Printable graphene-sustainable elastomer-based cross talk free sensor for point of care diagnostics
Printable graphene-sustainable elastomer-based cross talk free sensor for point of care diagnostics
Developing sensors for monitoring physiological parameters such as temperature and strain for point of care (POC) diagnostics is critical for better care of the patients. Various commercial sensors are available to get the job done; however, challenges like the structural rigidity of such sensors confine their usage. As an alternative, flexible sensors have been looked upon recently. In most cases, flexible sensors cannot discriminate the signals from different stimuli. While there have been reports on the printable sensors providing cross-talk-free solutions, research related to developing sensors from a sustainable source providing discriminability between signals is not well-explored. Herein, we report the development of a stencil printable composition made of graphene and epoxidized natural rubber. The stencil printability index was vetted using rheological studies. Post usage, the developed sensor was dissolved in an organic solvent at room temperature. This, along with the choice of a sustainable elastomer, warrants the minimization of electronic waste and carbon footprint. The developed material demonstrated good conformability with the skin and could perceive and decouple the signals from temperature and strain without inducing any crosstalks. Using a representative volume element model, a comparison between experimental findings and computation studies was made. The developed sensors demonstrated gauge factors of −506 and 407 in the bending strain regimes of 0–0.04% and 0.04%–0.09%, respectively, while the temperature sensitivity was noted to be −0.96%/°C. The printed sensors demonstrated a multifunctional sensing behavior for monitoring various active physiological parameters ranging from temperature, strain, pulse, and breathing to auditory responses. Using a Bluetooth module, various parameters like temperature and strain could be monitored seamlessly in a smart-phone. The current development would be crucial to open new avenues to fabricate crosstalk-free sensors from sustainable sources for POC diagnostics.
Sharma, Simran
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Selvan, Muthamil
da68d407-8d0a-476c-bb91-6fb4884b5997
Naskar, Susmita
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Mondal, Soumyadeep
b643e343-6976-4153-9763-f13b529ba995
Adhya, Pragyadipta
a06b6786-f391-40e4-878c-fd4371dd41bd
Mukhopadhyay, Tanmoy
2ae18ab0-7477-40ac-ae22-76face7be475
Mondal, Titash
39e1681f-837c-48ac-b529-0eebf63697cb
15 December 2022
Sharma, Simran
9214a1a7-22c8-4208-8e56-955daf0facec
Selvan, Muthamil
da68d407-8d0a-476c-bb91-6fb4884b5997
Naskar, Susmita
5f787953-b062-4774-a28b-473bd19254b1
Mondal, Soumyadeep
b643e343-6976-4153-9763-f13b529ba995
Adhya, Pragyadipta
a06b6786-f391-40e4-878c-fd4371dd41bd
Mukhopadhyay, Tanmoy
2ae18ab0-7477-40ac-ae22-76face7be475
Mondal, Titash
39e1681f-837c-48ac-b529-0eebf63697cb
Sharma, Simran, Selvan, Muthamil, Naskar, Susmita, Mondal, Soumyadeep, Adhya, Pragyadipta, Mukhopadhyay, Tanmoy and Mondal, Titash
(2022)
Printable graphene-sustainable elastomer-based cross talk free sensor for point of care diagnostics.
ACS Applied Materials and Interfaces.
(doi:10.1021/acsami.2c17805).
Abstract
Developing sensors for monitoring physiological parameters such as temperature and strain for point of care (POC) diagnostics is critical for better care of the patients. Various commercial sensors are available to get the job done; however, challenges like the structural rigidity of such sensors confine their usage. As an alternative, flexible sensors have been looked upon recently. In most cases, flexible sensors cannot discriminate the signals from different stimuli. While there have been reports on the printable sensors providing cross-talk-free solutions, research related to developing sensors from a sustainable source providing discriminability between signals is not well-explored. Herein, we report the development of a stencil printable composition made of graphene and epoxidized natural rubber. The stencil printability index was vetted using rheological studies. Post usage, the developed sensor was dissolved in an organic solvent at room temperature. This, along with the choice of a sustainable elastomer, warrants the minimization of electronic waste and carbon footprint. The developed material demonstrated good conformability with the skin and could perceive and decouple the signals from temperature and strain without inducing any crosstalks. Using a representative volume element model, a comparison between experimental findings and computation studies was made. The developed sensors demonstrated gauge factors of −506 and 407 in the bending strain regimes of 0–0.04% and 0.04%–0.09%, respectively, while the temperature sensitivity was noted to be −0.96%/°C. The printed sensors demonstrated a multifunctional sensing behavior for monitoring various active physiological parameters ranging from temperature, strain, pulse, and breathing to auditory responses. Using a Bluetooth module, various parameters like temperature and strain could be monitored seamlessly in a smart-phone. The current development would be crucial to open new avenues to fabricate crosstalk-free sensors from sustainable sources for POC diagnostics.
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Accepted/In Press date: 30 November 2022
Published date: 15 December 2022
Identifiers
Local EPrints ID: 475675
URI: http://eprints.soton.ac.uk/id/eprint/475675
ISSN: 1944-8244
PURE UUID: 0447a459-cf62-416e-b275-83cea3a5f85e
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Date deposited: 24 Mar 2023 17:30
Last modified: 17 Mar 2024 04:18
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Contributors
Author:
Simran Sharma
Author:
Muthamil Selvan
Author:
Soumyadeep Mondal
Author:
Pragyadipta Adhya
Author:
Tanmoy Mukhopadhyay
Author:
Titash Mondal
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