Quantification of DNA and protein adsorption by optical phase shift

Özkumur, Emre; Yalçın, Ayça; Cretich, Marina; Lopez, Carlos A.; Bergstein, D.A.; Goldberg, Bennett B.; Chiari, Marcella; Ünlü, M. Selim

doi:10.1016/j.bios.2009.06.033

Cited by 69 publications

(77 citation statements)

References 33 publications

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“…This method of monitoring protein binding can quantify the bound density with pg/mm 2 accuracy and precision. 19 Detection using a second antibody offers higher sensitivity and specificity than label-free detection of analytes. Labelfree methods lack an additional step to isolate specific binding from non-specific binding.…”

Section: Introductionmentioning

confidence: 99%

Integrated imaging instrument for self-calibrated fluorescence protein microarrays

Reddington

Monroe

Ünlü

2013

Review of Scientific Instruments

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Protein microarrays, or multiplexed and high-throughput assays, monitor multiple protein binding events to facilitate the understanding of disease progression and cell physiology. Fluorescence imaging is a popular method to detect proteins captured by immobilized probes with high sensitivity and specificity. Reliability of fluorescence assays depends on achieving minimal inter-and intra-assay probe immobilization variation, an ongoing challenge for protein microarrays. Therefore, it is desirable to establish a label-free method to quantify the probe density prior to target incubation to calibrate the fluorescence readout. Previously, a silicon oxide on silicon chip design was introduced to enhance the fluorescence signal and enable interferometric imaging to self-calibrate the signal with the immobilized probe density. In this paper, an integrated interferometric reflectance imaging sensor and widefield fluorescence instrument is introduced for sensitive and calibrated microarray measurements.

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Section: Introductionmentioning

confidence: 99%

Integrated imaging instrument for self-calibrated fluorescence protein microarrays

Reddington

Monroe

Ünlü

2013

Review of Scientific Instruments

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“…Deposition of DNA and protein molecules on the surface could change the refractive index, and we should regard the change of thickness with caution. Often lower surface density of molecules results in lower refractive index, and for our cases we can assume the refractive index of the biomaterial to be close to that of SiO 2 [70][71][72][73][74]. However, the additional amount of biomaterial on the surface can always be quantified accurately by the change of optical path length.…”

Section: White Light Reflectance Spectroscopymentioning

confidence: 99%

Spectral Self-Interference Fluorescence Microscopy to Study Conformation of Biomolecules with Nanometer Accuracy

Zhang¹,

Spuhler²,

Freedman³

et al. 2013

Nanoscale Spectroscopy With Applications

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“…Label-free optical imaging biosensors are those that use imaging optics to rapidly measure a large sensor surface area. In this section, we describe three members of the family of label-free optical imaging biosensors, which are darkfield microscopy (DF/TIRM), surface plasmon resonance imaging (SPRi), and interference reflectance imaging (IRIS, iSCAT) [31][32][33][34]. We also introduce the notion that for label-free imaging approaches, even more than for other types of label-free sensors, the surface morphology of the sensor's functionalization is extremely important.…”

Section: Label-free Optical Imaging Detectors Of Single Biological Namentioning

confidence: 99%

“…Interference reflectance imaging has been utilized in several label-free biosensor designs, namely, by the Gauglitz group as Reflectance Interference Spectroscopy (RIfS), Sandoghdar group as Interferometric Scattering Microscopy (iSCAT), and Ünlü group as the Interference Reflectance Imaging Sensor (IRIS) [34,52,53]. All of these techniques measure the binding of biomolecules as small changes in the reflectivity or reflectivity spectrum of a layered substrate.…”

Section: Application Of Interference Reflectance Imaging To Bnp Detecmentioning

confidence: 99%

“…Wide-field coherent light imaging is nontrivial because of long-range interference effects and laser speckle -to overcome these, a ground-glass diffuser with temporal averaging may be used to ameliorate these effects, provided the exposure time is sufficiently long [34]. A second option is to limit detection to dynamic measurements, in which sequential images are subtracted pixelwise, yielding highly sensitive detection of small changes in what is an otherwise highly nonuniform illumination field [53].…”

Section: Application Of Interference Reflectance Imaging To Bnp Detecmentioning

confidence: 99%

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Surface chemistry and morphology in single particle optical imaging

et al. 2017

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Biological nanoparticles such as viruses and exosomes are important biomarkers for a range of medical conditions, from infectious diseases to cancer. Biological sensors that detect whole viruses and exosomes with high specificity, yet without additional labeling, are promising because they reduce the complexity of sample preparation and may improve measurement quality by retaining information about nanoscale physical structure of the bio-nanoparticle (BNP). Towards this end, a variety of BNP biosensor technologies have been developed, several of which are capable of enumerating the precise number of detected viruses or exosomes and analyzing physical properties of each individual particle. Optical imaging techniques are promising candidates among broad range of label-free nanoparticle detectors. These imaging BNP sensors detect the binding of single nanoparticles on a flat surface functionalized with a specific capture molecule or an array of multiplexed capture probes. The functionalization step confers all molecular specificity for the sensor's target but can introduce an unforeseen problem; a rough and inhomogeneous surface coating can be a source of noise, as these sensors detect small local changes in optical refractive index. In this paper, we review several optical technologies for label-free BNP detectors with a focus on imaging systems. We compare the surface-imaging methods including dark-field, surface plasmon resonance imaging and interference reflectance imaging. We discuss the importance of ensuring consistently uniform and smooth surface coatings of capture molecules for these types of biosensors and finally summarize several methods that have been developed towards addressing this challenge.

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Quantification of DNA and protein adsorption by optical phase shift

Cited by 69 publications

References 33 publications

Integrated imaging instrument for self-calibrated fluorescence protein microarrays

Integrated imaging instrument for self-calibrated fluorescence protein microarrays

Spectral Self-Interference Fluorescence Microscopy to Study Conformation of Biomolecules with Nanometer Accuracy

Surface chemistry and morphology in single particle optical imaging

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