Statistical Disease Progression Modeling in Alzheimer Disease

Rakêt, Lars Lau

doi:10.3389/fdata.2020.00024

Cited by 49 publications

(61 citation statements)

References 59 publications

(63 reference statements)

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“…Resultingly, time 0 of the latent disease timescale corresponds to the average state of the cognitively normal participants at baseline. We have made both the univariate and multivariate models presented in Section 3 available in the progmod R package 20 which builds on the maximum likelihood estimation procedures in the nlme ‐package 21 . Example data and code for fitting both univariate and multivariate disease progression models are available in the package documentation.…”

Section: Methodsmentioning

confidence: 99%

“…These transformed outcomes are modeled using a linear mixed‐effects model and the identifiability of the latent time shifts is achieved by assuming that disease stage is the only consistent time‐invariant patient‐level effect across outcomes. Another recent disease progression modeling framework has been proposed by Raket 20 . This framework considers the same problem but differ in some key modeling choices.…”

Section: Introductionmentioning

confidence: 99%

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Simultaneous modeling of Alzheimer's disease progression via multiple cognitive scales

Kühnel

Berger

Markussen

et al. 2021

Statistics in Medicine

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Analyzing the progression of Alzheimer's disease (AD) is challenging due to lacking sensitivity in currently available measures. AD stages are typically defined based on cognitive cut‐offs, but this results in heterogeneous patient groups. More accurate modeling of the continuous progression of the disease would enable more accurate patient prognosis. To address these issues, we propose a new multivariate continuous‐time disease progression (MCDP) model. The model is formulated as a nonlinear mixed‐effects model that aligns patients based on their predicted disease progression along a continuous latent disease timeline. The model is evaluated using long‐term follow‐up data from 2152 participants in the Alzheimer's Disease Neuroimaging Initiative. The MCDP model was used to simultaneously model three cognitive scales; the Alzheimer's Disease Assessment Scale‐cognitive subscale, the Mini‐Mental State Examination, and the Clinical Dementia Rating scale—sum of boxes. Compared with univariate modeling and previously proposed multivariate disease progression models, the MCDP model showed superior ability to predict future patient trajectories. Finally, based on the multivariate disease timeline estimated using the MCDP model, the sensitivity of the individual items of the cognitive scales along the different stages of disease was analyzed. The analysis showed that delayed memory recall items had the highest sensitivity in the early stages of disease, whereas language and attention items were sensitive later in disease.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Simultaneous modeling of Alzheimer's disease progression via multiple cognitive scales

Kühnel

Berger

Markussen

et al. 2021

Statistics in Medicine

View full text Add to dashboard Cite

show abstract

“…On the whole there have been few treatment successes (and none of these are disease-modifying) despite substantive investment in pharmacological compounds for Alzheimer’s disease in symptomatic populations and early promise shown in pre-clinical studies ( Gauthier et al, 2016 ; Winblad et al, 2016 ; Anderson et al, 2017 ). There may be a number of possible explanations for the many failures including inadequate drug dosages, incorrect treatment targets and inappropriate trial populations where the disease process is too far along to be amenable to treatment ( Raket, 2020 ; Shi et al, 2020 ; Yiannopoulou and Papageorgiou, 2020 ). There is a consensus that the genesis of AD pathology occurs decades before the onset of dementia symptoms ( Braak and Braak, 1997 ; Hardy and Selkoe, 2002 ; Jack et al, 2010 ; Bateman et al, 2012 ; Braak and Del Tredici, 2012 ; Jack et al, 2013 ).…”

