December 1 - 6, 2024
Boston, Massachusetts
Symposium Supporters
2024 MRS Fall Meeting & Exhibit
EL03.01.02

Graphene Multiplexed Sensor for Point-of-Need Viral Wastewater-Based Epidemiology

When and Where

Dec 2, 2024
11:00am - 11:15am
Sheraton, Second Floor, Back Bay C

Presenter(s)

Co-Author(s)

Michael Geiwitz1,Owen Page1,Tio Marello1,Marina Nichols1,Narendra Kumar2,1,Stephen Hummel3,1,Vsevolod Belosovich1,Qiong Ma1,Tim van Opijnen4,1,Bruce Batten2,Michelle Meyer1,Kenneth Burch1

Boston College1,GRIP Molecular, Inc2,United States Military Academy3,Boston Children's Hospital4

Abstract

Michael Geiwitz1,Owen Page1,Tio Marello1,Marina Nichols1,Narendra Kumar2,1,Stephen Hummel3,1,Vsevolod Belosovich1,Qiong Ma1,Tim van Opijnen4,1,Bruce Batten2,Michelle Meyer1,Kenneth Burch1

Boston College1,GRIP Molecular, Inc2,United States Military Academy3,Boston Children's Hospital4
Wastewater-based epidemiology (WBE) can help mitigate the spread of respiratory infections through the early detection of viruses, pathogens, and other biomarkers in human waste. The need for sample collection, shipping, and testing facilities drives up the cost of WBE and hinders its use for rapid detection and isolation in environments with small populations and in low-resource settings. Given the ubiquitousness and regular outbreaks of respiratory syncytial virus, SARS-CoV-2, and various influenza strains, there is a rising need for a low-cost and easy-to-use biosensing platform to detect these viruses locally before outbreaks can occur and monitor their progression. To this end, we have developed an easy-to-use, cost-effective, multiplexed platform able to detect viral loads in wastewater with several orders of magnitude lower limit of detection than mass spectrometry. This is enabled by wafer scale production and aptamers pre-attached with linker molecules, producing forty-four chips at once. Each chip can simultaneously detect four target analytes using twenty transistors segregated into four sets of five for each analyte to allow for immediate statistical analysis. We show our platform’s ability to rapidly detect three virus proteins (SARS-CoV-2, RSV, and Influenza A) and a population normalization molecule (caffeine) in wastewater. Going forward, turning these devices into hand-held systems would enable waste-water epidemiology in low-resource settings and be instrumental for rapid, local outbreak prevention.

Symposium Organizers

Deji Akinwande, The University of Texas at Austin
Cinzia Casiraghi, University of Manchester
Carlo Grazianetti, CNR-IMM
Li Tao, Southeast University

Session Chairs

Chandan Biswas
Li Tao

In this Session