Your search keyword '"Sean P. Sanford"' showing total 4 results

1. Joint Moment Responses to Different Modes of Augmented Visual Feedback of Joint Kinematics during Two-Legged Squat Training

Author

Raviraj Nataraj, Sean Patrick Sanford, and Mingxiao Liu

Subjects

augmented visual feedback, motor rehabilitation, locomotion training, two-legged squat, Mechanics of engineering. Applied mechanics, TA349-359, Descriptive and experimental mechanics, QC120-168.85

Abstract

This study examined the effects of different modes of augmented visual feedback of joint kinematics on the emerging joint moment patterns during the two-legged squat maneuver. Training with augmented visual feedback supports improved kinematic performance of maneuvers related to sports or daily activities. Despite being representative of intrinsic motor actions, joint moments are not traditionally evaluated with kinematic feedback training. Furthermore, stabilizing joint moment patterns with physical training is beneficial to rehabilitating joint-level function (e.g., targeted strengthening and conditioning of muscles articulating that joint). Participants were presented with different modes of augmented visual feedback to track a target squat-motion trajectory. The feedback modes varied along features of complexity (i.e., number of segment trajectories shown) and body representation (i.e., trajectories shown as sinusoids versus dynamic stick-figure avatars). Our results indicated that mean values and variability (trial-to-trial standard deviations) of joint moments are significantly (p < 0.05) altered depending on the visual feedback features being applied, the specific joint (ankle, knee, hip), and the squat movement phase (early, middle, or late time window). This study should incentivize more optimal delivery of visual guidance during rehabilitative training with computerized interfaces (e.g., virtual reality).

Published

2023

2. Comparison of Human and Bovine Insulin Amyloidogenesis under Uniform Shear

Author

Amir Hirsa, Samantha A. McBride, Peter M. Tessier, Christopher F. Tilger, and Sean P. Sanford

Subjects

Models, Molecular, Amyloid, medicine.medical_treatment, Kinetics, Nucleation, macromolecular substances, Fibril, Protein Structure, Secondary, Materials Chemistry, medicine, Animals, Humans, Insulin, Physical and Theoretical Chemistry, Couette flow, Bovine insulin, Chemistry, Surfaces, Coatings and Films, Shear (geology), Hydrodynamics, Biophysics, Cattle, Protein Multimerization, Elongation, Shear Strength

Abstract

A diverse range of proteins can assemble into amyloid fibrils, a process that generally results in a loss of function and an increase in toxicity. The occurrence and rate of conversion is strongly dependent on several factors including molecular structure and exposure to hydrodynamic forces. To investigate the origins of shear-induced enhancement in the rate of fibrillization, a stable rotating Couette flow was used to evaluate the kinetics of amyloid formation under uniform shear for two similar insulin species (human and bovine) that demonstrate unique fibrillization kinetics. The presence of shear-induced nuclei predicted by previous studies is supported by observations of a lag between the consumption of soluble insulin and the precipitation of amyloid aggregates. The apparent fibrillization rate generally increases with shear. However, a two-parameter kinetic model revealed that the nucleation rate has a maximum value at intermediate shear rates. The fibril elongation rate increases monotonically with shear and is similar for both insulin variants, suggesting that increased elongation rates are related to mixing. Differences between human and bovine insulin kinetics under shear are attributable to the nucleation step.

Published

2015

3. Surface shear viscosity as a macroscopic probe of amyloid fibril formation at a fluid interface

Author

Aditya Raghunandan, Samantha A. McBride, Vignesh S. Balaraj, Philip C. H. Zeng, Amir Hirsa, Juan Lopez, and Sean P. Sanford

Subjects

0301 basic medicine, Shearing (physics), Circular dichroism, Materials science, Viscometer, General Chemistry, 010402 general chemistry, Condensed Matter Physics, Fibril, 01 natural sciences, 0104 chemical sciences, Shear rate, 03 medical and health sciences, Crystallography, 030104 developmental biology, Rheology, Shear (geology), Chemical physics, Newtonian fluid

Abstract

Amyloidogenesis of proteins is of wide interest because amyloid structures are associated with many diseases, including Alzheimer's and type II diabetes. Dozens of different proteins of various sizes are known to form amyloid fibrils. While there are numerous studies on the fibrillization of insulin induced by various perturbations, shearing at fluid interfaces has not received as much attention. Here, we present a study of human insulin fibrillization at room temperature using a deep-channel surface viscometer. The hydrodynamics of the bulk flow equilibrates in just over a minute, but the proteins at the air-water interface exhibit a very slow development during which the surface (excess) shear viscosity deduced from a Newtonian surface model increases slightly over a period of a day and a half. Then, there is a very rapid increase in the surface shear viscosity to effectively unbounded levels as the interface becomes immobilized. Atomic force microscopy shows that fibrils appear at the interface after it becomes immobilized. Fibrillization in the bulk does not occur until much later. This has been verified by concurrent atomic force microscopy and circular dichroism spectroscopy of samples from the bulk. The immobilized interface has zero in-plane shear rate, however due to the bulk flow, there is an increase in the strength of the normal component of the shear rate at the interface, implicating this component of shear in the fibrillization process ultimately resulting in a thick weave of fibrils on the interface. Real-time detection of fibrillization via interfacial rheology may find utility in other studies of proteins at sheared interfaces.

Published

2017

4. Shear-induced amyloid fibrillization: the role of inertia

Author

Amir Hirsa, Sean P. Sanford, Juan Lopez, and Samantha A. McBride

Subjects

Amyloid, media_common.quotation_subject, Kinetics, 02 engineering and technology, 010402 general chemistry, Inertia, Fibril, 01 natural sciences, Meridional circulation, chemistry.chemical_compound, Humans, Insulin, media_common, Shearing (physics), Protein species, General Chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 0104 chemical sciences, Crystallography, Monomer, chemistry, Shear (geology), Biophysics, Hydrodynamics, 0210 nano-technology, Hydrophobic and Hydrophilic Interactions

Abstract

Agitation of protein is known to induce deleterious effects on protein stability and structure, with extreme agitation sometimes resulting in complete aggregation into amyloid fibrils. Many mechanisms have been proposed to explain how protein becomes unstable when subjected to flow, including alignment of protein species, shear-induced unfolding, simple mixing, or fragmentation of existing fibrils to create new seeds. Here a shearing flow was imposed on a solution of monomeric human insulin via a rotating Couette device with a small hydrophobic fluid interface. The results indicate that even very low levels of shear are capable of accelerating amyloid fibril formation. Simulations of the flow suggest that the shear enhances fibrillization kinetics when flow inertia is non-negligible and the resulting meridional circulation allows for advection of bulk protein to the hydrophobic interface.

Published

2016