Dynamic whole-body PET imaging: principles, potentials and applications

Rahmim, Arman; Lodge, Martin A.; Karakatsanis, Nicolas A.; Panin, Vladimir; Zhou, Yun; McMillan, A.; Cho, Steve; Zaidi, Habib; Casey, Michael; Wahl, Richard L.

doi:10.1007/s00259-018-4153-6

Cited by 177 publications

(182 citation statements)

References 143 publications

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“…Our previous studies have proposed and validated a WB dynamic PET acquisition protocol for routine clinical imaging [17][18][19][20][21][22][23]. It is feasible to combine SUV and Patlak K i WB PET imaging in clinical oncology within a single clinical acceptable scanning time [30].…”

Section: Discussionmentioning

confidence: 99%

“…However, conventional SUV PET imaging only presents the three-dimensional (3D) spatial distribution of a tracer's activity concentration averaged over a single time frame of a PET acquisition. Recently, there has been increasing interest in dynamic WB Patlak-derived net uptake rate constant (K i ) PET imaging owing to its ability to estimate K i parametric images across the whole human body as a complement to standard-of-care SUV imaging [17][18][19][20][21][22][23]. Unlike static acquisitions and the SUV metric, dynamic PET imaging allows for tracking of the four-dimensional (4D) spatio-temporal distribution of the tracer uptake post-injection, thereby enabling the estimation of the tracer's K i value which may be of high clinical importance for certain types of malignancy.…”

Section: Introductionmentioning

confidence: 99%

“…Our previous studies reported on a clinically feasible WB dynamic PET acquisition protocol using both indirect and direct 4D Patlak reconstruction methods [17][18][19][20][21][22][23]. The purpose of the present study is to investigate the impact of four-tissue class segmentation in MRI-guided attenuation correction of SUV and Patlak K i images to assess the feasibility of WB Patlak PET/MRI.…”

Section: Introductionmentioning

confidence: 99%

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Impact of Tissue Classification in MRI-Guided Attenuation Correction on Whole-Body Patlak PET/MRI

et al. 2019

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Purpose: The aim of this work is to investigate the impact of tissue classification in magnetic resonance imaging (MRI)-guided positron emission tomography (PET) attenuation correction (AC) for whole-body (WB) Patlak net uptake rate constant (K i ) imaging in PET/MRI studies. Procedures: WB dynamic PET/CT data were acquired for 14 patients. The CT images were utilized to generate attenuation maps (μ-map CTAC ) of continuous attenuation coefficient values (A coeff ). The μ-map CTAC were then segmented into four tissue classes (μ-map 4-classes ), namely background (air), lung, fat, and soft tissue, where a predefined A coeff was assigned to each class. To assess the impact of bone for AC, the bones in the μ-map CTAC were then assigned a predefined soft tissue A coeff (0.1 cm −1 ) to produce an AC μ-map without bones (μ-map no-bones ). Thereafter, both WB static SUV and dynamic PET images were reconstructed using μ-map CTAC , μ-map 4-classes , and μ-map no-bones (PET CTAC, PET 4-classes , and PET no-bones ), respectively. WB indirect and direct parametric K i images were generated using Patlak graphical analysis. Malignant lesions were delineated on PET images with an automatic segmentation method that uses an active contour model (MASAC). Then, the quantitative metrics of the metabolically active tumor volume (MATV), target-to-background (TBR), contrast-to-noise ratio (CNR), peak region-of-interest (ROI peak ), maximum region-of-interest (ROI max ), mean region-of-interest (ROI mean ), and metabolic volume product (MVP) were analyzed. The Wilcoxon test was conducted to assess the difference between PET 4-classes and PET no-bones against PET CTAC for all images. The same test was also adopted to compare the differences between SUV, indirect K i , and direct K i images for each evaluated AC method.Results: No significant differences in MATV, TBR, and CNR were observed between PET 4classes and PET CTAC for either SUV or K i images. PET 4-classes significantly overestimated ROI peak , ROI max , ROI mean , as well as MVP scores compared with PET CTAC in both SUV and K i images. SUV images exhibited the highest median relative errors for PET 4-classes with respect to PET CTAC (RE 4-classes ): 6.91 %, 6.55 %, 5.90 %, and 6.56 % for ROI peak , ROI max , ROI mean , and MVP, respectively. On the contrary, K i images showed slightly reduced RE 4-classes (indirect 5.52 %, 5.95 %, 4.43 %, and 5.70 %, direct 6.61 %, 6.33 %, 5.53 %, and 4.96 %) for ROI peak , ROI max , ROI mean , and MVP, respectively. A higher TBR was observed on indirect and direct K i images relative to SUV, while direct K i images demonstrated the highest CNR. Conclusions: Four-tissue class AC may impact SUV and K i parameter estimation but only to a limited extent, thereby suggesting that WB Patlak K i imaging for dynamic WB PET/MRI studies is feasible. Patlak K i imaging can enhance TBR, thereby facilitating lesion segmentation and quantification. However, patient-specific A coeff for each tissue class should be used when possible to address the high inter...

