Theranostic SPECT reconstruction for improved resolution: application to radionuclide therapy dosimetry

Marquis, Harry; Deidda, Daniel; Gillman, Ashley; Willowson, Kathy; Gholami, Yaser Hadi; Hioki, Takanori; Eslick, Enid M.; Thielemans, Kris; Bailey, Dale L.

doi:10.1186/s40658-021-00362-x

Cited by 14 publications

(10 citation statements)

References 33 publications

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“…The reconstruction then becomes an optimisation problem in terms of ζ. This approach has been used in MMI : see [76,77,78] (PET with MRI), [79] (SPECT with PET), [80] (fluorescence molecular tomography with CT or MRI), [81] (DOT with CT), but also for MCMI : PET dynamic imaging using static images as guide [76] or temporal features derived from the raw data [82].…”

Section: (B)2 Kernel Methodsmentioning

confidence: 99%

(An overview of) Synergistic reconstruction for multimodality/multichannel imaging methods

Arridge

Ehrhardt

Thielemans

2021

Phil. Trans. R. Soc. A.

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Imaging is omnipresent in modern society with imaging devices based on a zoo of physical principles, probing a specimen across different wavelengths, energies and time. Recent years have seen a change in the imaging landscape with more and more imaging devices combining that which previously was used separately. Motivated by these hardware developments, an ever increasing set of mathematical ideas is appearing regarding how data from different imaging modalities or channels can be synergistically combined in the image reconstruction process, exploiting structural and/or functional correlations between the multiple images. Here we review these developments, give pointers to important challenges and provide an outlook as to how the field may develop in the forthcoming years. This article is part of the theme issue ‘Synergistic tomographic image reconstruction: part 1’.

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Section: (B)2 Kernel Methodsmentioning

confidence: 99%

(An overview of) Synergistic reconstruction for multimodality/multichannel imaging methods

Arridge

Ehrhardt

Thielemans

2021

Phil. Trans. R. Soc. A.

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“…MIP obtains a two-dimensional image by the projection method [24], which is generated by calculating the maximum-density pixels encountered along each ray of the scanned object as illustrated in Figure 2. Despite its simplicity, MIP has been widely adopted in medical image analysis, such as reconstruction [32,33], detection [34,35], and segmentation [36][37][38]. The paper proposing the JointVesselNet [23] applied the idea of MIP to cerebrovascular segmentation.…”

Section: Multi-directional Mipmentioning

confidence: 99%

Cerebrovascular Segmentation Model Based on Spatial Attention-Guided 3D Inception U-Net with Multi-Directional MIPs

Yong-wei

Kwak

2022

Applied Sciences

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The segmentation algorithm of cerebrovascular magnetic resonance angiography (MRA) images based on deep learning plays an essential role in medical study. Traditional segmentation algorithms face poor segmentation results and poor connectivity when the cerebrovascular vessels are thinner. An improved segmentation algorithm based on deep convolutional networks is proposed in this research. The proposed segmentation network combines the original 3D U-Net with the maximum intensity projection (MIP), which was transformed from the corresponding patch of a 3D MRA image. The MRA dataset provided by Jeonbuk National University Hospital was used to evaluate the experimental results in comparison with traditional 3D cerebrovascular segmentation methods and other state–of–the–art deep learning methods. The experimental results showed that our method achieved the best test performance among the compared methods in terms of the Dice score when Inception blocks and attention modules were placed in the proposed dual-path networks.

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Section: Single Photon Emission Computed Tomographymentioning

confidence: 99%

“…For instance, the emergence of radionuclide therapy, in which a radiolabeled molecule is used to target and damage a tumor rather than simply provide an image, has increased interest in the use of many molecules radiolabeled by a β − (electron) emitter, such as the clinically approved 177 Lu‐DOTATATE (lutathera) (Strosberg et al, 2017). In radionuclide therapy, it is sometimes desirable to be able to image the distribution of radioisotope for a variety of purposes, ranging from tumor tracking to internal dosimetry (Marquis et al, 2021). This approach is termed “theranostics.” While it sometimes involves dual‐radiolabeling with both a positron emitter for PET imaging and a β − emitter for therapy, some β − emitters may also emit gamma rays at a rate desirable for SPECT imaging, allowing one to use a single radioisotope for both therapy and imaging.…”

Section: Radionuclide‐based Imagingmentioning

confidence: 99%

Multimodality imaging of nanoparticle‐based vaccines: Shedding light on immunology

Younis

Tang

Cai

2022

WIREs Nanomed Nanobiotechnol

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In recent years, there have been significant innovations in the development of nanoparticle‐based vaccines and vaccine delivery systems. For the purposes of both design and evaluation, these nanovaccines are imaged using the wealth of understanding established around medical imaging of nanomaterials. An important insight to the advancement of the field of nanovaccines can be given by an analysis of the design rationale of an imaging platform, as well as the significance of the information provided by imaging. Nanovaccine imaging strategies can be categorized by the imaging modality leveraged, but it is also worth understanding the superiority or convenience of a given modality over others in a given context of a particular nanovaccine. The most important imaging modalities in this endeavor are optical imaging including near‐infrared fluorescence imaging (NIRF), emission tomography methods such as positron emission tomography (PET) and single photon emission computed tomography (SPECT) with or without computed tomography (CT) or magnetic resonance (MR), the emerging magnetic particle imaging (MPI), and finally, multimodal applications of imaging which include molecular imaging with magnetic resonance imaging (MRI) and photoacoustic (PA) imaging. One finds that each of these modalities has strengths and weaknesses, but optical and PET imaging tend, in this context, to be currently the most accessible, convenient, and informative modalities. Nevertheless, an important principle is that there is not a one‐size‐fits‐all solution, and that the specific nanovaccine in question must be compatible with a particular imaging modality. This article is categorized under: Nanotechnology Approaches to Biology > Nanoscale Systems in Biology Therapeutic Approaches and Drug Discovery > Nanomedicine for Oncologic Disease Therapeutic Approaches and Drug Discovery > Nanomedicine for Infectious Disease

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Theranostic SPECT reconstruction for improved resolution: application to radionuclide therapy dosimetry

Cited by 14 publications

References 33 publications

(An overview of) Synergistic reconstruction for multimodality/multichannel imaging methods

(An overview of) Synergistic reconstruction for multimodality/multichannel imaging methods

Cerebrovascular Segmentation Model Based on Spatial Attention-Guided 3D Inception U-Net with Multi-Directional MIPs

Multimodality imaging of nanoparticle‐based vaccines: Shedding light on immunology

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