Cancer cell detection using dielectrophoretic dynamic light scattering (DDLS) spectroscopy
First Claim
1. A non-invasive apparatus for detection of cancer cells in a biological sample, said apparatus comprising:
- an elongated housing having a distal end and a proximal end;
a pair of electrodes mounted at the distal end of the housing, the electrodes comprising an arcuate first electrode and a linear second electrode substantially centered in the arcuate first electrode;
an oscillating power source constructed to produce a sinusoidal electric voltage;
the oscillating power source electrically connected to said electrodes through a cable from the oscillating power source, through the proximal end of the housing to the electrodes;
wherein said electrodes generate a non-uniform sinusoidal electric field between the arcuate and linear electrodes;
a light source attached to the distal end of the housing constructed to deliver collimated light to a biological sample being exposed to said non-uniform electric field producing scattered light therefrom;
a detector also attached to the distal end of the housing adapted to collect the scattered light;
a processor mounted in said housing, the processor processing electrical signals from the detector related to the scattered light to produce an autocorrelation output signal, the processor comparing the autocorrelation output signal with stored autocorrelation signals taken from biological samples containing known cancer cells.
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Abstract
Non-invasive apparatus and method for determining and monitoring glucose concentrations in human subjects. Glucose level is estimated through the effect of glucose on biological cells with glucose dependencies, e.g., red blood cells. The invention is based on the interaction of such cells with oscillating electric field gradients. The response of biological cells depends on factors including shape, size, and electrical charge distribution. The field gradient causes the cells to undergo characteristic motion which is detected by light beam scattering. The autocorrelation of the scattered light is computed, and the Fourier transform (FT) is performed to produce a characteristic velocity spectrum in which the peaks are characteristic of the cell “bio-electrical” states. The glucose level is estimated through measurements of changes of FT with changes in glucose levels after calibration with standard glucose methods.
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Citations
3 Claims
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1. A non-invasive apparatus for detection of cancer cells in a biological sample, said apparatus comprising:
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an elongated housing having a distal end and a proximal end; a pair of electrodes mounted at the distal end of the housing, the electrodes comprising an arcuate first electrode and a linear second electrode substantially centered in the arcuate first electrode; an oscillating power source constructed to produce a sinusoidal electric voltage;
the oscillating power source electrically connected to said electrodes through a cable from the oscillating power source, through the proximal end of the housing to the electrodes;wherein said electrodes generate a non-uniform sinusoidal electric field between the arcuate and linear electrodes; a light source attached to the distal end of the housing constructed to deliver collimated light to a biological sample being exposed to said non-uniform electric field producing scattered light therefrom; a detector also attached to the distal end of the housing adapted to collect the scattered light; a processor mounted in said housing, the processor processing electrical signals from the detector related to the scattered light to produce an autocorrelation output signal, the processor comparing the autocorrelation output signal with stored autocorrelation signals taken from biological samples containing known cancer cells. - View Dependent Claims (2, 3)
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Specification