Brent Vernon
Associate Professor, School of Biological and Health Systems Engineering
Brent Vernon is an associate professor and undergraduate program chair in biomedical engineering in the School of Biological and Health Systems Engineering and the director of the Center for Interventional Biomaterials at Arizona State University. His research utilizes the principles of polymer science and chemistry to design and develop in situ gelling materials for drug delivery, tissue engineering and tissue reconstruction.
Spring 2024
Isabella Rachelle Matakas
Chemical engineering
Swelling Studies of PEG/PPG-Polyurethane Polymers for Medical Applications
Studying the swelling rate of different polymers at different temperatures over time will help with future biomedical applications.
Program: FURI
Tina Truc Ton
Biomedical engineering
Advancing Drug Delivery Systems: Building a Model for Thin Film Double-Layer Polyurethanes
Building a model to analyze thin film double-layer polymers will help with predicting drug releases to support future customized applications.
Program: FURI
Spring 2023
Tina Truc Ton
Biomedical engineering
Lower Critical Solution Temperatures of PEG-PPG Polyurethanes
Identifying the temperature at which PEG/PPG polyurethanes show a volume transition could lead to potential applications in drug delivery systems.
Program: FURI
Summer 2022
Gabriel Zdrale
Biomedical engineering
Optimization of PEG-Polyurethane Polymers for Biomedical Applications
Optimizing polymer material properties will allow for improvements in different biomedical applications such as tissue regeneration, heart valves and wound healing applications.
Program: MORE
Spring 2022
Gabriel Zdrale
Biomedical engineering
Synthesis and Characterization of PEG-Polyurethane for Biomedical Applications
Assessing the overall properties of PEG-Polyurethane will identify its possible regeneration capabilities in biomedical applications.
Program: FURI
Spring 2021
Priscilla Han
Biomedical engineering
Statistical Modeling of Drug Release from Spherical Surface-Degrading Particle Batch
Analyzing variation within microsphere batches and its effects on drug release will help dictate manufacturing parameters.
Program: FURI
Jinpyo Seo
Biomedical engineering
Microneedles for Basal Cell Carcinoma
Studying a transdermal delivery of a chemotherapy drug to bypass side effects and increase dose efficiency
Program: FURI
Fall 2020
Priscilla Han
Biomedical engineering
Creation of a Computational File for Calculating Drug Release from Degradable Spherical Gel Batch
Creating a computational file that identifies acceptable ranges for mean and standard deviation can streamline drug delivery approval processes.
Program: FURI
Michelle Loui
Biomedical engineering
Investigation of a polyether urethane-based polymer for promoting bone tissue healing
Developing a polyether urethane-based polymer will help create better treatments for repairing and promoting healing in the bone tissues of patients that have experienced major bone breaks and/or defects.
Program: MORE
Alicia Salas
Biomedical engineering
Investigating PEG-Polyurethane for Biomedical Applications
Evaluating the characteristics of PEG-Polyurethane will help determine its potential to optimize bone regeneration capabilities.
Program: FURI
Summer 2020
Alicia Salas
Biomedical engineering
Investigating PEG-Polyurethane as the Basis of Bone Scaffolding Technology
Evaluating the characteristics of PEG-Polyurethane will help determine its effectiveness in improving bone scaffolding technology.
Program: FURI
Spring 2020
Tori Johnson
Biomedical engineering
Silicon Netting for Surgical Organ Isolation
Using reusable silicon netting to assist with organ isolation and protection will help decrease surgery time and increase patient outcomes.
Program: FURI
Nathan S Hui
Biomedical engineering
Investigating Factors to Provide Sustained Release of Ketorolac in Temperature-Responsive Hydrogels
Designing safe drug delivery solutions for managing pain will help people find better alternatives to opioids.
Program: FURI
Michelle Loui
Biomedical engineering
Thermo-Responsive pNIPAAm-Based Polymers for Endovascular Brain Aneurysm Repair
Designing a thermo-responsive liquid embolic agent will create better methods of endovascular therapy for treating ruptured brain aneurysms.
Program: FURI
Jinpyo Seo
Biomedical engineering
Monodispersity of PLGA Microparticles
Analyzing the effect of size range on microparticles' ability to release drugs and naturally degrade will improve patient safety and satisfaction.
Program: FURI
Spring 2019
Michelle Loui
Biomedical engineering
Ultrasound-mediated Drug Delivery with Poly(N-isopropylacrylamide)-based Polymers
Designing a polymer that will break down when exposed to ultrasound will help create better methods of drug delivery in biological systems.
Program: FURI
Karolena Lein
Biomedical engineering
Ultrasound Cleavable Polymers for Reversible Vascular Embolization
Synthesizing a polymer that can be broken down with ultrasound will increase the safety and efficacy of embolization therapy.
Program: FURI
Tori Johnson
Biomedical engineering
Liquid Embolic Synthesis for Aneurysm Occlusion
Creating a biomaterial that degrades as tissue is regenerated will provide a better treatment for cerebral aneurysms.
Program: FURI
John Nate Gross
Biomedical engineering
Tyrosine Infused Micro Particles
Designing tyrosine-infused microparticles to raise metabolic rates will help treat conditions like hypothyroidism.
Program: FURI