· Kai-UweSchmitt PeterF.Niederer · MarkusH.Muser FelixWalz TraumaBiomechanics · Kai-Uwe Schmitt Peter F. Niederer · Markus H. Muser Felix Walz TraumaBiomechanics Accidental injury in traffic and sports Second Edition With88Figuresand30Tables 123 PDDr.sc.techn.Kai-UweSchmitt Prof.Dr.sc.techn.PeterF.Niederer Dr.sc.techn.MarkusH.Muser Prof.Dr.med.FelixWalz UniversityandETHZurich InstituteforBiomedicalEngineering, ETZF90 Gloriastraße35 8092Zurich Switzerland [email protected] LibraryofCongressControlNumber:2007931452 ISBN978-3-540-73872-5SpringerBerlinHeidelbergNewYork ISBN978-3-540-22299-61.AuflageSpringerBerlinHeidelbergNewYork Thisworkissubjecttocopyright.Allrightsarereserved,whetherthewholeorpartofthematerial is concerned, specificallythe rights of translation, reprinting, reuseof illustrations, recitation, broadcasting,reproductiononmicrofilmorinanyotherway,andstorageindatabanks.Duplication ofthispublicationorpartsthereofispermittedonlyundertheprovisionsoftheGermanCopyright LawofSeptember9,1965,initscurrentversion,andpermissionforusemustalwaysbeobtained fromSpringer.ViolationsareliabletoprosecutionundertheGermanCopyrightLaw. SpringerisapartofSpringerScience+BusinessMedia springer.com ©Springer-VerlagBerlinHeidelberg2004,2007 Theuseofgeneraldescriptivenames,registerednames,trademarks,etc.inthispublicationdoes notimply,evenintheabsenceofaspecificstatement,thatsuchnamesareexemptfromtherelevant protectivelawsandregulationsandthereforefreeforgeneraluse. Production:LE-TEXJelonek,Schmidt&V¨ocklerGbR,Leipzig Coverdesign:deblik,Berlin Printedonacid-freepaper SPIN11976738 60/3180YL-543210 Preface Everyday, more than 140’000 people are injured, 3000 killed, and 15’000 disabled for life everyday on the world's roads. Likewise, sports related injuries are numerous and have a significant socio-economic impact. The field of trauma biomechanics, or injury biomechanics, uses the principles of mechanics to study the response and tolerance level of biological tissues under extreme loading conditions. Through an understanding of mechanical factors that influence the function and structure of human tissues, countermeasures can be developed to alleviate or even eliminate such injuries. This book, Trauma-Biomechanics, surveys a wide variety of topics in injury biomechanics including anatomy, injury classification, injury mechanism, and injury criteria. It is the first collection I am aware of that lists regional injury reference values, or injury criterion, either currently in use or proposed by both U.S. and European communities. Although the book is meant to be an introduction for medical doctors and engineers who are beginners in the field of injury biomechanics, sufficient references are provided for those who wish to conduct further research, and even established researchers will find it useful as a reference for finding the biomechanical background of each proposed injury mechanism and injury criterion. As more people become aware of and understand this subject, it will someday lead to better mitigation and prevention of automotive adn sports related injuries. I like this book very much and believe that you will find the same. King H. Yang Professor of Biomedical Engineering and Mechanical Engineering Director of Bioengineering Center Wayne State University Acknowledgements The authors are gratefully indebted to their friends and colleagues, who assisted in the development of this book through their scientific work, comments and discussions. Furthermore we would like to thank the members of the board of the International Research Council on the Biomechanics of Injury (IRCOBI) for their support. Kai-Uwe Schmitt, Peter Niederer, Markus Muser, Felix Walz Contents 1 Introduction ..............................................................................................1 1.1 About the contents of this book .........................................................2 1.2 Historical remarks...............................................................................7 2 Methods in Trauma-Biomechanics ........................................................15 2.1 Statistics, field studies, databases ....................................................15 2.2 Injury criteria, injury scales and injury risk ....................................19 2.3 Basic technical definitions and accident reconstruction .................23 2.4 Experimental models .......................................................................29 2.5 Standardised test procedures ...........................................................34 2.5.1 Anthropomorphic test devices ...................................................40 2.6 Numerical methods .........................................................................48 2.7 References .......................................................................................52 3 Head Injuries ..........................................................................................55 3.1 Anatomy of the head .......................................................................55 3.2 Injuries and injury mechanisms .......................................................57 3.3 Mechanical response of the head ....................................................62 3.4 Injury criteria for head injuries ........................................................66 3.4.1 Head Injury Criterion (HIC) ......................................................67 3.4.2 Head Protection Criterion (HPC) ..............................................68 3.4.3 3 ms criterion (a ) .................................................................69 3ms 3.4.4 Generalized Acceleration Model for Brain Injury Threshold ...69 3.5 Head injuries in sports.......................................................................71 3.6 Head injury prevention......................................................................73 3.6.1 Head injury prevention in pedestrians.........................................75 3.7 References .......................................................................................78 4 Spinal Injuries .........................................................................................83 4.1 Anatomy of the spine ......................................................................84 4.2 Injury mechanisms ..........................................................................87 VIII Contents 4.3 Biomechanical response and tolerances ..........................................95 4.4 Injury criteria ...................................................................................99 4.4.1 Neck injury criterion NIC .......................................................100 4.4.2 N neck injury criterion ..........................................................101 ij 4.4.3 Neck protection criterion N ................................................103 km 4.4.4 Intervetebral neck injury criterion (IV-NIC) ...........................106 4.4.5 Neck displacement criterion (NDC) ........................................106 4.4.6 Lower Neck Load Index (LNL) ..............................................107 4.4.7 Neck injury criteria in ECE and FMVSS ................................107 4.4.8 Correlating neck injury criteria to the injury risk ....................109 4.5 Spinal injuries in sports...................................................................111 4.6 Prevention of soft tissue neck injury...............................................112 4.6.1 Head restraint geometry and padding material..........................114 4.6.2 Controlling head restraint position............................................115 4.6.3 Controlling seat back motion....................................................117 4.7 