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Chemical Sensing by RIFTS-Reflective Interferometric Fourier-Transform Spectroscopy: A Robust, Self-Compensating Method for Label-Free Detection of Biomolecules

技術優勢: The approach is very general. For example, the methodology should also work with other label-free transduction modalities in materials other than porous SiO 2 or porous Si that utilize refractive index changes, such as surface plasmon resonance or microcavity resonance. The built-in reference channel and Fourier method of analysis provides a general means to compensate for changes in sample matrix, non-specific binding, temperature, and other experimental variables.

技術應用: Label-free biosensing, high-throughput molecular sensing, array-based sensing, drug lead discovery, diagnostics, and characterization of kinetic and thermodynamic binding constants in biomolecular binding assays.

詳細技術說明: This invention utilizes a novel self-compensating interferometric biosensor comprised of two layers of porous SiO 2, stacked one on top of the other. The reflectivity spectrum displays a complex interference pattern that arises from a combination of Fabry-Pérot interference from these layers. A ratio of the peak intensities in the fast Fourier transform (FFT) allows discrimination of target analyte from matrix effects arising from non-specific compositional changes in the analyte solution.

*Abstract: Most optical transducers for label-free biosensing involve measurement of a change in the refractive index of a material induced upon analyte binding. While surface plasmon resonance (SPR) films, resonant and nonresonant diffraction gratings, reflectometric interference (RIFS) layers and Fabry-Perot interferometers show very sensitive responses to small changes in refractive index, these methods are all limited by zero-point-drift arising from changes in temperature, matrix composition, or nonspecific binding to the analytical surface.
A double-beam (Michelson-type) interferometer, in which one optical path acts as a reference channel, provides an excellent means of compensating for such effects. Various implementations of double-beam correction have been employed in micro-scale biosensor systems, generally involving two spatially distinct regions of a chip. However, because the sample and reference channels are separated in the X-Y plane, such designs pose significant alignment and manufacturability challenges, especially upon incorporation into high-throughput arrays.

*IP Issue Date: Mar 6, 2018

*Principal Investigation: Name: Gordon Miskelly
Department:

Name: Claudia Pacholski
Department:

Name: Michael Sailor
Department:

附加資料: Patent Number: US20110170106A1
Application Number: US2010683895A
Inventor: Pacholski, Claudia | Miskelly, Gordon M. | Sailor, Michael J.
Priority Date: 10 Mar 2005
Priority Number: US20110170106A1
Application Date: 7 Jan 2010
Publication Date: 14 Jul 2011
IPC Current: G01J000345
US Class: 356451
Assignee Applicant: The Regents of the University of California
Title: MULTIPLE SUPERIMPOSED INTERFACE PATTERN POROUS MICROSTRUCTURE MULTI LAYER BIOSENSING METHOD
Usefulness: MULTIPLE SUPERIMPOSED INTERFACE PATTERN POROUS MICROSTRUCTURE MULTI LAYER BIOSENSING METHOD
Summary: Porous microstructure multilayer bio-sensing method.
Novelty: Porous microstructure multilayer bio-sensing method, involves biological analyte to multilayer micro-porous thin film structure, and determining presence of bio molecule of interest in analyte from extracted optical parameters

主要類別: 生物醫學

細分類別: 醫療裝置

申請號碼: 9909985

其他

State Of Development

The concept has been demonstrated with a Protein A capture probe and Human Immunoglobulin G as the target analyte. The system response is shown to be insensitive to the addition of 4000-fold excess sucrose or 80-fold excess bovine serum albumin.

Related Materials

Tinsley-Bown, A. M. et al. Tuning the Pore Size and Surface Chemistry of Porous Silicon for Immunoassays. Phys. Status Solidi A 182, 547-53 (2000).
Létant, S. E., Content, S., Tan, T. T., Zenhausern, F. and Sailor, M. J. Integration of Porous Silicon Chips in an Electronic Artificial Nose. Sens. Actuators B 69, 193-198 (2000).
Sailor, M. J. et al. in Unattended Ground Sensor Technologies and Applications III (ed. Carapezza, E. M.) 153-165 (SPIE, Orlando, FL, 2001).
Collins, B. E., Dancil, K.-P., Abbi, G. and Sailor, M. J. Determining Protein Size Using an Electrochemically Machined Pore Gradient in Silicon. Adv. Funct. Mater. 12, 187-191 (2002).
Cunin, F. et al. Biomolecular Screening with Encoded Porous Silicon Photonic Crystals. Nature Mater. 1, 39-41 (2002).
See Professor Michael Sailor's June 2005 S mart Dust presentation.
Lin, H., Mock, J., Smith, D., Gao, T. & Sailor, M. J. Surface-Enhanced Raman Scattering from Silver-Plated Porous Silicon. J. Phys. Chem. B 108, 11654 -11659 (2004).
Lin, H., Gao, T., Fantini, J. and Sailor, M. J. A Porous Silicon-Palladium Composite Film for Optical Interferometric Sensing of Hydrogen. Langmuir 20, 5104-5108 (2004).

Intellectual Property Info

A patent application is pending.

Related Materials

Létant, S. & Sailor, M. J. Molecular Identification by Time Resolved Interferometry in a Porous Silicon Film. Adv. Mat. 13, 335-338 (2001).
Ghadiri, M. R., Sailor, M. J., Motesharei, K., Lin, S.-Y. & Dancil, K.-P. S. Porous semiconductor-based optical interferometric sensor. See U.S. patent number 6,720,177.
Ghadiri, M. R., Sailor, M. J., Motesharei, K., Lin, S.-Y. & Dancil, K.-P. S. Porous semiconductor-based optical interferometric sensor. See U.S. patent number 6,897,965.
Ghadiri, M. R., Motesharei, K., Lin, S.-Y., Sailor, M. J. & Dancil, K.-P. Porous semiconductor-based optical interferometric sensor. See U.S. patent number 6,248,539.
Sohn, H., Létant, S., Sailor, M. J. & Trogler, W. C. Detection of Fluorophosphonate Chemical Warfare Agents by Catalytic Hydrolysis with a Porous Silicon Interferometer. J. Am. Chem. Soc. 122, 5399-5400 (2000).
Dancil, K.-P. S., Greiner, D. P. & Sailor, M. J. A Porous Silicon Optical Biosensor: Detection of Reversible Binding of IgG to a Protein A-Modified Surface. J. Am. Chem. Soc. 121, 7925-7930 (1999).
Janshoff, A. et al. Macroporous P-Type Silicon Fabry-Perot Layers. Fabrication, Characterization, and Applications in Biosensing. J. Am. Chem. Soc. 120, 12108-12116 (1998).
Lin, V. S.-Y., Motesharei, K., Dancil, K. S., Sailor, M. J. & Ghadiri, M. R. A Porous Silicon-Based Optical Interferometric Biosensor. Science 278, 840-843 (1997).

Tech ID/UC Case

19503/2005-179-0

Related Cases

2005-179-0

國家/地區: 美國

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