A plug, print & play inkjet printing and impedance-based biosensing technology operating through a smartphone for clinical diagnostics

Simplicity is one of the key feature for the spread of any successful technological product. Here, a method for rapid and low-cost fabrication of electrochemical biosensors is presented. This “plug, print & play” method involves inkjet-printing even in an office-like environment, without the nee...

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Bibliographic Details
Published in:Biosensors & bioelectronics 2022-01, Vol.196, p.113737-113737, Article 113737
Main Authors: Rosati, Giulio, Urban, Massimo, Zhao, Lei, Yang, Qiuyue, de Carvalho Castro e Silva, Cecilia, Bonaldo, Stefano, Parolo, Claudio, Nguyen, Emily P., Ortega, Gabriel, Fornasiero, Paolo, Paccagnella, Alessandro, Merkoçi, Arben
Format: Article
Language:English
Subjects:
Aptasensors
Biosensing Techniques
Electric Impedance
Electrodes
Flexible electronics
Impedimetric biosensors
Inkjet-printed sensors
Nanofunctional inks
Smartphone
Smartphone readout
Technology
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Summary:Simplicity is one of the key feature for the spread of any successful technological product. Here, a method for rapid and low-cost fabrication of electrochemical biosensors is presented. This “plug, print & play” method involves inkjet-printing even in an office-like environment, without the need of highly specialized expertise or equipment, guaranteeing an ultra-fast idea to (scaled) prototype production time. The printed biosensors can be connected to a smartphone through its audio input for their impedance readout, demonstrating the validity of the system for point-of-care biosensing. Proper electrodes layout guarantees high sensitivity and is validated by finite element simulations. The introduction of a passivation method (wax printing) allowed to complete the devices fabrication process, increasing their sensitivity. Indeed, the wax allowed reducing the interference related to the parasitic currents flowing through the permeable coating of the employed substrates, which was used for the chemical sintering, thus avoiding the common thermal treatment after printing. As a case study, we used the devices to develop an electrochemical aptamer-based sensor for the rapid detection of neutrophil gelatinase-associated lipocalin (NGAL) in urine – a clinically important marker of acute kidney injury. The aptasensor platform is capable of detecting clinically relevant concentrations of NGAL with a simple and rapid smartphone readout. The developed technology may be extended in the future to continuous monitoring, taking advantage of its flexibility to integrate it in tubes, or to other diagnostic applications where cost/efficiency and rapidity of the research, development and implementation of point of care devices is a must. •FEM multiphysics simulations allows to optimize biosensors design in-silico.•Consumer inkjet printer can be easily used to fabricate electrochemical aptasensors.•Chemical sintering substrates combined with wax printing give optimal impedance.•Simple and fast aptamers functionalization allows for the rapid detection of NGAL.•NGAL detection in the AKI clinical range was obtained in artificial urine.
ISSN:0956-5663
1873-4235
DOI:10.1016/j.bios.2021.113737