A Paper-Based “Pop-up” Electrochemical Device for Analysis of Beta-Hydroxybutyrate

Wang, Chien-Chung; Hennek, Jonathan W.; Ainla, Alar; Kumar, Ashok Ashwin; Lan, Wenjie; Im, Judy S.; Smith, Barbara; Zhao, Mengxia; Whitesides, George M.

doi:10.1021/acs.analchem.6b00568

Cited by 155 publications

(118 citation statements)

References 89 publications

(194 reference statements)

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“…[6][7][8] Electrochemical sensors are also versatile: They can be made on the nanoscale, 1 have been 3D-printed, 9 and can be inexpensive. 10,11 The highly translatable nature of electrochemical techniques has already been demonstrated with the advent of Smart Bands 12 and iSTAT meters (Abbott Point of Care Inc.). 13,14 Detecting glutamate has many advantages: It advances our knowledge of the effects of pesticide exposure, explains some of the erratic behaviors seen after traumatic brain injuries, informs our dietary considerations (MSG), and, perhaps most importantly, functions as a window to understanding human memory and consciousness.…”

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confidence: 99%

Electrochemical Microphysiometry Detects Cellular Glutamate Uptake

Miller

McClain

Cliffel

2018

J. Electrochem. Soc.

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Glutamate is the principal excitatory amino acid in the vertebrate nervous system and is responsible for learning and memory. Understanding of these complex biological processes can be gained through experimentally accessible systems of glutamate detection. In this work, the microclinical analyzer (μCA) was used with a sensitive and stable glutamate sensor and model neuronal cells for quantitative glutamate detection under physiological relevant shear. Glutamate was detected by immobilized glutamate oxidase on a screen-printed electrode array. The sensor's linear range spanned glutamate's physiological to pathophysiological concentration range, and the biologically relevant sub-second to month temporal range. After 11 hours of use, the sensor retained 91 ± 1% of its signal, and it was able to be stored for a month without a significant decrease. When model neuronal cells were integrated into the μCA bioreactor and exposed to glutamate, they initially took up 210 ± 100 μmoles of glutamate, which increased to 390 ± 50 μmoles during their second exposure. These data suggest that the neurotransmitter uptake systems were functional and may be upregulated. The dynamic and durable μCA platform offers an experimentally accessible system of glutamate detection that can be used to monitor glutamate metabolism and signaling. Glutamate is one of the 20 canonical amino acids that together provide the structural and enzymatic foundation of proteins. Alone, glutamate plays a very different role and is itself an excitatory signaling molecule widely distributed throughout the central nervous system. In fact, glutamate is the most prevalent neurotransmitter and its function is essential for proper neurocognition, learning, and memory. Overactivation of glutamate receptors causes excitotoxicity, a pathological process whereby neurons are damaged or killed, which may result in neurodegeneration.1,2 Because of its central role in metabolic and cognitive processes, a strong effort has been put toward developing methods to detect glutamate. [2][3][4][5] Accurate detection of glutamate can be accomplished using many techniques, including spectrometry, spectroscopy, and electrochemistry. The benefits of spectrometry and spectroscopy include sensitivity and selectivity. However, mass spectrometry requires chromatographic separation or vacuum preparation, which decreases the temporal resolution of the system. 4 Although spectroscopic techniques, such as the iGluSNFR, 2 offer impressive temporal resolution, they require optical transparency thereby limiting the scope of samples that can be analyzed. In contrast, electrochemical sensors require almost no sample manipulation and can be placed directly in the area of interest, allowing, for example, detection of glutamate and dopamine signaling in the brain.6-8 Electrochemical sensors are also versatile: They can be made on the nanoscale, 1 have been 3D-printed, 9 and can be inexpensive.10,11 The highly translatable nature of electrochemical techniques has already been demonstrated with the a...

