Adaptive template generation for amyloid PET using a deep learning approach

Kang, Seung Kwan; Seo, Seongho; Shin, Seong A.; Byun, Min Soo; Kim, Yu Kyeong; Lee, Dong Hoon; Lee, Jae Sung

doi:10.1002/hbm.24210

Cited by 54 publications

(29 citation statements)

References 26 publications

(24 reference statements)

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“…In most areas of nuclear medicine, DL-based image processing and analysis techniques have received significant research attention [184,195,196]; namely, the DL-based image reconstruction and denoising for radiation dose reduction [197][198][199][200], automatic segmentation of various organs and structures for quantitative image analyses [201,202], image spatial normalization [203,204], voxel-based internal dosimetry [205], and the image-to-image transition for PET AC. Moreover, the DL-based lesion detection and image interpretation received significant research attention [206][207][208][209].…”

Section: Artificial Intelligence In Nuclear Medicinementioning

confidence: 99%

A Review of Deep-Learning-Based Approaches for Attenuation Correction in Positron Emission Tomography

Lee

2021

IEEE Trans. Radiat. Plasma Med. Sci.

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Attenuation correction (AC) is essential for the generation of artifact-free and quantitaAtively accurate positron emission tomography (PET) images. PET AC based on computed tomography (CT) frequently results in artifacts in attenuationcorrected PET images, and these artifacts mainly originate from CT artifacts and PET-CT mismatches. The AC in PET combined with a magnetic resonance imaging (MRI) scanner (PET/MRI) is more complex than PET/CT, given that MR images do not provide direct information on high energy photon attenuation. Deep learning (DL)-based methods for the improvement of PET AC have received significant research attention as alternatives to conventional AC methods. Many DL studies were focused on the transformation of MR images into synthetic pseudo-CT or attenuation maps. Alternative approaches that are not dependent on the anatomical images (CT or MRI) can overcome the limitations related to current CT-and MRI-based ACs and allow for more accurate PET quantification in stand-alone PET scanners for the realization of low radiation doses. In this article, a review is presented on the limitations of the PET AC in current dual-modality PET/CT and PET/MRI scanners, in addition to the current status and progress of DL-based approaches, for the realization of improved performance of PET AC.

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Section: Artificial Intelligence In Nuclear Medicinementioning

confidence: 99%

A Review of Deep-Learning-Based Approaches for Attenuation Correction in Positron Emission Tomography

Lee

2021

IEEE Trans. Radiat. Plasma Med. Sci.

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“…MRI scans for Cohorts 1 to 4 were acquired for each participant using a 3-T MR system (Achieva, Philips Medical Systems, Best, The Netherlands) equipped with an eight-channel sensitivity encoding head coil. A sagittal structural 3D T1-weighted (T1W) image was acquired using a turbo field echo sequence that is similar to the magnetization-prepared rapid acquisition of gradient echo (MPRAGE) sequence with the following parameters: repetition time (TR) =8.1 ms, echo time (TE) =3.7 ms, flip angle (FA) =8°, field-of-view (FOV) =236×236 mm 2 , acquisition voxel size =1×1×1 mm 3 , and reconstruction voxel size =1×1×1 mm 3 . In addition, T2-weighted turbo-spin-echo and FLAIR images were acquired to examine any brain malformations.…”

Section: Mri Acquisitionsmentioning

confidence: 99%

Development and evaluation of a T1 standard brain template for Alzheimer disease

Guo¹,

Chang²,

Kim³

et al. 2021

Quant Imaging Med Surg

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Background: Patients with Alzheimer disease (AD) and mild cognitive impairment (MCI) have high variability in brain tissue loss, making it difficult to use a disease-specific standard brain template. The objective of this study was to develop an AD-specific three-dimensional (3D) T1 brain tissue template and to evaluate the characteristics of the populations used to form the template. Methods: We obtained 3D T1-weighted images from 294 individuals, including 101 AD, 96 amnestic MCI, and 97 cognitively normal (CN) elderly individuals, and segmented them into different brain tissues to generate AD-specific brain tissue templates. Demographic data and clinical outcome scores were compared between the three groups. Voxel-based analyses and regions-of-interest-based analyses were performed to compare gray matter volume (GMV) and white matter volume (WMV) between the three participant groups and to evaluate the relationship of GMV and WMV loss with age, years of education, and Mini-Mental State Examination (MMSE) scores.Results: We created high-resolution AD-specific tissue probability maps (TPMs). In the AD and MCI groups, losses of both GMV and WMV were found with respect to the CN group in the hippocampus (F >44.60, P<0.001). GMV was lower with increasing age in all individuals in the left (r=−0.621, P<0.001) and right (r=−0.632, P<0.001) hippocampi. In the left hippocampus, GMV was positively correlated with years of education in the CN groups (r=0.345, P<0.001) but not in the MCI (r=0.223, P=0.0293) or AD (r=−0.021, P=0.835) groups. WMV of the corpus callosum was not significantly correlated with years of education in any of the three subject groups (r=0.035 and P=0.549 for left, r=0.013 and P=0.821 for right). In all individuals, GMV of the hippocampus was significantly correlated with MMSE scores (left, r=0.710 and P<0.001; right, r=0.680 and P<0.001), while WMV of the corpus callosum showed a weak correlation (left, r=0.142 and P=0.015; right, r=0.123 and P=0.035).Conclusions: A 3D, T1 brain tissue template was created using imaging data from CN, MCI, and AD participants considering the participants' age, sex, and years of education. Our disease-specific template can help evaluate brains to promote early diagnosis of MCI individuals and aid treatment of MCI and AD individuals.

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“…Kang et al trained 2 CNNs: convolutional autoencoder and generative adversarial network, using a patient dataset (n ¼ 681) of simultaneously acquired [ 11 C]PiB PET/MR scans of individuals with AD, mild cognitive impairment (MCI), and healthy controls (HCs). 31 The training regimen produced a spatially normalized PET image, given the transformation parameters obtained by the SN generated from the accompanying MR data. As a result, given an inputted PET image in native space, the neural network was able to generate an individually adaptive amyloid PET template to achieve accurate SN without the use of MR data.…”

Section: Spatial Normalizationmentioning

confidence: 99%

Improving PET Imaging Acquisition and Analysis With Machine Learning: A Narrative Review With Focus on Alzheimer's Disease and Oncology

2019

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Machine learning (ML) algorithms have found increasing utility in the medical imaging field and numerous applications in the analysis of digital biomarkers within positron emission tomography (PET) imaging have emerged. Interest in the use of artificial intelligence in PET imaging for the study of neurodegenerative diseases and oncology stems from the potential for such techniques to streamline decision support for physicians providing early and accurate diagnosis and allowing personalized treatment regimens. In this review, the use of ML to improve PET image acquisition and reconstruction is presented, along with an overview of its applications in the analysis of PET images for the study of Alzheimer's disease and oncology.

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Adaptive template generation for amyloid PET using a deep learning approach

Cited by 54 publications

References 26 publications

A Review of Deep-Learning-Based Approaches for Attenuation Correction in Positron Emission Tomography

A Review of Deep-Learning-Based Approaches for Attenuation Correction in Positron Emission Tomography

Development and evaluation of a T1 standard brain template for Alzheimer disease

Improving PET Imaging Acquisition and Analysis With Machine Learning: A Narrative Review With Focus on Alzheimer's Disease and Oncology

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