Electrochimica Acta

2018

DOI: 10.1016/j.electacta.2018.08.133

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Auxiliary electrode oxidation for naked-eye electrochemical determinations in microfluidics: Towards on-the-spot applications

Diego H. Martucci

¹

,

Fagner R Todão

²

,

Flávio M. Shimizu

³

et al.

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Microfluidic Point-of-care Devices1

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Cited by 7 publications

(3 citation statements)

References 54 publications

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“…This oxidation is expected to happen as the QREs also apply input potentials to WEs, as previously discussed. [ 90 ] Duplex experiments were next conducted. Consistently with the prior SWV data (see Figure 4A) and FEM simulations (see Figure 4B), these duplex analyses led to the same Δ E p as the values achieved by the prior individual analyses (see Figure 4C).…”

Section: Resultsmentioning

confidence: 99%

Single‐Response Duplexing of Electrochemical Label‐Free Biosensor from the Same Tag

Costa,

Pimentel,

Poker

et al. 2024

Adv Healthcare Materials

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Multiplexing is a valuable strategy to boost throughput and improve clinical accuracy. Exploiting the vertical, meshed design of reproducible and low‐cost ultra‐dense electrochemical chips, the unprecedented single‐response multiplexing of typical label‐free biosensors is reported. Using a cheap, handheld one‐channel workstation and a single redox probe, i.e., ferro/ferricyanide, the recognition events taking place on two spatially resolved locations of the same working electrode can be tracked along a single voltammetry scan by collecting the electrochemical signatures of the probe in relation to different quasi‐reference electrodes, Au (0.0 V) and Ag/AgCl ink (+0.2 V). This spatial isolation prevents crosstalk between the redox tags and interferences over functionalization and binding steps, representing an advantage over the existing non‐spatially resolved single‐response multiplex strategies. As proof of concept, peptide‐tethered immunosensors are demonstrated to provide the duplex detection of COVID‐19 antibodies from distinct samples, thereby doubling the throughput while achieving 100% accuracy in serum samples. We envision the approach to enable broad applications in high‐throughput and multi‐analyte platforms, as it can be tailored to other biosensing devices and formats.This article is protected by copyright. All rights reserved

“…This oxidation is expected to happen as the QREs also apply input potentials to WEs, as previously discussed. [ 90 ] Duplex experiments were next conducted. Consistently with the prior SWV data (see Figure 4A) and FEM simulations (see Figure 4B), these duplex analyses led to the same Δ E p as the values achieved by the prior individual analyses (see Figure 4C).…”

Section: Resultsmentioning

confidence: 99%

Single‐Response Duplexing of Electrochemical Label‐Free Biosensor from the Same Tag

Costa,

Pimentel,

Poker

et al. 2024

Adv Healthcare Materials

Self Cite

View full text Add to dashboard Cite

Multiplexing is a valuable strategy to boost throughput and improve clinical accuracy. Exploiting the vertical, meshed design of reproducible and low‐cost ultra‐dense electrochemical chips, the unprecedented single‐response multiplexing of typical label‐free biosensors is reported. Using a cheap, handheld one‐channel workstation and a single redox probe, i.e., ferro/ferricyanide, the recognition events taking place on two spatially resolved locations of the same working electrode can be tracked along a single voltammetry scan by collecting the electrochemical signatures of the probe in relation to different quasi‐reference electrodes, Au (0.0 V) and Ag/AgCl ink (+0.2 V). This spatial isolation prevents crosstalk between the redox tags and interferences over functionalization and binding steps, representing an advantage over the existing non‐spatially resolved single‐response multiplex strategies. As proof of concept, peptide‐tethered immunosensors are demonstrated to provide the duplex detection of COVID‐19 antibodies from distinct samples, thereby doubling the throughput while achieving 100% accuracy in serum samples. We envision the approach to enable broad applications in high‐throughput and multi‐analyte platforms, as it can be tailored to other biosensing devices and formats.This article is protected by copyright. All rights reserved

“…Such an integration makes this approach promising for future eHealth systems with computer-aided diagnosis, where machine learning, big data, and IoT technologies should converge with biosensing capabilities. In particular, biosensing applications are being explored with e-tongues by functionalizing the building nanolayers with biomolecules to control the specificity in the interactions with the analyte under study [68][69][70][71][72][73][74][75][76]. This latter application can be used to collect huge amounts of patient's biological data to feed machine learning algorithms, and then continuously convert them into knowledge (through big data and machine learning methods).…”