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mentioning

confidence: 99%

Electrochemical Microphysiometry Detects Cellular Glutamate Uptake

Miller

McClain

Cliffel

2018

J. Electrochem. Soc.

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“…21 The main difference (B) A "pop-up" electrochemical paper-based analytical device for analyzing β-hydroxybutyrate. 40 (C) Paper-based multilayer circuits for development of paper-based devices. 46 (D) Quantitative detection of oligonucleotides and proteins via paper electrochemical device.…”

Section: ·2 Designs: 2d and 3d Devicesmentioning

confidence: 99%

“…78 Figures are reproduced with permission from American Chemical Society. 21,40,46,53,78 between 2D and 3D sensors is how electrodes are displayed. In a 2D sensor, the three electrodes system is fabricated onto a single piece of paper, commonly on a circular or a channel-like hydrophobic test zone.…”

Section: ·2 Designs: 2d and 3d Devicesmentioning

confidence: 99%

“…1B). 40 The microfluidic channels were defined by wax printing on chromatography paper, followed by stencil-printing of the three electrodes system and circuits using graphite ink. A solution of enzyme and cofactor were added into the reaction zone and dried in the dark.…”

Section: ·2 Designs: 2d and 3d Devicesmentioning

confidence: 99%

“…1B). 40 This single-use PAD contained a sample port, a reaction zone for storing the enzyme and a detection zone spatially isolated from the first two zones. The device changed from "off" to "on" configuration when the sample port, reaction zone and detection zone were in contact through modest mechanical pressure by folding the device between thumb and forefinger or by placing some weight on top of the device.…”

Section: ·1 Clinical Diagnosticsmentioning

confidence: 99%

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Trends in Paper-based Electrochemical Biosensors: From Design to Application

et al. 2018

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Electrochemical bio-sensing using paper-based detection systems is the main focus of this review. The different existing designs of 2-dimensional and 3-dimensional sensors, and fabrication techniques are discussed. This review highlights the effect of adopting different sensor designs, distinct fabrication techniques, as well as different modification methods, in order to produce reliable and reproducible reading. The use of various nanomaterials have been demonstrated in order to modify the surface of electrodes during fabrication to further enhance the signal for subsequent analysis. The reviewed sensors were classified into categories based on their applications, such as diagnostics, environmental and food testing. One of the major advantages of using paper-based electrochemical sensors is the potential for miniaturization, which only requires relatively small amount of samples, and the low cost for the purpose of mass production. Additionally, most of the devices reviewed were made to be portable, making them well-suited for on-site detection. Finally, paper-based detection is an ideal platform to fabricate cost-effective, user-friendly and sensitive electrochemical biosensors, with large capacity for customization depending on functional needs.

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Origami Biosystems: 3D Assembly Methods for Biomedical Applications

et al. 2018

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Conventional assembly of biosystems has relied on bottom‐up techniques, such as directed aggregation, or top‐down techniques, such as layer‐by‐layer integration, using advanced lithographic and additive manufacturing processes. However, these methods often fail to mimic the complex three dimensional (3D) microstructure of naturally occurring biomachinery, cells, and organisms regarding assembly throughput, precision, material heterogeneity, and resolution. Pop‐up, buckling, and self‐folding methods, reminiscent of paper origami, allow the high‐throughput assembly of static or reconfigurable biosystems of relevance to biosensors, biomicrofluidics, cell and tissue engineering, drug delivery, and minimally invasive surgery. The universal principle in these assembly methods is the engineering of intrinsic or extrinsic forces to cause local or global shape changes via bending, curving, or folding resulting in the final 3D structure. The forces can result from stresses that are engineered either during or applied externally after synthesis or fabrication. The methods facilitate the high‐throughput assembly of biosystems in simultaneously micro or nanopatterned and layered geometries that can be challenging if not impossible to assemble by alternate methods. The authors classify methods based on length scale and biologically relevant applications; examples of significant advances and future challenges are highlighted.

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A Paper-Based “Pop-up” Electrochemical Device for Analysis of Beta-Hydroxybutyrate

Cited by 155 publications

References 89 publications

Electrochemical Microphysiometry Detects Cellular Glutamate Uptake

Electrochemical Microphysiometry Detects Cellular Glutamate Uptake

Trends in Paper-based Electrochemical Biosensors: From Design to Application

Origami Biosystems: 3D Assembly Methods for Biomedical Applications

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