Tuning the dynamic range and sensitivity of optical oxygen-sensors by employing differently substituted polystyrene-derivatives

Koren, Klaus; Hutter, Lukas; Enko, Barbara; Pein, Andreas; Borisov, Sergey M.; Klimant, Ingo

doi:10.1016/j.snb.2012.09.057

Cited by 39 publications

(24 citation statements)

References 25 publications

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“…Whereas polystyrene is known as a suitable matrix for the sensor dye with no tendency to dye aggregation (usually around 50 μs (ref. 35)), the decreased phosphorescence lifetime of PtTPTBPF in PPS at 0 hPa is most likely originating in this exact effect. Aggregation however did not affect the applicability of the sensor.…”

Section: Sensor Materials Compositionmentioning

confidence: 93%

Oxygen sensors for flow reactors – measuring dissolved oxygen in organic solvents

et al. 2019

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Section: Sensor Materials Compositionmentioning

confidence: 93%

Oxygen sensors for flow reactors – measuring dissolved oxygen in organic solvents

et al. 2019

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“…Direct conjugation of the nanosensor and enzyme, in addition to minimizing diffusion of the components, may also increase the sensitivity of the sensor system through more localized oxygen depletion which will in turn lower the minimal detection limit. The sensor response to oxygen levels can also be modulated through the choice of alternate dyes 12 or polymers 42 . Another important step towards longitudinal monitoring and improved sensitivity will be the incorporation of a reference fluorophore that is not sensitive to oxygen concentrations, which will enable ratiometric measurements.…”

Section: Resultsmentioning

confidence: 99%

Phosphorescent Nanosensors for in Vivo Tracking of Histamine Levels

Cash

Clark

2013

Anal. Chem.

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Continuously tracking bio-analytes in vivo will enable clinicians and researchers to profile normal physiology and monitor diseased states. Current in vivo monitoring system designs are limited by invasive implantation procedures and bio-fouling, limiting the utility of these tools for obtaining physiologic data. In this work, we demonstrate the first success in optically tracking histamine levels in vivo using a modular, injectable sensing platform based on a diamine oxidase and a phosphorescent oxygen nanosensor. Our new approach increases the range of measureable analytes by combining an enzymatic recognition element with a reversible nanosensor capable of measuring the effects of enzymatic activity. We use these enzyme nanosensors (EnzNS) to monitor the in vivo histamine dynamics as the concentration rapidly increases and decreases due to administration and clearance. The EnzNS system measured kinetics that match those reported from ex vivo measurements. This work establishes a modular approach to in vivo nanosensor design for measuring a broad range of potential target analytes. Simply replacing the recognition enzyme, or both the enzyme and nanosensor, can produce a new sensor system capable of measuring a wide range of specific analytical targets in vivo.

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“…For O 2 sensors the dynamic range of the sensor can be tuned by changing the analyte permeability of the matrix [95,96].…”

Section: Planar Optode Sensor Designmentioning

confidence: 99%

Two decades of chemical imaging of solutes in sediments and soils – a review

Santner

Larsen

Kreuzeder

et al. 2015

Analytica Chimica Acta

170

130

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The increasing appreciation of the small-scale (sub-mm) heterogeneity of biogeochemical processes in sediments, wetlands and soils has led to the development of several methods for high-resolution two-dimensional imaging of solute distribution in porewaters. Over the past decades, localised sampling of solutes (diffusive equilibration in thin films, diffusive gradients in thin films) followed by planar luminescent sensors (planar optodes) have been used as analytical tools for studies on solute distribution and dynamics. These approaches have provided new conceptual and quantitative understanding of biogeochemical processes regulating the distribution of key elements and solutes including O2, CO2, pH, redox conditions as well as nutrient and contaminant ion species in structurally complex soils and sediments. Recently these methods have been applied in parallel or integrated as so-called sandwich sensors for multianalyte measurements. Here we review the capabilities and limitations of the chemical imaging methods that are currently at hand, using a number of case studies, and provide an outlook on potential future developments for two-dimensional solute imaging in soils and sediments.

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Tuning the dynamic range and sensitivity of optical oxygen-sensors by employing differently substituted polystyrene-derivatives

Cited by 39 publications

References 25 publications

Oxygen sensors for flow reactors – measuring dissolved oxygen in organic solvents

Oxygen sensors for flow reactors – measuring dissolved oxygen in organic solvents

Phosphorescent Nanosensors for in Vivo Tracking of Histamine Levels

Two decades of chemical imaging of solutes in sediments and soils – a review

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