Section: Microfluidic Point-of-care Devicesmentioning

confidence: 99%

Microfluidic Point-of-Care Devices: New Trends and Future Prospects for eHealth Diagnostics

Mejía‐Salazar

¹

,

²

,

³

et al. 2020

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Point-of-care (PoC) diagnostics is promising for early detection of a number of diseases, including cancer, diabetes, and cardiovascular diseases, in addition to serving for monitoring health conditions. To be efficient and cost-effective, portable PoC devices are made with microfluidic technologies, with which laboratory analysis can be made with small-volume samples. Recent years have witnessed considerable progress in this area with “epidermal electronics”, including miniaturized wearable diagnosis devices. These wearable devices allow for continuous real-time transmission of biological data to the Internet for further processing and transformation into clinical knowledge. Other approaches include bluetooth and WiFi technology for data transmission from portable (non-wearable) diagnosis devices to cellphones or computers, and then to the Internet for communication with centralized healthcare structures. There are, however, considerable challenges to be faced before PoC devices become routine in the clinical practice. For instance, the implementation of this technology requires integration of detection components with other fluid regulatory elements at the microscale, where fluid-flow properties become increasingly controlled by viscous forces rather than inertial forces. Another challenge is to develop new materials for environmentally friendly, cheap, and portable microfluidic devices. In this review paper, we first revisit the progress made in the last few years and discuss trends and strategies for the fabrication of microfluidic devices. Then, we discuss the challenges in lab-on-a-chip biosensing devices, including colorimetric sensors coupled to smartphones, plasmonic sensors, and electronic tongues. The latter ones use statistical and big data analysis for proper classification. The increasing use of big data and artificial intelligence methods is then commented upon in the context of wearable and handled biosensing platforms for the Internet of things and futuristic healthcare systems.

“…Bu modellerle birlikte biyolojik süreçlerin araştırılmasıyla bir çipte organ geliştirilmiştir. Ayrıca karaciğer, kalp, kas ve göz gibi insan hayatında büyük öneme sahip organların çip üzerinde birçok doku modeli üzerinde çalışmalar yapılmıştır [13][14][15].…”

Section: Introductionunclassified

Mems Tabanli Mi̇kro-Akişkan Çi̇pi̇n Zamana Bağli Basinç Anali̇zi̇

¹

2020

International Journal of 3D Printing Technologies and Digital Industry

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Mikro elektromekanik sistemler (MEMS), ölçülen bir mekanik sinyalin makine tarafından okunabilir bir sinyale dönüştürülmesini sağlayan mekanik ve elektromekanik mikro ölçekte bileşenlerden oluşan bir teknolojidir. Geleneksel mekanik üretimin aksine, MEMS cihazının üretiminde, entegre bir devre ile uyumlu olan yüzey mikroişleme ve toplu mikroişleme süreçlerini içeren yarı iletken yöntemi kullanılır. Bu aygıtlar veya sistemler makro ölçekteki etkileri algılama, denetleme, etkinleştirme ve oluşturma yeteneğine sahiptir. Bu çalışmada, mikro litre ve daha küçük hacimlerdeki akışkanların mikro ölçekteki kanallar içerisinde kontrol edilmesini ve hareket etmesini sağlayan bir sistem olan mikro-akışkan çipin tasarımı 3B tasarım programı kullanılarak gerçekleştirilmiştir. Mikro-akışkan, tek kanal girişli ve dört kanal çıkışlı olacak biçimde tasarlanmıştır. Bu mikro-akışkanın ön fiziksel testleri, araştırılması ve zamana bağlı basınç analizleri COMSOL MultiPhysics programı ile yapılmıştır. Tasarımı gerçekleştirilen mikro-akışkan çipin t=0, 0.5, 1, 1.5 ve 2 s zaman değerlerine bağlı akış yönü ve basınç analizi yapılmıştır. Analiz sonucunda mikro-akışkan kanallarında zamana bağlı akış yönü ve basınç değerleri farklılık göstermiştir.

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