Anatomical-based FDG-PET reconstruction for the detection of hypo-metabolic regions in epilepsy

Positron emission tomography (PET) of the cerebral glucose metabolism has shown to be useful in the presurgical evaluation of patients with epilepsy. Between seizures, PET images using fluorodeoxyglucose (FDG) show a decreased glucose metabolism in areas of the gray matter (GM) tissue that are associated with the epileptogenic region. However, detection of subtle hypo-metabolic regions is limited by noise in the projection data and the relatively small thickness of the GM tissue compared to the spatial resolution of the PET system. Therefore, we present an iterative maximum-a-posteriori based reconstruction algorithm, dedicated to the detection of hypo-metabolic regions in FDG-PET images of the brain of epilepsy patients. Anatomical information, derived from magnetic resonance imaging data, and pathophysiological knowledge was included in the reconstruction algorithm. Two Monte Carlo based brain software phantom experiments were used to examine the performance of the algorithm. In the first experiment, we used perfect, and in the second, imperfect anatomical knowledge during the reconstruction process. In both experiments, we measured signal-to-noise ratio (SNR), root mean squared (rms) bias and rms standard deviation. For both experiments, bias was reduced at matched noise levels, when compared to post-smoothed maximum-likelihood expectation-maximization (ML-EM) and maximum a posteriori reconstruction without anatomical priors. The SNR was similar to that of ML-EM with optimal post-smoothing, although the parameters of the prior distributions were not optimized. We can conclude that the use of anatomical information combined with prior information about the underlying pathology is very promising for the detection of subtle hypo-metabolic regions in the brain of patients with epilepsy.

[1]  H. Lüders,et al.  Presurgical evaluation of epilepsy. , 2001, Brain : a journal of neurology.

[2]  Koenraad Van Leemput,et al.  Automated model-based tissue classification of MR images of the brain , 1999, IEEE Transactions on Medical Imaging.

[3]  G. Flint,et al.  Seizures and epilepsy. , 1988, British journal of neurosurgery.

[4]  Guy Marchal,et al.  Multimodality image registration by maximization of mutual information , 1997, IEEE Transactions on Medical Imaging.

[5]  J. Nuyts,et al.  A concave prior penalizing relative differences for maximum-a-posteriori reconstruction in emission tomography , 2000 .

[6]  Thomas Beyer,et al.  Clinically feasible reconstruction of 3D whole-body PET/CT data using blurred anatomical labels. , 2002, Physics in medicine and biology.

[7]  Conrad V. Kufta,et al.  FDG‐Positron Emission Tomography and Invasive EEG: Seizure Focus Detection and Surgical Outcome , 1997, Epilepsia.

[8]  R. F. Wagner,et al.  Unified SNR analysis of medical imaging systems , 1985, Physics in medicine and biology.

[9]  E. Hoffman,et al.  Noninvasive determination of local cerebral metabolic rate of glucose in man. , 1980, The American journal of physiology.

[10]  J.A. Fessler,et al.  Regularized emission image reconstruction using imperfect side information , 1991, Conference Record of the 1991 IEEE Nuclear Science Symposium and Medical Imaging Conference.

[11]  Jerry L Prince,et al.  Measurement of Radiotracer Concentration in Brain Gray Matter Using Positron Emission Tomography: MRI-Based Correction for Partial Volume Effects , 1992, Journal of cerebral blood flow and metabolism : official journal of the International Society of Cerebral Blood Flow and Metabolism.

[13]  Jeffrey A. Fessler,et al.  A penalized-likelihood image reconstruction method for emission tomography, compared to postsmoothed maximum-likelihood with matched spatial resolution , 2003, IEEE Transactions on Medical Imaging.

[14]  B F Hutton,et al.  Minimum cross-entropy reconstruction of PET images using prior anatomical information. , 1996, Physics in medicine and biology.

[15]  J. Nuyts,et al.  Comparison between MAP and post-processed ML for incorporating anatomical knowledge in emission tomography , 2003, 2003 IEEE Nuclear Science Symposium. Conference Record (IEEE Cat. No.03CH37515).

[16]  Jeffrey A. Fessler,et al.  Compensation for nonuniform resolution using penalized-likelihood reconstruction in space-variant imaging systems , 2004, IEEE Transactions on Medical Imaging.

[17]  C. Baumgartner,et al.  Nuclear medicine in the preoperative evaluation of epilepsy , 2001, Nuclear medicine communications.

[18]  F. Turkheimer,et al.  The Use of Spectral Analysis to Determine Regional Cerebral Glucose Utilization with Positron Emission Tomography and [18F]Fluorodeoxyglucose: Theory, Implementation, and Optimization Procedures , 1994, Journal of cerebral blood flow and metabolism : official journal of the International Society of Cerebral Blood Flow and Metabolism.

[19]  Richard E. Carson,et al.  Multimodality Bayesian algorithm for image reconstruction in positron emission tomography: a tissue composition model , 1997, IEEE Transactions on Medical Imaging.

[20]  L. Shepp,et al.  Maximum Likelihood Reconstruction for Emission Tomography , 1983, IEEE Transactions on Medical Imaging.

[21]  F Fazio,et al.  Importance of partial-volume correction in brain PET studies. , 2000, Journal of nuclear medicine : official publication, Society of Nuclear Medicine.

[22]  H. Malcolm Hudson,et al.  Accelerated image reconstruction using ordered subsets of projection data , 1994, IEEE Trans. Medical Imaging.

[23]  Anand Rangarajan,et al.  A Bayesian Joint Mixture Framework for the Integration of Anatomical Information in Functional Image Reconstruction , 2000, Journal of Mathematical Imaging and Vision.

[24]  Walter Oberschelp,et al.  Expectation maximization reconstruction of positron emission tomography images using anatomical magnetic resonance information , 1997, IEEE Transactions on Medical Imaging.

[25]  D. Louis Collins,et al.  Design and construction of a realistic digital brain phantom , 1998, IEEE Transactions on Medical Imaging.

[26]  A M Dale,et al.  Measuring the thickness of the human cerebral cortex from magnetic resonance images. , 2000, Proceedings of the National Academy of Sciences of the United States of America.