Études de résistance mécanique et électrochimique de la biopile à des étirements de 20% en 2D direction. © Xiaohong Chen, Département de chimie moléculaire (CNRS/Université Grenoble Alpes)
Études de résistance mécanique et électrochimique de la biopile à des étirements de 20% en 2D direction. © Xiaohong Chen, Département de chimie moléculaire (CNRS/Université Grenoble Alpes)
Science and technology
Article
A unique new flexible and stretchable device, worn against the skin and capable of producing electrical energy by transforming the compounds present in sweat, was recently developed and patented by CNRS researchers from l’Université Grenoble Alpes and the UC San Diego (USA). This cell is already capable of continuously lighting an LED, opening new avenues for the development of wearable electronics powered by autonomous and environmentally friendly biodevices. This research was published in Advanced Functional Materials on September 25, 2019.
The potential uses for wearable electronic devices continue to increase, especially for medical and athletic monitoring. Such devices require the development of a reliable and efficient energy source that can easily be integrated into the human body. Using “biofuels” present in human organic liquids has long been a promising avenue.

Scientists from the Département de chimie moléculaire (CNRS/Université Grenoble Alpes), who specialize in bioelectrochemistry, decided to collaborate with an American team from the UC San Diego, who are experts in nanomachines, biosensors, and nanobioelectronics. Together they developed a flexible conductive material consisting of carbon nanotubes, crosslinked polymers, and enzymes joined by stretchable connectors that are directly printed onto the material through screen-printing [1].

The biofuel cell, which follows deformations in the skin, produces electrical energy through the reduction of oxygen and the oxidation of the lactate present in perspiration. Once applied to the arm, it uses a voltage booster to continuously power an LED. It is relatively simple and inexpensive to produce, with the primary cost being the production of the enzymes that transform the compounds found in sweat. The researchers are now seeking to amplify the voltage provided by the biofuel cell in order to power larger portable devices.

etude
Study of the biofuel cell’s mechanical and electrochemical resistance under 20% stretching in 2D directions. © Xiaohong Chen, Département de chimie moléculaire (CNRS/Université Grenoble Alpes)
Image de la biopile portable collée sur un bras et alimentant une diode fixée sur le brassard noir entourant l’avant-bras. © Xiaohong Chen, Département de chimie moléculaire (CNRS/Université Grenoble Alpes)
Image of the wearable biofuel cell applied to the arm, powering a diode attached to the black armband on the forearm. © Xiaohong Chen, Département de chimie moléculaire (CNRS/Université Grenoble Alpes)

Notes

[1] Brevets :
  • F. Giroud, A. J. Gross, S. Cosnier. Bioelectrode for the detection and/or oxidation of glucose and its manufacturing process and device comprising it. French patent n° 1662997 submitted December 21, 2016 . Published 22 June 2018. Extension PCT n°PCT/FR2017053689 submitted December 21, 2017. Published PCT n° WO2018115710A1 28 June 2018.. Applicants: CNRS
    S. Cosnier, R. Haddad. Electrochemical reactor block. French patent n° 1559069 submitted September 25, 2015 ; n°3041819. Published March 31, 2017. Extension Europe, USA, Japan n°16777723.4 ; FR20160552310 ; submitted September 14, 2016.. Applicants: Université Joseph Fourier and CNRS
Publié le September 25, 2019
Mis à jour le September 27, 2019

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