Your search keyword '"Penner, Reginald M."' showing total 2 results

1. Electrochemical Quantification of Glycated and Non-glycated Human Serum Albumin in Synthetic Urine

Author

Attar, Aisha M, Richardson, Mark B, Speciale, Gaetano, Majumdar, Sudipta, Dyer, Rebekah P, Sanders, Emily C, Penner, Reginald M, and Weiss, Gregory A

Subjects

Analytical Chemistry, Engineering, Chemical Sciences, Diabetes, Biosensing Techniques, Electrochemical Techniques, Enzymes, Immobilized, Equipment Design, Glycation End Products, Advanced, Humans, Models, Biological, Serum Albumin, Serum Albumin, Human, Tetrahydrofolate Dehydrogenase, Glycated Serum Albumin, human serum albumin, glycated albumin, polythiophene, iminodiacetic acid, boronic acid, dihydrofolate reductase, biosensor, Nanoscience & Nanotechnology, Chemical sciences, Physical sciences

Abstract

A polymer-based electrode capable of specific detection of human serum albumin, and its glycated derivatives, is described. The sensor is constructed from a glass microscope slide coated with a synthesized, polythiophene film bearing a protected, iminodiacetic acid motif. The electrode surface is then further elaborated to a functional biosensor through deprotection of the iminodiacetic acid, followed by metal-affinity immobilization of a specific and high-affinity, albumin ligand. Albumin was then quantified in buffer and synthetic urine via electrochemical impedance spectroscopy. Glycated albumin was next bound to a boronic acid-modified, single-cysteine dihydrofolate reductase variant to quantify glycation ratios by square-wave voltammetry. The platform offers high sensitivity, specificity, and reproducibility in an inexpensive arrangement. The detection limits exceed the requirements for intermediate-term glycemic control monitoring in diabetes patients at 5 and 1 nM for albumin and its glycated forms, respectively.

Published

2019

2. The Virus Bioresistor: Wiring Virus Particles for the Direct, Label-Free Detection of Target Proteins

Author

Bhasin, Apurva, Ogata, Alana F, Briggs, Jeffrey S, Tam, Phillip Y, Tan, Ming X, Weiss, Gregory A, and Penner, Reginald M

Subjects

Data Management and Data Science, Information and Computing Sciences, Engineering, Bacteriophage M13, Biosensing Techniques, Electric Impedance, Equipment Design, Humans, Limit of Detection, Serum Albumin, Human, Virion, Bacteriophage, chemiresistor, biosensor, impedance, human serum albumin, Nanoscience & Nanotechnology

Abstract

The virus bioresistor (VBR) is a chemiresistor that directly transfers information from virus particles to an electrical circuit. Specifically, the VBR enables the label-free detection of a target protein that is recognized and bound by filamentous M13 virus particles, each with dimensions of 6 nm ( w) × 1 μm ( l), entrained in an ultrathin (∼250 nm) composite virus-polymer resistor. Signal produced by the specific binding of virus to target molecules is monitored using the electrical impedance of the VBR: The VBR presents a complex impedance that is modeled by an equivalent circuit containing just three circuit elements: a solution resistance ( Rsoln), a channel resistance ( RVBR), and an interfacial capacitance ( CVBR). The value of RVBR, measured across 5 orders of magnitude in frequency, is increased by the specific recognition and binding of a target protein to the virus particles in the resistor, producing a signal Δ RVBR. The VBR concept is demonstrated using a model system in which human serum albumin (HSA, 66 kDa) is detected in a phosphate buffer solution. The VBR cleanly discriminates between a change in the electrical resistance of the buffer, measured by Rsoln, and selective binding of HSA to virus particles, measured by RVBR. The Δ RVBR induced by HSA binding is as high as 200 Ω, contributing to low sensor-to-sensor coefficients-of-variation (

Published

2018