Disposable Sensors in Diagnostics, Food, and Environmental Monitoring

Dincer, Can; Bruch, Richard C.; Costa‐Rama, Estefanía; Fernández‐Abedul, M. Teresa; Merkoçi, Arben; Manz, Andreas; Urban, G.; Güder, Firat

doi:10.1002/adma.201806739

Cited by 591 publications

(382 citation statements)

References 247 publications

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“…However, these approaches still need error‐prone amplification steps prior to the miRNA detection, have rather tedious preparation steps, or are limited by the design of suitable primers . To address these issues, we combine microfluidics with an electrochemical signal readout to develop a sensitive (i.e., target amplification‐free) and selective diagnostic test, while enabling a miniaturization for POC testing . We further apply the newly discovered CRISPR/Cas13a technology, which is able of targeting almost any RNA, to our developed electrochemical biosensor, creating a novel and powerful tool for miRNA diagnostics ( Figure a).…”

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confidence: 99%

CRISPR/Cas13a‐Powered Electrochemical Microfluidic Biosensor for Nucleic Acid Amplification‐Free miRNA Diagnostics

et al. 2019

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Noncoding small RNAs, such as microRNAs, are becoming the biomarkers of choice for multiple diseases in clinical diagnostics. A dysregulation of these microRNAs can be associated with many different diseases, such as cancer, dementia, and cardiovascular conditions. The key for effective treatment is an accurate initial diagnosis at an early stage, improving the patient's survival chances. In this work, the first clustered regularly interspaced short palindromic repeats (CRISPR)/Cas13a‐powered microfluidic, integrated electrochemical biosensor for the on‐site detection of microRNAs is introduced. Through this unique combination, the quantification of the potential tumor markers microRNA miR‐19b and miR‐20a is realized without any nucleic acid amplification. With a readout time of 9 min and an overall process time of less than 4 h, a limit of detection of 10 pm is achieved, using a measuring volume of less than 0.6 µL. Furthermore, the feasibility of the biosensor platform to detect miR‐19b in serum samples of children, suffering from brain cancer, is demonstrated. The validation of the obtained results with a standard quantitative real‐time polymerase chain reaction method shows the ability of the electrochemical CRISPR‐powered system to be a low‐cost, easily scalable, and target amplification‐free tool for nucleic acid based diagnostics.

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confidence: 99%

CRISPR/Cas13a‐Powered Electrochemical Microfluidic Biosensor for Nucleic Acid Amplification‐Free miRNA Diagnostics

et al. 2019

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“…Portable and wearable low‐power consumption chemical sensors that generate rapid and reliable quantitative information, particularly in resource‐limited settings, are in tremendous demand for application in areas such as medical diagnostics, food and environmental monitoring 1. Sensors based on organic field‐effect transistors (OFETs) are attractive candidates due to the intrinsic advantages of low‐power consumption, light weight, substrate flexibility (e.g., paper or plastic) and direct electrical transduction of the analyte response 2.…”

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confidence: 99%

“…They deliver reliable sensing performance over multiple cycles of ammonia exposure (2 to 50 ppm) with an estimated limit-of-detection below 1 ppm.Portable and wearable low-power consumption chemical sensors that generate rapid and reliable quantitative information, particularly in resource-limited settings, are in tremendous demand for application in areas such as medical diagnostics, food and environmental monitoring. [1] Sensors based on…”

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confidence: 99%

Robust High‐Capacitance Polymer Gate Dielectrics for Stable Low‐Voltage Organic Field‐Effect Transistor Sensors

Rahmanudin

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Marcial-Hernández

et al. 2020

Adv Elect Materials

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Organic field‐effect transistors (OFETs) have shown great promise for use as chemical sensors for applications that range from the monitoring of food spoilage to the determination of air quality and the diagnosis of disease. However, for these devices to be truly useful, they must deliver reliable and stable low‐voltage operation over extended timescales. An important element to address this challenge is the development of a high‐capacitance gate dielectric that delivers excellent insulation with robust chemical resistance against the solution processing of organic semiconductors (OSC). The development of a bilayer gate dielectric containing a high‐k fluoropolymer relaxor ferroelectric layer modified at the OSC/dielectric interface with a photo‐crosslinked chemically resistant low‐k methacrylate‐based copolymer buffer layer is reported. Bottom‐gate OFET chemical sensors using this bilayer dielectric operate at low‐voltage with exceptional operational stability. They deliver reliable sensing performance over multiple cycles of ammonia exposure (2 to 50 ppm) with an estimated limit‐of‐detection below 1 ppm.

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“…POCT systems not only have to deliver a high performance (regarding sensitivity, selectivity and turnaround times), but they also should be cost-effective without the need for bulky instrumentation (for example, for sample preparation or signal readout). In order to produce low-cost on-site testing cost on-site testing systems in high throughput, the employed materials have shifted over the last years from silicon, glass or ceramics, used mainly for micro-and nanoelectromechanical systems, to polymers [4]. In contrast to these advanced materials, mainly requiring expensive and timeconsuming fabrication processes, polymers offer a facile and cost-effective mass production of sensors.…”

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confidence: 99%

Enhanced Protein Immobilization on Polymers—A Plasma Surface Activation Study

et al. 2020

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Over the last years, polymers have gained great attention as substrate material, because of the possibility to produce low-cost sensors in a high-throughput manner or for rapid prototyping and the wide variety of polymeric materials available with different features (like transparency, flexibility, stretchability, etc.). For almost all biosensing applications, the interaction between biomolecules (for example, antibodies, proteins or enzymes) and the employed substrate surface is highly important. In order to realize an effective biomolecule immobilization on polymers, different surface activation techniques, including chemical and physical methods, exist. Among them, plasma treatment offers an easy, fast and effective activation of the surfaces by micro/nanotexturing and generating functional groups (including carboxylic acids, amines, esters, aldehydes or hydroxyl groups). Hence, here we present a systematic and comprehensive plasma activation study of various polymeric surfaces by optimizing different parameters, including power, time, substrate temperature and gas composition. Thereby, the highest immobilization efficiency along with a homogenous biomolecule distribution is achieved with a 5-min plasma treatment under a gas composition of 50% oxygen and nitrogen, at a power of 1000 W and a substrate temperature of 80 • C. These results are also confirmed by different surface characterization methods, including SEM, XPS and contact angle measurements.

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Disposable Sensors in Diagnostics, Food, and Environmental Monitoring

Cited by 591 publications

References 247 publications

CRISPR/Cas13a‐Powered Electrochemical Microfluidic Biosensor for Nucleic Acid Amplification‐Free miRNA Diagnostics

CRISPR/Cas13a‐Powered Electrochemical Microfluidic Biosensor for Nucleic Acid Amplification‐Free miRNA Diagnostics

Robust High‐Capacitance Polymer Gate Dielectrics for Stable Low‐Voltage Organic Field‐Effect Transistor Sensors

Enhanced Protein Immobilization on Polymers—A Plasma Surface Activation Study

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