Dual-lifetime referencing (DLR): a powerful method for on-line measurement of internal pH in carrier-bound immobilized biocatalysts

Boniello, Caterina; Mayr, Torsten; Bolívar, Juan M.; Nidetzky, Bernd

doi:10.1186/1472-6750-12-11

Cited by 38 publications

(44 citation statements)

References 26 publications

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“…Self-referenced measurements and fluorescence lifetime [191] determinations exhibit superior analytical performance in agitated systems. Dual lifetime referencing (DLR), in particular [170,171,192], offers high versatility, independent on catalyst concentration, reactor configuration and scale of operation [170,171].…”

Section: Opto-chemical Internal Sensing Of Ph and Omentioning

confidence: 99%

Advanced characterization of immobilized enzymes as heterogeneous biocatalysts

2016

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Section: Opto-chemical Internal Sensing Of Ph and Omentioning

confidence: 99%

Advanced characterization of immobilized enzymes as heterogeneous biocatalysts

2016

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“…The sensor spot's indicator pK a can be altered with different immobilisation approaches, such as the type of membrane and support matrix used [12]. Immobilisation in more hydrophilic membranes such as cellulose results in smaller pK a changes compared to more hydrophobic membranes such as polyurethane hydrogels [42]. Crosslinking within the membrane may change the pore size, while charges in the membrane can affect both the sensitivity and pK a [43].…”

Section: Immobilised Sensing Spotsmentioning

confidence: 99%

Characterisation and deployment of an immobilised pH sensor spot towards surface ocean pH measurements

Clarke

Achterberg

Rérolle

et al. 2015

Analytica Chimica Acta

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The oceans are a major sink for anthropogenic atmospheric carbon dioxide, and the uptake causes changes to the marine carbonate system and has wide ranging effects on flora and fauna. It is crucial to develop analytical systems that allow us to follow the increase in oceanic pCO2 and corresponding reduction in pH. Miniaturised sensor systems using immobilised fluorescence indicator spots are attractive for this purpose because of their simple design and low power requirements. The technology is increasingly used for oceanic dissolved oxygen measurements. We present a detailed method on the use of immobilised fluorescence indicator spots to determine pH in ocean waters across the pH range 7.6-8.2. We characterised temperature (-0.046 pH/°C from 5 to 25 °C) and salinity dependences (-0.01 pH/psu over 5-35), and performed a preliminary investigation into the influence of chlorophyll on the pH measurement. The apparent pKa of the sensor spots was 6.93 at 20 °C. A drift of 0.00014 R (ca. 0.0004 pH, at 25 °C, salinity 35) was observed over a 3 day period in a laboratory based drift experiment. We achieved a precision of 0.0074 pH units, and observed a drift of 0.06 pH units during a test deployment of 5 week duration in the Southern Ocean as an underway surface ocean sensor, which was corrected for using certified reference materials. The temperature and salinity dependences were accounted for with the algorithm, R=0.00034-0.17·pH+0.15·S(2)+0.0067·T-0.0084·S·1.075. This study provides a first step towards a pH optode system suitable for autonomous deployment. The use of a short duration low power illumination (LED current 0.2 mA, 5 μs illumination time) improved the lifetime and precision of the spot. Further improvements to the pH indicator spot operations include regular application of certified reference materials for drift correction and cross-calibration against a spectrophotometric pH system. Desirable future developments should involve novel fluorescence spots with improved response time and apparent pKa values closer to the pH of surface ocean waters.

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“…In operando characterization of the catalyst (i.e. : in realistic conditions of applications of the biocatalyst) have been carried out by applying diverse analytical methods directly within the solid support: examples include optochemical sensing [68][69][70][71] as well as spectroscopic imaging and electrochemical sensing (see table 5 in reference [51]). These methods yield direct handle on reagents' local concentration, gradients and diffusion properties with both temporal and spatial information.…”

Section: Applications and Characterization Of Immobilized Enzymesmentioning

confidence: 99%

“…The introduction of NMR of sedimented solutes [69][70][71] has lifted the needs for crystallization in the case of soluble proteins, yielding access to soluble but non-crystallizing targets such as PEGylated proteins [130]. However, as seen by NMR, biomaterials are complex entities: the protein and the inorganic matrix interplay to define physicochemical characteristics of the composite, in terms of mobility, hydration, etc.…”

Section: Biomaterials From the Nmr Standpointmentioning

confidence: 99%