Label-Free Prehybridization DNA Microarray Imaging Using Photonic Crystals for Quantitative Spot Quality Analysis

George, Sherine; Block, Ian D.; Jones, Sarah I.; Mathias, Patrick C.; Chaudhery, Vikram; Vuttipittayamongkol, Pattaramon; Wu, Hsin‐Yu; Vodkin, Lila O.; Cunningham, Brian T.

doi:10.1021/ac101551c

Cited by 31 publications

(40 citation statements)

References 13 publications

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“…An alternative is angular scan. However, for sensitive sensing, it requires highly precise mechanical control and has been demonstrated only in research [7]. Scanning an instrumental parameter, either the wavelength or the angle, results in costly instrumentation and larger amount of data.…”

Section: "Peak-tracking Chip" Imagingmentioning

confidence: 99%

Fano lineshapes of 'Peak-tracking chip' spatial profiles analyzed with correlation analysis for bioarray imaging and refractive index sensing

Bougot-Robin¹,

Li²,

Yue³

et al. 2013

SPIE Proceedings

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Section: "Peak-tracking Chip" Imagingmentioning

confidence: 99%

Fano lineshapes of 'Peak-tracking chip' spatial profiles analyzed with correlation analysis for bioarray imaging and refractive index sensing

Bougot-Robin¹,

Li²,

Yue³

et al. 2013

SPIE Proceedings

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“…Change of resonance condition might be measured through the shift of the resonant response, for instance from spectral measurement (u≡λ) [2,3] or angular scan (u≡θ) [4], or through the change of diffraction efficiency I refl (u=u 0 ) measured in fixed spectro-angular optical configuration [5]. While the shift in resonance response is more robust measurement as it is based on an intensity sequence instead of one point, it however relies on costly instrumentation.…”

Section: Resonance Spatial Trackingmentioning

confidence: 99%

Analysis of Fano-line shapes from agile resonant waveguide grating sensors using correlation techniques

Bougot-Robin

Wen

Bénisty

2013

Optical Sensors 2013

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The asymmetric Fano resonance lineshape, resulting from interference between background and a resonant scattering, is archetypal in resonant waveguide grating (RWG) reflectivity. Resonant profile shift resulting from a change of refractive index (from fluid medium or biomolecules at the chip surface) is classically used to perform label-free sensing. Lineshapes are sometimes sampled at discretized "detuning" values to relax instrumental demands, the highest reflectivity element giving a coarse resonance estimate. A finer extraction, needed to increase sensor sensitivity, can be obtained using a correlation approach, correlating the sensed signal to a zero-shifted reference signal. Correlation approach is robust to asymmetry of Fano lineshapes and allows more accurate determination than usual fitting options such as Gaussian or Lorentz shape fitting. Our findings are illustrated with resonance profiles from silicon nitride "chirped" RWGs operated at visible wavelengths. The scheme circumvents the classical but demanding spectral or angular scans: instead of varying angle or wavelength through fragile moving parts or special optics, a RWG structure parameter is varied. Then, the spatial reflectivity profiles of tracks composed of RWGs units with slowly varying filling factor (thus slowly varying resonance condition) are measured under monochromatic conditions. Extracting the resonance location using plain images of these "pixelated" Fano profiles allows multiplex refractive index based sensing with a sensitivity down to 2×10 -5 RIU as demonstrated experimentally. This scheme based on a "Peak-tracking chip" demonstrates a new technique for bioarray imaging using a simpler set-up that maintains high performance with cheap lenses.

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“…Label-free biosensors are very versatile platforms, since they can be developed in different materials, such as silicon or its compounds, glasses, metals, or polymers, and they offer different detection modes and configurations that can be combined [12]. In perspective, optical label-free biosensors are expected to replace fluorescent biosensors in DNA micro-arrays and lab-on-a-chip (LOC) applications [13][14][15].…”

Section: Introductionmentioning

confidence: 99%

Bioengineered Surfaces for Real-Time Label-Free Detection of Cancer Cells

Martucci¹,

Migliaccio²,

ImmacolataRuggiero³

et al. 2016

Lab-on-a-Chip Fabrication and Application

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Biosensing technology is an advancing field that benefits from the properties of biological processes combined to functional materials. Recently, biosensors have emerged as essential tools in biomedical applications, offering advantages over conventional clinical techniques for diagnosis and therapy. Optical biosensors provide fast, selective, direct, and cost-effective analyses allowing label-free and real-time tests. They have also shown exceptional potential for integration in lab-on-a-chip (LOC) devices. The major challenge in the biosensor field is to achieve a fully operative LOC platform that can be used in any place at any time. The choice of an appropriate strategy to immobilize the biological element on the sensor surface becomes the key factor to obtain an applicable analytical tool. In this chapter, after a brief description of the main biofunctionalization procedures on silicon devices, two silicon-based chips that present an (i) IgG antibody or (ii) an Id-peptide as molecular probe, directed against the B-cell receptor of lymphoma cancer cells, will be presented. From a comparison in detecting cells, the Id-peptide device was able to detect lymphoma cells also at low cell concentrations (8.5 × 10 −3 cells/μm 2 ) and in the presence of a large amount of non-specific cells. This recognition strategy could represent a proof-of-concept for an innovative tool for the targeting of patient-specific neoplastic B cells during the minimal residual disease; in addition, it represents an encouraging starting point for the construction of a lab-on-a-chip system for the specific recognition of neoplastic cells in biological fluids enabling the follow-up of the changes of cancer cells number in patients, highly demanded for therapy monitoring applications.

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Label-Free Prehybridization DNA Microarray Imaging Using Photonic Crystals for Quantitative Spot Quality Analysis

Cited by 31 publications

References 13 publications

Fano lineshapes of 'Peak-tracking chip' spatial profiles analyzed with correlation analysis for bioarray imaging and refractive index sensing

Fano lineshapes of 'Peak-tracking chip' spatial profiles analyzed with correlation analysis for bioarray imaging and refractive index sensing

Analysis of Fano-line shapes from agile resonant waveguide grating sensors using correlation techniques

Bioengineered Surfaces for Real-Time Label-Free Detection of Cancer Cells

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