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Biomedical Engineering and Bioengineering Commons™
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Articles 1 - 3 of 3
Full-Text Articles in Biomedical Engineering and Bioengineering
Beating Human Induced Pluripotent Stem Cell-Derived Cardiomyocytes On Porcine Extracellular Matrix, Kaitlyn J. Mcentire, Alonzo Cook, Toph Knutson, Gevan Eldredge, Hunter Behrmann, Clayton Holding, Matthew Hodgson, Dillon Despain, Jacob Preslar, Joseph Rich, Matthew Stephens, Matthew Trone, Michael Neff, Sam Worrall, Joshua Mcclellan, Abbie Kondel, Donnie Pfeifer
Beating Human Induced Pluripotent Stem Cell-Derived Cardiomyocytes On Porcine Extracellular Matrix, Kaitlyn J. Mcentire, Alonzo Cook, Toph Knutson, Gevan Eldredge, Hunter Behrmann, Clayton Holding, Matthew Hodgson, Dillon Despain, Jacob Preslar, Joseph Rich, Matthew Stephens, Matthew Trone, Michael Neff, Sam Worrall, Joshua Mcclellan, Abbie Kondel, Donnie Pfeifer
Biomedical Engineering Western Regional Conference
Despite modern technology and developments in heart disease treatment and prevention, heart disease remains the number one cause of death in America. With an inability to meet an ever-increasing demand for heart transplants and the dangers of immunosuppressant drugs, any potential alternative to cardiac transplantation must be pursued. The end goal of this research is to engineer biocompatible tissues that are fully functional to repair or replace damaged portions of the heart following the loss of cardiac function. This research investigates the effect of porcine extracellular matrix as the scaffold for beating IPS-differentiated cardiomyocytes.
Design And Evaluation Of 3d Printed Features To Improve Stability Of Plasma-Cell Pack Interface In Bacteria Separating Hollow Spinning Disk, Colin G. Bledsoe, Ryan L. Wood, Daneil S. Mcclellan, Dr. William G. Pitt
Design And Evaluation Of 3d Printed Features To Improve Stability Of Plasma-Cell Pack Interface In Bacteria Separating Hollow Spinning Disk, Colin G. Bledsoe, Ryan L. Wood, Daneil S. Mcclellan, Dr. William G. Pitt
Biomedical Engineering Western Regional Conference
PDF submission of abstract.
Molecular Modeling Of Antibody-Antigen Binding Near Solid Surfaces, Derek Bush, Thomas Knotts
Molecular Modeling Of Antibody-Antigen Binding Near Solid Surfaces, Derek Bush, Thomas Knotts
Biomedical Engineering Western Regional Conference
Antibody microarrays are biosensors that have the potential to revolutionize molecular detection in medicine, scientific research, and national defense. However, current microarrays are not widely used due to problems including poor reproducibility and signal quality, unbalanced antibody performance, and cross-reactivity. Prior work in the area focused mainly on the stability of the antibody alone and not its affinity for its antigen. This presentation shows results of using molecular simulation to determine how different types of surfaces affect antigen binding to surface-tethered antibodies. The results offer an unprecedented, molecular-level view into these protein-protein-surface interactions and how to drive binding to occur.