Veryst is proud to have supported 3D BioLabs LLC with a study described in its recent publication titled “Rodent Model for Orthotopic Implantation of Engineered Liver Devices.” The publication presents a novel surgical technique to provide blood supply to implanted cellularized devices that augment or replace liver tissue function.
Veryst's simulation capabilities—and work from Dr. Alireza Kermani—were again highlighted in a recent COMSOL blog titled "Designing Effective Transdermal Drug Delivery Patches with Simulation."
Allyson Hartzell was invited to be a judge at the iMatSci Innovator Showcase, part of the 2016 MRS [Materials Research Society] Fall Meeting & Exhibit. The Showcase took place November 28-30, 2016 in Boston, MA. MRS describes the e
Allyson Hartzell shared her expertise in a webinar titled “Ask the Experts: Technology Transfer.” Hosted by the MEMS & Sensors Industry Group (MSIG), this webinar provided an opportunity for MSIG members to communicate directly with a panel of industry experts to get answers and insight into technical MEMS and sensors issues.
Dr. Nagi Elabbasi spoke about "Challenges in Radio Frequency Tissue Ablation Simulations at the 2016 NAFEMS European Multiphysics Conference. Veryst has developed computational models that illustrate the sensitivity of RF thermal ablation response and highlight the importance of model validation.
Dr. Sean Teller spoke about “A New High Strain-Rate Biaxial Experiment to Validate Constitutive Models for Polymers” and about “Fracture Testing and Cohesive Zone Modeling of Automotive Adhesives” at ASME IMECE.
"Stress-free Simulation: The Art of Accurate Polymer Modelling" is the title of an article by Veryst's Eric Schmitt and Jorgen Bergstrom. The article appears in the October 2016 issue of Benchmark magazine, published by NAFEMS.
Dr. Mark Oliver spoke about “Experimentally Calibrating Cohesive Zone Models for Structural Automotive Adhesives” at the 2016 Adhesives & Sealant Convention.
Dr. Alireza Kermani spoke about “Using Computational Fluid Dynamics (CFD) to simulate airflow in a hospital room,” addressing forced and natural ventilation and the flow of bacteria particles originating from a sick patient.