References .....................................................................................119 5 Thoracic Injuries ...................................................................................127 5.1 Anatomy of the thorax ...................................................................127 5.2 Injury mechanisms ........................................................................129 5.2.1 Rib fractures ............................................................................131 5.2.2 Lung injuries ...........................................................................132 5.2.3 Injuries to other thoracic organs ..............................................133 5.3 Biomechanical response ................................................................135 5.3.1 Frontal loading ........................................................................135 5.3.2 Lateral loading ........................................................................141 5.4 Injury tolerances and criteria .........................................................143 5.4.1 Acceleration and force ............................................................143 5.4.2 Thoracic Trauma Index (TTI) .................................................143 5.4.3 Compression Criterion (C) ......................................................144 5.4.4 Viscous Criterion (VC) ...........................................................144 5.4.5 Combined Thoracic Index (CTI) .............................................145 5.4.6 Other criteria ............................................................................146 5.5 Thoracic injuries in sports...............................................................146 5.6 References .....................................................................................147 6 Abdominal Injuries ...............................................................................149 6.1 Anatomy of the abdomen ..............................................................149 6.2 Injury mechanisms ........................................................................150 6.3 Testing the biomechanical response ..............................................153 6.4 Injury tolerance .............................................................................155 Contents IX 6.4.1 Injury criteria ...........................................................................156 6.5 Influence of seat belt use ...............................................................157 6.6 Abdominal injuries in sports...........................................................157 6.7 References .....................................................................................158 7 Injuries of the Pelvis and the Lower Extremities .................................161 7.1 Anatomy of the lower limbs ..........................................................161 7.2 Injury mechanisms ........................................................................163 7.2.1 Injuries of the pelvis and the proximal femur .........................168 7.2.2 Leg, knee and foot injury ........................................................170 7.3 Impact tolerance of the pelvis and the lower extremities ..............172 7.4 Injury criteria .................................................................................176 7.4.1 Compression force ..................................................................176 7.4.2 Femur Force Criterion (FFC) ..................................................176 7.4.3 Tibia Index (TI) .......................................................................177 7.4.4 Other criteria ...........................................................................177 7.5 Pelvic and lower extremity injuries in sports..................................178 7.6 Prevention of lower extremity injuries ............................................181 7.6.1 Pedestrian injury conuntermeasures.........................................182 7.7 References .....................................................................................183 8 Injuries of the Upper Extremities .........................................................187 8.1 Anatomy of the upper limbs ..........................................................188 8.2 Injury incidences and mechanisms ................................................189 8.3 Impact tolerance ............................................................................191 8.4 Injury criteria and evaluation of injury risk from airbags .............193 8.5 Upper extremity injuries in sports...................................................194 8.6 References .....................................................................................198 9 Impairment and injuries resulting from chronic mechanical exposure...201 9.1 Occupational health.........................................................................204 9.2 Sports..............................................................................................206 9.2.1 Non contact sports.....................................................................206 9.2.2 Contact sports............................................................................208 9.3 Household work..............................................................................208 9.4 Conclusions.....................................................................................208 9.5 References.......................................................................................209 1 Introduction The human being is exposed to mechanical loads throughout his or her life. Besides gravity and forces due to electromagnetic fields, there is a great variety of forces acting on the human body from contacts with the surrounding; in addition, numerous forces are generated in the course of physiological processes inside the body in the different organs and tissues. Throughout evolution, all forms of life adapted their physiology to mechanical interactions; some of them to the extent that a proper function in fact requires the influence of forces, for example bone remodelling. The science of biomechanics is devoted to the analysis, measurement and modelling of the effects which are observed under the various mechanical loading situations primarily in humans, but also in animals and plants. As this definition suggests, a quantitative approach is thereby in the foreground. The range of forces which is of interest is enormous: Internal forces may originate from the action of molecules, contractile fibres on a cellular level or muscles on a macroscopic scale, moreover, pressures and shear stresses may be generated by biological fluid flows or active biological transport processes including osmosis. External forces, in turn, occurring in everyday life may span a virtually unlimited extent. Accordingly, the forces of interest in biomechanics cover typically a range from pN to MN (lower or higher forces, respectively, are hardly considered because of lack of biological effect on the lower side or complete devastation on the upper), and they may vary with time within picoseconds to years. An inevitable consequence of forces acting in- or outside the human body consists of the possibility that they may cause injury. Such adverse consequences are usually associated with the action of excessive external forces impinging during unfavourable events with which we may be confronted in daily life. Internal forces, in contrast, are mostly thought to be governed by anatomical or physiological constraints which prevent the occurrence of injury. Yet, broken ribs due to intense coughing, rupture of muscle fibres because of tetanic contraction or endocardial bleeding in