Optical grating coupler biosensors
By incorporating a grating in a planar optical waveguide one creates a device with which the spectrum of guided lightmodes can be measured. When the surface of the waveguide is exposed to different solutions, the peaks in the spectrum shift due to molecular interactions with the surface. Optical wav...
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| Published in: | Biomaterials Vol. 23; no. 17; pp. 3699 - 3710 |
|---|---|
| Main Authors: | , , , , , , |
| Format: | Journal Article |
| Language: | English |
| Published: |
Netherlands
Elsevier Ltd
01.09.2002
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| Subjects: | |
| ISSN: | 0142-9612, 1878-5905 |
| Online Access: | Get full text |
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| Abstract | By incorporating a grating in a planar optical waveguide one creates a device with which the spectrum of guided lightmodes can be measured. When the surface of the waveguide is exposed to different solutions, the peaks in the spectrum shift due to molecular interactions with the surface. Optical waveguide lightmode spectroscopy (OWLS) is a highly sensitive technique that is capable of real-time monitoring of these interactions. Since this integrated optical method is based on the measurement of the polarizability density (i.e., refractive index) in the vicinity of the waveguide surface, radioactive, fluorescent or other kinds of labeling are not required. In addition, measurement of at least two guided modes enables the absolute mass of adsorbed molecules to be determined. In this article, the technique will be described in some detail, and applications from different areas will be discussed. Selected examples will be presented to demonstrate how monitoring the modification of different metal oxides with polymers and the response of the coated oxides to biofluids help in the design of novel biomaterials; how OWLS is useful for accurate bioaffinity sensing, which is a key issue in the development of new drugs; and how the quantitative study of protein–DNA/RNA and cell–surface interactions can enhance the understanding of processes in molecular and cellular biology. |
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| AbstractList | By incorporating a grating in a planar optical waveguide one creates a device with which the spectrum of guided lightmodes can be measured. When the surface of the waveguide is exposed to different solutions, the peaks in the spectrum shift due to molecular interactions with the surface. Optical waveguide lightmode spectroscopy (OWLS) is a highly sensitive technique that is capable of real-time monitoring of these interactions. Since this integrated optical method is based on the measurement of the polarizability density (i.e., refractive index) in the vicinity of the waveguide surface, radioactive, fluorescent or other kinds of labeling are not required. In addition, measurement of at least two guided modes enables the absolute mass of adsorbed molecules to be determined. In this article, the technique will be described in some detail, and applications from different areas will be discussed. Selected examples will be presented to demonstrate how monitoring the modification of different metal oxides with polymers and the response of the coated oxides to biofluids help in the design of novel biomaterials; how OWLS is useful for accurate bioaffinity sensing, which is a key issue in the development of new drugs; and how the quantitative study of protein–DNA/RNA and cell–surface interactions can enhance the understanding of processes in molecular and cellular biology. By incorporating a grating in a planar optical waveguide one creates a device with which the spectrum of guided lightmodes can he measured. When the surface of the waveguide is exposed to different solutions, the peaks in the spectrum shift due to molecular interactions with the surface. Optical waveguide lightmode spectroscopy (OWLS) is a highly sensitive technique that is capable of real-time monitoring of these interactions. Since this integrated optical method is based on the measurement of the polarizability density (i.e., refractive index) in the vicinity of the waveguide surface, radioactive, fluorescent or other kinds of labeling are not required. In addition, measurement of at least two guided modes enables the absolute mass of adsorbed molecules to be determined. In this article, the technique will be described in some detail, and applications from different areas will be discussed. Selected examples will be presented to demonstrate how monitoring the modification of different metal oxides with polymers and the response of the coated oxides to biofluids help in the design of novel biomaterials; how OWLS is useful for accurate bioaffinity sensing, which is a key issue in the development of new drugs; and how the quantitative study of protein-DNA/RNA and cell surface interactions can enhance the understanding of processes in molecular and cellular biology. Optimal waveguide lightmode spectroscopy (OWLS) is a highly sensitive technique, capable of real-time monitoring of molecular interactions with the surface of a planar optical waveguide. The technique is described in detail and applications from different areas are discussed. Selected examples are presented to demonstrate: (1) how monitoring the modification of different metal oxides with polymers and the response of the coated oxides to biofluids help in the design of novel biomaterials, (2) how OWLS is useful for accurate bioaffinity sensing, which is a key issue in the development of new drugs and (3) how the quantitative study of protein-DNA/RNA and