Optode: Difference between revisions
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{{Short description|Optical sensor device to measure a specific substance usually with the aid of a chemical transducer}} |
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{{Refimprove|date=March 2013}} |
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An '''optode''' or '''optrode''' is an optical [[sensor]] device that optically measures a specific substance usually with the aid of a chemical [[transducer]].<ref name="Neuroscience University of Toronto">{{cite book|last1=Ju|first1=William|title=Neuroscience|location=Toronto|publisher=University of Toronto|date= November 1, 2023|url=https://ecampusontario.pressbooks.pub/neurosciencecdn/chapter/3-2-molecular-toolbox-neural-circuits-the-basics/|at=3.2 Molecular toolbox - Neuroal Circuits: The Basics}}</ref> |
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==Construction== |
==Construction== |
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An optode requires three components to function: a chemical that responds to an [[analyte]], a [[polymer]] to immobilise the chemical transducer and instrumentation ([[Optical fiber|optical fibre]], [[Light|light source]], detector and other electronics). Optodes usually have the polymer matrix coated onto the tip of an optical fibre, but in the case of [[evanescent wave]] optodes the polymer is coated on a section of fibre that has been unsheathed. |
An optode requires three components to function: a chemical that responds to an [[analyte]], a [[polymer]] to immobilise the chemical transducer and instrumentation ([[Optical fiber|optical fibre]], [[Light|light source]], detector and other electronics). Optodes usually have the polymer matrix coated onto the tip of an optical fibre, but in the case of [[evanescent wave]] optodes the polymer is coated on a section of fibre that has been unsheathed.{{cn|date=May 2021}} |
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==Operation== |
==Operation== |
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Optodes can apply various optical measurement schemes such as [[reflection]], [[absorption]], evanescent wave, [[luminescence]] ([[fluorescence]] and [[phosphorescence]]s), [[chemiluminescence]], [[surface plasmon resonance]]. By far the most popular methodology is luminescence. |
Optodes can apply various optical measurement schemes such as [[Reflection (physics)|reflection]], [[absorption (electromagnetic radiation)|absorption]], evanescent wave, [[luminescence]] ([[fluorescence]] and [[phosphorescence]]s), [[chemiluminescence]], [[surface plasmon resonance]]. By far the most popular methodology is luminescence. |
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Luminescence in solution obeys the linear [[ |
Luminescence in solution obeys the linear [[Stern–Volmer relationship]]. Fluorescence of a molecule is [[Quenching (fluorescence)|quenched]] by specific analytes, e.g., [[ruthenium]] complexes are quenched by oxygen. When a [[fluorophore]] is immobilised within a polymer matrix myriad micro-environments are created. The micro-environments reflect varying diffusion co-efficients for the analyte. This leads to a [[Nonlinearity|non-linear]] relationship between the fluorescence and the quencher (analyte). This relationship is modelled in various ways, the most popular model is the two site model created by James Demas (University of Virginia). |
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The signal (fluorescence) to oxygen ratio is not linear, and an optode is most sensitive at low oxygen concentration, i.e. the sensitivity decreases as oxygen concentration increases. The optode sensors can however work in the whole region |
The signal (fluorescence) to oxygen ratio is not linear, and an optode is most sensitive at low oxygen concentration, i.e., the sensitivity decreases as oxygen concentration increases. The optode sensors can however work in the whole region 0–100% [[oxygen saturation]] in water, and the calibration is done the same way as with the [[Clark electrode|Clark type sensor]]. No oxygen is consumed and hence the sensor is stirring insensitive, but the signal will stabilize more quickly if the sensor is stirred after being put into the sample. |
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==Popularity== |
==Popularity== |
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Optical sensors are growing in popularity due to the low-cost, low power requirements and long term stability. They provide viable alternatives to electrode-based sensors or more complicated analytical instrumentation. |
