Your search keyword '"StartReact"' showing total 112 results

1. Age‐related changes in reticulospinal contributions to anticipatory postural adjustments between back extensors and abdominal muscles

Author

Shin‐Yi Chiou, Catherine Unwin, and Alice Lilley

Subjects

ageing, descending pathways, postural control, StartReact, subcortical structures, trunk, Physiology, QP1-981

Abstract

Abstract Anticipatory postural adjustments (APAs) give feedforward postural control of the trunk, but they are delayed with ageing, affecting balance and mobility in older individuals. The reticulospinal tract contributes to postural control of the trunk; however, the extent to which age‐related changes affect the reticulospinal contributions to APAs of the trunk remains unknown in humans. Here, we tested the hypothesis that a startling acoustic sound, which activates the reticulospinal tract, improves delayed APAs in older individuals. Twenty‐two old (75 ± 6 years) and 20 healthy young adults (21 ± 4 years) performed a self‐initiated fast bilateral shoulder flexion or shoulder extension task in response to visual, visual and auditory (80 dB), or visual and startling (115 dB) cues. Electromyography (EMG) was recorded from bilateral anterior deltoid (AD) and erector spinae (ES) during shoulder flexion and from bilateral posterior deltoid (PD) and rectus abdominis (RA) during shoulder extension. EMG onset of all muscles shortened during the startling cue in both age groups, suggesting a non‐specific modulation of the reticulospinal tract on prime movers (AD or PD) and non‐prime movers (ES or RA). Interestingly, APAs of the ES were accelerated in older participants to a similar degree as in younger participants during the startling cue. Conversely, APAs of the RA were not influenced by the startling cue in older participants. Our results suggest differential effects of ageing on functional contributions of the reticulospinal tract to APAs between back extensors and abdominal muscles.

Published

2024

2. Age‐related changes in reticulospinal contributions to anticipatory postural adjustments between back extensors and abdominal muscles.

Author

Chiou, Shin‐Yi, Unwin, Catherine, and Lilley, Alice

Subjects

*EXTENSOR muscles, *ABDOMINAL muscles, *OLDER people, *EXPECTATION (Psychology), *RECTUS abdominis muscles

Abstract

Anticipatory postural adjustments (APAs) give feedforward postural control of the trunk, but they are delayed with ageing, affecting balance and mobility in older individuals. The reticulospinal tract contributes to postural control of the trunk; however, the extent to which age‐related changes affect the reticulospinal contributions to APAs of the trunk remains unknown in humans. Here, we tested the hypothesis that a startling acoustic sound, which activates the reticulospinal tract, improves delayed APAs in older individuals. Twenty‐two old (75 ± 6 years) and 20 healthy young adults (21 ± 4 years) performed a self‐initiated fast bilateral shoulder flexion or shoulder extension task in response to visual, visual and auditory (80 dB), or visual and startling (115 dB) cues. Electromyography (EMG) was recorded from bilateral anterior deltoid (AD) and erector spinae (ES) during shoulder flexion and from bilateral posterior deltoid (PD) and rectus abdominis (RA) during shoulder extension. EMG onset of all muscles shortened during the startling cue in both age groups, suggesting a non‐specific modulation of the reticulospinal tract on prime movers (AD or PD) and non‐prime movers (ES or RA). Interestingly, APAs of the ES were accelerated in older participants to a similar degree as in younger participants during the startling cue. Conversely, APAs of the RA were not influenced by the startling cue in older participants. Our results suggest differential effects of ageing on functional contributions of the reticulospinal tract to APAs between back extensors and abdominal muscles. What is the central question of this study?Does the reticulospinal tract contribute to anticipatory postural adjustments (APAs) of trunk muscles, and what is the effect of ageing on the reticulospinal contributions to the APAs of the trunk?What is the main finding and its importance?Startling stimuli shortened APAs of the trunk extensors during shoulder flexion, but not the trunk flexors during shoulder extension, in older participants. However, quiet acoustic stimuli did not affect APA control of the trunk muscles. Our results suggest an increase in the reticulospinal input to the trunk extensors for anticipatory postural control with ageing. [ABSTRACT FROM AUTHOR]

Published

2024

3. Startling Acoustic Stimulation Has Task-Specific Effects on Intracortical Facilitation and Inhibition at Rest and During Visually Guided Isometric Elbow Flexion in Healthy Individuals.

