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High Throughput High Dimensional Multi-parametric Analysis of the Immune System


Generating solutions

It cannot be emphasized enough, as to the current analytical climate that the FCM community is currently facing. It is clear, that the bioinformatic tools for FCM have fallen way behind (many years) when compared to how bioinformatic tools for other platforms in genomics and proteomics have matured. The current scale-up from 5 to 10 colours and the imminent scaling up to 17 colours or more, at the same type as the scale-up of sample throughput from a few samples in a small research lab to dozens, hundreds, even thousands in clinical applications will deeply confound the FCM communities ability to derive scientific value in proportion to the cost of running these experiments. The development of these tools will have the most profound, immediate impact that the FCM community has seen in the last 20 years. Automated high throughput tools will bring the analysis time from weeks to hours. This significantly reduces the cost needed to publish the results in academic journals. New visualizations into high-dimensional data will vastly improve reporting and scientific interpretation, as new FCM standards will facilitate experiment reproducibility. Moreover, these tools will reshape dramatically the biomedical research in Canada by increasing the efficiency of an already widely adopted research and clinical tool, as well as generating intellectual property (IP) for commercialization.

This project has developed FCM tools that are available to the international research community through one of the most well known public bioinformatic platforms available called GenePattern, provided by the Broad Institute:

a. More efficient Tooling for the community: will reduce the laborious nature of FCM data analysis increase the scientific value.

b. Unrestricted use for the academic community: tools will be available for the academic community through genepattern. org

c. Reduced Cost and Analysis time: tremendous potential for saving time and cost with efficient and objective analysis tools.

d. Reproducible reporting: precise reporting with strong statistical support.

e. Global recognition: An important contribution to the international community.






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Fiscal Year Project Launched


Project Description

Flow cytometry (FCM) is a technique for counting, examining, and sorting microscopic particles, usually cells, suspended in a stream of fluid. As the cells flow through an optical/electronic detection apparatus multiparametric measurements of the cells’ physical and/or chemical characteristics are made by a series of one or more light sources (usually lasers) and detectors.

Each suspended particle passing through the beam scatters the light and fluorescent chemicals found in the particle, or attached to the particle during a labeling process designed to target specific proteins. This combination of scattered and fluorescent light is picked up by the detectors, and by analyzing fluctuations in brightness at each detector it is then possible to extrapolate various types of information about the physical (e.g., size and shape) and chemical composition (e.g., relative amount of protein present) of each individual particle. FCM is proteomic technique that can be used for the identification of cell populations and/or for physically sorting and separating the cells. The technology is applied to many fields of science, including molecular biology, pathology, immunology, plant biology and marine biology. In the field of molecular biology it is especially useful when used with fluorescence tagged antibodies.

These specific antibodies bind to proteins on or in the target cells and help to give information on specific characteristics of the cells being studied in the cytometer. FCM is integral part of proteomic and genomic technology. It has broad application in medicine (especially in transplantation, hematology, oncology, immunology, chemotherapy, and genetics). In marine biology, the auto-fluorescent properties of photosynthetic plankton can be exploited by flow cytometry in order to characterize abundance and community structure. In protein engineering, flow cytometry is used in conjunction with yeast display and bacterial display to identify cell surface-displayed protein variants with desired properties.

FCM can generate complex datasets both in terms of the number of parameters measured for each individual cell (over 20), as well as the number of individual cells analyzed per experiment (in the millions). As a result, the amount of data that is generated is enormous (gigabytes to terabytes), and the analysis is complex and very time consuming. Unfortunately, the bioinformatic tools available for FCM analysis have lagged behind other platforms like sequencing, arrays, mass spectrophotometry, etc. The objective of this project is to create new tools able to take advantage of the high dimensionality of high throughput FCM (HT-FCM) data and to combine the result with genomics and proteomics. The methods proposed here will revolutionize the current basic academic and commercial tools in the scientific community. The integration of HT-FCM, genomics and proteomics data will provide a deeper understanding of specific immune cell behavior.

The functional relationships identified will provide new knowledge enabling the elucidation of disease mechanisms, the prediction of therapeutic and vaccine outcome, and the development personalized medicine. To do so, we will create

(1) A High Throughput Flow Analysis Application (HT-FAA) to remove the excessive manual labor associated with the current 2- dimensional analysis methods and provide statistically sound, objective analysis methods to take advantage of the multivariate nature of HT-FCM data using true multi-dimensional analysis techniques. We will develop

(2) A High Throughput Reporting Application (HT-RA) for creating novel visualizations for HT-FAA processed data and for integrating the results with other functional (genomics, proteomics) data and public scientific annotations, using novel visualizations into multi-dimensional data. Finally, we will define

(3) A Patient Immuno Profiling Process (PIPP) by improving experiment reporting and presenting a more complete functional genomic view of cells involved in the immune system.