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Impact of Tissue Classification in MRI-Guided Attenuation Correction on Whole-Body Patlak PET/MRI

et al. 2019

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“…Filtering parameter optimization and fine tuning could be achieved more effectively when the frequency response of the filter is limited independent of the frequency content of the input image. These features make the hybrid approach a versatile tool for denoising of PET images with different tracers presenting with various spatial and temporal distributions, For instance, in dynamic or low-dose PET imaging (Karakatsanis et al 2016, Yan et al 2016, Rahmim et al 2018 where the low SNR induces severe bias and large variance in estimates of physiological parameters, image denoising capable of preserving the spatial resolution and quantitative accuracy is highly desirable. In this regard, the hybrid approach appears to be an effective denoising technique owing to its relatively high quantitative accuracy and improved SNR.…”

Section: Discussionmentioning

confidence: 99%

Improvement of image quality in PET using post-reconstruction hybrid spatial-frequency domain filtering

Arabi

Zaidi

2018

Phys. Med. Biol.

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PET images commonly suffer from the high noise level and poor signal-to-noise ratio (SNR), thus adversely impacting lesion detectability and quantitative accuracy. In this work, a novel hybrid dualdomain PET denoising approach is proposed, which combines the advantages of both spatial and transform domain filtering to preserve image textures while minimizing quantification uncertainty. Spatial domain denoising techniques excel at preserving high-contrast patterns compared to transform domain filters, which perform well in recovering low-contrast details normally smoothed out by spatial domain filters. For spatial domain filtering, the non-local mean algorithm was chosen owing to its performance in denoising high-contrast features whereas multi-scale curvelet denoising was exploited for the transform domain owing to its capability to recover small details. The proposed hybrid method was compared to conventional post-reconstruction Gaussian and edge preserving bilateral filters. Computer simulations of a thorax phantom containing three small lesions, experimental measurements using the Jaszczak phantom and clinical whole-body PET/ CT studies were used to evaluate the performance of the proposed PET denoising technique. The proposed hybrid filter increased the SNR from 8.0 (non-filtered PET image) to 39.3 for small lesions in the computerized thorax phantom, while Gaussian and bilateral filtering led to SNRs of 23.3 and 24.4, respectively. For the experimental Jaszczak phantom, the contrast-to-noise ratio (CNR) improved from 10.84 when using Gaussian smoothing to 14.02 and 19.39 using the bilateral and the proposed hybrid filters, respectively. The clinical studies further demonstrated the superior performance of the hybrid method, yielding a quantification change (the original noisy OSEM image was used as reference in the absence of ground truth) in malignant lesions of −2.4% compared to −11.9% and −6.6% achieved using Gaussian and bilateral filters, respectively. In some cases, the visual difference between the bilateral and hybrid filtered images is not substantial; however the improved CNR score from 11.3 by OSEM to 17.1 and 21.8 by bilateral to the hybrid filtering, respectively, demonstrates the overall gain achieved by the hybrid approach. The proposed hybrid algorithm improved the contrast, SNR and quantitative accuracy compared to Gaussian and bilateral approaches, and can be utilized as an alternative post-reconstruction filter in clinical PET/CT imaging.

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“…As my opponent notes in supporting Dr. Carson's idea of using dynamic scanning during the uptake phase, more studies are required to determine when dynamic whole‐body scans will prove beneficial. Commercial manufacturers are also starting to make multi‐pass continuous bed motion acquisition protocols available so that dynamic whole‐body PET will be increasingly feasible in the clinic. With this capability available, we can expect to see a rapid increase in the number of whole‐body dynamic studies that will provide evidence for the potential impact of whole‐body dynamic studies.…”

Section: Against the Proposition: Ronald Boellaard Phdmentioning

confidence: 99%

Whole‐body parametric PET imaging will replace conventional image‐derived PET metrics in clinical oncology

Leahy

Boellaard

Zaidi³

2018

Medical Physics

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Dynamic whole-body PET imaging: principles, potentials and applications

Cited by 177 publications

References 143 publications

Impact of Tissue Classification in MRI-Guided Attenuation Correction on Whole-Body Patlak PET/MRI

Impact of Tissue Classification in MRI-Guided Attenuation Correction on Whole-Body Patlak PET/MRI

Improvement of image quality in PET using post-reconstruction hybrid spatial-frequency domain filtering

Whole‐body parametric PET imaging will replace conventional image‐derived PET metrics in clinical oncology

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