Inkjet-printed O2 gas sensors in intelligent packaging
MetadataShow full item record
AuthorFernández Ramos, María Dolores; Pageo Cabrera, María; Capitán Vallvey, Luis Fermín; Pérez de Vargas Sansalvador, Isabel María
Royal Society of Chemistry
Analyst, 2021, 146, 3177. [https://doi.org/10.1039/d1an00295c]
SponsorshipSpanish Ministerio de Economia y Competitividad PID2019-103938RB-I00 CTQ2017-86125-P; Junta de Andalucia B-FQM-243-UGR18 P18-RT-2961; European Commission
An inkjet printed membrane is presented as a colorimetric sensor for oxygen for use in smart packaging, in order to quickly inform the consumer about possible degradation reactions in modified atmosphere products (MAP). The colorimetric sensor is based on the redox dye, toluidine blue (TB), a sacrificial electron donor, glycerol, and, hydroxypropyl methylcellulose, as the hydrophilic polymeric matrix. The UVC-wavelength activated TB is photoreduced by SnO2 nanoparticle ink. This colorimetric oxygen indicator stays colourless upon exposure in nitrogen atmosphere to 7 min UVC light (6 W center dot cm(-2)). The photoreduced TB to leuco TB recovers its original colour upon exposure to oxygen for 55 min under ambient conditions (similar to 21 degrees C, similar to 55%RH, 21% O-2). The characteristics of the sensor have been evaluated, including its functionality through the colorimetric response to different oxygen concentrations as well as the influence of experimental variables such as humidity and temperature using a digital camera as the detector. The results obtained show that: (1) the colorimetric sensor remains stable in the absence of oxygen; (2) relative humidity greater than 60% significantly affects the reoxidation process; and (3) the temperature has a significant influence on the colour recovery, although the stability increases considerably when the sensor is kept refrigerated at 4 degrees C. A real application to packaged ham was performed, demonstrating that the printed colorimetric sensor is stable for at least 48 hours once activated and when the container deteriorates upon the entrance of oxygen, the sensor returns to its original blue colour, demonstrating its utility as a UVC-activated colorimetric oxygen sensor.