Author

Yen-Ting Chen, Shengai Li, Yingchun Zhang, Ping Zhou, Sheng Li, Chen, Yen-Ting, Li, Shengai, Zhang, Yingchun, Zhou, Ping, and Li, Sheng

Subjects

ACOUSTIC stimulation, STARTLE reaction, MUSCLE contraction, TRANSCRANIAL magnetic stimulation, MOTOR cortex, ELBOW, EVOKED potentials (Electrophysiology)

Abstract

Startling acoustic stimulation (SAS) causes a transient effect on the primary motor cortex (M1) nonreflexively. It reduces the cortical excitability at rest, but not during voluntary contraction. However, the effect of SAS on intracortical activity is not clear. The purpose of this study was to investigate the SAS effect on short-interval intracortical inhibition and intracortical facilitation using transcranial magnetic stimulation (TMS). Eleven healthy individuals performed isometric elbow flexion at 10% of maximum voluntary contraction on the dominant side with a real-time visual target (i.e., M1 preactivation) or at rest. TMS was delivered to the M1 ipsilateral to elbow flexion without or with SAS delivered 90 ms prior to TMS. There were three TMS delivery conditions: (a) single pulse, (b) short-interval intracortical inhibition, and (c) intracortical facilitation. TMS-induced motor-evoked potential (MEP) was compared between predetermined TMS and SAS conditions at rest and during ipsilateral voluntary contraction. We confirmed that SAS decreased the MEP amplitude at rest, but not during M1 preactivation. SAS caused task-specific effects on intracortical excitability. Specifically, SAS increased intracortical facilitation at rest and during voluntary contraction. However, SAS decreased short-interval intracortical inhibition only during M1 preactivation. Collectively, our results suggest that SAS transiently influences the motor cortex excitability, possibly via its activation of higher centers, to achieve a visually guided goal-directed task. [ABSTRACT FROM AUTHOR]

Published

2023

4. Evidence for reticulospinal plasticity underlying motor recovery in Brown-Séquard-plus Syndrome: a case report.

Author

Eilfort, Antonia Maria, Rasenack, Maria, Zörner, Björn, Curt, Armin, and Filli, Linard

Subjects

TRANSCRANIAL magnetic stimulation, FLEXOR muscles, EVOKED potentials (Electrophysiology), BICEPS brachii, NEUROLOGICAL disorders

Abstract

Brown-Séquard Syndrome (BSS) is a rare neurological condition caused by a unilateral spinal cord injury (SCI). Upon initial ipsilesional hemiplegia, patients with BSS typically show substantial functional recovery over time. Preclinical studies on experimental BSS demonstrated that spontaneous neuroplasticity in descending motor systems is a key mechanism promoting functional recovery. The reticulospinal (RS) system is one of the main descending motor systems showing a remarkably high ability for neuroplastic adaptations after incomplete SCI. In humans, little is known about the contribution of RS plasticity to functional restoration after SCI. Here, we investigated RS motor drive to different muscles in a subject with Brown-Séquard-plus Syndrome (BSPS) five months post-injury using the StartReact paradigm. RS drive was compared between ipsi-and contralesional muscles, and associated with measures of functional recovery. Additionally, corticospinal (CS) drive was investigated using transcranial magnetic stimulation (TMS) in a subset of muscles. The biceps brachii showed a substantial enhancement of RS drive on the ipsi- vs. contralesional side, whereas no signs of CS plasticity were found ipsilesionally. This finding implies that motor recovery of ipsilesional elbow flexion is primarily driven by the RS system. Results were inversed for the ipsilesional tibialis anterior, where RS drive was not augmented, but motor-evoked potentials recovered over six months post-injury, suggesting that CS plasticity contributed to improvements in ankle dorsiflexion. Our findings indicate that the role of RS and CS plasticity in motor recovery differs between muscles, with CS plasticity being essential for the restoration of distal extremity motor function, and RS plasticity being important for the functional recovery of proximal flexor muscles after SCI in humans. [ABSTRACT FROM AUTHOR]

Published

2024

5. Evidence for reticulospinal plasticity underlying motor recovery in Brown-Séquard-plus Syndrome: a case report

Author

Antonia Maria Eilfort, Maria Rasenack, Björn Zörner, Armin Curt, and Linard Filli

Subjects

Brown-Séquard Syndrome, spinal cord injury, reticulospinal tract, corticospinal tract, StartReact, motor recovery, Neurology. Diseases of the nervous system, RC346-429

