Your search keyword '"Reschechtko, Sasha"' showing total 22 results

1. Reach corrections toward moving objects are faster than reach corrections toward instantaneously switching targets

Author

Reschechtko, Sasha, Gnanaseelan, Cynthiya, and Andrew Pruszynski, J.

Published

2023

2. Future movement plans interact in sequential arm movements.

Author

Kashefi, Mehrdad, Reschechtko, Sasha, Ariani, Giacomo, Shahbazi, Mahdiyar, Tan, Alice, Diedrichsen, Jörn, and Pruszynski, J. Andrew

Subjects

*MOVEMENT sequences

Abstract

Real-world actions often comprise a series of movements that cannot be entirely planned before initiation. When these actions are executed rapidly, the planning of multiple future movements needs to occur simultaneously with the ongoing action. How the brain solves this task remains unknown. Here, we address this question with a new sequential arm reaching paradigm that manipulates how many future reaches are available for planning while controlling execution of the ongoing reach. We show that participants plan at least two future reaches simultaneously with an ongoing reach. Further, the planning processes of the two future reaches are not independent of one another. Evidence that the planning processes interact is twofold. First, correcting for a visual perturbation of the ongoing reach target is slower when more future reaches are planned. Second, the curvature of the current reach is modified based on the next reach only when their planning processes temporally overlap. These interactions between future planning processes may enable smooth production of sequential actions by linking individual segments of a long sequence at the level of motor planning. [ABSTRACT FROM AUTHOR]

Published

2024

3. Synergic control of action in levodopa-naïve Parkinson’s disease patients: I. Multi-finger interaction and coordination

Author

de Freitas, Paulo B., Freitas, Sandra M. S. F., Reschechtko, Sasha, Corson, Tyler, Lewis, Mechelle M., Huang, Xuemei, and Latash, Mark L.

Published

2020

4. Multi-finger synergies and the muscular apparatus of the hand

Author

Cuadra, Cristian, Bartsch, Angelo, Tiemann, Paula, Reschechtko, Sasha, and Latash, Mark L.

Published

2018

5. Performance drifts in two-finger cyclical force production tasks performed by one and two actors

Author

Hasanbarani, Fariba, Reschechtko, Sasha, and Latash, Mark L.

Published

2018

6. The synergic control of multi-finger force production: stability of explicit and implicit task components

Author

Reschechtko, Sasha, Zatsiorsky, Vladimir M., and Latash, Mark L.

Published

2017

7. Postural sway is not affected by estrogen fluctuations during the menstrual cycle.

Author

Reschechtko, Sasha, Nguyen, Thuy Ngoc, Tsang, Michelle, Giltvedt, Kristine, Kern, Mark, and Hooshmand, Shirin

Subjects

*MENSTRUAL cycle, *ESTROGEN, *CONTRACEPTION, *ORAL contraceptives, *SEX hormones

Abstract

When people stand still, they exhibit a phenomenon called postural sway, or spontaneous movement of the body's center of pressure, which is related to balance control. In general females show less sway than males, but this difference only begins to appear around puberty, pointing to different levels of sex hormones as one potential mechanism for sway sex differences. In this study, we followed cohorts of young females using oral contraceptives (n = 32) and not using oral contraceptives (n = 19), to investigate associations between estrogen availability and postural sway. All participants visited the lab four times over the putative 28‐day menstrual cycle. At each visit, we performed blood draws to measure plasma estrogen (estradiol) levels, and tests of postural sway using a force plate. During late follicular and mid‐luteal phase, estradiol levels were lower in participants using oral contraceptives (mean differences [95% CI], respectively: −231.33; [−800.44, 337.87]; −613.26; [−1333.60, 107.07] pmol/L; main effect p < 0.001), reflecting expected consequences of oral contraceptive use. Despite these differences, postural sway was not significantly different between participants who were using oral contraceptives and participants who were not (mean difference: 2.09 cm; 95% CI = [−1.05, 5.22]; p = 0.132). Overall, we found no significant effects of the estimated menstrual cycle phase—or absolute levels of estradiol—on postural sway. [ABSTRACT FROM AUTHOR]

Published

2023

8. Interpersonal synergies: static prehension tasks performed by two actors

Author

Solnik, Stanislaw, Reschechtko, Sasha, Wu, Yen-Hsun, Zatsiorsky, Vladimir M., and Latash, Mark L.

