Fabrication and Characterization of Roll-to-Roll-Coated Cantilever-Structured Touch Sensors

Lee, Sang Yoon

doi:10.1021/acsami.0c14889

Cited by 13 publications

(13 citation statements)

References 58 publications

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“…A productive roll-to-roll printed method for fabricating touch sensors (shown in Fig. 5 c) [ 41 , 147 ]. The bottom electrode, the dielectric, and the sacrificial layers were coated on a flexible substrate by roll-to-roll slot-die, while the roll-to-roll gravure printing was used to form the top electrode.…”

Section: Fabrications Of the Flexible Ofets-based Sensorsmentioning

confidence: 99%

Flexible organic field-effect transistors-based biosensors: progress and perspectives

Zhang

et al. 2023

Anal Bioanal Chem

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Organic field-effect transistors (OFETs) have been proposed beyond three decades while becoming a research hotspot again in recent years because of the fast development of flexible electronics. Many novel flexible OFETs-based devices have been reported in these years. Among these devices, flexible OFETs-based sensors made great strides because of the extraordinary sensing capability of FET. Most of these flexible OFETs-based sensors were designed for biological applications due to the advantages of flexibility, reduced complexity, and lightweight. This paper reviews the materials, fabrications, and applications of flexible OFETs-based biosensors. Besides, the challenges and opportunities of the flexible OFETs-based biosensors are also discussed. Graphical abstract

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Section: Fabrications Of the Flexible Ofets-based Sensorsmentioning

confidence: 99%

Flexible organic field-effect transistors-based biosensors: progress and perspectives

Zhang

et al. 2023

Anal Bioanal Chem

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“…In CFM (Clear and Nealey 1999;Takano et al, 1999;Okabe et al, 2000;Fiorini et al, 2001;Kreller et al, 2002;Brewer and Leggett 2004;Gourianova et al, 2005;Cameron et al, 2006;Dague et al, 2007;Dufrene 2008;Foster et al, 2009;Sirghi et al, 2009;Barattin and Voyer 2011;Teobaldi et al, 2011;Alsteens et al, 2012;Picas et al, 2012;Beaussart et al, 2014;Hibino and Nakano-Nishida 2014), cantilever tips are chemically functionalized with particular functional groups for performing specific functions in a system. CFM relies on two approaches: microcantilever-based biosensors (MC-B) (Subramanian and Catchmark 2007;Lang and Gerber 2008;Gruber et al, 2011;Johnson and Mutharasan 2012;Peiner and Wasisto 2019;Bennett et al, 2020;Lee and Lee 2020;Mamou et al, 2021) and nanomechanical cantilever sensors (NCS) to achieve these goals of characterizing and understanding the system at single-molecule level with high reproducibility and repeatability. The microcantilever-based biosensing utilizes the specific binding of biomolecules for analytical sensing.…”

Section: Afm As Biosensormentioning

confidence: 99%

Biosensing, Characterization of Biosensors, and Improved Drug Delivery Approaches Using Atomic Force Microscopy: A Review

Sarkar

2022

Front. Nanotechnol.

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Since its invention, atomic force microscopy (AFM) has come forth as a powerful member of the “scanning probe microscopy” (SPM) family and an unparallel platform for high-resolution imaging and characterization for inorganic and organic samples, especially biomolecules, biosensors, proteins, DNA, and live cells. AFM characterizes any sample by measuring interaction force between the AFM cantilever tip (the probe) and the sample surface, and it is advantageous over other SPM and electron micron microscopy techniques as it can visualize and characterize samples in liquid, ambient air, and vacuum. Therefore, it permits visualization of three-dimensional surface profiles of biological specimens in the near-physiological environment without sacrificing their native structures and functions and without using laborious sample preparation protocols such as freeze-drying, staining, metal coating, staining, or labeling. Biosensors are devices comprising a biological or biologically extracted material (assimilated in a physicochemical transducer) that are utilized to yield electronic signal proportional to the specific analyte concentration. These devices utilize particular biochemical reactions moderated by isolated tissues, enzymes, organelles, and immune system for detecting chemical compounds via thermal, optical, or electrical signals. Other than performing high-resolution imaging and nanomechanical characterization (e.g., determining Young’s modulus, adhesion, and deformation) of biosensors, AFM cantilever (with a ligand functionalized tip) can be transformed into a biosensor (microcantilever-based biosensors) to probe interactions with a particular receptors of choice on live cells at a single-molecule level (using AFM-based single-molecule force spectroscopy techniques) and determine interaction forces and binding kinetics of ligand receptor interactions. Targeted drug delivery systems or vehicles composed of nanoparticles are crucial in novel therapeutics. These systems leverage the idea of targeted delivery of the drug to the desired locations to reduce side effects. AFM is becoming an extremely useful tool in figuring out the topographical and nanomechanical properties of these nanoparticles and other drug delivery carriers. AFM also helps determine binding probabilities and interaction forces of these drug delivery carriers with the targeted receptors and choose the better agent for drug delivery vehicle by introducing competitive binding. In this review, we summarize contributions made by us and other researchers so far that showcase AFM as biosensors, to characterize other sensors, to improve drug delivery approaches, and to discuss future possibilities.