Abstract

Brown-Séquard Syndrome (BSS) is a rare neurological condition caused by a unilateral spinal cord injury (SCI). Upon initial ipsilesional hemiplegia, patients with BSS typically show substantial functional recovery over time. Preclinical studies on experimental BSS demonstrated that spontaneous neuroplasticity in descending motor systems is a key mechanism promoting functional recovery. The reticulospinal (RS) system is one of the main descending motor systems showing a remarkably high ability for neuroplastic adaptations after incomplete SCI. In humans, little is known about the contribution of RS plasticity to functional restoration after SCI. Here, we investigated RS motor drive to different muscles in a subject with Brown-Séquard-plus Syndrome (BSPS) five months post-injury using the StartReact paradigm. RS drive was compared between ipsi- and contralesional muscles, and associated with measures of functional recovery. Additionally, corticospinal (CS) drive was investigated using transcranial magnetic stimulation (TMS) in a subset of muscles. The biceps brachii showed a substantial enhancement of RS drive on the ipsi- vs. contralesional side, whereas no signs of CS plasticity were found ipsilesionally. This finding implies that motor recovery of ipsilesional elbow flexion is primarily driven by the RS system. Results were inversed for the ipsilesional tibialis anterior, where RS drive was not augmented, but motor-evoked potentials recovered over six months post-injury, suggesting that CS plasticity contributed to improvements in ankle dorsiflexion. Our findings indicate that the role of RS and CS plasticity in motor recovery differs between muscles, with CS plasticity being essential for the restoration of distal extremity motor function, and RS plasticity being important for the functional recovery of proximal flexor muscles after SCI in humans.

Published

2024

6. Startling stimuli increase maximal motor unit discharge rate and rate of force development in humans.

Author

Škarabot, Jakob, Folland, Jonathan P., Holobar, Aleš, Baker, Stuart N., and Del Vecchio, Alessandro

Subjects

*MOTOR unit, *RETICULAR formation, *VASTUS medialis, *VASTUS lateralis, *STARTLE reaction, *MOTOR neurons

Abstract

Maximal rate of force development in adult humans is determined by the maximal motor unit discharge rate, however, the origin of the underlying synaptic inputs remains unclear. Here, we tested a hypothesis that the maximal motor unit discharge rate will increase in response to a startling cue, a stimulus that purportedly activates the pontomedullary reticular formation neurons that make mono- and disynaptic connections to motoneurons via fast-conducting axons. Twenty-two men were required to produce isometric knee extensor forces "as fast and as hard" as possible from rest to 75% of maximal voluntary force, in response to visual (VC), visual-auditory (VAC; 80 dB), or visual-startling cue (VSC; 110 dB). Motoneuron activity was estimated via decomposition of high-density surface electromyogram recordings over the vastus lateralis and medialis muscles. Reaction time was significantly shorter in response to VSC compared with VAC and VC. The VSC further elicited faster neuromechanical responses including a greater number of discharges per motor unit per second and greater maximal rate of force development, with no differences between VAC and VC. We provide evidence, for the first time, that the synaptic input to motoneurons increases in response to a startling cue, suggesting a contribution of subcortical pathways to maximal motoneuron output in humans. [ABSTRACT FROM AUTHOR]

Published

2022

7. Does the reticulospinal tract mediate adaptation to resistance training in humans?

Author

Atkinson, Elliott, Škarabot, Jakob, Ansdell, Paul, Goodall, Stuart, Howatson, Glyn, and Thomas, Kevin

Subjects

RESISTANCE training, MUSCLE strength, NEUROPLASTICITY, CENTRAL nervous system, PYRAMIDAL tract

Abstract

Resistance training increases volitional force-producing capacity, and it is widely accepted that such an increase is partly underpinned by adaptations in the central nervous system, particularly in the early phases of training. Despite this, the neural substrate(s) responsible for mediating adaptation remains largely unknown. Most studies have focused on the corticospinal tract, the main descending pathway controlling movement in humans, with equivocal findings. It is possible that neural adaptation to resistance training is mediated by other structures; one such candidate is the reticulospinal tract. The aim of this narrative mini-review is to articulate the potential of the reticulospinal tract to underpin adaptations in muscle strength. Specifically, we 1) discuss why the structure and function of the reticulospinal tract implicate it as a potential site for adaptation; 2) review the animal and human literature that supports the idea of the reticulospinal tract as an important neural substrate underpinning adaptation to resistance training; and 3) examine the potential methodological options to assess the reticulospinal tract in humans. [ABSTRACT FROM AUTHOR]