cell-surface interactions can enhance the understanding of processes in molecular and cellular biology. (Original abstract - amended) By incorporating a grating in a planar optical waveguide one creates a device with which the spectrum of guided lightmodes can he measured. When the surface of the waveguide is exposed to different solutions, the peaks in the spectrum shift due to molecular interactions with the surface. Optical waveguide lightmode spectroscopy (OWLS) is a highly sensitive technique that is capable of real-time monitoring of these interactions. Since this integrated optical method is based on the measurement of the polarizability density (i.e., refractive index) in the vicinity of the waveguide surface, radioactive, fluorescent or other kinds of labeling are not required. In addition, measurement of at least two guided modes enables the absolute mass of adsorbed molecules to be determined. In this article, the technique will be described in some detail, and applications from different areas will be discussed. Selected examples will be presented to demonstrate how monitoring the modification of different metal oxides with polymers and the response of the coated oxides to biofluids help in the design of novel biomaterials; how OWLS is useful for accurate bioaffinity sensing, which is a key issue in the development of new drugs; and how the quantitative study of protein-DNA/RNA and cell surface interactions can enhance the understanding of processes in molecular and cellular biology.By incorporating a grating in a planar optical waveguide one creates a device with which the spectrum of guided lightmodes can he measured. When the surface of the waveguide is exposed to different solutions, the peaks in the spectrum shift due to molecular interactions with the surface. Optical waveguide lightmode spectroscopy (OWLS) is a highly sensitive technique that is capable of real-time monitoring of these interactions. Since this integrated optical method is based on the measurement of the polarizability density (i.e., refractive index) in the vicinity of the waveguide surface, radioactive, fluorescent or other kinds of labeling are not required. In addition, measurement of at least two guided modes enables the absolute mass of adsorbed molecules to be determined. In this article, the technique will be described in some detail, and applications from different areas will be discussed. Selected examples will be presented to demonstrate how monitoring the modification of different metal oxides with polymers and the response of the coated oxides to biofluids help in the design of novel biomaterials; how OWLS is useful for accurate bioaffinity sensing, which is a key issue in the development of new drugs; and how the quantitative study of protein-DNA/RNA and cell surface interactions can enhance the understanding of processes in molecular and cellular biology. |
| Author | Textor, M Spencer, N.D Ramsden, J.J Csúcs, G Szendrő, I De Paul, S.M Vörös, J |
| Author_xml | – sequence: 1 givenname: J surname: Vörös fullname: Vörös, J email: voros@surface.mat.ethz.ch organization: Laboratory for Surface Science and Technology, ETH Materials, Zurich, Switzerland – sequence: 2 givenname: J.J surname: Ramsden fullname: Ramsden, J.J organization: Biozentrum, University of Basel, Basel, Switzerland – sequence: 3 givenname: G surname: Csúcs fullname: Csúcs, G organization: Laboratory for Biomechanics, Department of Materials, ETH Zurich, Zurich, Switzerland – sequence: 4 givenname: I surname: Szendrő fullname: Szendrő, I organization: MicroVacuum Ltd., Budapest, Hungary – sequence: 5 givenname: S.M surname: De Paul fullname: De Paul, S.M organization: Laboratory for Surface Science and Technology, ETH Materials, Zurich, Switzerland – sequence: 6 givenname: M surname: Textor fullname: Textor, M organization: Laboratory for Surface Science and Technology, ETH Materials, Zurich, Switzerland – sequence: 7 givenname: N.D surname: Spencer fullname: Spencer, N.D organization: Laboratory for Surface Science and Technology, ETH Materials, Zurich, Switzerland |
| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/12109695$$D View this record in MEDLINE/PubMed |
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| Keywords | Surface modification Adsorption kinetics Cell–surface interactions Optical grating coupler biosensors Lipid bilayers Protein–DNA interactions |
| Language | English |
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| PublicationTitle | Biomaterials |
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| Snippet | By incorporating a grating in a planar optical waveguide one creates a device with which the spectrum of guided lightmodes can be measured. When the surface of... By incorporating a grating in a planar optical waveguide one creates a device with which the spectrum of guided lightmodes can he measured. When the surface of... Optimal waveguide lightmode spectroscopy (OWLS) is a highly sensitive technique, capable of real-time monitoring of molecular interactions with the surface of... |
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| SubjectTerms | Adsorption Adsorption kinetics Biocompatible Materials - chemistry Biosensing Techniques - instrumentation Cell–surface interactions DNA - chemistry Kinetics Lipid bilayers Lipid Bilayers - chemistry Macromolecular Substances Materials Testing Membranes, Artificial Optical grating coupler biosensors Optics and Photonics - instrumentation Protein Binding Proteins - chemistry Protein–DNA interactions Surface modification Surface Properties |
| Title | Optical grating coupler biosensors |
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