Human Body Model Morphing for Assessment of Crash Rib Fracture Risk for the Population of Car Occupants
Doctoral thesis, 2023
Fractured ribs are prevalent injury outcomes for vehicle occupants involved in crashes. Sex, age, and anthropometry of an occupant influences the risk to sustain rib fractures.
The SAFER human body model (SHBM) represents an average sized male and includes a detailed ribcage model that has been validated for prediction of rib fracture risk in virtual crash simulations. Developments in parametric morphing of human body models have enabled re-shaping the SHBM to represent a wide range of body sizes for both adult males and females which can influence kinematic and injury risk predictions. The aim for this thesis was to enable the assessment of crash kinematics and rib fracture risk for the population of occupants by morphing the SHBM. Research was performed within objectives that included: providing a definition of the occupant population, creating morphed versions of the SHBM (MHBMs) and validating MHBM crash kinematic and rib fracture risk predictions within the defined population, develop a method to efficiently compute rib fracture risk across the population, and investigate factors beyond morphing that influences MHBM rib fracture risk predictions.
The population definition includes 90 % of the U.S.-population in terms of male and female height and weight variability. For validation, parametric morphing was used to create MHBMs geometrically matching age, sex, height, and weight of 22 human subjects in previous crash tests. Rib fracture risk and kinematic predictions from MHBMs were validated by comparison to test results and MHBMs showed good correlation for kinematics and had acceptable utility to predict rib fracture outcomes. However, the rib fracture risk for the most vulnerable, predominantly older, occupants was underestimated. One reason can be rib cortical bone microstructural defects, that are not represented by current SHBM rib material modeling.
To compute population rib fracture risk in crashes, a metamodeling method based on 25 differently sized MHBMs of each sex was recommended. Using this metamodeling method it was also identified that seven selected MHBMs of each sex can be used to predict the population risk across two specific crash scenarios. This indicates a possibility to identify a small family of MHBMs that are generally representative of population rib fracture risk in future work.
For further improving rib fracture risk predictions, a new rib fracture risk function was developed based on human rib test results. The new function is more sensitive to age compared to previous risk functions. Additionally, it was identified that the individual variability in rib cross-sectional width, as well as cortical bone thickness and material properties all substantially influence rib fracture risk predictions. Including the individual variability in these influential parameters in MHBM models will improve the capability of MHBMs to predict the rib fracture risk variability that exists in the population of occupants independently of sex, height, and weight.
It is concluded that MHBMs representing geometrical shape trends due to height, weight and sex, and individual rib local variability can be used to assess kinematics and rib fracture risk for wide range of males and females of different sizes. However, more research is needed to accurately predict the risk for the most vulnerable, predominantly older occupants.
The SAFER human body model (SHBM) represents an average sized male and includes a detailed ribcage model that has been validated for prediction of rib fracture risk in virtual crash simulations. Developments in parametric morphing of human body models have enabled re-shaping the SHBM to represent a wide range of body sizes for both adult males and females which can influence kinematic and injury risk predictions. The aim for this thesis was to enable the assessment of crash kinematics and rib fracture risk for the population of occupants by morphing the SHBM. Research was performed within objectives that included: providing a definition of the occupant population, creating morphed versions of the SHBM (MHBMs) and validating MHBM crash kinematic and rib fracture risk predictions within the defined population, develop a method to efficiently compute rib fracture risk across the population, and investigate factors beyond morphing that influences MHBM rib fracture risk predictions.
The population definition includes 90 % of the U.S.-population in terms of male and female height and weight variability. For validation, parametric morphing was used to create MHBMs geometrically matching age, sex, height, and weight of 22 human subjects in previous crash tests. Rib fracture risk and kinematic predictions from MHBMs were validated by comparison to test results and MHBMs showed good correlation for kinematics and had acceptable utility to predict rib fracture outcomes. However, the rib fracture risk for the most vulnerable, predominantly older, occupants was underestimated. One reason can be rib cortical bone microstructural defects, that are not represented by current SHBM rib material modeling.
To compute population rib fracture risk in crashes, a metamodeling method based on 25 differently sized MHBMs of each sex was recommended. Using this metamodeling method it was also identified that seven selected MHBMs of each sex can be used to predict the population risk across two specific crash scenarios. This indicates a possibility to identify a small family of MHBMs that are generally representative of population rib fracture risk in future work.
