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Surface Plasmon Resonance: Sensitivity and Resolution
Linköping University, Department of Physics, Measurement Technology, Biology and Chemistry. Linköping University, The Institute of Technology.
2000 (English)Doctoral thesis, comprehensive summary (Other academic)
Abstract [en]

Surface plasmon resonance (SPR) is a frequently used technique for detection of biomolecular interactions at surfaces. The SPR phenomenon emanates from an electromagnetic surface wave that is exited by a light source. At excitation, the incident light is absorbed, either at a certain angle of incidence of the light, or at a certain wavelength, depending on the configuration of the SPR apparatus.

There is always a need for higher sensitivity, i.e. lower detection limits. This work shows how different parameters, like the SPR-metal, the prism, the wavelength, the detector, and the SPR-dip finding algorithm influence the sensitivity.

Many biochemical and biological interactions are complex, e.g. different interaction sites have different kinetic properties, or reaction complexes may show conformational changes. A measurement of a complex biochemical reaction often leads to a small signal superimposed on a large background. To be able to resolve the small signal, linearity errors of the instrument should be small. An SPR instrument utilizing an array detector will introduce linearity errors that may lead to misinterpretation of kinetic data. The linearity errors are quantified, both theoretically and experimentally, and possible misinterpretations are shown.

The response from an SPR apparatus is calculated from the relative change in position of the SPR dip using a dip finding algorithm. There are several different dip finding algorithms, which all have different properties. A dip finding algorithm should suppress noise, drifts, linearity errors, and enhance the resolution. The resolution is the smallest increment of the response that can be observed. It is limited by the resolution of the analogue to digital converter (ADC), and is highly dependent on the dip finding algorithm used and the number of pixels in the detector. Simulations show the relationships between the resolution of the response and the resolution of the ADC, the number of pixels in a detector, and the shape of an SPR-dip. By using a 1024-pixel detector anda 16-bit ADC, it is found that an instrumental resolution of 10-9 refractive index units should be possible to obtain.

There is a need for high throughput analysis of biochemical interactions, e.g. screening of medical substances. Therefore a multi wavelength imaging SPR apparatus is described that allows simultaneous analysis of many interactions with a high sensitivity.

Place, publisher, year, edition, pages
Linköping: Linköping University , 2000. , p. 30
Series
Linköping Studies in Science and Technology. Dissertations, ISSN 0345-7524 ; 624
National Category
Atom and Molecular Physics and Optics
Identifiers
URN: urn:nbn:se:liu:diva-185686Libris ID: 7624506ISBN: 9172196998 (print)OAI: oai:DiVA.org:liu-185686DiVA, id: diva2:1666248
Public defence
2000-04-06, Planck, Fysikhuset, Linköpings universitet, Linköping, 10:15
Opponent
Note

All or some of the partial works included in the dissertation are not registered in DIVA and therefore not linked in this post.

Available from: 2022-06-08 Created: 2022-06-08 Last updated: 2022-06-08Bibliographically approved
List of papers
1. Sensitivity deviation: Instrumental linearity errors that influence concentration analyses and kinetic evaluation of biomolecular interactions
Open this publication in new window or tab >>Sensitivity deviation: Instrumental linearity errors that influence concentration analyses and kinetic evaluation of biomolecular interactions
2000 (English)In: Biosensors & bioelectronics, ISSN 0956-5663, E-ISSN 1873-4235, Vol. 15, no 9-10, p. 503-509Article in journal (Refereed) Published
Abstract [en]