Published

2022

8. Influence of task complexity on movement planning and release after stroke: insights from startReact.

Author

Lee, Hyunglae, Honeycutt, Claire, and Perreault, Eric

Subjects

*STANDING position, *STROKE patients, *FORELIMB, *TASKS, *CAPACITY requirements planning

Abstract

The capacity to plan movement following stroke is diminished when reaching from a standing position. Two mechanisms have been proposed: increased task complexity compared to simpler tasks and inhibition between the pathways controlling whole-body posture and upper extremity reaching. The objective of this study was to determine if task complexity alone can alter planning and release (or involuntary execution) capacity when whole-body postural adjustment is not required. Data were collected from 10 stroke survivors and 8 age-matched controls. Ballistic elbow extension movements were performed with and without voluntary shoulder abduction, adding complexity by anti-gravity arm support that enhanced the expression of abnormal muscle synergies linking elbow and shoulder after stroke. Our primary finding was in support of our hypothesis that startReact (involuntary release of planned movement by a startling stimulus) would be intact but that the increased task complexity would decrease the capacity to plan and release movement. StartReact was intact for both tasks with and without shoulder abduction. Despite the intact startReact response across both conditions following stroke, the incidence of startReact was decreased during the shoulder abduction task similar to prior studies showing a decrease during tasks of higher complexity. Our results suggest that individuals with stroke have a diminished capacity to plan and release movement as task complexity increases. This study highlights the unique potential for startReact to be used as a clinical tool to probe the capacity to plan and release movement following stroke and how that capacity is affected by the complexity of the task being performed. Such a tool may be useful for assessing functional impairments and tracking changes during the rehabilitation process. [ABSTRACT FROM AUTHOR]

Published

2022

9. A systematic review with meta-analysis of the StartReact effect on motor responses in stroke survivors and healthy individuals.

Author

DeLuca, Mara, Low, Daniel, Kumari, Veena, Parton, Andrew, Davis, Jessica, and Mohagheghi, Amir A.

Subjects

*STROKE patients, *SPINAL cord, *STARTLE reaction, *CEREBRAL cortex, *STROKE rehabilitation

Abstract

Control of limb movements may be impaired after stroke due to the loss of connectivity between the cerebral cortex and spinal cord. A notion to improve motor function in stroke survivors is to use alternate motor fibers, such as the reticulospinal tract (RST), which originate from the brainstem and terminate at different levels of spinal cord. One way of targeting the RST is to use a "StartReact" protocol to foster premature release of a preplanned movement in response to a startling stimulus. Our aim was to find support for the preservation of such StartReact effect in stroke survivors. We conducted a systematic review with meta-analysis of literature published in English up to September 2020, to explore differences in motor responses to startling stimuli in StartReact effects. Protocol of the study was registered (PROSPERO Registration No. CRD42020191581). PubMed, Google Scholar, Web of Science, PsycINFO, and Science Direct were searched for relevant literature. The meta-analysis contained six studies involving a total of 151 stroke and healthy participants. Muscle onset latency data were extracted from the qualifying studies and compared using RevMan. StartReact effect was present in both stroke and healthy groups, represented by short- ened muscle onset latency when startling stimulus was present. There was considerable heterogeneity of the outcome meas- ures, which was attributed to the range of motor impairments among stroke survivors and methodologies used. Our findings support the notion of preservation of preprogramming ability and suitability of RST and StartReact effect for motor rehabilitation following stroke. [ABSTRACT FROM AUTHOR]

Published

2022

10. Engagement of the contralateral limb can enhance the facilitation of motor output by loud acoustic stimuli.

Author

McInnes, Aaron N., Nguyen, An T., Carroll, Timothy J., Lipp, Ottmar V., and Marinovic, Welber

Subjects

*RECOVERY movement, *MUSCLE contraction, *STROKE rehabilitation, *EXTENSOR muscles, *NEUROLOGICAL disorders, *ACOUSTIC stimulation