Published

2016

9. Force-stabilizing synergies in motor tasks involving two actors

Author

Solnik, Stanislaw, Reschechtko, Sasha, Wu, Yen-Hsun, Zatsiorsky, Vladimir M., and Latash, Mark L.

Published

2015

10. Voluntary modification of rapid tactile-motor responses during reaching differs from its visuomotor counterpart.

Author

Reschechtko, Sasha and Pruszynski, J. Andrew

Abstract

People commonly hold and manipulate a variety of objects in everyday life, and these objects have different physical properties. To successfully control this wide range of objects, people must associate new patterns of tactile stimuli with appropriate motor outputs. We performed a series of experiments investigating the extent to which people can voluntarily modify tactile-motor associations in the context of a rapid tactile-motor response guiding the hand to a moving target (previously described in Pruszynski JA, Johansson RS, Flanagan JR. Curr Biol 26: 788-792, 2016) by using an anti-reach paradigm in which participants were instructed to move their hands in the opposite direction of a target jump. We compared performance to that observed when people make visually guided reaches to a moving target (cf. Day BL, Lyon IN. Exp Brain Res 130: 159-168, 2000; Pisella L, Grea H, Tilikete C, Vighetto A, Desmurget M, Rode G, Boisson D, Rossetti Y. Nat Neurosci 3: 729-736, 2000). When participants had visual feedback, motor responses during the anti-reach task showed early automatic responses toward the moving target before later modification to move in the instructed direction. When the same participants had only tactile feedback, however, they were able to suppress this early phase of the motor response, which occurs <100 ms after the target jump. Our results indicate that while the tactile motor and visual motor systems both support rapid responses that appear similar under some conditions, the circuits underlying responses show sharp distinctions in terms of their malleability. NEW & NOTEWORTHY When people reach toward a visual target that moves suddenly, they automatically correct their reach to follow the object; even when explicitly instructed not to follow a moving visual target, people exhibit an initial incorrect movement before moving in the correct direction. We show that when people use tactile feedback, they do not show an initial incorrect response, even though early muscle activity still occurs. [ABSTRACT FROM AUTHOR]

Published

2020

11. Effect of Sensory Deprivation on Maximal Force Abilities from Local to Non-local Digits.

Author

Reschechtko, Sasha, Wang, Hu, Alendry, Kerlin, Benson, Cynthia, Hahn, Barry, and Zhang, Wei

Subjects

*SENSORY deprivation, *NERVE block, *MUSCLE contraction, *TASK forces, *FINGER physiology, *GRIP strength, *RESEARCH, *RESEARCH methodology, *EVALUATION research, *MEDICAL cooperation, *PHYSIOLOGICAL adaptation, *COMPARATIVE studies, *PSYCHOTHERAPY

Abstract

The present study investigates the effect of sensory deprivation of the index and middle finger on motor function of all digits during maximal voluntary force production tasks. A total of 27 subjects performed maximal isometric pressing tasks by using different instructed finger combinations. Subjects completed the same tasks in two visits: a control visit when they had normal sensory feedback in all fingers, and an anesthesia visit when digital nerve blocks were performed on their right index and middle fingers. We evaluated three aspects of motor adaptation on both local (anesthetized) and non-local (non-anesthetized) digits during maximal force production: (1) task-relevant and overall force magnitude, (2) force directional application, and (3) digital individuation and force sharing. Our results indicate that selective digital anesthesia resulted in decreased maximal force magnitude, changed direction of force production, and significant changes extended to non-local digits. The motor weakness and inefficiency revealed in the non-local digits implies that sensory information from each digit can be shared across the digits to assist motor execution within the same hand. [ABSTRACT FROM AUTHOR]

