초록 ▼

A scanning method for scanning samples of biological cells using optical tomography includes preparing, acquiring, reconstructing and viewing three-dimensional images of cell samples. Concentration and enrichment of the cell sample follows. The cell sample is stained. Cells are isolated from the cel

A scanning method for scanning samples of biological cells using optical tomography includes preparing, acquiring, reconstructing and viewing three-dimensional images of cell samples. Concentration and enrichment of the cell sample follows. The cell sample is stained. Cells are isolated from the cell sample and purified. A cell/solvent mixture is injected into a gel by centrifugation. A cell/gel mixture is injected into a capillary tube until a cell appears centered in a field of view using a stopped-flow method. An optical imaging system, such as a fixed or variable motion optical tomography system acquires a projection image. The sample is rotated about a tube axis to generate additional projections. Once image acquisition is completed, the acquired image projections are corrected for errors. A computer or other equivalent processor is used to compute filtered backprojection information for 3D reconstruction.

대표청구항 ▼

What is claimed is: 1. A scanning method for scanning samples of biological cells using optical tomography comprising the steps of: concentrating and enriching a cell sample; staining the cell sample; isolating and purifying cells from the cell sample; injecting the isolated and purified cells into

What is claimed is: 1. A scanning method for scanning samples of biological cells using optical tomography comprising the steps of: concentrating and enriching a cell sample; staining the cell sample; isolating and purifying cells from the cell sample; injecting the isolated and purified cells into a liquid or gel medium to produce a cell mixture; injecting the cell mixture into a capillary tube until a cell appears in a field of view of a pseudo-projection viewing subsystem; acquiring at least one pseudo-projection image of at least one object that is in the field of view using the pseudo-projection viewing subsystem, the pseudo-projection viewing subsystem comprising a fixed objective lens, a detector, and a plurality of mechanical scanning components that are mounted to engage opposing sides of the capillary tube proximate to the fixed objective lens so as to vibrate the capillary tube to enable the at least one object to be axially scanned by the fixed objective lens, wherein each pseudo-projection image thus formed comprises an integration of focal plane images acquired during a single exposure of the detector; rotating the capillary tube about a tube axis to generate additional pseudo-projection images at different views using the pseudo-projection viewing subsystem; determining whether a pseudo-projection data set is complete and, if not, repeating the above steps of injecting into the field of view, acquiring at least one pseudo-projection image, and rotating the capillary tube to generate additional pseudo-projection images of another object; correcting the pseudo-projection images for errors to produce corrected pseudo-projection image information; and from the corrected pseudo-projection image information computing filtered backprojection information for 3D reconstruction. 2. The scanning method of claim 1 further comprising the steps of: analyzing images of the 3D reconstruction; and viewing the images. 3. The scanning method of claim 1 wherein the step of injecting the cell mixture into a capillary tube comprises using a stopped-flow method. 4. The scanning method of claim 3 wherein the cell mixture comprises at least one cell embedded in a liquid having a viscosity >1 million cps. 5. The scanning method of claim 3 wherein the cell mixture comprises at least one cell embedded in a thixotropic gel. 6. The scanning method of claim 1 wherein the plurality of mechanical scanning components comprise: a pair of piezotubes, wherein the piezotubes are coupled at opposing ends of the capillary tube and configured to vibrate the capillary tube. 7. The scanning method of claim 1 wherein the step of correcting the pseudo-projection images further comprises the steps of illuminating a portion of the cell mixture such that light rays passing through the portion of the cell mixture pass through a Fourier plane of the fixed objective lens; using a spatial filter mask in the Fourier plane to filter light rays projecting through the objective lens to produce spatially filtered light; and reconstructing 3D images from the spatially filtered light. 8. The scanning method of claim 7 wherein the spatial filter mask has a spatially varying optical density, ODNA=q, which incorporates a quasi-ramp filter, said quasi-ramp filter functioning as a high-pass filter at low spatial frequencies. 9. A scanning system for scanning a sample, wherein the sample includes a series of objects in a container, the scanning system comprising: a pseudo-projection viewing subsystem for imaging the objects, wherein the pseudo-projection viewing subsystem includes a detector and a fixed objective lens; and a plurality of mechanical scanning components mounted to engage opposing sides of the sample proximate to the fixed objective lens so as to vibrate the sample to allow the sample to axially scanned by the fixed objective lens; wherein the pseudo-projection viewing subsystem is configured to produce at least one pseudo-projection image of the objects in a field of view of the pseudo-projection viewing subsystem, each pseudo-projection image comprising an integration of focal plane images acquired during a single exposure of the detector. 10. The scanning system of claim 9 wherein the plurality of mechanical scanning components comprise piezoelectric pushers. 11. The scanning system of claim 9 wherein the sample comprises a series of objects embedded in a semi-rigid medium. 12. The scanning system of claim 11 wherein the semi-rigid medium is selected from the group consisting of a polymer thread, a capillary tube, cell beads and a frozen liquid stream. 13. The scanning system of claim 9 further comprising at least one stepper motor coupled to the sample for rotating the sample. 14. The scanning system of claim 13 wherein the at least one stepper motor operates in cooperation with the plurality of mechanical scanning components to allow scanning of the sample through multiple angles. 15. The scanning system of claim 9 wherein the fixed objective lens comprises an oil immersion lens and piezoelectric pushers are located around the fixed objective lens, so that the sample is immersed within a liquid environment for refractive index matching. 16. The scanning system of claim 9 wherein the fixed objective lens comprises an air immersion lens.