Cell size measurements using light in flow cytometry and cell sorting
First Claim
1. A new and improved method of measuring the size of a biological cell in a flow cytometer, comprising the steps of:
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Abstract
In a flow cytometer where the laser beam is larger than the size of each biological cell of a column of cells being passed through the laser beam at a high rate wherein new and improved method and means are used to calculate the size of the cells as sensed by low angle forward light scatter or secondary emission of fluorescent material on the surface of the cell by measuring the time-of-flight of the smaller cell across the laser beam, with the time-of-flight being measured by integrating an electrical signal from either the forward light scatter or the secondary flourescent emission from a single cell as it passes through the laser beam and deriving still another electrical signal measuring the peak amplitude of the first signal and then dividing the integrated signal by the peak signal and subtracting a constant electrical signal from that quotient.
100 Citations
12 Claims
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1. A new and improved method of measuring the size of a biological cell in a flow cytometer, comprising the steps of:
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2. Directing said biological cells in column flow at a constant velocity;
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2. Passing a laser beam having a cross section larger than each of said cells through said biological cells in column flow so that only one biological cell passes through said laser beam at a time; 3. Measuring the time of flight of each said biological cell through said laser beam deriving an electrical signal commensurate with the width and/or volume of each said biological cell by a. deriving a first electrical signal from the low angle forward light scatter characteristic or secondary fluorescent emission from a single cell as it passes through the said laser beam; b. deriving a second electrical signal having an amplitude determined by the time integral of said first electrical signal; c. deriving a third electrical signal having an amplitude equal to the peak (maximum) amplitude of said first electrical signal; d. deriving a fourth electrical signal by dividing the said second electrical signal by the said third electrical signal therefore deriving an electrical signal commensurate with the width of each said biological cell plus the width of the laser beam; e. deriving a fifth electrical signal by subtracting from said fourth electrical signal a constant electrical signal proportional to the width of the said laser beam whereby the fifth electrical signal is directly proportional to the width of said biological cell. - View Dependent Claims (5, 8, 11)
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- 3. A new and improved flow cytometer means for measuring the size of a biological cell, comprising:
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4. Means for directing said biological cells in column flow at a constant velocity;
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2. Means for passing a laser beam having a cross section larger than each of said cells through said biological cells in column flow so that only one biological cell passes through said laser beam at a time; 3. Means for measuring the time of flight of each said biological cell through said laser beam deriving an electrical signal commensurate with the width and/or volume of each said biological cell or its nucleus, comprising; a. means for deriving a first electrical signal from the low angle forward light scatter characteristic or secondary fluorescent emission from each cell as it passes through the said laser beam; b. means for deriving a second electrical signal having an amplitude determined by the time integral of said first electrical signal; c. means for deriving a third electrical signal having an amplitude equal to the peak amplitude of said first electrical signal; d. means for deriving a fourth electrical signal by dividing the said second electrical signal by the said third electrical signal therefore deriving an electrical signal commensurate with the width of each said biological cell plus the width of the laser beam; e. means for deriving a fifth electrical signal by subtracting from said fourth electrical signal a constant electrical signal proportional to the width of the laser beam whereby the fifth electrical signal is directly proportional to the width of said biological cell.
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7. A new and improved flow cytometer means for measuring the size of a biological cell, comprising:
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1. Means for directing said biological cells in column flow at a constant velocity; 2. Means for passing a laser beam having a cross section larger than each of said cells through said biological cells in column flow so that only one biological cell passes through said laser beam at a time; 3. Means for measuring the time of flight of each said biological cell through said laser beam deriving an electrical signal commensurate with the width and/or volume of each said biological cell or its nucleus, comprising; a. means for deriving a first electrical signal from the secondary fluorescent emission from each cell as it passes through the said laser beam; b. means for deriving a second electrical signal having an amplitude determined by the time integral of said first electrical signal; c. means for deriving a third electrical signal having an amplitude equal to the peak amplitude of said first electrical signal; d. means for deriving a fourth electrical signal by dividing the said second electrical signal by the said third electrical signal therefore deriving an electrical signal commensurate with the width of each biological cell plus the width of the laser beam; e. means for deriving a fifth electrical signal by subtracting from said fourth electrical signal a constant electrical signal proportional to the width of the laser beam whereby the fifth electrical signal is directly proportional to the size of nucleus or cytoplasm of said biological cell.
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10. A new and improved flow cytometer means for measuring the size of a biological cell, comprising:
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1. Means for directing said biological cells in column flow at a constant velocity; 2. Means for passing a laser beam having a cross section larger than each of said cells through said biological cells in column flow so that only one biological cell passes through said laser beam at a time; 3. Means for measuring the time of flight of each said biological cell through said laser beam deriving an electrical signal commensurate with the width and/or volume of each said biological cell, comprising; a. means for deriving a first electrical signal from the low angle forward light scatter characteristic from each cell as it passes through the said laser beam; b. means for deriving a second electrical signal having an amplitude determined by the time integral of said first electrical signal; c. means for deriving a third electrical signal having an amplitude equal to the peak amplitude of said first electrical signal; d. means for deriving a fourth electrical signal by dividing the said second electrical signal by the said third electrical signal therefore deriving an electrical signal commensurate with the width of each said biological cell plus the width of the laser beam; e. means for deriving a fifth electrical signal by subtracting from said fourth electrical signal a constant electrical signal proportional to the width of the laser beam whereby the fifth electrical signal is directly proportional to the width of said biological cell.
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Specification