Published

2020

12. Force-stabilizing synergies can be retained by coordinating sensory-blocked and sensory-intact digits.

Author

Zhang, Wei, Reschechtko, Sasha, Hahn, Barry, Benson, Cynthia, and Youssef, Elias

Subjects

*MUSCLE contraction, *TASK performance, *ARTIFICIAL satellite attitude control systems, *ANESTHESIA

Abstract

The present study examined the effects of selective digital deafferentation on the multi-finger synergies as a function of total force requirement and the number of digits involved in isometric pressing. 12 healthy adults participated in maximal and sub-maximal isometric pressing tasks with or without digital anesthesia to selective digits from the right hand. Our results indicate that selective anesthesia paradigm induces changes in both anesthetized (local) and non-anesthetized (non-local) digits' performance, including: (1) decreased maximal force abilities in both local and non-local digits; (2) reduced force share during multi-finger tasks from non-local but not local digits; (3) decreased force error-making; and (4) marginally increased motor synergies. These results reinforce the contribution of somatosensory feedback in the process of maximal voluntary contraction force, motor performance, and indicate that somatosensation may play a role in optimizing secondary goals during isometric force production rather than ensuring task performance. [ABSTRACT FROM AUTHOR]

Published

2019

13. Maintaining arm control during self‐triggered and unpredictable unloading perturbations.

Author

Reschechtko, Sasha, Johansson, Anders S., and Andrew Pruszynski, J.

Subjects

*SLIDING friction, *NEURAL circuitry, *STATIC friction, *RESISTIVE force

Abstract

We often perform actions where we must break through some resistive force, but want to remain in control during this unpredictable transition; for example, when an object we are pushing on transitions from static to dynamic friction and begins to move. We designed a laboratory task to replicate this situation in which participants actively pushed against a robotic manipulandum until they exceeded an unpredictable threshold, at which point the manipulandum moved freely. Human participants were instructed to either stop the movement of the handle following this unloading perturbation, or to continue pushing. We found that participants were able to modulate their reflexes in response to this unpredictable and self‐triggered unloading perturbation according to the instruction they were following, and that this reflex modulation could not be explained by pre‐perturbation muscle state. However, in a second task, where participants reactively produced force during the pre‐unloading phase in response to the robotic manipulandum to maintain a set hand position, they were unable to modulate their reflexes in the same task‐dependent way. This occurred even though the forces they produced were matched to the first task and they had more time to prepare for the unloading event. We suggest this disparity occurs because of different neural circuits involved in posture and movement, meaning that participants in the first task did not require additional time to switch from postural to movement control. [ABSTRACT FROM AUTHOR]

Published

2019

14. Stability of hand force production. II. Ascending and descending synergies.

Author

Reschechtko, Sasha and Latash, Mark L.

Subjects

*FINGER physiology, *JOINT stiffness, *MOTOR ability, *ELECTROPHYSIOLOGY, *ANALYSIS of covariance

Abstract

We combined the theory of neural control of movement with referent coordinates and the uncontrolled manifold hypothesis to investigate multifinger coordination. We tested hypotheses related to stabilization of performance by covarying control variables, translated into apparent stiffness and referent coordinate, at different levels of an assumed hierarchy of control. Subjects produced an accurate combination of total force and total moment of force with the four fingers under visual feedback on both variables and after feedback was partly or completely removed. The "inverse piano" device was used to estimate control variables. We observed strong synergies in the space of hypothetical control variables that stabilized total force and moment of force, as well as weaker synergies stabilizing individual finger forces; whereas the former were attenuated by alteration of visual feedback, the latter were much less affected. In addition, we investigated the organization of "ascending synergies" stabilizing task-level control variables by covaried adjustments of finger-level control variables. We observed intertrial covariation of individual fingers' referent coordinates that stabilized hand-level referent coordinate, but we observed no such covariation for apparent stiffness. The observations suggest the existence of both descending and ascending synergies in a hierarchical control system. They confirm a trade-off between synergies at different levels of control and corroborate the hypothesis on specialization of different fingers for the control of force and moment. The results provide strong evidence for the importance of central back-coupling loops in ensuring stability of action. [ABSTRACT FROM AUTHOR]

Published

2018

15. Force illusions and drifts observed during muscle vibration.

Author

Reschechtko, Sasha, Cuadra, Cristian, and Latash, Mark L.

