Purdue University Graduate School
Browse
- No file added yet -

ENGINEERING DESIGN OF NOVEL 3D MICROPHYSIOLOGICAL SYSTEM AND SENSOR FOR FUNCTIONAL ASSESSMENT OF PANCREATIC BETA-CELLS

Download (9.43 MB)
thesis
posted on 2023-04-25, 19:13 authored by Emma VanderlaanEmma Vanderlaan

  

Diabetes, a chronic condition characterized by elevated blood glucose levels, arises when pancreatic β-cells lose capacity to produce a robust, dynamic glucose-stimulated insulin secretion (GSIS) response. Accurate measurement of β-cell health and function ex vivo is thus fundamental to diabetes research, including studies evaluating disease mechanisms, novel drug candidates, and replacement β-cell populations. However, present-day dynamic GSIS assays typically represent end-point measurements, involve expensive commercial perifusion machines, and require time-consuming enzyme-linked immunosorbent assays (ELISA) for insulin detection. Microfluidic devices developed as accessible, low-cost alternatives still rely on secondary ELISAs and suspend islets in liquid medium, limiting their survival in vitro. Here, we present a novel, 3D-printed microphysiological system (MPS) designed to recreate components of in-vivo microenvironments through encapsulation in fibrillar type I collagen and restoration of favorable molecular transport conditions. Following computational-informed design and rapid prototyping, the MPS platform sustained collagen-encapsulated mouse islet viability and cytoarchitecture for 5 days and supported in-situ measurements of dynamic β-cell function. To rapidly detect insulin secretion from β-cells in the MPS, we then developed a highly sensitive electrochemical sensor for zinc (Zn2+), co-released with insulin, based on glassy carbon electrodes modified with bismuth and indium and coated with Nafion. Finally, we validated sensor detection of Zn2+ released from glucose-stimulated INS-1 β-cells and primary mouse islets, finding high correlation with insulin as measured by standard ELISA. Together, the 3D MPS and Zn2+ sensor developed in this dissertation represent novel platforms for evaluating β-cell health and function in a low-cost, user-friendly, and physiologically-relevant manner. 

History

Degree Type

  • Doctor of Philosophy

Department

  • Biomedical Engineering

Campus location

  • West Lafayette

Advisor/Supervisor/Committee Chair

Sherry Voytik-Harbin

Additional Committee Member 2

Carmella Evans-Molina

Additional Committee Member 3

Hyowon Lee

Additional Committee Member 4

Adrian Buganza Tepole

Additional Committee Member 5

Luis Solorio