2006
DOI: 10.1002/cyto.a.20326
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High intensity solid‐state UV source for time‐gated luminescence microscopy

Abstract: Background: The unique discriminative ability of immunofluorescent probes can be severely compromised when probe emission competes against naturally occurring, intrinsically fluorescent substances (autofluorophores). Luminescence microscopes that operate in the timedomain can selectively resolve probes with long fluorescence lifetimes (s > 100 ls) against short-lived fluorescence to deliver greatly improved signal-to-noise ratio (SNR). A novel time-gated luminescence microscope design is reported that employs … Show more

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Cited by 46 publications
(71 citation statements)
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“…Output power and temporal parameters of LEDs can be controlled easily by simple electronics in contrast to flash lamp electronics. The technological advancement of LEDs has already resulted in the development of the lanthanide chelates based time-resolved systems using LED excitation at 365 nm [9]. A 100 mW single LED at 365 nm with pulse duration of 101 μs and a gate delay of 5 μs was employed for excitation in time-gated luminescence microscopy [9].…”
Section: Introductionmentioning
confidence: 99%
See 1 more Smart Citation
“…Output power and temporal parameters of LEDs can be controlled easily by simple electronics in contrast to flash lamp electronics. The technological advancement of LEDs has already resulted in the development of the lanthanide chelates based time-resolved systems using LED excitation at 365 nm [9]. A 100 mW single LED at 365 nm with pulse duration of 101 μs and a gate delay of 5 μs was employed for excitation in time-gated luminescence microscopy [9].…”
Section: Introductionmentioning
confidence: 99%
“…The technological advancement of LEDs has already resulted in the development of the lanthanide chelates based time-resolved systems using LED excitation at 365 nm [9]. A 100 mW single LED at 365 nm with pulse duration of 101 μs and a gate delay of 5 μs was employed for excitation in time-gated luminescence microscopy [9]. LEDs at 365 nm were also used in a time-resolved luminescence microscope for pulsed epi-illumination [10].…”
Section: Introductionmentioning
confidence: 99%
“…The UV optics match the peak absorption (300-330 nm) for the most biocompatible terbium complexes (9,18,21). A 0.5-mW, 315 nm LED source (UVTOP310 with a hemispherical lens window, Sensor Electronic Technology, Columbia, SC, USA, http://www.s-et.com) replaced the previously reported highpower, 365 nm (UV) LED (1,31); since the typical objective lens and cover slip glass cut-off transmission is below 330 nm, a MicroSpot Focusing UV objective 403, 240-360 nm, and NA 5 0.50 (Thorlabs, LMU-40X-UVB, http://www.thorlabs. com/) was used for epi-illumination.…”
Section: Methodsmentioning
confidence: 99%
“…The sample was then washed three times with the mAb buffer. Subsequently, 20 lL of the diluted LanthaScreen 1 Tb-Streptavidin conjugate solution (50 lg/mL) was added and allowed to react for another 2 hr. This was followed by one wash with 400 lL of the mAb buffer to prepare the Cryptosporidium parvum oocysts in 100 lL suspension for microscopy imaging.…”
Section: Cryptosporidium Labelingmentioning
confidence: 99%
“…Also in this issue, a multicontinent collaboration is reported by Yiqing Lu et al describing an approach for the automated detection of rare-event pathogens through time-gated luminescence scanning microscopy. It has been recognized that luminescence microscopes operating in the time-domain can improve the detection of signals from long fluorescence lifetimes (tau > 100 microseconds) in a background of short-lived autofluorescence lifetime noise frequently observed in micro-organisms (10). The team addressed the need to improve methods for the rapid detection of infectious disease, in particular monitoring waterborne pathogenic microorganisms in recreational waters (typically, Giardia lamblia cysts and Cryptosporidium parvum oocysts).…”
mentioning
confidence: 99%