Subjects

*FOREARM, *TIME trials, *MUSCULAR sense, *FINGERS

Abstract

Force illusions and drifts observed during muscle vibration. J Neurophysiol 119: 326 -336, 2018. First published October 4, 2017; doi:10.1152/jn.00563.2017.--We explored predictions of a scheme that views position and force perception as a result of measuring proprioceptive signals within a reference frame set by ongoing efferent process. In particular, this hypothesis predicts force illusions caused by muscle vibration and mediated via changes in both afferent and efferent components of kinesthesia. Healthy subjects performed accurate steady force production tasks by pressing with the four fingers of one hand (the task hand) on individual force sensors with and without visual feedback. At various times during the trials, subjects matched the perceived force using the other hand. High-frequency vibration was applied to one or both of the forearms (over the hand and finger extensors). Without visual feedback, subjects showed a drop in the task hand force, which was significantly smaller under the vibration of that forearm. Force production by the matching hand was consistently higher than that of the task hand. Vibrating one of the forearms affected the matching hand in a manner consistent with the perception of higher magnitude of force produced by the vibrated hand. The findings were consistent between the dominant and nondominant hands. The effects of vibration on both force drift and force mismatching suggest that vibration led to shifts in both signals from proprioceptors and the efferent component of perception, the referent coordinate and/or coactivation command. The observations fit the hypothesis on combined perception of kinematic-kinetic variables with little specificity of different groups of peripheral receptors that all contribute to perception of forces and coordinates. NEW & NOTEWORTHY We show that vibration of hand/finger extensors produces consistent errors in finger force perception. Without visual feedback, finger force drifted to lower values without a drift in the matching force produced by the other hand; hand extensor vibration led to smaller finger force drift. The findings fit the scheme with combined perception of kinematic-kinetic variables and suggest that vibration leads to consistent shifts of the referent coordinate and, possibly, of coactivation command to the effector. [ABSTRACT FROM AUTHOR]

Published

2018

16. The recovery response to a novel unannounced laboratory-induced slip: The “first trial effect” in older adults.

Author

Liu, Xuan, Reschechtko, Sasha, Wang, Shuaijie, and Pai, Yi-Chung (Clive)

Subjects

*ACCIDENTAL fall prevention, *DIAGNOSIS, *GAIT in humans, *KINEMATICS, *OLD age

Abstract

Background After a single slip, older adults rapidly make adaptive changes to avoid or eliminate further backward loss of balance or a fall. This rapid adaptation has been termed the “single trial effect”. The purpose of this study was to explore the relationship between the motor errors subjects experienced upon a novel slip and the selection and execution of corrective response by which they modified their ongoing gait pattern and turned it into a protective step. Methods A forward slip was induced in the laboratory among 145 community-living older (≥ 65 year old) adults who were protected by an overhead full body harness system. An eight-camera motion analysis system recorded subjects' kinematics, which was used to compute their instability (motor error), recovery step placement (response selection), and stability gain (motor correction). Findings A linear relationship was found between the stability errors at recovery foot liftoff and the distance between the recovery foot and slipping foot at the time of its touchdown, reflecting an appropriate selection of response that was proportionate to the motor error. A linear relationship was also found between this step modification and resulting stability gain, indicating that greater step modification resulted in greater stability gain. This learning behavior was surprisingly consistent regardless whether the outcome was a recovery or a fall. Interpretations These results suggest that fallers and non-fallers all have an intact motor learning foundation that has enabled them to rapidly improve their stability in subsequent exposures. [ABSTRACT FROM AUTHOR]

Published

2017

17. Unintentional force changes in cyclical tasks performed by an abundant system: Empirical observations and a dynamical model.

