IEEE Access (Jan 2019)

Extended Blind End-Member and Abundance Extraction for Biomedical Imaging Applications

  • Daniel U. Campos-Delgado,
  • Omar Gutierrez-Navarro,
  • Jose J. Rico-Jimenez,
  • Elvis Duran-Sierra,
  • Himar Fabelo,
  • Samuel Ortega,
  • Gustavo Callico,
  • Javier A. Jo

DOI
https://doi.org/10.1109/ACCESS.2019.2958985
Journal volume & issue
Vol. 7
pp. 178539 – 178552

Abstract

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In some applications of biomedical imaging, a linear mixture model can represent the constitutive elements (end-members) and their contributions (abundances) per pixel of the image. In this work, the extended blind end-member and abundance extraction (EBEAE) methodology is mathematically formulated to address the blind linear unmixing (BLU) problem subject to positivity constraints in optical measurements. The EBEAE algorithm is based on a constrained quadratic optimization and an alternated least-squares strategy to jointly estimate end-members and their abundances. In our proposal, a local approach is used to estimate the abundances of each end-member by maximizing their entropy, and a global technique is adopted to iteratively identify the end-members by reducing the similarity among them. All the cost functions are normalized, and four initialization approaches are suggested for the end-members matrix. Synthetic datasets are used first for the EBEAE validation at different noise types and levels, and its performance is compared to state-of-the-art algorithms in BLU. In a second stage, three experimental biomedical imaging applications are addressed with EBEAE: m-FLIM for chemometric analysis in oral cavity samples, OCT for macrophages identification in post-mortem artery samples, and hyper-spectral images for in-vivo brain tissue classification and tumor identification. In our evaluations, EBEAE was able to provide a quantitative analysis of the samples with none or minimal a priori information.

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