Your search keyword '"Donlon JP"' showing total 4 results

1. Fiber-based modeling of in situ ankle ligaments with consideration of progressive failure.

Author

Nie B, Forman JL, Panzer MB, Mait AR, Donlon JP, and Kent RW

Subjects

Adult, Ankle Injuries physiopathology, Biomechanical Phenomena, Humans, Ligaments, Articular physiopathology, Male, Sprains and Strains physiopathology, Ankle physiopathology, Ligaments, Articular injuries, Models, Biological

Abstract

Ligament sprains account for a majority of injuries to the foot and ankle complex among athletic populations. The infeasibility of measuring the in situ response and load paths of individual ligaments has precluded a complete characterization of their mechanical behavior via experiment. In the present study a fiber-based modeling approach of in situ ankle ligaments was developed and validated for determining the heterogeneous force-elongation characteristics and the consequent injury patterns. Nine major ankle ligaments were modeled as bundles of discrete elements, corresponding functionally to the structure of collagen fibers. To incorporate the progressive nature of ligamentous injury, the limit strain at the occurrence of fiber failure was described by a distribution function ranging from 12% to 18% along the width of the insertion site. The model was validated by comparing the structural kinetic and kinematic response obtained experimentally and computationally under well-controlled foot rotations. The simulation results replicated the 6 degree-of-freedom bony motion and ligamentous injuries and, by implication, the in situ deformations of the ligaments. Gross stiffness of the whole ligament derived from the fibers was comparable to existing experimental data. The present modeling approach provides a biomechanically realistic, interpretable and computationally efficient way to characterize the in situ ligament slack, sequential and heterogeneous uncrimping of collagen fascicles and failure propagation as the external load is applied. Applications of this model include functional ankle joint mechanics, injury prevention and countermeasure design for athletes., (Copyright © 2017 Elsevier Ltd. All rights reserved.)

Published

2017

2. Transient and long-time kinetic responses of the cadaveric leg during internal and external foot rotation.

Author

Mait AR, Mane A, Forman JL, Donlon JP, Nie B, and Kent RW

Subjects

Adult, Ankle Joint physiology, Cadaver, Humans, Kinetics, Knee Joint physiology, Male, Middle Aged, Range of Motion, Articular, Rotation, Subtalar Joint physiology, Bones of Lower Extremity physiology, Foot physiology

Abstract

The purpose of this study was to determine the long-time and transient characteristics of the moment generated by external (ER) and internal (IR) rotation of the calcaneus with respect to the tibia. Two human cadaver legs were disarticulated at the knee joint while maintaining the connective tissue between the tibia and fibula. An axial rotation of 21° was applied to the proximal tibia to generate either ER or IR while the fibula was unconstrained and the calcaneus was permitted to translate in the transverse plane. These boundary conditions were intended to allow natural motion of the fibula and for the effective applied axis of rotation to move relative to the ankle and subtalar joints based on natural articular motions among the tibia, fibula, talus, and calcaneus. A load cell at the proximal tibia measured all components of force and moment. A quasi-linear model of the moment along the tibia axis was developed to determine the transient and long-time loads generated by this ER/IR. Initially neutral, everted, inverted, dorsiflexed, and plantarflexed foot orientations were tested. For the neutral position, the transient elastic moment was 16.5N-m for one specimen and 30.3N-m for the other in ER with 26.3 and 32.1N-m in IR. The long-time moments were 5.5 and 13.2N-m (ER) and 9.0 and 9.5N-m (IR). These loads were found to be transient over time similar to previous studies on other biological structures where the moment relaxed as time progressed after the initial ramp in rotation., (Copyright © 2017 Elsevier Ltd. All rights reserved.)

Published

2017

3. Development of a computational framework to adjust the pre-impact spine posture of a whole-body model based on cadaver tests data.

Author

Poulard D, Subit D, Donlon JP, and Kent RW

Subjects

Biomechanical Phenomena, Cadaver, Finite Element Analysis, Humans, Models, Theoretical, Wounds and Injuries pathology, Computer Simulation, Head anatomy & histology, Models, Biological, Pelvis anatomy & histology, Posture, Spine anatomy & histology

Abstract

A method was developed to adjust the posture of a human numerical model to match the pre-impact posture of a human subject. The method involves pulling cables to prescribe the position and orientation of the head, spine and pelvis during a simulation. Six postured models matching the pre-impact posture measured on subjects tested in previous studies were created from a human numerical model. Posture scalars were measured on pre- and after applying the method to evaluate its efficiency. The lateral leaning angle θL defined between T1 and the pelvis in the coronal plane was found to be significantly improved after application with an average difference of 0.1±0.1° with the PMHS (4.6±2.7° before application). This method will be applied in further studies to analyze independently the contribution of pre-impact posture on impact response using human numerical models., (Copyright © 2015 Elsevier Ltd. All rights reserved.)

Published

2015

4. Understanding how pre-impact posture can affect injury outcome in side impact sled tests using a new tool for visualization of cadaver kinematics.

Author

Donlon JP, Poulard D, Lessley D, Riley P, and Subit D

Subjects

Adult, Biomechanical Phenomena, Cadaver, Humans, Incidence, Male, Scapula injuries, Accidents, Traffic, Imaging, Three-Dimensional methods, Posture, Shoulder Fractures epidemiology

Abstract

The effect of posture and subject-specific factors on injury outcome is an active field of research in injury biomechanics, in particular in automotive safety research where post-mortem human subjects (PMHS) are used as surrogates. Current PMHS tests routinely include acquisition of the subjects׳ geometry and kinematics. However, combining these two datasets to better understand the injury mechanism is still a challenge. This study investigated the connection between pre-impact posture and resulting injuries in six previously published side impact sled tests (three with a rigid wall and three with an airbag) by creating three-dimensional kinematic animations (3DKA) of the tests. The 3DKA allow qualitative assessment of parameters related to posture and their possible effect on injury outcome. The orientation of the struck scapula and the lateral leaning of the torso were identified as potentially significant parameters. The ranges of variation in these parameters were quantified and compared to the number of rib fractures for each subject: the data suggested a correlation, but there was insufficient data for a probabilistic analysis. The 3DKA were published with this study and are freely available., (Copyright © 2015 Elsevier Ltd. All rights reserved.)

Published

2015