Optical sensors are growing in popularity due to the low-cost, low power requirements and long term stability. They provide viable alternatives to electrode-based sensors or more complicated analytical instrumentation, especially in the field of [[environmental monitoring]]<ref>Tengberg A, Hovdenes J, Andersson H, Brocandel O, Diaz R, Hebert D, Arnerich T, Huber C, Kortzinger A, Khripounoff Alexis, Rey F, Ronning C, Schimanski J, Sommer S, Stangelmayer A (2006). Evaluation of a lifetime-based optode to measure oxygen in aquatic systems. Limnology and Oceanography methods, 4, 7-17. Open Access version : http://archimer.ifremer.fr/doc/00000/1413/</ref> although in the case of oxygen optrodes, they do not have the resolution as the most recent cathodic [[Sensor|microsensors]].<ref>Revsbech NP, Thamdrup B, Dalsgaard T, Canfield DE (2011). Construction of STOX oxygen sensors and their application for determination of O2 concentrations in oxygen minimum zones. Methods Enzymol, 486:325-41.</ref> |
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Major international conferences are devoted to their development e.g Europtrode VIII Tubeingen 2006, OFS 18, Cancun 2006. |
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==See also== |
==See also== |
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[[Oxygen sensor]] |
*[[Oxygen sensor]] |
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==References== |
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{{Reflist}} |
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[[Category:Optical devices]] |
[[Category:Optical devices]] |
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[[Category:Spectroscopy]] |
[[Category:Spectroscopy]] |
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[[Category:Fluorescence]] |
[[Category:Fluorescence]] |
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{{Tech-stub}} |
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Latest revision as of 14:28, 8 January 2024
 | This article needs additional citations for verification. (March 2013) |
An optode or optrode is an optical sensor device that optically measures a specific substance usually with the aid of a chemical transducer.[1]
Construction
[edit]An optode requires three components to function: a chemical that responds to an analyte, a polymer to immobilise the chemical transducer and instrumentation (optical fibre, light source, detector and other electronics). Optodes usually have the polymer matrix coated onto the tip of an optical fibre, but in the case of evanescent wave optodes the polymer is coated on a section of fibre that has been unsheathed.[citation needed]
Operation
[edit]Optodes can apply various optical measurement schemes such as reflection, absorption, evanescent wave, luminescence (fluorescence and phosphorescences), chemiluminescence, surface plasmon resonance. By far the most popular methodology is luminescence.
Luminescence in solution obeys the linear Stern–Volmer relationship. Fluorescence of a molecule is quenched by specific analytes, e.g., ruthenium complexes are quenched by oxygen. When a fluorophore is immobilised within a polymer matrix myriad micro-environments are created. The micro-environments reflect varying diffusion co-efficients for the analyte. This leads to a non-linear relationship between the fluorescence and the quencher (analyte). This relationship is modelled in various ways, the most popular model is the two site model created by James Demas (University of Virginia).
The signal (fluorescence) to oxygen ratio is not linear, and an optode is most sensitive at low oxygen concentration, i.e., the sensitivity decreases as oxygen concentration increases. The optode sensors can however work in the whole region 0–100% oxygen saturation in water, and the calibration is done the same way as with the Clark type sensor. No oxygen is consumed and hence the sensor is stirring insensitive, but the signal will stabilize more quickly if the sensor is stirred after being put into the sample.
Popularity
[edit]Optical sensors are growing in popularity due to the low-cost, low power requirements and long term stability. They provide viable alternatives to electrode-based sensors or more complicated analytical instrumentation, especially in the field of environmental monitoring[2] although in the case of oxygen optrodes, they do not have the resolution as the most recent cathodic microsensors.[3]
See also
[edit]References
[edit]- ^ Ju, William (November 1, 2023). Neuroscience. Toronto: University of Toronto. 3.2 Molecular toolbox - Neuroal Circuits: The Basics.
- ^ Tengberg A, Hovdenes J, Andersson H, Brocandel O, Diaz R, Hebert D, Arnerich T, Huber C, Kortzinger A, Khripounoff Alexis, Rey F, Ronning C, Schimanski J, Sommer S, Stangelmayer A (2006). Evaluation of a lifetime-based optode to measure oxygen in aquatic systems. Limnology and Oceanography methods, 4, 7-17. Open Access version : http://archimer.ifremer.fr/doc/00000/1413/
- ^ Revsbech NP, Thamdrup B, Dalsgaard T, Canfield DE (2011). Construction of STOX oxygen sensors and their application for determination of O2 concentrations in oxygen minimum zones. Methods Enzymol, 486:325-41.