Many scientific instruments utilise multiple element detectors, e.g. CCD's or photodiode arrays, to monitor the change in a position of an optical pattern. For example, instruments for affinity biosensing based on surface plasmon resonance (SPR) or resonant mirror are equipped with such detectors. An important and desired property of these bioanalytical instruments is that the calculation of the movement or change in shape follows the true change. This is often not the case and it may lead to linearity errors, and to sensitivity errors. The sensitivity is normally defined as the slope of the calibration curve. A new parameter is introduced to account for the linearity errors, the sensitivity deviation, defined as the deviation from the undistorted slope of the calibration curve. The linearity error and the sensitivity deviation are intimately related and the sensitivity deviation may lead to misinterpretation of kinetic data, mass transport limitations and concentration analyses. Because the linearity errors are small (e.g. 10 pg/mm2 of biomolecules on the sensor surface) with regard to the dynamic range (e.g. 30 000 pg/mm2), they can be difficult to discover. However, the linearity errors are often not negligible with regard to a typical response (e.g. 0-100 pg/mm2), and may therefore cause serious problems. A method for detecting linearity errors is outlined. Further on, this paper demonstrates how integral linearity errors of less than 1% can result in a sensitivity deviation of 10%, a value that in our opinion cannot be ignored in biospecific interaction analysis (BIA). It should also be stressed out that this phenomenon also occurs in other instruments using array detectors. (C) 2000 Elsevier Science S.A.Many scientific instruments utilize multiple element detectors, e.g. CCD's or photodiode arrays, to monitor the change in a position of an optical pattern. For example, instruments for affinity biosensing based on surface plasmon resonance (SPR) or resonant mirror are equipped with such detectors. An important and desired property of these bioanalytical instruments is that the calculation of the movement or change in shape follows the true change. This is often not the case and it may lead to linearity errors, and to sensitivity errors. The sensitivity is normally defined as the slope of the calibration curve. A new parameter is introduced to account for the linearity errors, the sensitivity deviation, defined as the deviation from the undistorted slope of the calibration curve. The linearity error and the sensitivity deviation are intimately related and the sensitivity deviation may lead to misinterpretation of kinetic data, mass transport limitations and concentration analyses. Because the linearity errors are small (e.g. 10 pg/mm2 of biomolecules on the sensor surface) with regard to the dynamic range (e.g. 30 000 pg/mm2), they can be difficult to discover. However, the linearity errors are often not negligible with regard to a typical response (e.g. 0-100 pg/mm2), and may therefore cause serious problems. A method for detecting linearity errors is outlined. Further on, this paper demonstrates how integral linearity errors of less than 1% can result in a sensitivity deviation of 10%, a value that in our opinion cannot be ignored in biospecific interaction analysis (BIA). It should also be stressed out that this phenomenon also occurs in other instruments using array detectors.

National Category
Engineering and Technology
Identifiers
urn:nbn:se:liu:diva-47548 (URN)10.1016/S0956-5663(00)00109-3 (DOI)
Available from: 2009-10-11 Created: 2009-10-11 Last updated: 2022-06-08
2. Imaging surface plasmon resonance sensor based on multiple wavelengths: Sensitivity considerations
Open this publication in new window or tab >>Imaging surface plasmon resonance sensor based on multiple wavelengths: Sensitivity considerations
2000 (English)In: Review of Scientific Instruments, ISSN 0034-6748, E-ISSN 1089-7623, Vol. 71, no 9, p. 3530-3538Article in journal (Refereed) Published
Abstract [en]

A new, multiple wavelength surface plasmon resonance apparatus for imaging applications is presented. It can be used for biosensing, e.g., for monitoring of chemical and biological reactions in real time with label-free molecules. A setup with a fixed incident angle in the Kretschmann configuration with gold as the supporting metal is described, both theoretically and experimentally. Simulations of the sensor response based on independently recorded optical (ellipsometric) data of gold show that the sensitivity for three-dimensional recognition layers (bulk) increases with increasing wavelength. For two-dimensional recognition layers (adlayer) maximum sensitivity is obtained within a limited wavelength range. In this situation, the rejection of bulk disturbances, e.g., emanating from temperature variations, decreases, with increasing wavelength. For imaging surface plasmon resonance the spatial resolution decreases with increasing wavelength. Hence, there is always a compromise between spatial resolution, bulk disturbance rejection, and sensitivity. Most importantly, by simultaneously using multiple wavelengths, it is possible to maintain a high sensitivity and accuracy over a large dynamic range. Furthermore, our simulations show that the sensitivity is independent of the refractive index of the prism. (C) 2000 American Institute of Physics. [S0034-6748(00)02909-9].

National Category
Engineering and Technology
Identifiers
urn:nbn:se:liu:diva-49611 (URN)
Available from: 2009-10-11 Created: 2009-10-11 Last updated: 2022-06-08

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