Recent Developments in the Field of Optical Immunosensors Focusing on a Label-Free, White Light Reflectance Spectroscopy-Based Immunosensing Platform

Karachaliou, Chrysoula-Evangelia; Koukouvinos, Georgios; Goustouridis, D.; Raptis, Ioannis; Kakabakos, Sotirios; Livaniou, Evangelia; Petrou, Panagiota

doi:10.3390/s22145114

Cited by 8 publications

(12 citation statements)

References 111 publications

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“…The immunosensor proposed herein is the first optical sensor using “compact” instrumentation that is based on the white light reflectance spectroscopy and has, therefore, high potential to evolve to a point-of-need analytical tool. The same detection principle with less integrated instrumentation has been previously applied for the determination of other mycotoxins in different matrices, including aflatoxin B1, fumonisins B and deoxynivalenol in cereals and aflatoxin M1 in milk [ 20 ], but not to the detection of OTA. In terms of analytical sensitivity, the LoD of the proposed method (30 pg/mL in buffer, 60 pg/mL in cereal flour extracts, which corresponds to 0.3 μg/kg in the initial cereal sample and 300 pg/mL in wine) is 10 times lower than the current EU regulatory limit for OTA in cereals (3 μg/kg) and 7 times lower than the one in wines (2 ng/mL).…”

Section: Resultsmentioning

confidence: 99%

“…In the current work, a newly developed polyclonal antibody against OTA was employed for the development of an immunosensor for the accurate, rapid, low-cost and laborious-free determination of OTA in cereal flours and wines based on the white light reflectance spectroscopy (WLRS) principle. The WLRS sensing platform has been successfully applied to the quantitative determination of both high- and low-molecular-weight analytes [ 20 ] after proper biofunctionalization of the sensing surface with immunoreagents (antigen conjugates or antibodies depending on the assay format). WLRS biosensing principle relies on the real-time monitoring of the reflectance spectrum spectral shifts in the VIS/NIR range and associates them with the effective thickness of the biomolecular layer that grows on the biochip surface during the bioreaction.…”

Section: Introductionmentioning

confidence: 99%

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Fast and Accurate Determination of Minute Ochratoxin A Levels in Cereal Flours and Wine with the Label-Free White Light Reflectance Spectroscopy Biosensing Platform

et al. 2022

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Ochratoxin A (OTA) is one of the most toxic naturally encountered contaminants and is found in a variety of foods and beverages, including cereals and wine. Driven by the strict regulations regarding the maximum allowable OTA concentration in foodstuff and the necessity for on-site determination, the development of fast and sensitive methods for the OTA determination in cereal flours and wine samples, based on white light reflectance spectroscopy, is presented. The method relied on appropriately engineered silicon chips, on top of which an OTA-protein conjugate was immobilized. A polyclonal antibody against OTA was then employed to detect the analyte in the framework of a competitive immunoassay; followed by the subsequent addition of a biotinylated secondary antibody and streptavidin for signal enhancement. A small size instrument performed all assay steps automatically and the bioreactions were monitored in real time as the software converted the spectral shifts into effective biomolecular adlayer thickness increase. The assay developed had a detection limit of 0.03 ng/mL and a working range up to 200 ng/mL. The assay lasted 25 min (less than 1h, including calibrators/antibody pre-incubation) and was accomplished following a simple sample preparation protocol. The method was applied to corn and wheat flour samples and white and red wines with recovery values ranging from 87.2 to 111%. The simplicity of the overall assay protocol and convenient instrumentation demonstrates the potential of the immunosensor developed for OTA detection at the point of need.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Fast and Accurate Determination of Minute Ochratoxin A Levels in Cereal Flours and Wine with the Label-Free White Light Reflectance Spectroscopy Biosensing Platform

et al. 2022

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“…Spectra were recorded with a 15 ms integration time and fitted in the spectral range 400–560 nm using the Levenberg–Marquardt algorithm considering the refractive indices n (λ) of all layers of a multilayer stack of water/protein and silane layer/SiO 2 /silicon substrates. The algorithm was applied to evaluate the initial thickness of the SiO 2 /APTES adlayer and to transform in real time the spectral shift in effective biomolecular layer thickness d Γ …”

