Age-dependent decline in density of human nerve and spinal ganglia neurons expressing the α3 isoform of Na/K-ATPase

Romanovsky, Dmitry; Mrak, Robert E.; Dobretsov, Maxim

doi:10.1016/j.neuroscience.2015.09.034

Cited by 6 publications

(7 citation statements)

References 46 publications

(91 reference statements)

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“…Indeed, old compared with young adults have deficits in muscle strength (Faulkner et al 2007 ; Thompson 2009 ), muscle power (Bassey et al 1992 ; Faulkner et al 2007 ; Thompson 2009 ) and mobility (Beijersbergen et al 2013 ), are less able to integrate proprioceptive feedback (Goble et al 2009 ) and to coordinate agonist–antagonist muscle pairs (Hortobágyi and Devita 2006 ), critical in reaching movements. Furthermore, old adults show decrements in central nervous system functioning such as a reduction in motor cortical inhibition (Hortobágyi et al 2006 ; Papegaaij et al 2014 ; Peinemann et al 2001 ), white matter lesions (Ge et al 2002 ; Pantoni 2002 ; Schulz et al 2014 ) and decrements in the number and size of afferent fibers (Romanovsky et al 2015 ). Such neuronal and neuromuscular deficits have been associated with impaired and slow execution of ADLs (Rosano et al 2012 ; Sleimen-Malkoun et al 2013 ; Van Halewyck et al 2015 ), poor balance control (Baloh et al 2003 ; Huxhold et al 2006 ; Papegaaij et al 2014 ) and mobility disability in walking (Beijersbergen et al 2013 ; Rosano et al 2012 ; Sorond et al 2015 ).…”

Section: Discussionmentioning

confidence: 99%

“…Flexibility is the capacity of the neuromuscular system to make fine adjustments in the coordination of the available degrees of freedom (e.g., joint angles) while ensuring successful completion of the intended motor act (Domkin et al 2005 ; Latash et al 2007 ; Scholz and Schöner 1999 ). However, even healthy old adults exhibit subclinical peripheral and central nervous system dysfunctions such as increased agonist–antagonist muscle co-activation, deterioration in the size and number of muscle fibers, and impaired intracortical inhibition, possibly affecting motor flexibly (Bassey et al 1992 ; Beijersbergen et al 2013 ; Faulkner et al 2007 ; Ge et al 2002 ; Goble et al 2009 ; Hortobágyi and Devita 2006 ; Pantoni 2002 ; Papegaaij et al 2014 ; Peinemann et al 2001 ; Romanovsky et al 2015 ; Schulz et al 2014 ; Thompson 2009 ).…”

Section: Introductionmentioning

confidence: 99%

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Old adults preserve motor flexibility during rapid reaching

2017

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PurposeOur ability to flexibly coordinate the available degrees of freedom allows us to perform activities of daily living under various task constraints. Healthy old adults exhibit subclinical peripheral and central nervous system dysfunctions, possibly compromising the flexibility in inter-joint coordination during voluntary movements and the ability to adapt to varying task constraints.MethodWe examined how healthy old (75.4 ± 5.2 years, n = 14) compared with young adults (24.3 ± 2 years, n = 15) make use of the available motor flexibility to adapt to physical and dexterity constraints during a rapid goal-directed reaching task. We manipulated physical and dexterity demands by changing, respectively, external resistance and target size. Motor flexibility was quantified by an uncontrolled manifold (UCM) analysis.ResultsWe found that healthy young and old adults employ similar motor flexibility as quantified by the ratio between goal equivalent and non-goal equivalent variability (V Ratio) and were similarly able to adapt to increases in physical and dexterity demands during goal-directed rapid reaching (V Ratio: p = .092; young: 0.548 ± 0.113; old: 0.264 ± 0.117). Age affected end-effector kinematics. Motor flexibility and end-effector kinematics did not correlate.ConclusionThe data challenge the prevailing view that old age affects movement capabilities in general and provide specific evidence that healthy old adults preserve motor flexibility during a reaching task. Future studies applying UCM analysis should examine if experimental set-ups limit movement exploration, leaving possible age differences undetected.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Old adults preserve motor flexibility during rapid reaching

