INTRODUCTION: In previous studies we and others have demonstrated the usefulness of violet laser diodes (VLDs) as replacement laser sources for krypton-ion lasers on stream-in-air cytometers. Previously available VLDs had a maximum available power of less than 25 mW; this was sufficient for excitation of densely labeled cell surface antigens using fluorochromes such as Cascade Blue or Pacific Blue, but may have been insufficient for applications requiring higher levels of photon saturation, such as low-level expression of Cyan Fluorescent Protein (ECFP) in CFP-YFP FRET applications. In this follow-up study, we have tested more powerful VLDs emitting at 55 mW, and a beam-merged dual module VLD with 100 mW combined output, for their ability to excite a variety of violet-excited fluorochromes, including CFP. METHODS: A dual module VLD (two linear polarized VLDs with their beams merged by a polarized beam combiner) emitting at 404 nm was mounted on a BD FACSVantage DiVa stream-in-air cytometer. The individual polarized 55 mW beams or the 100 mW combined beams were used to analyze PBMCs labeled with the violet-excited probes Cascade Blue, Alexa Fluor 405, Cascade Yellow and Pacific Orange dyes. Violet-excited fluorescent microsphere mixtures with decreasing fluorescence levels were also used to detect the minimum sensitivity threshold and precision of these lasers. VLD excitation on a gel-coupled cuvette flow cytometer was used as a sensitivity baseline. RESULTS: The dual module 100 mW VLD gave both sensitivity and precision levels approaching that observed for lower-power sources on a cuvette cytometer. Single polarized VLD modules at 55 mW gave slightly decreased sensitivity for the microspheres standards and all the tested fluorochromes compared to the 100 mW source. CONCLUSIONS: While 55 mW laser sources performed adequately in the stream-in-air format, increasing the power to 100 mW did give a small but detectable increase in instrument sensitivity. This sensitivity level approached that of cuvette systems. (c) 2006 International Society for Analytical Cytology.
INTRODUCTION: In previous studies we and others have demonstrated the usefulness of violet laser diodes (VLDs) as replacement laser sources for krypton-ion lasers on stream-in-air cytometers. Previously available VLDs had a maximum available power of less than 25 mW; this was sufficient for excitation of densely labeled cell surface antigens using fluorochromes such as Cascade Blue or Pacific Blue, but may have been insufficient for applications requiring higher levels of photon saturation, such as low-level expression of Cyan Fluorescent Protein (ECFP) in CFP-YFP FRET applications. In this follow-up study, we have tested more powerful VLDs emitting at 55 mW, and a beam-merged dual module VLD with 100 mW combined output, for their ability to excite a variety of violet-excited fluorochromes, including CFP. METHODS: A dual module VLD (two linear polarized VLDs with their beams merged by a polarized beam combiner) emitting at 404 nm was mounted on a BD FACSVantage DiVa stream-in-air cytometer. The individual polarized 55 mW beams or the 100 mW combined beams were used to analyze PBMCs labeled with the violet-excited probes Cascade Blue, Alexa Fluor 405, Cascade Yellow and Pacific Orange dyes. Violet-excited fluorescent microsphere mixtures with decreasing fluorescence levels were also used to detect the minimum sensitivity threshold and precision of these lasers. VLD excitation on a gel-coupled cuvette flow cytometer was used as a sensitivity baseline. RESULTS: The dual module 100 mW VLD gave both sensitivity and precision levels approaching that observed for lower-power sources on a cuvette cytometer. Single polarized VLD modules at 55 mW gave slightly decreased sensitivity for the microspheres standards and all the tested fluorochromes compared to the 100 mW source. CONCLUSIONS: While 55 mW laser sources performed adequately in the stream-in-air format, increasing the power to 100 mW did give a small but detectable increase in instrument sensitivity. This sensitivity level approached that of cuvette systems. (c) 2006 International Society for Analytical Cytology.
Authors: Veena Kapoor; Vladimir Karpov; Claudette Linton; Fedor V Subach; Vladislav V Verkhusha; William G Telford Journal: Cytometry A Date: 2008-06 Impact factor: 4.355
Authors: T Kalina; J Flores-Montero; V H J van der Velden; M Martin-Ayuso; S Böttcher; M Ritgen; J Almeida; L Lhermitte; V Asnafi; A Mendonça; R de Tute; M Cullen; L Sedek; M B Vidriales; J J Pérez; J G te Marvelde; E Mejstrikova; O Hrusak; T Szczepański; J J M van Dongen; A Orfao Journal: Leukemia Date: 2012-09 Impact factor: 11.528