Section: Methodsmentioning

confidence: 99%

“…Light emitted from the light source is directed vertically to the chip surface by six fibers arranged at the circumference of the reflection probe. The reflected light from the chip is collected and guided to the spectrometer by the seventh central fiber to be continuously recorded and analyzed . For in-flow protein immobilization and assay, transparent microfluidic modules (ThetaMetrisis S.A., Athens, Greece) were placed on top of functionalized Si/SiO 2 chips. , A single chip assembled with its microfluidic cell was then placed in the WLRS instrument docking station.…”

Section: Methodsmentioning

confidence: 99%

“…8 The deposition of biomolecules on the sensor surface from solution could be realized by the in-flow strategy or under static conditions involving immersion in solution or bioprinting techniques. Despite the fact that in most biosensors a microfluidic module is typically involved to allow flow of the sample solution and real-time monitoring of the layer formation during the assay, immobilization of the capture molecules is achieved frequently under static conditions before assembling the microfluidic module 25 rather than using an in situ in-flow strategy. The advantages of the latter are the opportunity to monitor the formation of the capture molecule layer and also the spatial limitation of their immobilization to the array covered by the fluidic channels.…”

Section: Introductionmentioning

confidence: 99%

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Covalent and Non-covalent In-Flow Biofunctionalization for Capture Assays on Silicon Chips: White Light Reflectance Spectroscopy Immunosensor Combined with TOF-SIMS Resolves Immobilization Stability and Binding Stoichiometry

Gajos,

Orzech,

Sanocka

et al. 2023

Langmuir

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Immunosensors that combine planar transducers with microfluidics to achieve in-flow biofunctionalization and assay were analyzed here regarding surface binding capacity, immobilization stability, binding stoichiometry, and amount and orientation of surface-bound IgG antibodies. Two IgG immobilization schemes, by physical adsorption [3-aminopropyltriethoxysilane (APTES)] and glutaraldehyde covalent coupling (APTES/GA), followed by blocking with bovine serum albumin (BSA) and streptavidin (STR) capture, are monitored with white light reflectance spectroscopy (WLRS) sensors as thickness d Γ of the adlayer formed on top of aminosilanized silicon chips. Multi-protein surface composition (IgG, BSA, and STR) is determined by time of flight secondary ion mass spectrometry (TOF-SIMS) combined with principal component analysis (applying barycentric coordinates to the score plot). In-flow immobilization shows at least 1.7 times higher surface binding capacity than static adsorption. In contrast to physical immobilization, which is unstable during blocking with BSA, chemisorbed antibodies desorb (reducing d Γ ) only when the bilayer is formed. Also, TOF-SIMS data show that IgG molecules are partially exchanged with BSA on APTES but not on APTES/ GA modified chips. This is confirmed by the WLRS data that show different binding stoichiometry between the two immobilization schemes for the direct binding IgG/anti-IgG assay. The identical binding stoichiometry for STR capture results from partial replacement with BSA of vertically aligned antibodies on APTES, with fraction of exposed Fab domains higher than on APTES/GA.

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Electrochemical, optical and mass-based immunosensors: A comprehensive review of Bacillus anthracis detection methods

Tyśkiewicz

Fedorowicz

Nakonieczna

et al. 2023

Analytical Biochemistry

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Recent Developments in the Field of Optical Immunosensors Focusing on a Label-Free, White Light Reflectance Spectroscopy-Based Immunosensing Platform

Cited by 8 publications

References 111 publications

Fast and Accurate Determination of Minute Ochratoxin A Levels in Cereal Flours and Wine with the Label-Free White Light Reflectance Spectroscopy Biosensing Platform

Fast and Accurate Determination of Minute Ochratoxin A Levels in Cereal Flours and Wine with the Label-Free White Light Reflectance Spectroscopy Biosensing Platform

Covalent and Non-covalent In-Flow Biofunctionalization for Capture Assays on Silicon Chips: White Light Reflectance Spectroscopy Immunosensor Combined with TOF-SIMS Resolves Immobilization Stability and Binding Stoichiometry

Electrochemical, optical and mass-based immunosensors: A comprehensive review of Bacillus anthracis detection methods

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