For further improving rib fracture risk predictions, a new rib fracture risk function was developed based on human rib test results. The new function is more sensitive to age compared to previous risk functions. Additionally, it was identified that the individual variability in rib cross-sectional width, as well as cortical bone thickness and material properties all substantially influence rib fracture risk predictions. Including the individual variability in these influential parameters in MHBM models will improve the capability of MHBMs to predict the rib fracture risk variability that exists in the population of occupants independently of sex, height, and weight.
It is concluded that MHBMs representing geometrical shape trends due to height, weight and sex, and individual rib local variability can be used to assess kinematics and rib fracture risk for wide range of males and females of different sizes. However, more research is needed to accurately predict the risk for the most vulnerable, predominantly older occupants.
crash
human body model
morphing
SAFER HBM
rib fracture risk
vehicle safety
Author
Karl-Johan Larsson
Chalmers, Mechanics and Maritime Sciences (M2), Vehicle Safety
Evaluation of a diverse population of morphed human body models for prediction of vehicle occupant crash kinematics
Computer Methods in Biomechanics and Biomedical Engineering,; Vol. 25(2022)p. 1125 -1155
Journal article
Larsson K-J, Östh J, Iraeus J, Pipkorn B. A First Step Towards a Family of Morphed Human Body Models Enabling Prediction of Population Injury Outcomes
Rib Cortical Bone Fracture Risk as a Function of Age and Rib Strain: Updated Injury Prediction Using Finite Element Human Body Models
Frontiers in Bioengineering and Biotechnology,; Vol. 9(2021)
Journal article
Influences of human thorax variability on population rib fracture risk prediction using human body models
Frontiers in Bioengineering and Biotechnology,; Vol. 11(2023)
Journal article
Human body models representing crash rib fracture risk for everyone
Fractured ribs remain a common and severe outcome in car crashes. Car crash safety has been developed mainly based on injury risk from crash test dummies representing three different sizes, both in physical crash tests and virtual crash simulations. In virtual crash safety evaluations, human body models (HBMs) representing human occupants are also used. This thesis aimed to enable rib fracture risk estimations in crashes for the population of occupants using HBMs. Based on population data, the SAFER HBM was reshaped by morphing to represent males and females of a wide range of heights and weights. Predictions from the morphed models were validated by comparing them to human crash test results. Methods to calculate the crash rib fracture risk for the population of occupants were evaluated. It was found that males and females, even of similar height and weight, do not have the same injury risk and that 25 differently sized occupant models of each sex are needed to represent the rib fracture risk outcome across the population in a crash. Beyond height, weight and sex, several other human factors that can influence rib fracture risk were investigated. It was found that individual variations in rib size, bone material and thickness have the most substantial influence on rib fracture risk. Morphed human body models representing human variability important for rib fracture risk can be used to develop cars and crash safety systems with a reduced rib fracture risk.
Fractured ribs remain a common and severe outcome in car crashes. Car crash safety has been developed mainly based on injury risk from crash test dummies representing three different sizes, both in physical crash tests and virtual crash simulations. In virtual crash safety evaluations, human body models (HBMs) representing human occupants are also used. This thesis aimed to enable rib fracture risk estimations in crashes for the population of occupants using HBMs. Based on population data, the SAFER HBM was reshaped by morphing to represent males and females of a wide range of heights and weights. Predictions from the morphed models were validated by comparing them to human crash test results. Methods to calculate the crash rib fracture risk for the population of occupants were evaluated. It was found that males and females, even of similar height and weight, do not have the same injury risk and that 25 differently sized occupant models of each sex are needed to represent the rib fracture risk outcome across the population in a crash. Beyond height, weight and sex, several other human factors that can influence rib fracture risk were investigated. It was found that individual variations in rib size, bone material and thickness have the most substantial influence on rib fracture risk. Morphed human body models representing human variability important for rib fracture risk can be used to develop cars and crash safety systems with a reduced rib fracture risk.
Assessment of Passenger Safety in Future Cars
VINNOVA (2017-01945), 2017-05-01 -- 2020-04-30.
Passagerarsäkerhet i bil - till nästa nivå
VINNOVA (2020-02943), 2020-11-01 -- 2023-10-31.
Subject Categories
Mechanical Engineering
Other Mechanical Engineering
Other Health Sciences
Driving Forces
Sustainable development
Innovation and entrepreneurship
Areas of Advance
Transport
ISBN
978-91-7905-836-4
Doktorsavhandlingar vid Chalmers tekniska högskola. Ny serie: 5302
Publisher
Chalmers