Principal Investigator Peter So
Co-investigator Bevin Engelward
Project Website http://web.mit.edu.ezproxy.canberra.edu.au/solab/Research/ImageCytometry.html
We are developing 3-D image cytometer based on a video-rate two-photon scanning microscopy. The high speed of this microscope allows the sampling of a large cell population and measures cellular properties high statistical precision. The use of a two-photon microscope further allows properties of individual cells to be assessed inside tissues in vivo. Two-photon 3-D cytometer has the potential for the detection of rare cellular events inside living animals. A promising application of this 3-D image cytometer is for the study of mitotic recombination events in tissues.
A major direction we are pushing the application of two-photon microscopy (TPM) is in the area of image cytometry. As the name implies, image cytometry is an image-based study or measurement of cells. How image cytometry differs from normal microscopic studies of cells is that very large populations of cells (typically on the order of 104 to 108 cells) are imaged. To make this technically feasible on the two-photon microscope, high-speed imaging techniques are required.
We have previously developed a video-rate two-photon microscope that allows us to acquire images at speeds as high as 30 frames per second1. Below is a schematic of our video-rate microscope, which is based on a standard galvanometer scanner, combined with a high speed polygonal scanner.
When we combine this with a mechanical stage that can translate the sample over several centimeters it becomes possible to image large areas in reasonable amounts of time. Below is a composite image of a population of a genetically modified 3T3 cells, which have had two non-functional yellow fluorescent protein (YFP) cassettes inserted into their genome, and a smaller zoomed-in region.
The cells have been stained with the DNA stain Hoescht 3328. The upper image is a ratio image of the green and blue channel, while the two lower images are the separated green channel and blue channels. One of the main strengths of image cytometry is its ability to identify rare events in a population of cells. The above image shows a cell that is fluorescent yellow that has undergone a recombination event that has restored the fluorescence of the YFP gene. Since this recombination event is a very low probability event (1 cell in 105) a large number of cells must be imaged in order to find such an event. We can also segment the cells and classify them using a cluster plot.
One of the main strengths of TPM is its ability to image thick tissues specimens. This gives us the ability to perform image cytometry in thick 3D samples such as tissues. Below is a composite image of a ex vivo human skin sample 1 cm which has been imaged down to a depth of 70 microns. Thus it is possible to perform image cytometry on cells while they are still in their intact state, preserving many of their biochemical and mechanical inputs, and most importantly their native 3D morphology and its relation to the 3D architecture of the tissue. This provides a wealth of information about tissue biophysics and biology on macroscopic samples that has not been available before.
We are currently extending the capability of the instrument by increasing the scanning speed to make it comparable to processing rates found in flow cytometry, and combing histological sectioning to allow us to evaluate specimens that have an axial extent greater than the standard 200 - 500 micron limit in two-photon microscopy.
An important avenue that we are also pursing is the visualization and image analysis tools necessary to study these types of datasets. A typical dataset can generate tens of gigabytes of data, far too much for a human operator to manually classify. It becomes necessary to use automated segmentation procedures to classify the cell population into various sub-populations of biological interest.
We are currently working on developing the computer algorithms for studying these datasets.