai R, Wu C, Han R, Li B. Comparison of ballistic impact effects between biological tissue and gelatin. J Mech Behav Biomed Mater. Elsevier Ltd. 2018;78:292–7.

19.

Kieser DC, Carr DJ, Leclair SC, Horsfall I, Theis J-C, Swain M v, et al. Clothing increases the risk of indirect ballistic fractures. J Orthop Surg Res. 2013;8:42. Available from: http://www.josr-online.com/content/8/1/42.

20.

Chanda A. Biomechanical modeling of human skin tissue surrogates. Biomimetics. MDPI Multidisciplinary Digital Publishing Institute. 2018;3.

21.

Flynn C, Taberner AJ, Nielsen PMF, Fels S. Simulating the three-dimensional deformation of in vivo facial skin. J Mech Behav Biomed Mater. 2013;28:484–94.CrossRefPubMed

22.

Dai A, Wang S, Zhou L, Wei H, Wang Z, He W. In vivo mechanical characterization of human facial skin combining curved surface imaging and indentation techniques. Skin Res Technol. 2019;25:142–9.CrossRefPubMed

23.

Ní Annaidh A, Bruyère K, Destrade M, Gilchrist MD, Otténio M. Characterization of the anisotropic mechanical properties of excised human skin. J Mech Behav Biomed Mater. 2012;5:139–48.CrossRefPubMed

24.

Zahouani H, Pailler-Mattei C, Sohm B, Vargiolu R, Cenizo V, Debret R. Characterization of the mechanical properties of a dermal equivalent compared with human skin in vivo by indentation and static friction tests. Skin Res Technol. 2009;15:68–76.CrossRefPubMed

25.

Vexler A, Polyansky I, Gorodetsky R. Evaluation of skin viscoelasticity and anisotropy by measurement of speed of shear wave propagation with viscoelasticity skin analyzer 1. J Invest Dermatol. 1999;113.

26.

Jussila J. Measurement of kinetic energy dissipation with gelatine fissure formation with special reference to gelatine validation. Forensic Sci Int Elsevier Ireland Ltd. 2005;150:53–62.CrossRef

27.

Roberts JC, O’Connor JV, Ward EE. Modeling the effect of nonpenetrating ballistic impact as a means of detecting behind-armor blunt trauma. J Trauma. 2005;58:1241–51.

28.

Diab M, Kumaraswamy N, Reece GP, Hanson SE, Fingeret MC, Markey MK, et al. Characterization of human female breast and abdominal skin elasticity using a bulge test. J Mech Behav Biomed Mater. Elsevier Ltd. 2020;103.

29.

Koser J, Chirvi S, Banerjee A, Pintar FA, Hampton C, Kleinberger M. Repeated measures analysis of projectile penetration in porcine legs as a function of storage condition. J Forensic Legal Med. 2022;90:102395. Available from: https://linkinghub.elsevier.com/retrieve/pii/S1752928X22000932.

30.

Chen J, Zhang B, Chen W, Kang JY, Chen KJ, Wang AM, et al. Local and distant trauma after hypervelocity ballistic impact to the pig hind limb. Springerplus. SpringerOpen. 2016;5.

31.

Ellis CL, Hazell P. Visual methods to assess strain fields in armour materials subjected to dynamic deformation-A review. Applied Sciences (Switzerland). MDPI AG. 2020;10.

32.

Mrozek RA, Leighliter B, Gold CS, Beringer IR, Yu JH, VanLandingham MR, et al. The relationship between mechanical properties and ballistic penetration depth in a viscoelastic gel. J Mech Behav Biomed Mater. Elsevier Ltd. 2015;44:109–20.

33.

Zook JA, Frank K, Silsby GF. terminal ballistics test and analysis guidelines for the penetration mechanics branch. US Army Ballistic Research Laboratory. 1992;BRL-MR-3960. Available from: https://apps.dtic.mil/sti/pdfs/ADA246922.pdf.

34.

US Army Test and Evaluation Command Test Operations Procedure. Ballistic tests of armor materials. US Army Aberdeen Proving Ground. 1984;TOP 2–2–710. Available from: https://apps.dtic.mil/sti/pdfs/ADA137873.pdf.

35.

Fonk R, Schneeweiss S, Simon U, Engelhardt L. Hand motion capture from a 3d leap motion controller for a musculoskeletal dynamic simulation. Sensors (Switzerland). MDPI AG. 2021;21:1–14.

36.

Cohen EJ, Bravi R, Minciacchi D. 3D reconstruction of human movement in a single projection by dynamic marker scaling. PLoS ONE. Public Library of Science. 2017;12.

37.

Chen S, Fatemi M, Greenleaf JF. Quantifying elasticity and viscosity from measurement of shear wave speed dispersion. J Acoust Soc Am. 2004;115:2781–5.

38.

Zhang X. A noninvasive surface wave technique for measuring finger’s skin stiffness. J Biomech Elsevier Ltd. 2018;68:115–9.CrossRef

39.

Zhang X. A surface wave elastography technique for measuring tissue viscoelastic properties. Med Eng Phys Elsevier Ltd. 2017;42:111–5.CrossRef

40.

Djaghloul M, Abdouni A, Thieulin C, Zahouani H. Wave propagation as a marker of structural and topographic properties of human skin. Surf Topog Metrol Proper. 2018;6. Available from: https://doi.org/10.1088/2051.

41.

