Aging induced loss of complexity and dedifferentiation: consequences for coordination dynamics within and between brain, muscular and behavioral levels

Sleimen-Malkoun, Rita; Temprado, Jean-Jacques; Hong, S. Lee

doi:10.3389/fnagi.2014.00140

Cited by 94 publications

(85 citation statements)

References 169 publications

(270 reference statements)

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“…In other words, the results might suggest that the set of dynamical repertoires used is the same between age groups but elderly do not switch between them as often or alternatively that a smaller set of dynamical repertoires is available. Only the latter case would be consistent with the dedifferentiation hypotheses (Sleimen-Malkoun et al, 2014) which was also found for the kinematic data presented here. The analyses of muscular synergies allowed answering this question.…”

Section: Discussionsupporting

confidence: 94%

“…Accordingly, aging is a dynamic process that presents itself with both alterations within all subsystems—though each having their individual timescale—and with changes in their couplings (e.g., Sleimen-Malkoun et al, 2014). These changes lie at the origin of an age-related loss of behavioral adaptability.…”

Section: Introductionmentioning

confidence: 99%

“…To address this issue, a possible strategy consists of forcing the system to reorganize to accommodate a progressive increase in task constraints (Haken et al, 1985; Kelso and Jeka, 1992; Kelso, 2009; Sleimen-Malkoun et al, 2014). In the present experiment, we adopted a similar strategy to study reorganizations in muscular dynamics in parallel to (before, around, and after) transitions between dynamics regimes in Fitts' task.…”

Section: Introductionmentioning

confidence: 99%

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The Effect of Aging on Muscular Dynamics Underlying Movement Patterns Changes

Vernooij

Rao

Berton

et al. 2016

Front. Aging Neurosci.

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Introduction: Aging leads to alterations not only within the complex subsystems of the neuro-musculo-skeletal system, but also in the coupling between them. Here, we studied how aging affects functional reorganizations that occur both within and between the behavioral and muscular levels, which must be coordinated to produce goal-directed movements. Using unimanual reciprocal Fitts' task, we examined the behavioral and muscular dynamics of older adults (74.4 ± 3.7 years) and compared them to those found for younger adults (23.2 ± 2.0 years).Methods: To achieve this objective, we manipulated the target size to trigger a phase transition in the behavioral regime and searched for concomitant signatures of a phase transition in the muscular coordination. Here, muscular coordination was derived by using the method of muscular synergy extraction. With this technique, we obtained functional muscular patterns through non-negative matrix factorization of the muscular signals followed by clustering the resulting synergies.Results: Older adults showed a phase transition in behavioral regime, although, in contrast to young participants, their kinematic profiles did not show a discontinuity. In parallel, muscular coordination displayed two typical signatures of a phase transition, that is, increased variability of coordination patterns and a reorganization of muscular synergies. Both signatures confirmed the existence of muscular reorganization in older adults, which is coupled with change in dynamical regime at behavioral level. However, relative to young adults, transition occurred at lower index of difficulty (ID) in older participants and the reorganization of muscular patterns lasted longer (over multiple IDs).Discussion: This implies that consistent changes occur in coordination processes across behavior and muscle. Furthermore, the repertoire of muscular patterns was reduced and somewhat modified for older adults, relative to young participants. This suggests that aging is not only related to changes in individual muscles (e.g., caused by dynapenia) but also in their coordination.

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Section: Discussionsupporting

confidence: 94%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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The Effect of Aging on Muscular Dynamics Underlying Movement Patterns Changes

Vernooij

Rao

Berton

et al. 2016

Front. Aging Neurosci.

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“…These reductions in dFC speed and complexity correlate with the level of general cognitive and behavioural performance, as probed by both standard clinical assessments of cognitive impairments (Nasreddine et al, 2005) and a simple visuomotor coordination task (Houweling et al, 2008). The fact that slowing down and complexity loss in dFC are associated with degraded performance can be linked to prominent theories of cognitive aging, speculatively establishing alterations of dFC random walk properties as novel imaging correlates of processing speed reduction (Salthouse, 1996;Finkel et al, 2007) and de-differentiation (Baltes, 1980;Sleimen-Malkoun et al, 2014).…”

Section: Introductionmentioning

confidence: 97%

Dynamic Functional Connectivity between Order and Randomness and its Evolution across the Human Adult Lifespan

Battaglia

Boudou

Hansen

et al. 2017

Preprint

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The aging brain undergoes alterations of both Structural Connectivity (SC) and timeaveraged Functional Connectivity in the resting state (rs FC). Here, we show by means of functional MRI (fMRI) human brain imaging that aging also profoundly impacts on the spontaneous temporal reconfiguration of this rs FC. Analyzing time-dependent correlations between human rs fMRI blood oxygen level dependent (BOLD) time series, we describe Functional Connectivity Dynamics (FCD) as a switching between epochs of meta-stable FC and transients of fast network reconfiguration. We find that the flux of FCD markedly slows down and becomes more "viscous" across the adult lifespan (18-80 yrs), also accounting for the wide inter-subject variability of performance observed in cognitive screening tasks. Such remodeling of FCD discloses qualitatively novel effects of aging that cannot be captured by variations of SC or of static FC, opening the way to improved imaging-based characterizations of the functional mechanisms underlying cognitive aging.

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“…From the point of view of chaos theory, multiscale and non-linear complexity (structure and interactions of individual subsystems) appears to degrade with ageing and disease [47]. The structures and functions of the individual subsystems are not only affected by the process but also the interactions between them [48]. For this reason, the loss of complexity has even been hypothesized to be an indicator of the transition from normal ageing to frailty [49].…”

Section: Fractal Dimension and Ageingmentioning

confidence: 99%

Fractal Analysis of Cardiovascular Signals Empowering the Bioengineering Knowledge

Armentano¹,

Legnani²,

Cymberknop³

2017

Fractal Analysis - Applications in Health Sciences and Social Sciences

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The cardiovascular system is composed of a complex network of vessels, where highly uniform hierarchical branching structures are regulated by the anatomy and local flow requirements. Arteries bifurcate many times before they become capillaries where the scaling factor of vessel length, diameter and angle between two children branches is established at each level of recurrence. This behaviour can be easily described using a fractal scaling principle. Moreover, it was observed that the basic pattern of blood distribution is also fractal, imposed both by the anatomy of the vascular tree and the local regulation of vascular tone. In this chapter, arterial physiology was analysed, where waveform complexity of arterial pressure time series was related to arterial stiffness changes, pulse pressure variations and the presence wave reflection. Fractal dimension was used as a nonlinear measure, giving place to a 'holistic approach of fractal dimension variations throughout the arterial network', both in health and disease.

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Aging induced loss of complexity and dedifferentiation: consequences for coordination dynamics within and between brain, muscular and behavioral levels

Cited by 94 publications

References 169 publications

The Effect of Aging on Muscular Dynamics Underlying Movement Patterns Changes

The Effect of Aging on Muscular Dynamics Underlying Movement Patterns Changes

Dynamic Functional Connectivity between Order and Randomness and its Evolution across the Human Adult Lifespan

Fractal Analysis of Cardiovascular Signals Empowering the Bioengineering Knowledge

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