The virtual aging brain: a model-driven explanation for cognitive decline in older subjects

Lavanga, Mario; Stumme, Johanna; Yalçınkaya, Bahar Hazal; Fousek, J.; Jockwitz, Christiane; Sheheitli, Hiba; Bittner, Nóra; Hashemi, Meysam; Petkoski, Spase; Caspers, Svenja; Jirsa, Viktor

doi:10.1101/2022.02.17.480902

Cited by 12 publications

(23 citation statements)

References 106 publications

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“…The temporal evolution of the brain FC is represented by sliding window technique and it is quantified via switching index (for further detail Material and Methods section). The index related with brain fluidity (Figure 1E) (Hansen et al, 2015; Melozzi et al, 2019; Courtiol et al, 2020) quantifies the switching behaviour of resting state networks (Rabuffo et al, 2021; Lavanga et al, 2022). Empirical resting-state fMRI analysis showed that patients with cognitive decline had a significant reduction in both homotopic dysconnectivity (Figure 2B), and brain fluidity as measured by FCD variance of the limbic network (Figure 2C) (Pillai’s Trace = 0.86, F (4, 218) = 40.97, p < 0.001).…”

Section: Resultsmentioning

confidence: 99%

“…Specifically, reduced inter-hemispheric homotopic FC (Figure 1D) is also associated with AD (Wang et al, 2015, Qiu et al, 2016). Functional connectivity dynamics (FCD) (see Figure 1.E) refers to the flexibility of the brain to flow between different states to facilitate cognition and has been shown to be altered in healthy lifespan (Battaglia et al, 2020, Petkoski et al, 2022), normal mild-life and older adults (Lavanga et al, 2022), and AD (Córdova-Palomera et al, 2017, Jie et al, 2018). These changes in FCD may provide insight into the neural mechanisms underlying cognitive decline in AD.…”

Section: Introductionmentioning

confidence: 99%

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Personalized virtual brains of Alzheimer’s Disease link dynamical biomarkers of fMRI with increased local excitability

Yalçınkaya

Ziaeemehr

Fousek

et al. 2023

Preprint

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Alzheimer's disease (AD) is a neurodegenerative disorder characterized by the accumulation of abnormal beta-amyloid (Aβ) and hyperphosphorylated Tau (pTau). These proteinopathies disrupt neuronal activity, causing, among others, an excessive and hypersynchronous neuronal firing that promotes hyperexcitability and leads to brain network dysfunction and cognitive deficits. In this study, we used computational network modeling to build a causal inference framework to explain AD-related abnormal brain activity. We constructed personalized brain network models with a set of working points to enable maximum dynamical complexity for each brain. Structural brain topographies were combined, either with excitotoxicity, or postsynaptic depression, as two leading mechanisms of the Aβ and pTau on neuronal activity. By applying various levels of these putative mechanisms to the limbic regions that typically present, with the earliest and largest protein burden, we found that the excitotoxicity is sufficient and necessary to reproduce empirical biomarkers two biometrics associated with AD pathology: homotopic dysconnectivity and a decrease in limbic network dynamical fluidity. This observation was shown not only in the clinical groups (aMCI and AD), but also in healthy subjects that were virtually-diseased with excitotoxicity as these abnormal proteins can accumulate before the appearance of any cognitive changes. The same findings were independently confirmed by a mechanistic deep learning inference framework. Taken together, our results show the crucial role of protein burden-induced hyperexcitability in altering macroscopic brain network dynamics, and offer a mechanistic link between structural and functional biomarkers of cognitive dysfunction due to AD.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Personalized virtual brains of Alzheimer’s Disease link dynamical biomarkers of fMRI with increased local excitability

Yalçınkaya

Ziaeemehr

Fousek

et al. 2023

Preprint

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“…This is thought to reduce the capacity to also behaviorally switch between concepts and to slow the rate of functional adaptations to external influences (Escrichs et al, 2021 ; Lee et al, 2019 ; Xia et al, 2019 ). Computational models showed that reduced metastability is a response to SC decline (Deco & Kringelbach, 2016 ; Lavanga et al, 2022 ; Naik et al, 2017 ). Hence, the functionally highly interconnected system found in the second component could point towards a low capacity to switch between functional states potentially resulting from the incipient SC decline and would explain the strongest association with cognitive performance decline.…”

