Support Vector Machine and Parametric Wavelet-Based Texture Classification of Stem Cell Images

Abstract

Stem cell research is one of the most promising and cutting-edge fields in the medical sciences. It is believed that this innovative research will lead to lifesaving treatments in the coming years. As part of their work, stem cell researchers must first determine which of their stem cell colonies are of sufficiently high quality to be suitable for experimental studies and therapeutic treatments. Since colony texture is a major discriminating feature in determining quality, we introduce a non-invasive, semi-automated texture-based stem cell colony classification methodology to aid researchers in colony quality control. We first consider the general problem of textural image segmentation. In a new approach to this problem, we characterize image texture by the subband energies of the image's wavelet decomposition, and we employ a non-parametric support vector machine to perform the classification that yields the segmentation. We also adapt a parametric wavelet-based classifier that utilizes the Kullback-Leibler distance. We apply both methods to a set of benchmark textural images, report low segmentation error rates and comment on the applicability of and tradeoffs between the non-parametric and parametric segmentation methods. We then apply the two classifiers to the segmentation of stem cell colony images into regions of varying quality. This provides stem cell researchers with a rich set of descriptive graphical representations of their colonies to aid in quality control. From these graphical representations, we extract colony-wise textural features to which we add colony-wise border features. Taken together, these features characterize overall colony quality. Using these features as inputs to a multiclass support vector machine, we successfully categorize full stem cell colonies into several quality categories. This methodology provides stem cell researchers with a novel, non-invasive quantitative quality control tool.

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Document Details

Document Type
Technical Report
Publication Date
May 14, 2004
Accession Number
ADA424467

Entities

People

  • Christopher G. Jeffreys

Organizations

  • Air Force Institute of Technology

Tags

Communities of Interest

  • Autonomy
  • Energy and Power Technologies

DTIC Thesaurus Topics

  • Air Force
  • Cells
  • Computer Vision
  • Data Mining
  • Data Science
  • Databases
  • Image Classification
  • Image Processing
  • Image Segmentation
  • Information Processing
  • Information Science
  • Kernel Functions
  • Machine Learning
  • Signal Processing
  • Stem Cells
  • Supervised Machine Learning
  • Therapy

Readers

  • Computer Vision.
  • Distributed Systems and Data Platform Development
  • Oncology (Cancer Research).

Technology Areas

  • AI & ML
  • Biotechnology