Section: Introductionmentioning

confidence: 99%

“…Various disease progression and sub-type approaches have been proposed and developed. These include survival and multi-state models for investigating transitions between disease states ( Hubbard and Zhou, 2011 ; Vos et al, 2013 ; van den Hout, 2016 ; Wei and Kryscio, 2016 ; Robitaille et al, 2018 ; Zhang et al, 2019 ); mixed effects models (linear, generalized, non-linear) that incorporate subject-specific random effects and can be extended to handle latent time shifts, random change points, latent factors, processes and classes, hidden states, and multiple outcomes ( Hall et al, 2000 ; Jedynak et al, 2012 ; Liu et al, 2013 ; Proust-Lima et al, 2013 ; Donohue et al, 2014 ; Samtani et al, 2014 ; Lai et al, 2016 ; Zhang et al, 2016 ; Geifman et al, 2018 ; Li et al, 2018 ; Wang et al, 2018 ; Lorenzi et al, 2019 ; Proust-Lima et al, 2019 ; Villeneuve et al, 2019 ; Younes et al, 2019 ; Bachman et al, 2020 ; Kulason et al, 2020 ; Raket, 2020 ; Segalas et al, 2020 ; Williams et al, 2020 ) and can be combined with models for event-history data ( Marioni et al, 2014 ; Blanche et al, 2015 ; Proust-Lima et al, 2016 ; Rouanet et al, 2016 ; Li et al, 2017 ; Iddi et al, 2019 ; Li and Luo, 2019 ; Wu et al, 2020 ); event-based models which attempt to model the pathological cascade of events occurring as the disease develops and progresses through disease stages ( Fonteijn et al, 2012 ; Young et al, 2014 ; Chen et al, 2016 ; Goyal et al, 2018 ; Oxtoby et al, 2018 ); and various clustering approaches for discovering risk stratification/disease progression groups and endotypes. For example, those based on hierarchical, partitioning and model-based clustering algorithms/methods ( Dong et al, 2016 ; Racine et al, 2016 ; Dong et al, 2017 ; ten Kate et al, 2018 ; Young et al, 2018 ).…”

Section: Introductionmentioning

confidence: 99%

Disease Modelling of Cognitive Outcomes and Biomarkers in the European Prevention of Alzheimer’s Dementia Longitudinal Cohort

et al. 2021

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A key challenge for the secondary prevention of Alzheimer’s dementia is the need to identify individuals early on in the disease process through sensitive cognitive tests and biomarkers. The European Prevention of Alzheimer’s Dementia (EPAD) consortium recruited participants into a longitudinal cohort study with the aim of building a readiness cohort for a proof-of-concept clinical trial and also to generate a rich longitudinal data-set for disease modelling. Data have been collected on a wide range of measurements including cognitive outcomes, neuroimaging, cerebrospinal fluid biomarkers, genetics and other clinical and environmental risk factors, and are available for 1,828 eligible participants at baseline, 1,567 at 6 months, 1,188 at one-year follow-up, 383 at 2 years, and 89 participants at three-year follow-up visit. We novelly apply state-of-the-art longitudinal modelling and risk stratification approaches to these data in order to characterise disease progression and biological heterogeneity within the cohort. Specifically, we use longitudinal class-specific mixed effects models to characterise the different clinical disease trajectories and a semi-supervised Bayesian clustering approach to explore whether participants can be stratified into homogeneous subgroups that have different patterns of cognitive functioning evolution, while also having subgroup-specific profiles in terms of baseline biomarkers and longitudinal rate of change in biomarkers.

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“…Various disease progression and sub-type approaches have been proposed and developed. These include survival and multi-state models for investigating transitions between disease states (Hubbard and Zhou, 2011;Vos et al, 2013;van den Hout, 2016;Wei and Kryscio, 2016;Robitaille et al, 2018;Zhang et al, 2019); mixed effects models (linear, generalized, non-linear) that incorporate subject-specific random effects and can be extended to handle latent time shifts, random change points, latent factors, processes and classes, hidden states, and multiple outcomes (Hall et al, 2000;Jedynak et al, 2012;Liu et al, 2013;Proust-Lima et al, 2013;Donohue et al, 2014;Samtani et al, 2014;Lai et al, 2016;Zhang et al, 2016;Geifman et al, 2018;Li et al, 2018;Wang et al, 2018;Lorenzi et al, 2019;Proust-Lima et al, 2019;Villeneuve et al, 2019;Younes et al, 2019;Bachman et al, 2020;Kulason et al, 2020;Raket, 2020;Segalas et al, 2020;Williams et al, 2020) and can be combined with models for event-history data (Marioni et al, 2014;Blanche et al, 2015;Proust-Lima et al, 2016;Rouanet et al, 2016;Li et al, 2017;Iddi et al, 2019;Li and Luo, 2019;Wu et al, 2020); event-based models which attempt to model the pathological cascade of events occurring as the disease develops and progresses through disease stages (Fonteijn et al, 2012;...…”

Section: Introductionmentioning

confidence: 99%

fdata-04-676168.pdf

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Statistical Disease Progression Modeling in Alzheimer Disease

Cited by 49 publications

References 59 publications

Simultaneous modeling of Alzheimer's disease progression via multiple cognitive scales

Simultaneous modeling of Alzheimer's disease progression via multiple cognitive scales

Disease Modelling of Cognitive Outcomes and Biomarkers in the European Prevention of Alzheimer’s Dementia Longitudinal Cohort

fdata-04-676168.pdf

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