Abstract

When intense sound is presented during light muscle contraction, inhibition of the corticomotoneuronal pathway is observed. During action preparation, this effect is reversed, with sound resulting in excitation of the corticomotoneuronal pathway. We investigated how the combined maintenance of a muscle contraction during preparation for a ballistic action impacts the magnitude of the facilitation of motor output by a loud acoustic stimulus (LAS), a phenomenon known as the StartReact effect. Participants executed ballistic wrist flexion movements and a LAS was presented simultaneously with the imperative signal in a subset of trials. We examined whether the force level or muscle used to maintain a contraction during preparation for the ballistic response impacted reaction time and/or the force of movements triggered by the LAS. These contractions were sustained either ipsilaterally or contralaterally to the ballistic response. The magnitude of facilitation by the LAS was greatest when low-force flexion contractions were maintained in the limb contralateral to the ballistic response during preparation. There was little change in facilitation when contractions recruited the contralateral extensor muscle or when they were sustained in the same limb that executed the ballistic response. We conclude that a larger network of neurons that may be engaged by a contralateral sustained contraction prior to initiation may be recruited by the LAS, further contributing to the motor output of the response. These findings may be particularly applicable in stroke rehabilitation, where engagement of the contralesional side may increase the benefits of a LAS to the functional recovery of movement. NEW & NOTEWORTHY The facilitation of reaction time, force, and vigor of a ballistic action by loud acoustic stimuli can be enhanced by the maintenance of a sustained contraction during preparation. This enhanced facilitation is observed when the sustained contraction is maintained with low force contralaterally and congruently with the ballistic response. This increased facilitation may be particularly applicable to rehabilitative applications of loud acoustic stimuli in improving the functional recovery of movement after neurological conditions such as stroke. [ABSTRACT FROM AUTHOR]

Published

2022

11. Effects of transcranial direct current stimulation (tDCS) on posture, movement planning, and execution during standing voluntary reach following stroke

Author

Chieh-ling Yang, Alon Gad, Robert A. Creath, Laurence Magder, Mark W. Rogers, and Sandy McCombe Waller

Subjects

Transcranial direct current stimulation, startReact, Motor preparation, Postural control, Reach, Stroke, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Abstract Background Impaired movement preparation of both anticipatory postural adjustments and goal directed movement as shown by a marked reduction in the incidence of StartReact responses during a standing reaching task was reported in individuals with stroke. We tested how transcranial direct current stimulation (tDCS) applied over the region of premotor areas (PMAs) and primary motor area (M1) affect movement planning and preparation of a standing reaching task in individuals with stroke. Methods Each subject performed two sessions of tDCS over the lesioned hemisphere on two different days: cathodal tDCS over PMAs and anodal tDCS over M1. Movement planning and preparation of anticipatory postural adjustment-reach sequence was examined by startReact responses elicited by a loud acoustic stimulus of 123 dB. Kinetic, kinematic, and electromyography data were recorded to characterize anticipatory postural adjustment-reach movement response. Results Anodal tDCS over M1 led to significant increase of startReact responses incidence at loud acoustic stimulus time point − 500 ms. Increased trunk involvement during movement execution was found after anodal M1 stimulation compared to PMAs stimulation. Conclusions The findings provide novel evidence that impairments in movement planning and preparation as measured by startReact responses for a standing reaching task can be mitigated in individuals with stroke by the application of anodal tDCS over lesioned M1 but not cathodal tDCS over PMAs. This is the first study to show that stroke-related deficits in movement planning and preparation can be improved by application of anodal tDCS over lesioned M1. Trial registration ClinicalTrial.gov, NCT04308629, Registered 16 March 2020—Retrospectively registered, https://www.clinicaltrials.gov/ct2/show/NCT04308629

Published

2021

12. Premovement inhibition can protect motor actions from interference by response‐irrelevant sensory stimulation.

Author

McInnes, Aaron N., Lipp, Ottmar V., Tresilian, James R., Vallence, Ann‐Maree, and Marinovic, Welber

Subjects

*PYRAMIDAL tract, *SENSORY stimulation, *ACOUSTIC stimulation, *TRANSCRANIAL magnetic stimulation