Section: Discussionmentioning

confidence: 99%

“…Higher overall communication in the brain, that is, connectivity, requires higher energy consumption (Tomasi et al, 2013 ). At the same time, a highly interconnected functional system reduces the ability to efficiently switch between brain states (Chan et al, 2014 , 2017 ; Colcombe et al, 2005 ; Goh, 2011 ; Nashiro et al, 2017 ; Park et al, 2004 ), which is associated with lower cognitive performance (Lavanga et al, 2022 ). Accordingly, the functional connectivity system of this third component could reflect a rather low‐energy state of the resting brain, which at the same time may involve a high ability to efficiently adapt to external stimuli.…”

Section: Discussionmentioning

confidence: 99%

“…Computational models showed that reduced metastability is a response to SC decline (Deco & Kringelbach, 2016;Lavanga et al, 2022;Naik et al, 2017). Hence, the functionally highly interconnected system found in the second component could point towards a low capacity to switch between functional states potentially resulting from the incipient SC decline and would explain the strongest association with cognitive performance decline.…”

Section: Third Componentmentioning

confidence: 99%

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Interrelating differences in structural and functional connectivity in the older adult's brain

Stumme

Krämer

Miller

et al. 2022

Human Brain Mapping

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In the normal aging process, the functional connectome restructures and shows a shift from more segregated to more integrated brain networks, which manifests itself in highly different cognitive performances in older adults. Underpinnings of this reorganization are not fully understood, but may be related to age-related differences in structural connectivity, the underlying scaffold for information exchange between regions. The structure-function relationship might be a promising factor to understand the neurobiological sources of interindividual cognitive variability, but remain unclear in older adults. Here, we used diffusion weighted and resting-state functional magnetic resonance imaging as well as cognitive performance data of 573 older subjects from the 1000BRAINS cohort (55-85 years, 287 males) and performed a partial least square regression on 400 regional functional and structural connectivity (FC and SC, respectively) estimates comprising seven resting-state networks. Our aim was to identify FC and SC patterns that are, together with cognitive performance, characteristic of the older adults aging process. Results revealed three different aging profiles prevalent in older adults. FC was found to behave differently depending on the severity of age-related SC deteriorations. A functionally highly interconnected system is associated with a structural connectome that shows only minor age-related decreases. Because this connectivity profile was associated with the most severe age-related cognitive decline, a more interconnected FC system in older adults points to a process of dedifferentiation. Thus, functional network integration appears to increase primarily when SC begins to decline, but this does not appear to mitigate the decline in cognitive performance.

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Prediction of cognitive performance differences in older age from multimodal neuroimaging data

Krämer¹,

Stumme²,

Campos³

et al. 2023

GeroScience

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Differences in brain structure and functional and structural network architecture have been found to partly explain cognitive performance differences in older ages. Thus, they may serve as potential markers for these differences. Initial unimodal studies, however, have reported mixed prediction results of selective cognitive variables based on these brain features using machine learning (ML). Thus, the aim of the current study was to investigate the general validity of cognitive performance prediction from imaging data in healthy older adults. In particular, the focus was with examining whether (1) multimodal information, i.e., region-wise grey matter volume (GMV), resting-state functional connectivity (RSFC), and structural connectivity (SC) estimates, may improve predictability of cognitive targets, (2) predictability differences arise for global cognition and distinct cognitive profiles, and (3) results generalize across different ML approaches in 594 healthy older adults (age range: 55–85 years) from the 1000BRAINS study. Prediction potential was examined for each modality and all multimodal combinations, with and without confound (i.e., age, education, and sex) regression across different analytic options, i.e., variations in algorithms, feature sets, and multimodal approaches (i.e., concatenation vs. stacking). Results showed that prediction performance differed considerably between deconfounding strategies. In the absence of demographic confounder control, successful prediction of cognitive performance could be observed across analytic choices. Combination of different modalities tended to marginally improve predictability of cognitive performance compared to single modalities. Importantly, all previously described effects vanished in the strict confounder control condition. Despite a small trend for a multimodal benefit, developing a biomarker for cognitive aging remains challenging.

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The virtual aging brain: a model-driven explanation for cognitive decline in older subjects

Cited by 12 publications

References 106 publications

Personalized virtual brains of Alzheimer’s Disease link dynamical biomarkers of fMRI with increased local excitability

Personalized virtual brains of Alzheimer’s Disease link dynamical biomarkers of fMRI with increased local excitability

Interrelating differences in structural and functional connectivity in the older adult's brain

Prediction of cognitive performance differences in older age from multimodal neuroimaging data

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