Modeling of failure of the human cervical spine in the course of the car collision with the road barrier

The aim of the project is to propose the numerical model of a human-occupied car crash against road safety barriers. The particular goal of the proposed research is to derive the mathematical description of a spine’s soft tissues behavior with the emphasis on the cervical part during highly nonlinear dynamic events, such as collisions against cable, steel or concrete barriers. The motivation for the research follows from the investigations of General Director for National Roads and Motorways (Generalna Dyrekcja Dróg Krajowych i Autostrad) into recommendations for design and usage of barriers mounted at Polish highways and expressways. Specifically, the most frequent injuries should be considered, that is those of the cervical spine. The knowledge about the potential range of injuries may have an impact on the recommendations for selection of barrier types in Poland. The original aspect of this project is to develop 2D and 3D anisotropic material law for modelling ligaments subjected to high speed dynamic loads as well as propose anisotropic viscoelastic material law for spinal cord.. Material parameters for soft tissues are to be acquired directly from the experiments performed on the human cervical spines. The experimental static tests will be done using surface imagining of strain variation system and dynamical test will be done using impulse load and high speed cameras. The numerical models will be validated by numerical simulations of experimental tests using authors’ FEM codes and LS-DYNA system. The results obtained during the project will be original on a global scale and will help in better understanding of mathematical and numerical description of cervical spine’s soft tissues during impact dynamics. The obtained conclusions may appear useful for medical personnel that assists the victims of real accidents by giving information about expected injuries depending on the conditions of the event. The proposed project requires an interdisciplinary research, conducted both by scientists from Gdańsk University of Technology and from Medical University of Gdańsk, into socially important aspects of human health and safety. The undertaken research will serve as the basis for scientific development and thus a step toward scientific degrees or titles for members of the research teams will be taken.

Details

Financial Program Name:

OPUS

Organization:

Narodowe Centrum Nauki (NCN) (National Science Centre)

Agreement:

UMO-2020/37/B/ST8/03231 z dnia 2021-01-11

Realisation period:

2021-01-11 - 2024-01-10

Project manager:

prof. dr hab. inż. Krzysztof Wilde

Team members:

researcher prof. dr hab. inż. Wojciech Witkowski
researcher prof. dr hab. inż. Jacek Chróścielewski
researcher prof. dr hab. inż. Magdalena Rucka
researcher dr hab. inż. Agnieszka Sabik
researcher dr inż. Karol Daszkiewicz
researcher mgr inż. Tomasz Wiczenbach
10.01.2024 dr inż. Dawid Bruski
researcher mgr inż. Błażej Meronk
researcher dr inż. Angela Jadwiga Andrzejewska-Sroka
researcher dr inż. Łukasz Pachocki
researcher Radosław Wolny

Realised in:

Katedra Wytrzymałości Materiałów

External institutions participating in project:

Gdański Uniwersytet Medyczny (Poland)

Project's value:

1 472 400.00 PLN

Request type:

National Research Programmes

Domestic:

Domestic project

Verified by:

Gdańsk University of Technology

Papers associated with that project

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total: 5

Year 2024

Mechanical response of human thoracic spine ligaments under quasi-static loading: An experimental study
Publication
- R. Wolny
- T. Wiczenbach
- A. J. Andrzejewska-Sroka (formerly: A. Andrzejewska)
- J. H. Spodnik
- Journal of the Mechanical Behavior of Biomedical Materials - Year 2024
Purpose This study aimed to investigate the geometrical and mechanical properties of human thoracic spine ligaments subjected to uniaxial quasi-static tensile test. Methods Four human thoracic spines, obtained through a body donation program, were utilized for the study. The anterior longitudinal ligament (ALL), posterior longitudinal ligament (PLL), capsular ligament (CL), ligamenta flava (LF), and the interspinous ligament and...

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Numerical modelling of different airbag folding patterns and their influence on occupant responses in frontal vehicle impact
Publication
- Ł. Pachocki
- H. Fang
- INTERNATIONAL JOURNAL OF CRASHWORTHINESS - Year 2024
This paper presented a procedure for airbag folding for the application in occupant safety studies and analysed the influence of different airbag folding patterns on the occupant severity in frontal impact. Airbags were folded in two patterns: zig-zag and top-roll, using two folding techniques: Initial Metric Method and Explicit Folding. The explicit folding was found to be more expensive in terms of preparation time. However,...

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Year 2023

Development and validation of lumbar spine finite element model
Publication
- T. Wiczenbach
- Ł. Pachocki
- K. Daszkiewicz
- P. Łuczkiewicz
- W. Witkowski
- PeerJ - Year 2023
The functional biomechanics of the lumbar spine have been better understood by finite element method (FEM) simulations. However, there are still areas where the behavior of soft tissues can be better modeled or described in a different way. The purpose of this research is to develop and validate a lumbar spine section intended for biomechanical research. A FE model of the 50th percentile adult male (AM) Total Human Model for Safety...

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On implementation of fibrous connective tissues’ damage in Abaqus software
Publication
- A. Sabik
- W. Witkowski
- JOURNAL OF BIOMECHANICS - Year 2023
Connective fibrous tissues, such as tendons and ligaments, in humans and animals exhibit hyperelastic behaviour. The constitution of the material of these tissues is anisotropic due to the presence of the collagen fibres, where one family of fibres is the typical case. Traumatic events and/or aging may sometimes lead to the damage of the tissue. The study of motion of affected joints or limbs is usually not permitted in vivo. This...

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Year 2021

Biomechanics of Lumbar Spine Injury in Road Barrier Collision–Finite Element Study
Publication
- Ł. Pachocki
- K. Daszkiewicz
- P. Łuczkiewicz
- W. Witkowski
- Frontiers in Bioengineering and Biotechnology - Year 2021
Literature and field data from CIREN database have shown that lumbar spine injuries occur during car crashes. There are multiple hypotheses regarding how they occur; however, there is no biomechanical explanation for these injuries during collisions with road safety barriers (RSBs). Therefore, the objective of this study was to investigate the mechanics of vertebral fractures during car collisions with concrete RSBs. The finite...

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