Analytical propagation of errors in dynamic SPECT: estimators, degrading factors, bias and noise.

Dynamic SPECT is a relatively new technique that may potentially benefit many imaging applications. Though similar to dynamic PET, the accuracy and precision of dynamic SPECT parameter estimates are degraded by factors that differ from those encountered in PET. In this work we formulate a methodology for analytically studying the propagation of errors from dynamic projection data to kinetic parameter estimates. This methodology is used to study the relationships between reconstruction estimators, image degrading factors, bias and statistical noise for the application of dynamic cardiac imaging with 99mTc-teboroxime. Dynamic data were simulated for a torso phantom, and the effects of attenuation, detector response and scatter were successively included to produce several data sets. The data were reconstructed to obtain both weighted and unweighted least squares solutions, and the kinetic rate parameters for a two-compartment model were estimated. The expected values and standard deviations describing the statistical distribution of parameters that would be estimated from noisy data were calculated analytically. The results of this analysis present several interesting implications for dynamic SPECT. Statistically weighted estimators performed only marginally better than unweighted ones, implying that more computationally efficient unweighted estimators may be appropriate. This also suggests that it may be beneficial to focus future research efforts upon regularization methods with beneficial bias-variance trade-offs. Other aspects of the study describe the fundamental limits of the bias variance trade-off regarding physical degrading factors and their compensation. The results characterize the effects of attenuation, detector response and scatter, and they are intended to guide future research into dynamic SPECT reconstruction and compensation methods.

[1]  Ralph. Deutsch,et al.  Estimation Theory , 1966 .

[2]  Contents , 2020, American Journal of Kidney Diseases.

[3]  B. Mazoyer,et al.  Kinetic data analysis with a noisy input function. , 1987, Physics in medicine and biology.

[4]  M. Kendall,et al.  Kendall's advanced theory of statistics , 1995 .

[5]  T. Ichihara,et al.  Dynamic acquisition with a three-headed SPECT system: application to technetium 99m-SQ30217 myocardial imaging. , 1991, Journal of nuclear medicine : official publication, Society of Nuclear Medicine.

[6]  J. Leppo,et al.  A review of cardiac imaging with sestamibi and teboroxime. , 1991, Journal of nuclear medicine : official publication, Society of Nuclear Medicine.

[7]  J M Links,et al.  Effect of differential tracer washout during SPECT acquisition. , 1991, Journal of nuclear medicine : official publication, Society of Nuclear Medicine.

[8]  Ronald J. Jaszczak,et al.  Reconstruction of SPECT images using generalized matrix inverses , 1992, IEEE Trans. Medical Imaging.

[9]  Eric C. Frey,et al.  A fast projector-backprojector pair modeling the asymmetric, spatially varying scatter response function for scatter compensation in SPECT imaging , 1993 .

[10]  G. Gullberg,et al.  A reconstruction algorithm using singular value decomposition of a discrete representation of the exponential Radon transform using natural pixels , 1993, 1993 IEEE Conference Record Nuclear Science Symposium and Medical Imaging Conference.

[11]  B.M.W. Tsui,et al.  Quantitative cardiac SPECT reconstruction with reduced image degradation due to patient anatomy , 1993, 1993 IEEE Conference Record Nuclear Science Symposium and Medical Imaging Conference.

[12]  G. Gullberg,et al.  Kinetic modeling of teboroxime using dynamic SPECT imaging of a canine model. , 1994, Journal of nuclear medicine : official publication, Society of Nuclear Medicine.

[13]  A. W. Kemp,et al.  Kendall's Advanced Theory of Statistics. , 1994 .

[14]  Grant T. Gullberg,et al.  Dynamic cardiac SPECT computer simulations for teboroxime kinetics , 1994 .

[15]  W. Rogers,et al.  Compartmental analysis of technetium-99m-teboroxime kinetics employing fast dynamic SPECT at rest and stress. , 1994, Journal of nuclear medicine : official publication, Society of Nuclear Medicine.

[16]  G. Gullberg,et al.  An investigation of the effect of finite system resolution and photon noise on the bias and precision of dynamic cardiac SPECT parameters. , 1995, Medical physics.

[17]  B. Tsui,et al.  A new method for modeling the spatially-variant, object-dependent scatter response function in SPECT , 1996, 1996 IEEE Nuclear Science Symposium. Conference Record.

[18]  G. Gullberg,et al.  Experimental verification of technetium 99m-labeled teboroxime kinetic parameters the the myocardium with dynamic single-photon emission computed tomography: Reproducibility, correlation to flow, and susceptibility to extravascular contamination , 1996, Journal of nuclear cardiology : official publication of the American Society of Nuclear Cardiology.

[19]  E C Frey,et al.  Analysis of the reconstructibility and noise properties of scattered photons in 99mTc SPECT. , 1997, Physics in medicine and biology.

[20]  Matt A. King,et al.  Evaluation of right and left ventricular volume and ejection fraction using a mathematical cardiac torso phantom. , 1997, Journal of nuclear medicine : official publication, Society of Nuclear Medicine.

[21]  R. Huesman,et al.  An investigation into the effect of input function shape and image acquisition interval on estimates of washin for dynamic cardiac SPECT. , 1997, Physics in medicine and biology.

[22]  E C Frey,et al.  Fast implementations of reconstruction-based scatter compensation in fully 3D SPECT image reconstruction. , 1998, Physics in medicine and biology.