Abstract

Key points: Suppression of corticospinal excitability is reliably observed during preparation for a range of motor actions, leading to the belief that this preparatory inhibition is a physiologically obligatory component of motor preparation. The neurophysiological function of this suppression is uncertain.We restricted the time available for participants to engage in preparation and found no evidence for preparatory inhibition.The function of preparatory inhibition can be inferred from our findings that sensory stimulation can disrupt motor output in the absence of preparatory inhibition, but enhance motor output when inhibition is present.These findings suggest preparatory inhibition may be a strategic process which acts to protect prepared actions from external interference.Our findings have significant theoretical implications for preparatory processes. Findings may also have a pragmatic benefit in that acoustic stimulation could be used therapeutically to facilitate movement, but only if the action can be prepared well in advance. Shortly before movement initiation, the corticospinal system undergoes a transient suppression. This phenomenon has been observed across a range of motor tasks, suggesting that it may be an obligatory component of movement preparation. We probed whether this was also the case when the urgency to perform a motor action was high, in a situation where little time was available to engage in preparatory processes. We controlled the urgency of an impending motor action by increasing or decreasing the foreperiod duration in an anticipatory timing task. Transcranial magnetic stimulation (TMS; experiment 1) or a loud acoustic stimulus (LAS; experiment 2) were used to examine how corticospinal and subcortical excitability were modulated during motor preparation. Preparatory inhibition of the corticospinal tract was absent when movement urgency was high, though motor actions were initiated on time. In contrast, subcortical circuits were progressively inhibited as the time to prepare increased. Interestingly, movement force and vigour were reduced by both TMS and the LAS when movement urgency was high, and enhanced when movement urgency was low. These findings indicate that preparatory inhibition may not be an obligatory component of motor preparation. The behavioural effects we observed in the absence of preparatory inhibition were induced by both TMS and the LAS, suggesting that accessory sensory stimulation may disrupt motor output when such stimulation is presented in the absence of preparatory inhibition. We conclude that preparatory inhibition may be an adaptive strategy which can serve to protect the prepared motor action from external interference. Key points: Suppression of corticospinal excitability is reliably observed during preparation for a range of motor actions, leading to the belief that this preparatory inhibition is a physiologically obligatory component of motor preparation. The neurophysiological function of this suppression is uncertain.We restricted the time available for participants to engage in preparation and found no evidence for preparatory inhibition.The function of preparatory inhibition can be inferred from our findings that sensory stimulation can disrupt motor output in the absence of preparatory inhibition, but enhance motor output when inhibition is present.These findings suggest preparatory inhibition may be a strategic process which acts to protect prepared actions from external interference.Our findings have significant theoretical implications for preparatory processes. Findings may also have a pragmatic benefit in that acoustic stimulation could be used therapeutically to facilitate movement, but only if the action can be prepared well in advance. [ABSTRACT FROM AUTHOR]

Published

2021

13. Effects of transcranial direct current stimulation (tDCS) on posture, movement planning, and execution during standing voluntary reach following stroke.

Author

Yang, Chieh-ling, Gad, Alon, Creath, Robert A., Magder, Laurence, Rogers, Mark W., and Waller, Sandy McCombe

Subjects

*POSTURE, *TRANSCRANIAL direct current stimulation, *GOAL (Psychology), *STROKE

Abstract

Background: Impaired movement preparation of both anticipatory postural adjustments and goal directed movement as shown by a marked reduction in the incidence of StartReact responses during a standing reaching task was reported in individuals with stroke. We tested how transcranial direct current stimulation (tDCS) applied over the region of premotor areas (PMAs) and primary motor area (M1) affect movement planning and preparation of a standing reaching task in individuals with stroke.Methods: Each subject performed two sessions of tDCS over the lesioned hemisphere on two different days: cathodal tDCS over PMAs and anodal tDCS over M1. Movement planning and preparation of anticipatory postural adjustment-reach sequence was examined by startReact responses elicited by a loud acoustic stimulus of 123 dB. Kinetic, kinematic, and electromyography data were recorded to characterize anticipatory postural adjustment-reach movement response.Results: Anodal tDCS over M1 led to significant increase of startReact responses incidence at loud acoustic stimulus time point - 500 ms. Increased trunk involvement during movement execution was found after anodal M1 stimulation compared to PMAs stimulation.Conclusions: The findings provide novel evidence that impairments in movement planning and preparation as measured by startReact responses for a standing reaching task can be mitigated in individuals with stroke by the application of anodal tDCS over lesioned M1 but not cathodal tDCS over PMAs. This is the first study to show that stroke-related deficits in movement planning and preparation can be improved by application of anodal tDCS over lesioned M1. Trial registration ClinicalTrial.gov, NCT04308629, Registered 16 March 2020-Retrospectively registered, https://www.clinicaltrials.gov/ct2/show/NCT04308629. [ABSTRACT FROM AUTHOR]

