Your search keyword '"Sebastian Bawab"' showing total 8 results

1. Computational Assessment of Neural Probe and Brain Tissue Interface under Transient Motion

Author

Michael Polanco, Sebastian Bawab, and Hargsoon Yoon

Subjects

neural electrodes, brain, finite element analysis, viscoelasticity, Biotechnology, TP248.13-248.65

Abstract

The functional longevity of a neural probe is dependent upon its ability to minimize injury risk during the insertion and recording period in vivo, which could be related to motion-related strain between the probe and surrounding tissue. A series of finite element analyses was conducted to study the extent of the strain induced within the brain in an area around a neural probe. This study focuses on the transient behavior of neural probe and brain tissue interface with a viscoelastic model. Different stages of the interface from initial insertion of neural probe to full bonding of the probe by astro-glial sheath formation are simulated utilizing analytical tools to investigate the effects of relative motion between the neural probe and the brain while friction coefficients and kinematic frequencies are varied. The analyses can provide an in-depth look at the quantitative benefits behind using soft materials for neural probes.

Published

2016

2. A comparison of intervertebral ligament properties utilized in a thoracic spine functional unit through kinematic evaluation

Author

Michael Polanco, Stacie Ringleb, Michel Audette, Rumit Kakar, and Sebastian Bawab

Subjects

Human-Computer Interaction, Biomedical Engineering, Bioengineering, General Medicine, Computer Science Applications

Abstract

Ligament properties in the literature are variable, yet scarce, but needed to calibrate computational models for spine clinical research applications. A comparison of ligament stiffness properties and their effect on the kinematic behavior of a thoracic functional spinal unit (FSU) is examined in this paper. Six unique ligament property sets were utilized within a volumetric T7-T8 finite element (FE) model developed using computer-aided design (CAD) spinal geometry. A 7.5 Nm moment was applied along three anatomical planes both with and without costovertebral (CV) joints present. Range of Motion (RoM) was assessed for each property set and compared to published experimental data. Intact and serial ligament removal procedures were implemented in accordance with experimental protocol. The variance in both kinematic behavior and comparability with experimental data among property sets emphasizes the role nonlinear characterization plays in determining proper kinematic behavior in spinal FE models. Additionally, a decrease in RoM variation among property sets was exhibited when the model setup incorporated the CV joint. With proper assessment of the source and size of each ligament, the material properties considered here could be expanded and justified for implementation into thoracic spine clinical studies.

Published

2022

3. Load sharing assessment of osseoligamentous structures within a thoracic spine segment during surgical release

Author

Michael Polanco, James Bennett, Austin Tapp, Michel Audette, Stacie Ringleb, and Sebastian Bawab

Abstract

Spinal surgical procedures often require release of intervertebral discs and ligaments to optimally achieve postural correction on a patient-specific basis. In this paper, a T7-T8 Finite Element (FE) model is utilized to examine internal load sharing during resection steps performed in a Ponte osteotomy. The FE model was rotated bidirectionally along three anatomical planes using an externally applied moment. In each step, the Ranges of Motion (RoM), Instantaneous Centers of Rotation (ICR), and forces from ligaments, discs, facet, and costovertebral joints were calculated. The product of each component’s force and the distance between the ICR and their position were used to calculate percent load sharing at the maximum moment magnitude. Removal of the facet joints accounts for overall significant increases in load sharing to the intervertebral disc, with maximum values reported in extension by approximately 18 percent and axial rotation by 16 percent. This study highlights key spine components whose kinematic influence may be considered to achieve desired surgical outcomes.

Published

2022

4. Generating Scoliotic Computed Tomography Volumes from Finite Element Spine Models

Author

Austin Tapp, Michael Polanco, Isaac Kumi, Sebastian Bawab, Stacie Ringleb, Rumit Kakar, Carl St. Remy, James Bennett, and Michel Audette

Published

2022

5. Examination of Intervertebral Ligament Property Sensitivity on a Thoracic Spine Functional Unit

Author

Michael Polanco, Sebastian Bawab, Stacie Ringleb, Michel Audette, and Rumit Kakar

Subjects

History, Polymers and Plastics, Business and International Management, Industrial and Manufacturing Engineering

Published

2021

6. Generation of Patient-Specific, Ligamentoskeletal, Finite Element Meshes for Scoliosis Correction Planning

Author

Austin Tapp, Christian Payer, Jérôme Schmid, Michael Polanco, Isaac Kumi, Sebastian Bawab, Stacie Ringleb, Carl St. Remy, James Bennett, Rumit Singh Kakar, and Michel Audette

Published

2021

7. System Design And Integration For Repeated Impact Tests

Author

Cheng Lin, Gene Hou, Sebastian Bawab, Timothy Coats, and Hesham Nassar

Published

2020

8. The effects of a semi-rigid ankle brace on a simulated isolated subtalar joint instability

Author

Julie, Choisne, Matthew C, Hoch, Sebastian, Bawab, Ian, Alexander, and Stacie I, Ringleb

Subjects

Joint Instability, Male, Braces, Humans, Subtalar Joint, Female, Middle Aged, Range of Motion, Articular, Lateral Ligament, Ankle, Aged, Biomechanical Phenomena

Abstract

Subtalar joint instability is hypothesized to occur after injuries to the calcaneofibular ligament (CFL) in isolation or in combination with the cervical and the talocalcaneal interosseous ligaments. A common treatment for hindfoot instability is the application of an ankle brace. However, the ability of an ankle brace to promote subtalar joint stability is not well established. We assessed the kinematics of the subtalar joint, ankle, and hindfoot in the presence of isolated subtalar instability, investigated the effect of bracing in a CFL deficient foot and with a total rupture of the intrinsic ligaments, and evaluated how maximum inversion range of motion is affected by the position of the ankle in the sagittal plane. Kinematics from nine cadaveric feet were collected with the foot placed in neutral, dorsiflexion, and plantar flexion. Motion was applied with and without a brace on an intact foot and after sequentially sectioning the CFL and the intrinsic ligaments. Isolated CFL sectioning increased ankle joint inversion, while sectioning the CFL and intrinsic ligaments affected subtalar joint stability. The brace limited inversion at the subtalar and ankle joints. Additionally, examining the foot in dorsiflexion reduced ankle and subtalar joint motion.

Published

2013