Basis material decomposition in spectral CT using a semi-empirical, polychromatic adaption of the Beer-Lambert model

S. Ehn, T. Sellerer, K. Mechlem, A. Fehringer, M. Epple, J. Herzen, F. Pfeiffer, P. B. Noël

Research output: Contribution to journalArticlepeer-review

33 Scopus citations

Abstract

Following the development of energy-sensitive photon-counting detectors using high-Z sensor materials, application of spectral x-ray imaging methods to clinical practice comes into reach. However, these detectors require extensive calibration efforts in order to perform spectral imaging tasks like basis material decomposition. In this paper, we report a novel approach to basis material decomposition that utilizes a semi-empirical estimator for the number of photons registered in distinct energy bins in the presence of beam-hardening effects which can be termed as a polychromatic Beer-Lambert model. A maximum-likelihood estimator is applied to the model in order to obtain estimates of the underlying sample composition. Using a Monte-Carlo simulation of a typical clinical CT acquisition, the performance of the proposed estimator was evaluated. The estimator is shown to be unbiased and efficient according to the Cramér-Rao lower bound. In particular, the estimator is capable of operating with a minimum number of calibration measurements. Good results were obtained after calibration using less than 10 samples of known composition in a two-material attenuation basis. This opens up the possibility for fast re-calibration in the clinical routine which is considered an advantage of the proposed method over other implementations reported in the literature.

Original languageEnglish
Pages (from-to)N1-N17
JournalPhysics in Medicine and Biology
Volume62
Issue number1
DOIs
StatePublished - 7 Jan 2017

Keywords

  • CT
  • material decomposition
  • photon-counting detectors
  • spectral imaging

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