2017

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“…For example, old as compared to young adults have an impaired ability to integrate proprioceptive feedback (Goble et al 2009 ) and to coordinate agonist–antagonist muscle pairs (Hortobágyi and Devita 2006 ). Furthermore the central nervous system suffers from a decline in number and size of afferent fibers (Romanovsky et al 2015 ), less cortical and spinal neurons (Dinse 2006 ; Eisen et al 1996 ; Erim et al 1999 ), a reduction in motor cortical inhibition (Hortobágyi et al 2006 ; Papegaaij et al 2014 ; Peinemann et al 2001 ) and cognitive dysfunctions involved in postural control (Morris et al 2016 ; Seidler et al 2011 ; Woollacott and Shumway-Cook 2002 ). Based on these well-established findings on age differences in neuromuscular functions previous studies assumed that flexibility in joint coordination might also decline with ageing.…”

Section: Discussionmentioning

confidence: 99%

Flexibility in joint coordination remains unaffected by force and balance demands in young and old adults during simple sit-to-stand tasks

2018

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Purpose We examined the possibility that old adults use flexibility in joint coordination as a compensatory mechanism for the age-related decline in muscle strength when performing the sit-to-stand (STS) task repeatedly under high force and balance demands. Method Young ( n = 14, 22.4 ± 2.1) and old ( n = 12, 70 ± 3.2) healthy adults performed repeated STSs under high and low force and balance demands. The balance demand was manipulated by reducing the base of support and the force demand by increasing body weight with a weight vest. Uncontrolled manifold analysis was used to quantify age differences in motor flexibility. Results While there were age-typical differences in kinematic STS strategies, flexibility in joint coordination was independent of age and task difficulty during repeated STSs. Discussion That simple manipulations of force and balance demands did not affect flexibility in joint coordination in old and young adults suggests that motor flexibility acts as a compensatory mechanism only at the limits of available muscle strength and balance abilities during STS movements. Intervention studies should identify how changes in specific neuromuscular functions affect flexibility in joint coordination during activities of daily living such as STS.

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“…Clock Scan Protocol: The Clock Scan protocol is a fast and simple tool of image analysis. The advantages of this protocol, compared to existing common approaches of image analysis (such as linear pixel intensity scans or calculation of mean pixel intensity of the ROI), have been described in details in previous publications 1,9 . Briefly, this protocol allows the generation of integral radial pixel-intensity profiles by quantifying the intensity of pixels located at different distances from the ROI center such as the object's border, or a pre-determined location outside the object (background).…”

Section: Discussionmentioning

confidence: 99%

“…The major limitation for distributing and sharing the original protocol was the platform-dependence of its code which was developed with Visual Basic 6.0 (VB) 1,9 . This problem has been recently addressed by one of the research groups at the Leibniz Institute of Molecular Pharmacology, Germany, by developing a similar Fuji ImageJ Clock Scan plugin 2 .…”

Section: Clock Scan Pluginsmentioning

confidence: 99%

Clock Scan Protocol for Image Analysis: ImageJ Plugins

Dobretsov

Petkau

Hayar

et al. 2017

JoVE

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The clock scan protocol for image analysis is an efficient tool to quantify the average pixel intensity within, at the border, and outside (background) a closed or segmented convex-shaped region of interest, leading to the generation of an averaged integral radial pixel-intensity profile. This protocol was originally developed in 2006, as a visual basic 6 script, but as such, it had limited distribution. To address this problem and to join similar recent efforts by others, we converted the original clock scan protocol code into two Java-based plugins compatible with NIH-sponsored and freely available image analysis programs like ImageJ or Fiji ImageJ. Furthermore, these plugins have several new functions, further expanding the range of capabilities of the original protocol, such as analysis of multiple regions of interest and image stacks. The latter feature of the program is especially useful in applications in which it is important to determine changes related to time and location. Thus, the clock scan analysis of stacks of biological images may potentially be applied to spreading of Na or Ca within a single cell, as well as to the analysis of spreading activity (e.g., Ca waves) in populations of synaptically-connected or gap junction-coupled cells. Here, we describe these new clock scan plugins and show some examples of their applications in image analysis.

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Age-dependent decline in density of human nerve and spinal ganglia neurons expressing the α3 isoform of Na/K-ATPase

Cited by 6 publications

References 46 publications

Old adults preserve motor flexibility during rapid reaching

Old adults preserve motor flexibility during rapid reaching

Flexibility in joint coordination remains unaffected by force and balance demands in young and old adults during simple sit-to-stand tasks

Clock Scan Protocol for Image Analysis: ImageJ Plugins

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