Karol Malecha scite author profile

Fundamentals of quantum dots (QDs) sensing phenomena show the predominance of these fluorophores over standard organic dyes, mainly because of their unique optical properties such as sharp and tunable emission spectra, high emission quantum yield and broad absorption. Moreover, they also indicate no photo bleaching and can be also grown as no blinking emitters. Due to these properties, QDs may be used e.g., for multiplex testing of the analyte by simultaneously detecting multiple or very weak signals. Physico-chemical mechanisms used for analyte detection, like analyte stimulated QDs aggregation, nonradiative Förster resonance energy transfer (FRET) exhibit a number of QDs, which can be applied in sensors. Quantum dots-based sensors find use in the detection of ions, organic compounds (e.g., proteins, sugars, volatile substances) as well as bacteria and viruses.

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A Fluorescent Biosensors for Detection Vital Body Fluids’ Agents

Nawrot

Drzozga

Baluta

et al. 2018

Sensors

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The clinical applications of sensing tools (i.e., biosensors) for the monitoring of physiologically important analytes are very common. Nowadays, the biosensors are being increasingly used to detect physiologically important analytes in real biological samples (i.e., blood, plasma, urine, and saliva). This review focuses on biosensors that can be applied to continuous, time-resolved measurements with fluorescence. The material presents the fluorescent biosensors for the detection of neurotransmitters, hormones, and other human metabolites as glucose, lactate or uric acid. The construction of microfluidic devices based on fluorescence uses a variety of materials, fluorescent dyes, types of detectors, excitation sources, optical filters, and geometrical systems. Due to their small size, these devices can perform a full analysis. Microfluidics-based technologies have shown promising applications in several of the main laboratory techniques, including blood chemistries, immunoassays, nucleic-acid amplification tests. Of the all technologies that are used to manufacture microfluidic systems, the LTCC technique seems to be an interesting alternative. It allows easy integration of electronic and microfluidic components on a single ceramic substrate. Moreover, the LTCC material is biologically and chemically inert, and is resistant to high temperature and pressure. The combination of all these features makes the LTCC technology particularly useful for implementation of fluorescence-based detection in the ceramic microfluidic systems.

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A PDMS/LTCC bonding technique for microfluidic application

Malecha¹,

Gancarz²,

Gołonka³

2009

J. Micromech. Microeng.

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A novel bonding method of glass-covered low-temperature co-fired ceramics (LTCC) to transparent polydimethylsiloxane (PDMS) polymer is reported in this paper. The irreversible bonding between both materials was achieved by exposing their surfaces to an oxygen plasma. The influence of different plasma treatment process parameters (system power, time of surfaces activation) and glass/ceramics firing temperatures (Tmax = 700–875 °C, co-fired, post-fired) on the bonding process was investigated. Scanning electron microscopy (SEM) was used to study the glass surface quality after firing at various temperatures. Contact angle measurements, x-ray photoelectron spectroscopy (XPS), Fourier transform infrared spectroscopy-attenuated total reflection (FTIR-ATR) and atomic force microscopy (AFM) were used to investigate properties of the PDMS and glass-covered LTCC surfaces before and after oxygen plasma treatment.

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Karol Malecha

Optical Sensors Based on II-VI Quantum Dots

A Fluorescent Biosensors for Detection Vital Body Fluids’ Agents

A PDMS/LTCC bonding technique for microfluidic application

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