Predicting conversion of brain β-amyloid positivity in amyloid-negative individuals

Park, Chae Jung; Seo, Young-Hoon; Choe, Yeong Sim; Lee, Hye-Joo; Kim, Jun Pyo

doi:10.1186/s13195-022-01067-8

Cited by 8 publications

(7 citation statements)

References 31 publications

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“…Similarly, another study by the same group 39 , detected baseline Aβ-positivity using demographic, APOE, and cognitive information and achieved an AUC of 0.65 in cognitively healthy individuals. However, we are aware of only two studies that have focused on predicting future Aβ-positivity 12,44 . The first study by Elman et al 44 examined the association of baseline cognitive measures with progression to Aβ-positivity in Aβ-negative individuals.…”

Section: Discussionmentioning

confidence: 99%

“…The first study by Elman et al 44 examined the association of baseline cognitive measures with progression to Aβ-positivity in Aβ-negative individuals. The second study conducted by Park et al 12 employed machine learning algorithms to predict future Aβ-positivity in Aβ-negative individuals. In Park et al 12 study, they used a PET biomarker for subject classification in Aβ+/Aβ-groups and developed a classifier with baseline age, gender, APOE4 genotype, and PET SUVR measures in ADNI data.…”

Section: Discussionmentioning

confidence: 99%

“…The second study conducted by Park et al 12 employed machine learning algorithms to predict future Aβ-positivity in Aβ-negative individuals. In Park et al 12 study, they used a PET biomarker for subject classification in Aβ+/Aβ-groups and developed a classifier with baseline age, gender, APOE4 genotype, and PET SUVR measures in ADNI data. They achieved a cross-validated AUC of 0.67 using basic demographic and genetic factors, which improved to 0.84 when including PET SUVR measures.…”

Section: Discussionmentioning

confidence: 99%

“…They achieved a cross-validated AUC of 0.67 using basic demographic and genetic factors, which improved to 0.84 when including PET SUVR measures. Our work has a similar objective to the study by Park et al 12 , but we focused on widely available non-invasive measures to predict future Aβ conversion. Moreover, a key characteristic of our study was to assess the future predictability of Aβ-positivity determined based on either CSF and PET biomarkers whereas Park et al 12 only considered a PET-based definition.…”

Section: Discussionmentioning

confidence: 99%

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Machine learning prediction of future amyloid beta positivity in amyloid-negative individuals

Moradi

Prakash

Hall

et al. 2023

Preprint

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INTRODUCTION: The pathophysiology of Alzheimer's disease (AD) involves beta-amyloid (A beta) accumulation. Early identification of individuals with abnormal beta-amyloid levels is crucial, but A beta quantification with positron emission tomography (PET) and cerebrospinal fluid (CSF) is invasive and expensive. METHODS: We propose a machine learning framework using standard non-invasive (MRI, demographics, APOE, neuropsychology) measures to predict future A beta-positivity in A beta-negative individuals. We separately study A beta-positivity defined by PET and CSF. RESULTS: Cross-validated AUC for 4-year A beta conversion prediction was 0.78 for the CSF-based and 0.68 for the PET-based A beta definitions. Although not trained for the clinical status-change prediction, the CSF-based model excelled in predicting future mild cognitive impairment (MCI)/dementia conversion in cognitively normal/MCI individuals (AUCs, respectively, 0.76 and 0.89 with a separate dataset). DISCUSSION: Standard measures have the potential in detecting future A beta-positivity and assessing conversion risk, even in cognitively normal individuals. The CSF-based definition led to better predictions than the PET-based definition.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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Machine learning prediction of future amyloid beta positivity in amyloid-negative individuals

Moradi

Prakash

Hall

et al. 2023

Preprint

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“…For example, lecanemab, a humanized IgG1 monoclonal antibody that targets soluble aggregated Aβ species (protofibrils), demonstrated robust amyloid-PET reduction in early AD [50]. One recent study developed a DL model to predict amyloid-PET positivity conversion, which might contribute to the screening of early treatment candidates [54] as it has been reported that positivity in both amyloid and tau PET scans put cognitively unimpaired individual at high risk for future cognitive decline [55 ▪▪ ]. In clinical settings, large multicentre studies have shown that amyloid-PET results change both diagnosis and patient management and that quantification can accurately predict rates of cognitive decline.…”

Section: Amyloid-petmentioning

confidence: 99%

Advanced brain imaging for the diagnosis of Alzheimer disease

Wang,

Rosa-Neto,

Gauthier

2023

Current Opinion in Neurology

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Purpose of review The purpose is to review the latest advances of brain imaging for the diagnosis of Alzheimer disease (AD). Recent findings Brain imaging techniques provide valuable and complementary information to support the diagnosis of Alzheimer disease in clinical and research settings. The recent FDA accelerated approvals of aducanumab, lecanemab and donanemab made amyloid-PET critical in helping determine the optimal window for anti-amyloid therapeutic interventions. Tau-PET, on the other hand, is considered of key importance for the tracking of disease progression and for monitoring therapeutic interventions in clinical trials. PET imaging for microglial activation, astrocyte reactivity and synaptic degeneration are still new techniques only used in the research field, and more studies are needed to validate their use in the clinical diagnosis of AD. Finally, artificial intelligence has opened new prospective in the early detection of AD using MRI modalities. Summary Brain imaging techniques using PET improve our understanding of the different AD-related pathologies and their relationship with each other along the course of disease. With more robust validation, machine learning and deep learning algorithms could be integrated with neuroimaging modalities to serve as valuable tools for clinicians to make early diagnosis and prognosis of AD.

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Machine learning prediction of future amyloid beta positivity in amyloid-negative individuals

Moradi,

Prakash,

Hall

et al. 2024

Alz Res Therapy

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Background The pathophysiology of Alzheimer’s disease (AD) involves $$\beta$$ β -amyloid (A$$\beta$$ β ) accumulation. Early identification of individuals with abnormal $$\beta$$ β -amyloid levels is crucial, but A$$\beta$$ β quantification with positron emission tomography (PET) and cerebrospinal fluid (CSF) is invasive and expensive. Methods We propose a machine learning framework using standard non-invasive (MRI, demographics, APOE, neuropsychology) measures to predict future A$$\beta$$ β -positivity in A$$\beta$$ β -negative individuals. We separately study A$$\beta$$ β -positivity defined by PET and CSF. Results Cross-validated AUC for 4-year A$$\beta$$ β conversion prediction was 0.78 for the CSF-based and 0.68 for the PET-based A$$\beta$$ β definitions. Although not trained for the clinical status-change prediction, the CSF-based model excelled in predicting future mild cognitive impairment (MCI)/dementia conversion in cognitively normal/MCI individuals (AUCs, respectively, 0.76 and 0.89 with a separate dataset). Conclusion Standard measures have potential in detecting future A$$\beta$$ β -positivity and assessing conversion risk, even in cognitively normal individuals. The CSF-based definition led to better predictions than the PET-based definition.

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Predicting conversion of brain β-amyloid positivity in amyloid-negative individuals

Cited by 8 publications

References 31 publications

Machine learning prediction of future amyloid beta positivity in amyloid-negative individuals

Machine learning prediction of future amyloid beta positivity in amyloid-negative individuals

Advanced brain imaging for the diagnosis of Alzheimer disease

Machine learning prediction of future amyloid beta positivity in amyloid-negative individuals

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