Fluorescent-particle analyzer with timing alignment for analog pulse subtraction of fluorescent pulses arising from different excitation locations
First Claim
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1. A fluorescence analyzer comprising:
- an excitation source for illuminating a first location with a first excitation wavelength and a second location with a second excitation wavelength;
motion means for relatively guiding a sample particle and timing particles past said first location and then past said second location at a predetermined velocity;
an optical subsystem for directing radiation from said first and second locations;
photodetector means for providing pulses in response to changes in said radiation that occur while one of said particles is at one of said locations, said photodetector means providing a first set of undelayed first fluorescence pulses including at least one undelayed first fluorescence pulse when said sample particle is at said first location, said photodetector means providing a second set of second fluorescence pulses including at least one undelayed second fluorescence pulse when said sample particle is at said second location, said photodetector providing first timing pulses at times when one of said timing particles is at said first location, said photodetector providing second timing pulses at times when one of said timing particles is at said second location;
variable delay means for delaying each undelayed first fluorescence pulse of said first set relative to each undelayed second fluorescence pulse of said second set to yield a set of delayed first fluorescence pulses, said delay means delaying said undelayed first timing pulses to yield respective delayed first timing pulses, said delay means having a delay control input;
pulse detection means for providing timing indications corresponding to predetermined reference points on said timing pulses, said pulse detection means being coupled to said photodetector means for receiving said first timing pulses and said second timing pulses;
controller means for adjusting said delay means to control the timing alignment of said set of delayed first fluorescence pulses with respect to said set of undelayed second fluorescence pulses, said controller means being coupled to said delay means for controlling the delay between said each undelayed second fluorescence pulse and said each delayed first fluorescence pulse, said controller means being coupled to said pulse detection means for receiving said timing indications therefrom, said controller means determining a timing error from said timing indications, said controller means adjusting said delay means so as to reduce said timing error when said timing error exceeds a predetermined error tolerance; and
pulse subtraction means for providing a difference pulse proportional to one of said fluorescence pulses less an amount that varies linearly with said undelayed second fluorescence pulse, said pulse subtraction means having at least a first input coupled to said delay means for receiving said delayed first set, said pulse subtraction means having at least a second input to said photodetector means for receiving said second set.
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Abstract
A flow cytometry system includes a flow tube through which particles marked with different fluorochromes pass from a first location, illuminated by a red laser, to a second location, illuminated by a blue laser. A "red" photodetector is optically coupled to detect red fluorescence from both locations. "Yellow" and "green" photodetectors respectively detect yellow and green fluorescence from the second location, while a "scattered light" detector detects scattered light from the second location. During a sample run, the red photodetector can output pulses that correspond primarily to APC fluorochrome at the first location and to PerCP at the second location respectively. A delay device delays the APC pulse relative to the PerCP pulse so that the peaks can be scaled and subtracted in the analog electrical domain to remove APC/PerCP crosstalk. The delay is calibrated using a set of APC tagged cells. Each of these cells generates a red fluorescence electrical pulse while at the first location and a scattered light pulse while at the second location. The average time differential between these two pulses for the set of timing cells determines the target delay. This is compared with the actual delay imposed by the delay device. If the error is greater than 0.5 μS, the imposed delay can be adjusted until the delay is below 0.5 μS, or within the tolerance required for reliable difference pulses to be generated by the pulse subtractor.
188 Citations
5 Claims
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1. A fluorescence analyzer comprising:
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an excitation source for illuminating a first location with a first excitation wavelength and a second location with a second excitation wavelength; motion means for relatively guiding a sample particle and timing particles past said first location and then past said second location at a predetermined velocity; an optical subsystem for directing radiation from said first and second locations; photodetector means for providing pulses in response to changes in said radiation that occur while one of said particles is at one of said locations, said photodetector means providing a first set of undelayed first fluorescence pulses including at least one undelayed first fluorescence pulse when said sample particle is at said first location, said photodetector means providing a second set of second fluorescence pulses including at least one undelayed second fluorescence pulse when said sample particle is at said second location, said photodetector providing first timing pulses at times when one of said timing particles is at said first location, said photodetector providing second timing pulses at times when one of said timing particles is at said second location; variable delay means for delaying each undelayed first fluorescence pulse of said first set relative to each undelayed second fluorescence pulse of said second set to yield a set of delayed first fluorescence pulses, said delay means delaying said undelayed first timing pulses to yield respective delayed first timing pulses, said delay means having a delay control input; pulse detection means for providing timing indications corresponding to predetermined reference points on said timing pulses, said pulse detection means being coupled to said photodetector means for receiving said first timing pulses and said second timing pulses; controller means for adjusting said delay means to control the timing alignment of said set of delayed first fluorescence pulses with respect to said set of undelayed second fluorescence pulses, said controller means being coupled to said delay means for controlling the delay between said each undelayed second fluorescence pulse and said each delayed first fluorescence pulse, said controller means being coupled to said pulse detection means for receiving said timing indications therefrom, said controller means determining a timing error from said timing indications, said controller means adjusting said delay means so as to reduce said timing error when said timing error exceeds a predetermined error tolerance; and pulse subtraction means for providing a difference pulse proportional to one of said fluorescence pulses less an amount that varies linearly with said undelayed second fluorescence pulse, said pulse subtraction means having at least a first input coupled to said delay means for receiving said delayed first set, said pulse subtraction means having at least a second input to said photodetector means for receiving said second set. - View Dependent Claims (2, 3, 4)
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5. A method comprising the steps of:
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illuminating a first location with radiation of a first wavelength and illuminating a second location with radiation of a second wavelength; flowing serially a set of timing particles past said first and second locations in that order; for said timing particles, generating a respective undelayed first timing pulses when said timing particles respectively reach said first location and generating respective undelayed second timing pulses when said timing particle respectively reach said second location; using a delay device, delaying said undelayed first timing pulses to yield respective delayed first timing pulses; determining a timing error between said delayed first timing pulses and said undelayed second timing pulses; if said error is greater than a predetermined tolerance, adjusting said delay device to reduce said error below said tolerance; flowing a fluorescent particle past said first and second locations in that order; detecting fluorescence emitted by said particle so as to generate an undelayed first fluorescence pulse while said fluorescent particle is at said first location and so as to generate an undelayed second fluorescence pulse while said fluorescent particle is at said second location; using said delay device, delaying said undelayed first fluorescence pulse; and subtracting from one of said delayed first fluorescence pulse and said undelayed second fluorescence pulse a fraction of said second pulse.
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Specification
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Current AssigneeBecton, Dickinson & Co
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Original AssigneeBecton, Dickinson & Co
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InventorsHoffman, Michael A.
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Primary Examiner(s)Tokar, Michael J.
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Assistant Examiner(s)TYLER, VIRGIL O
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Application NumberUS08/417,744Time in Patent Office936 DaysField of Search250/458.1, 250/459.1, 250/462.1, 250/226, 356/411, 356/39, 348/343, 348/344US Class Current250/458.1CPC Class CodesG01N 15/14 Optical investigation techn...G01N 2015/1438 Using two lasers in succession
