BF Hutton scite author profile

BF Hutton

5Publications

61Citation Statements Received

50Citation Statements Given

How they've been cited

143

How they cite others

Affiliations

University College London, Royal Prince Alfred Hospital, Westmead Hospital

Publications

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Monte Carlo simulations of clinical PET and SPECT scans: impact of the input data on the simulated images

Stute¹,

Carlier²,

Cristina³

et al. 2011

Phys. Med. Biol.

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Monte Carlo simulations of emission tomography have proven useful to assist detector design and optimize acquisition and processing protocols. The more realistic the simulations, the more straightforward the extrapolation of conclusions to clinical situations. In emission tomography, accurate numerical models of tomographs have been described and well validated under specific operating conditions (collimator, radionuclide, acquisition parameters, count rates, etc). When using these models under these operating conditions, the realism of simulations mostly depends on the activity distribution used as an input for the simulations. It has been proposed to derive the input activity distribution directly from reconstructed clinical images, so as to properly model the heterogeneity of the activity distribution between and within organs. However, reconstructed patient images include noise and have limited spatial resolution. In this study, we analyse the properties of the simulated images as a function of the properties of the reconstructed images used to define the input activity distributions in (18)F-FDG PET and (131)I SPECT simulations. The propagation through the simulation/reconstruction process of the noise and spatial resolution in the input activity distribution was studied using simulations. We found that the noise properties of the images reconstructed from the simulated data were almost independent of the noise in the input activity distribution. The spatial resolution in the images reconstructed from the simulations was slightly poorer than that in the input activity distribution. However, using high-noise but high-resolution patient images as an input activity distribution yielded reconstructed images that could not be distinguished from clinical images. These findings were confirmed by simulated highly realistic (131)I SPECT and (18)F-FDG PET images from patient data. In conclusion, we demonstrated that (131)I SPECT and (18)F-FDG PET images indistinguishable from real scans can be simulated using activity maps with spatial resolution higher than that used in routine clinical applications.

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SPECT scatter correction in non-homogeneous media

Meikle

Hutton

Bailey

et al.

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Accelerated EM reconstruction in total-body PET: potential for improving tumour detectability

et al. 1994

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Total-body positron emission tomography (PET) is a useful diagnostic tool for evaluating malignant disease. However, tumour detection is limited by image artefacts due to the lack of attenuation correction and noise. Attenuation correction may be possible using transmission data acquired after or simultaneously with emission data. Despite the elimination of attenuation artefacts, however, tumour detection is still hampered by noise, which is amplified during image reconstruction by filtered backprojection (FBP). We have investigated, as an alternative to FBP, an accelerated expectation maximization (EM) algorithm for its potential to improve tumour detectability in total-body PET. Signal to noise ratio (SNR), calculated for a tumour with respect to the surrounding background, is used as a figure of merit. A software tumour phantom, with conditions typical of those encountered in a total-body PET study using simultaneous acquisition, is used to optimize and compare various reconstruction approaches. Accelerated EM reconstruction followed by two-dimensional filtering is shown to yield significantly higher SNR than FBP for a range of tumour sizes, concentrations and counting statistics (deltaSNR = 6.3 +/- 3.9, p < 0.001). The methods developed are illustrated by examples derived from physical phantom and patient data.

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The HICAM Gamma Camera

Fiorini

Busca

Peloso

et al. 2012

IEEE Trans. Nucl. Sci.

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INSERT: A Novel Clinical Scanner for Simultaneous SPECT/MRI Brain Studies

Hutton

Erlandsson

Salvado

et al. 2017

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BF Hutton

Monte Carlo simulations of clinical PET and SPECT scans: impact of the input data on the simulated images

SPECT scatter correction in non-homogeneous media

Accelerated EM reconstruction in total-body PET: potential for improving tumour detectability

The HICAM Gamma Camera

INSERT: A Novel Clinical Scanner for Simultaneous SPECT/MRI Brain Studies

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