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Main Authors: Ahmerkamp, Soeren, Pacherres, Cesar O, Mosshammer, Maria, Godefroid, Mathilde, Wind-Hansen, Michael, Kuypers, Marcel, Behrendt, Lars, Koren, Klaus, Kühl, Michael
Format: Artículo científico
Language:en
Published: ACS sensors 2024
Subjects:
Online Access:https://pubmed.ncbi.nlm.nih.gov/39401449/
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author Ahmerkamp, Soeren
Pacherres, Cesar O
Mosshammer, Maria
Godefroid, Mathilde
Wind-Hansen, Michael
Kuypers, Marcel
Behrendt, Lars
Koren, Klaus
Kühl, Michael
author_facet Ahmerkamp, Soeren
Pacherres, Cesar O
Mosshammer, Maria
Godefroid, Mathilde
Wind-Hansen, Michael
Kuypers, Marcel
Behrendt, Lars
Koren, Klaus
Kühl, Michael
Ahmerkamp, Soeren
Pacherres, Cesar O
Mosshammer, Maria
Godefroid, Mathilde
Wind-Hansen, Michael
Kuypers, Marcel
Behrendt, Lars
Koren, Klaus
Kühl, Michael
collection PubMed - marine biology
contents Novel Approach for Lifetime-Proportional Luminescence Imaging Using Frame Straddling. Ahmerkamp, Soeren Pacherres, Cesar O Mosshammer, Maria Godefroid, Mathilde Wind-Hansen, Michael Kuypers, Marcel Behrendt, Lars Koren, Klaus Kühl, Michael Luminescent Measurements Luminescence Oxygen Optode-based chemical imaging is a rapidly evolving field that has substantially enhanced our understanding of the role of microenvironments and chemical gradients in biogeochemistry, microbial ecology, and biomedical sciences. Progress in sensor chemistry has resulted in a broadened spectrum of analytes, alongside enhancements in sensor performance (e.g., sensitivity, brightness, and photostability). However, existing imaging techniques are often costly, challenging to implement, and limited in their recording speed. Here we use the "frame-straddling" technique, originally developed for particle image velocimetry for imaging the O-dependent, integrated luminescence decay of optical O sensor materials. The method synchronizes short excitation pulses and camera exposures to capture two frames at varying brightness, where the first excitation pulse occurs at the end of the exposure of the first frame and the second excitation pulse at the beginning of the second frame. Here the first frame truncates the luminescence decay, whereas the second frame fully captures it. The difference between the frames quantifies the integral of the luminescence decay curve, which is proportional to the luminescence lifetime, at time scales below one millisecond. Short excitation pulses avoid depopulation of the ground state of luminophores, resulting in a linear Stern-Volmer response with increasing concentrations of the quencher (O), which can be predicted through a simple model. This methodology is compatible with a wide range of camera systems, making it a versatile tool for various optode based chemical imaging applications. We showcase the utility of frame straddling in measuring O dynamics around algae and by observing O scavenging sodium dithionite particles sinking through oxygenated water.
format Artículo científico
id pubmed_39401449
institution PubMed
language en
publishDate 2024
publisher ACS sensors
record_format pubmed
spellingShingle Novel Approach for Lifetime-Proportional Luminescence Imaging Using Frame Straddling.
Ahmerkamp, Soeren
Pacherres, Cesar O
Mosshammer, Maria
Godefroid, Mathilde
Wind-Hansen, Michael
Kuypers, Marcel
Behrendt, Lars
Koren, Klaus
Kühl, Michael
Luminescent Measurements
Luminescence
Oxygen
Novel Approach for Lifetime-Proportional Luminescence Imaging Using Frame Straddling. Ahmerkamp, Soeren Pacherres, Cesar O Mosshammer, Maria Godefroid, Mathilde Wind-Hansen, Michael Kuypers, Marcel Behrendt, Lars Koren, Klaus Kühl, Michael Luminescent Measurements Luminescence Oxygen Optode-based chemical imaging is a rapidly evolving field that has substantially enhanced our understanding of the role of microenvironments and chemical gradients in biogeochemistry, microbial ecology, and biomedical sciences. Progress in sensor chemistry has resulted in a broadened spectrum of analytes, alongside enhancements in sensor performance (e.g., sensitivity, brightness, and photostability). However, existing imaging techniques are often costly, challenging to implement, and limited in their recording speed. Here we use the "frame-straddling" technique, originally developed for particle image velocimetry for imaging the O-dependent, integrated luminescence decay of optical O sensor materials. The method synchronizes short excitation pulses and camera exposures to capture two frames at varying brightness, where the first excitation pulse occurs at the end of the exposure of the first frame and the second excitation pulse at the beginning of the second frame. Here the first frame truncates the luminescence decay, whereas the second frame fully captures it. The difference between the frames quantifies the integral of the luminescence decay curve, which is proportional to the luminescence lifetime, at time scales below one millisecond. Short excitation pulses avoid depopulation of the ground state of luminophores, resulting in a linear Stern-Volmer response with increasing concentrations of the quencher (O), which can be predicted through a simple model. This methodology is compatible with a wide range of camera systems, making it a versatile tool for various optode based chemical imaging applications. We showcase the utility of frame straddling in measuring O dynamics around algae and by observing O scavenging sodium dithionite particles sinking through oxygenated water.
title Novel Approach for Lifetime-Proportional Luminescence Imaging Using Frame Straddling.
topic Luminescent Measurements
Luminescence
Oxygen
url https://pubmed.ncbi.nlm.nih.gov/39401449/