Author

Reschechtko, Sasha, Hasanbarani, Fariba, Akulin, Vladimir M., and Latash, Mark L.

Subjects

*PHYSIOLOGICAL control systems, *AUDITORY perception, *CEREBRAL dominance, *TASK performance, *DYNAMIC models, *STANDARD deviations

Abstract

The study explored unintentional force changes elicited by removing visual feedback during cyclical, two-finger isometric force production tasks. Subjects performed two types of tasks at 1 Hz, paced by an auditory metronome. One – Force task – required cyclical changes in total force while maintaining the sharing, defined as relative contribution of a finger to total force. The other task – Share task – required cyclical changes in sharing while keeping total force unchanged. Each trial started under full visual feedback on both force and sharing; subsequently, feedback on the variable that was instructed to stay constant was frozen, and finally feedback on the other variable was also removed. In both tasks, turning off visual feedback on total force elicited a drop in the mid-point of the force cycle and an increase in the peak-to-peak force amplitude. Turning off visual feedback on sharing led to a drift of mean share toward 50:50 across both tasks. Without visual feedback there was consistent deviation of the two force time series from the in-phase pattern (typical of the Force task) and from the out-of-phase pattern (typical of the Share task). This finding is in contrast to most earlier studies that demonstrated only two stable patterns, in-phase and out-of-phase. We interpret the results as consequences of drifts of parameters in a dynamical system leading in particular to drifts in the referent finger coordinates toward their actual coordinates. The relative phase desynchronization is caused by the right–left differences in the hypothesized drift processes, consistent with the dynamic dominance hypothesis. [ABSTRACT FROM AUTHOR]

Published

2017

18. Movement Variability Is Processed Bilaterally by Inferior Parietal Lobule.

Author

Mehler, David Marc Anton and Reschechtko, Sasha

Subjects

*BODY movement, *PARIETAL lobe, *ANATOMY

Abstract

A review of the article "Individual movement variability magnitudes are explained by cortical neural variability" by S. Haar and colleagues, which appeared in the periodical "Journal of Neuroscience" in 2017, is presented.

Published

2018

19. Task-Specific Stability of Multifinger Steady-State Action.

Author

Reschechtko, Sasha, Zatsiorsky, Vladimir M., and Latash, Mark L.

Subjects

*ISOMETRIC exercise, *PERTURBATION theory, *STANDARD deviations, *MOTOR ability, *FINGER physiology

Abstract

The authors explored task-specific stability during accurate multifinger force production tasks with different numbers of instructed fingers. Subjects performed steady-state isometric force production tasks and were instructed not to interfere voluntarily with transient lifting-and-lowering perturbations applied to the index finger. The main results were (a) intertrial variance in the space of finger modes at steady states was larger within the subspace that had no effect on the total force (the uncontrolled manifold [UCM]); (b) perturbations caused large deviations of finger modes within the UCM (motor equivalence); and (c) deviations caused by the perturbation showed larger variance within the UCM. No significant effects of the number of task fingers were noted in any of the 3 indicators. The results are discussed within the frameworks of the UCM and referent configuration hypotheses. The authors conclude, in particular, that all the tasks were effectively 4-finger tasks with different involvement of task and nontask fingers. [ABSTRACT FROM AUTHOR]

Published

2015

20. Stability of multifinger action in different state spaces.

Author

Reschechtko, Sasha, Zatsiorsky, Vladimir M., and Latash, Mark L.