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“…However, many other applications, such as implantable cerebrovascular and arterial stents, brain–machine interfaces, and fully printed wearable devices, are of tremendous interest [ 10 , 150 ]. Other systems have been successfully fabricated with high throughput methods, as summarized in Table 4 [ 37 , 129 , 162 , 163 , 164 , 165 , 166 ]. One area of critical interest is wearable electrophysiology monitoring.…”

Section: Applications For Bioelectronicsmentioning

confidence: 99%

“…Another interesting area of research is the development of capacitive touch sensors, which have been widely reported in the literature using traditional MEMS fabrication. Lee et al created such a touch sensor with an air gap instead of PDMS dielectric, and noted that the increased dielectric constant of air allowed for highly improved sensitivity (ΔC/C 0 (%) of 0.118%) and high linear sensing range from 0–20 KPa [ 37 ]. One area of high interest is in printing on TPU substrates, and this was the focus of a recent investigation by Jansson et al using screen-printed AgNP inks.…”

Section: Applications For Bioelectronicsmentioning

confidence: 99%

“…There are four crucial design challenges that must be met to make high throughput manufacturing of hybrid bioelectronics a reality, as depicted in Figure 1 [ 16 , 33 , 34 , 35 , 36 , 37 , 38 , 39 ], and all four are highly interdependent on each other. First, conductive nanomaterials must be identified and produced based on the final application requirements.…”

Section: Introductionmentioning

confidence: 99%

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Recent Advances in High-Throughput Nanomaterial Manufacturing for Hybrid Flexible Bioelectronics

2021

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Hybrid flexible bioelectronic systems refer to integrated soft biosensing platforms with tremendous clinical impact. In this new paradigm, electrical systems can stretch and deform with the skin while previously hidden physiological signals can be continuously recorded. However, hybrid flexible bioelectronics will not receive wide clinical adoption until these systems can be manufactured at industrial scales cost-effectively. Therefore, new manufacturing approaches must be discovered and studied under the same innovative spirit that led to the adoption of novel materials and soft structures. Recent works have taken mature manufacturing approaches from the graphics industry, such as gravure, flexography, screen, and inkjet printing, and applied them to fully printed bioelectronics. These applications require the cohesive study of many disparate parts. For instance, nanomaterials with optimal properties for each specific application must be dispersed in printable inks with rheology suited to each printing method. This review summarizes recent advances in printing technologies, key nanomaterials, and applications of the manufactured hybrid bioelectronics. We also discuss the existing challenges of the available nanomanufacturing methods and the areas that need immediate technological improvements.

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Fabrication and Characterization of Roll-to-Roll-Coated Cantilever-Structured Touch Sensors

Cited by 13 publications

References 58 publications

Flexible organic field-effect transistors-based biosensors: progress and perspectives

Flexible organic field-effect transistors-based biosensors: progress and perspectives

Biosensing, Characterization of Biosensors, and Improved Drug Delivery Approaches Using Atomic Force Microscopy: A Review

Recent Advances in High-Throughput Nanomaterial Manufacturing for Hybrid Flexible Bioelectronics

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