Method and apparatus for motility contrast imaging
First Claim
1. A system for motility contrast imaging of multiple biological targets, the system comprising:
- a multi-well plate having a plurality of wells, each well containing a living biological target;
a micro-lens array with a plurality of lenses corresponding to said plurality of wells, the lens centers oriented to concentrate incident light onto each living biological target contained within each of the plurality of wells;
low-coherence illumination source for generating an incident light beam;
a beam splitter oriented at 45 degrees to the incident light beam for receiving the incident light beam and for producing a multitude of incident beams that illuminate each biological target in each of said plurality of wells, in which the path lengths from the illumination source to each biological target are substantially equal;
a pixel array detector located at the common Fourier plane of the micro-lens array;
a computer-controlled delay stage for zero-path-matching a single reference beam to backscattered object beams, reflected from each biological target in each of said plurality of wells, at the Fourier plane;
a single reference beam that intersects the plurality of backscattered object beams at an angle to produce a series of interference fringes that modulate Fourier-domain information at multiple Fourier regions on the pixel array detector, each Fourier region corresponding to the biological target in each of said plurality of wells; and
a computer for receiving the Fourier-domain information;
wherein the interference fringes between the plurality of backscattered object beams and the reference beam are recorded as a function of time by the pixel array detector and passed to the computer which constructs a time-dependent digital hologram of the biological target within each of said plurality of wells;
and further wherein the computer is configured to control the delay stage to generate said time-dependent digital holograms at successive depths within the biological target within each of said plurality of wells, and to generate a 3D volumetric image from said time-dependent digital holograms at successive depths.
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Accused Products
Abstract
A system for motility contrast imaging a biological target within tissue comprising a CCD array; an illumination source for generating an incoming beam; a first beam splitter for receiving the incoming beam and producing an object beam and a reference beam; a second beam splitter for illuminating a multitude of biological targets with the object beam and for directing backscattered object beams towards the CCD array; a computer-controlled delay stage for zero-path-matching the reference beam to the backscattered object beams; a reference beam that intersects the backscattered object beams at an angle to produce a series of interference fringes that modulate Fourier-domain information; and a computer for receiving a time series of Fourier-domain information. The interference fringes between the backscattered object beam and the reference beam are recorded by the CCD array and passed to the computer which constructs a digital hologram at successive times.
20 Citations
11 Claims
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1. A system for motility contrast imaging of multiple biological targets, the system comprising:
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a multi-well plate having a plurality of wells, each well containing a living biological target; a micro-lens array with a plurality of lenses corresponding to said plurality of wells, the lens centers oriented to concentrate incident light onto each living biological target contained within each of the plurality of wells; low-coherence illumination source for generating an incident light beam; a beam splitter oriented at 45 degrees to the incident light beam for receiving the incident light beam and for producing a multitude of incident beams that illuminate each biological target in each of said plurality of wells, in which the path lengths from the illumination source to each biological target are substantially equal; a pixel array detector located at the common Fourier plane of the micro-lens array; a computer-controlled delay stage for zero-path-matching a single reference beam to backscattered object beams, reflected from each biological target in each of said plurality of wells, at the Fourier plane; a single reference beam that intersects the plurality of backscattered object beams at an angle to produce a series of interference fringes that modulate Fourier-domain information at multiple Fourier regions on the pixel array detector, each Fourier region corresponding to the biological target in each of said plurality of wells; and a computer for receiving the Fourier-domain information; wherein the interference fringes between the plurality of backscattered object beams and the reference beam are recorded as a function of time by the pixel array detector and passed to the computer which constructs a time-dependent digital hologram of the biological target within each of said plurality of wells; and further wherein the computer is configured to control the delay stage to generate said time-dependent digital holograms at successive depths within the biological target within each of said plurality of wells, and to generate a 3D volumetric image from said time-dependent digital holograms at successive depths. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11)
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Specification