Kirkpatrick SJ, Duncan DD, Fang L. Low-frequency surface wave propagation and the viscoelastic behavior of porcine skin. J Biomed Opt. SPIE-Intl Soc Optical Eng. 2004;9:1311.

42.

Deroy C, Destrade M, Mc Alinden A, Ní Annaidh A. Non-invasive evaluation of skin tension lines with elastic waves. Skin Res Technol. Blackwell Publishing Ltd. 2017;23:326–35.

43.

Li C, Guan G, Reif R, Huang Z, Wang RK. Determining elastic properties of skin by measuring surface waves from an impulse mechanical stimulus using phase-sensitive optical coherence tomography. J R Soc Interface. 2012;9:831–41.

44.

van Albert SA, Bruney III PF. Development of a ballistic impact detection system. North Atlantic Treaty Organization Science and Technology Organization. 2004;MP-HFM-109–27.

45.

Tarasenko A, Čtvrtlík R, Kudělka R. Theoretical and experimental revision of surface acoustic waves on the (100) plane of silicon. Sci Rep. 2021;11.

46.

Mavko G, Mukerji T, Dvorkin J. The rock physics handbook. Cambridge: Cambridge University Press. 2009 [cited 2021 Dec 12]. Available from: http://ebooks.cambridge.org/ref/id/CBO9780511626753.

47.

Lloyd BA. Tissue Properties: Density. ITIS Foundation. 2022 [cited 2022 Apr 23]. Available from: https://itis.swiss/virtual-population/tissue-properties/database/density/.

48.

Delalleau A, Josse G, Lagarde JM, Zahouani H, Bergheau JM. Characterization of the mechanical properties of skin by inverse analysis combined with the indentation test. J Biomech. 2006;39:1603–10.CrossRefPubMed

49.

Stefanopoulos PK, Filippakis K, Soupiou OT, Pazarakiotis VC. Wound ballistics of firearm-related injuries-Part 1: missile characteristics and mechanisms of soft tissue wounding. Int J Oral Maxillofac Surg. Churchill Livingstone. 2014;43:1445–58.

50.

Anderson PSL, Lacosse J, Pankow M. Point of impact: the effect of size and speed on puncture mechanics. Interface Focus. Royal Society of London. 2016;6.

51.

Rozen N, Dudkiewicz I. Wound ballistics and tissue damage. Armed Conflict Injuries to the Extremities. Springer Berlin Heidelberg. 2011;21–33.

52.

Flynn C, Taberner A, Nielsen P. Mechanical characterisation of in vivo human skin using a 3D force-sensitive micro-robot and finite element analysis. Biomech Model Mechanobiol. 2011;10:27–38.CrossRefPubMed

53.

Chen S, Scott J, Bush TR, Roccabianca S. Inverse finite element characterization of the human thigh soft tissue in the seated position. Biomech Model Mechanobiol Springer. 2020;19:305–16.CrossRef

54.

Hendriks FM, Brokken D, van Eemeren JTWM, Oomens CWJ, Baaijens FPT, Horsten JBAM. A numerical-experimental method to characterize the non-linear mechanical behaviour of human skin. Skin Res Technol. 2003;9:274–83.CrossRefPubMed

55.

Trotta A, Ní Annaidh A. Mechanical characterisation of human and porcine scalp tissue at dynamic strain rates. J Mech Behav Biomed Mater. Elsevier Ltd. 2019;100.

56.

Kalra A, Lowe A. Mechanical behaviour of skin: a review. J Mater Sci Eng. OMICS Publishing Group. 2016;5.

Titel: Surface wave analysis of the skin for penetrating and non-penetrating projectile impact in porcine legs
verfasst von: Joseph LeSueur
Carolyn Hampton
Jared Koser
Sajal Chirvi
Frank A. Pintar
Publikationsdatum: 14.09.2022
Verlag: Springer US
Erschienen in: Forensic Science, Medicine and Pathology / Ausgabe 1/2023
Print ISSN: 1547-769X
Elektronische ISSN: 1556-2891
DOI: https://doi.org/10.1007/s12024-022-00521-1

Live-Webinar "Urologie und Sexualmedizin in der Praxis"

Springer Medizin

Surface wave analysis of the skin for penetrating and non-penetrating projectile impact in porcine legs

Abstract

Neu im Fachgebiet Pathologie

Assistierter Suizid durch Infusion von Thiopental

Molekularpathologische Untersuchungen im Wandel der Zeit

Vergleichende Pathologie in der onkologischen Forschung

Gastrointestinale Stromatumoren

Live-Webinar "Urologie und Sexualmedizin in der Praxis"

Springer Medizin

Abstract

Bitte loggen Sie sich ein, um Zugang zu diesem Inhalt zu erhalten

Weitere Artikel der Ausgabe 1/2023

Death following rapidly progressive demyelinating disorder in a young female—a case report

Dermatologic features of chronic intramuscular use of ketamine: a case report

Assessing the applicability of cerebrospinal fluid collected from the spinal cord for the determination of ethyl alcohol in post-mortem toxicology

Applicability and usefulness of the Declaration of Helsinki for forensic research with human cadavers and remains

So lange sind COVID-19-Leichname infektiös

Does Bak Kut Teh really cause hepatotoxicity?

Neu im Fachgebiet Pathologie

Assistierter Suizid durch Infusion von Thiopental

Molekularpathologische Untersuchungen im Wandel der Zeit

Vergleichende Pathologie in der onkologischen Forschung

Gastrointestinale Stromatumoren