Subjects

*PERTURBATION theory, *TASK performance, *COMPARATIVE studies, *NEUROPHYSIOLOGY, *NEUROSCIENCES

Abstract

We investigated stability of action by a multifinger system with three methods: analysis of intertrial variance, application of transient perturbations, and analysis of the system's motion in different state spaces. The "inverse piano" device was used to apply transient (lifting-andlowering) perturbations to individual fingers during single- and two- finger accurate force production tasks. In each trial, the perturbation was applied either to a finger explicitly involved in the task or one that was not. We hypothesized that, in one-finger tasks, task-specific stability would be observed in the redundant space of finger forces but not in the nonredundant space of finger modes (commands to explicitly involved fingers). In two-finger tasks, we expected that perturbations applied to a nontask finger would not contribute to task-specific stability in mode space. In contrast to our expectations, analyses in both force and mode spaces showed lower stability in directions that did not change total force output compared with directions that did cause changes in total force. In addition, the transient perturbations led to a significant increase in the enslaving index. We consider these results within a theoretical scheme of control with referent body configurations organized hierarchically, using multiple few-to-many mappings organized in a synergic way. The observed volatility of enslaving, greater equifinality of total force compared with elemental variables, and large magnitude of motor equivalent motion in both force and mode spaces provide support for the concept of task-specific stability of performance and the existence of multiple neural loops, which ensure this stability. [ABSTRACT FROM AUTHOR]

Published

2014

21. Stretch reflexes.

Author

Reschechtko S and Pruszynski JA

Subjects

Humans, Motor Activity physiology, Muscle, Skeletal physiology, Reaction Time physiology, Reflex, Stretch physiology, Tendons physiology

Abstract

Many of us know about stretch reflexes from the doctor's office, when a physician taps the tendon near our kneecap to elicit a quick knee extension. This procedure is used as a diagnostic tool to determine the integrity of the spinal cord and the extension response it elicits may seem otherwise useless. In fact, the tendon tap taps into one aspect of a critical building block of mammalian motor control, the stretch reflexes. Stretch reflexes are often thought to quickly resist unexpected changes in muscle length via a very simple circuit in the spinal cord, and this is one circuit that the tendon tap engages. It turns out, however, that stretch reflexes support a myriad of functions and are highly flexible. Under naturalistic conditions, stretch reflexes are shaped by peripheral physiology and engage neural circuits spanning the spinal cord, brainstem and cerebral cortex. In this Primer, we outline what is currently known about stretch reflex function and its underlying mechanisms, with a specific focus on how the cascade of nested responses collectively known as stretch reflexes interact with and build off of one another to support real-world motor behavior., (Copyright © 2020 Elsevier Inc. All rights reserved.)

Published

2020

22. Stability of hand force production. I. Hand level control variables and multifinger synergies.

Author

Reschechtko S and Latash ML

Subjects

Adult, Female, Humans, Male, Visual Perception, Feedback, Sensory, Fingers physiology, Movement, Psychomotor Performance

Abstract

We combined the theory of neural control of movement with referent coordinates and the uncontrolled manifold hypothesis to explore synergies stabilizing the hand action in accurate four-finger pressing tasks. In particular, we tested a hypothesis on two classes of synergies, those among the four fingers and those within a pair of control variables, stabilizing hand action under visual feedback and disappearing without visual feedback. Subjects performed four-finger total force and moment production tasks under visual feedback; the feedback was later partially or completely removed. The "inverse piano" device was used to lift and lower the fingers smoothly at the beginning and at the end of each trial. These data were used to compute pairs of hypothetical control variables. Intertrial analysis of variance within the finger force space was used to quantify multifinger synergies stabilizing both force and moment. A data permutation method was used to quantify synergies among control variables. Under visual feedback, synergies in the spaces of finger forces and hypothetical control variables were found to stabilize total force. Without visual feedback, the subjects showed a force drift to lower magnitudes and a moment drift toward pronation. This was accompanied by disappearance of the four-finger synergies and strong attenuation of the control variable synergies. The indexes of the two types of synergies correlated with each other. The findings are interpreted within the scheme with multiple levels of abundant variables. NEW & NOTEWORTHY We extended the idea of hierarchical control with referent spatial coordinates for the effectors and explored two types of synergies stabilizing multifinger force production tasks. We observed synergies among finger forces and synergies between hypothetical control variables that stabilized performance under visual feedback but failed to stabilize it after visual feedback had been removed. Indexes of two types of synergies correlated with each other. The data suggest the existence of multiple mechanisms stabilizing motor actions., (Copyright © 2017 the American Physiological Society.)

Published

2017