About this Research Topic
This Research Topic is part of the article collection series, The Contribution of Postural Adjustments to Body Balance and Motor Performance.
The control of balance is crucial to maintain our posture and perform efficiently our daily motor tasks. Humans, like all terrestrial species, indeed evolve in a gravity field that permanently tends to induce postural destabilization by its attracting effect towards the center of the earth. Other external forces, arising from the environment such as those elicited by the contact with a player in sports practice or by the acceleration of a train in which one stands, may also challenge body balance. In addition, many studies from the last decades and to date pointed out the disturbing effect of internal forces induced by vegetative functions (respiration, heart bump, peristaltism, etc.) and by voluntary segmental movements, even the tiniest ones such as single-finger movements. To keep the body (or part of it) steady, these disturbing forces must be compensated, at least partly. It is known that this compensation involves dynamical phenomena sub-served by highly coordinated patterns of muscle activation/deactivation disseminated throughout the whole-body and called “postural adjustments”. Current research shows that these postural phenomena are triggered by a complex tune of intertwined feed-forward and feedback mechanisms that may be released before (the so-called “early postural adjustments” and “anticipatory postural adjustments, EPA and APA, respectively), during (“simultaneous postural adjustments”, SPA) and/or after (“consecutive postural adjustments”, CPA) the disturbance. According to the biomechanical concept of “posturo-kinetic capacity” (PKC), both postural stability and motor performance would depend on the capacity of the central nervous system to generate these postural phenomena.
Postural adjustments primarily depend on the biomechanical parameters of the task to perform, but might also be influenced by other factors (e.g. psychological, cognitive, physiological, environmental) likely to interfere with the motor control programming.
In addition, it is noteworthy that SPA and CPA have only been recently described in the literature, and the question of the coordination between the different components of postural adjustments, namely APA, SPA, and CPA still largely remains to be clarified.
Besides their basic interest in unveiling the mechanisms behind motor control, results from such investigations might be relevant to develop new methods or tools to improve postural stability and motor performance, with applications in the fields of neurodegenerative conditions, rehabilitation, ergonomics, and sports activities. Establishing the interaction between postural control, locomotion and cognition has important clinical implications, especially in terms of fall prevention, and will improve our knowledge of the underlying neural correlates.
The goal of this Research Topic is to provide an up-to-date picture of the relationship between postural adjustments, body balance, and motor performance. We welcome submissions focusing on the various factors, such as normal/pathological aging, cognitive impairments, experimental/clinical pain, kinesiophobia etc., which may influence posture and locomotion, on the relationship between the successive sequences of postural adjustments (APS, SPA, CPA), and on the use of postural adjustments in specific applications. The Topic covers the different aspects of motor control, from body balance assessment to the analysis of dynamic tasks and gait and its interaction with cognitive functions. Submissions, which should use the state of art method and technology (EMG, force plate, 3D analysis, etc.) for human movement analysis can be any article type (review, original research, technical note, etc.).
The control of balance is crucial to maintain our posture and perform efficiently our daily motor tasks. Humans, like all terrestrial species, indeed evolve in a gravity field that permanently tends to induce postural destabilization by its attracting effect towards the center of the earth. Other external forces, arising from the environment such as those elicited by the contact with a player in sports practice or by the acceleration of a train in which one stands, may also challenge body balance. In addition, many studies from the last decades and to date pointed out the disturbing effect of internal forces induced by vegetative functions (respiration, heart bump, peristaltism, etc.) and by voluntary segmental movements, even the tiniest ones such as single-finger movements. To keep the body (or part of it) steady, these disturbing forces must be compensated, at least partly. It is known that this compensation involves dynamical phenomena sub-served by highly coordinated patterns of muscle activation/deactivation disseminated throughout the whole-body and called “postural adjustments”. Current research shows that these postural phenomena are triggered by a complex tune of intertwined feed-forward and feedback mechanisms that may be released before (the so-called “early postural adjustments” and “anticipatory postural adjustments, EPA and APA, respectively), during (“simultaneous postural adjustments”, SPA) and/or after (“consecutive postural adjustments”, CPA) the disturbance. According to the biomechanical concept of “posturo-kinetic capacity” (PKC), both postural stability and motor performance would depend on the capacity of the central nervous system to generate these postural phenomena.
Postural adjustments primarily depend on the biomechanical parameters of the task to perform, but might also be influenced by other factors (e.g. psychological, cognitive, physiological, environmental) likely to interfere with the motor control programming.
In addition, it is noteworthy that SPA and CPA have only been recently described in the literature, and the question of the coordination between the different components of postural adjustments, namely APA, SPA, and CPA still largely remains to be clarified.
Besides their basic interest in unveiling the mechanisms behind motor control, results from such investigations might be relevant to develop new methods or tools to improve postural stability and motor performance, with applications in the fields of neurodegenerative conditions, rehabilitation, ergonomics, and sports activities. Establishing the interaction between postural control, locomotion and cognition has important clinical implications, especially in terms of fall prevention, and will improve our knowledge of the underlying neural correlates.
The goal of this Research Topic is to provide an up-to-date picture of the relationship between postural adjustments, body balance, and motor performance. We welcome submissions focusing on the various factors, such as normal/pathological aging, cognitive impairments, experimental/clinical pain, kinesiophobia etc., which may influence posture and locomotion, on the relationship between the successive sequences of postural adjustments (APS, SPA, CPA), and on the use of postural adjustments in specific applications. The Topic covers the different aspects of motor control, from body balance assessment to the analysis of dynamic tasks and gait and its interaction with cognitive functions. Submissions, which should use the state of art method and technology (EMG, force plate, 3D analysis, etc.) for human movement analysis can be any article type (review, original research, technical note, etc.).
Important Note: All contributions to this Research Topic must be within the scope of the section and journal to which they are submitted, as defined in their mission statements. Frontiers reserves the right to guide an out-of-scope manuscript to a more suitable section or journal at any stage of peer review.