Published

2021

14. Temporal binding and agency under startle.

Author

Scott, Mark and Chiu, Chenhao

Abstract

Forward models are a component of the motor system that predicts the sensory consequences of our actions. These models play several key roles in motor control and are hypothesized to underlie (among other things) the two phenomena under investigation in this experiment: The feeling of agency that we have over self-initiated actions (as opposed to reflexes), and "temporal binding", in which self-caused sensations are judged to have occurred earlier in time than they actually did. This experiment probes the connection between forward models and both of these phenomena using the "Startle" paradigm. In the Startle paradigm, a startlingly loud sound causes people to initiate a prepared action at a very short latency. It is hypothesized that the latency of a startle-initiated action is so short that normal cortical operations (including forward models) are circumvented. This experiment replicates the temporal-binding effect and simultaneously measures participants' sense of agency over their actions. The results show that both the temporal-binding effect and the sense of agency we have over our own actions is disrupted under the startle paradigm in line with the theory that these phenomena both rely on forward models. Furthermore, this experiment provides evidence in support of the claim that a startle-induced action is qualitatively different from other actions. [ABSTRACT FROM AUTHOR]

Published

2021

15. Experts, but not novices, exhibit StartReact indicating experts use the reticulospinal system more than novices.

Author

Bartels, Brandon M., Quezada, Maria Jose, Ravichandran, Vengateswaran J., and Honeycutt, Claire F.

Subjects

*RETICULAR formation, *MOTOR ability, *SPECIALISTS, *MOTOR learning

Abstract

Motor skill acquisition utilizes a wide array of neural structures; however, few articles evaluate how the relative contributions of these structures shift over the course of learning. Recent evidence from rodents and songbirds suggests there is a transfer from cortical to subcortical structures following intense, repetitive training. Evidence from humans indicate that the reticulospinal system is modulated over the course of skill acquisition and may be a subcortical facilitator of learning. The objective of this study was to evaluate how reticulospinal contributions are modulated by task expertise. Reticulospinal contributions were assessed using StartReact (SR). We hypothesized that expert typists would show SR during an individuated, keystroke task but SR would be absent in novices. Expert (75.2 ± 9.8 WPM) and novice typists (41.6 ± 8.2 WPM) were evaluated during an individuated, keystroke movements. In experts, SR was present but was absent in novices. Together, these results suggest that experts use reticulospinal contributions more for movement than novices indicating that the reticular formation becomes increasingly important for movement execution in highly trained, skilled tasks even those that require individuated movement of the fingers. [ABSTRACT FROM AUTHOR]

Published

2021

16. Understanding the dual-task costs of walking: a StartReact study.

Author

Nonnekes, Jorik, Dibilio, Valeria, Barthel, Claudia, Solis-Escalante, Teodoro, Bloem, Bastiaan R., and Weerdesteyn, Vivian

Subjects

*COMPETITION (Biology), *STARTLE reaction, *TASK performance, *COST

Abstract

The need to perform multiple tasks more or less simultaneously is a common occurrence during walking in daily life. Performing tasks simultaneously typically impacts task performance negatively. Hypothetically, such dual-task costs may be explained by a lowered state of preparation due to competition for attentional resources, or alternatively, by a 'bottleneck' in response initiation. Here, we investigated both hypotheses by comparing 'StartReact' effects during a manual squeezing task under single-task (when seated) and dual-task (when walking) conditions. StartReact is the acceleration of reaction times by a startling stimulation (a startling acoustic stimulus was applied in 25% of trials), attributed to the startling stimulus directly releasing a pre-prepared movement. If dual-task costs are due to a lowered state of preparation, we expected trials both with and without an accompanying startling stimulus to be delayed compared to the single-task condition, whereas we expected only trials without a startling stimulus to be delayed if a bottleneck in response initiation would underlie dual-task costs. Reaction times of the manual squeezing task in the flexor digitorum superficialis and extensor carpi radialis muscle were significantly delayed (approx. 20 ms) when walking compared to the seated position. A startling acoustic stimulus significantly decreased reaction times of the squeezing task (approx. 60 ms) both when walking and sitting. Dual-task costs during walking are, therefore, likely the result of lowered task preparation because of competition for attentional resources. [ABSTRACT FROM AUTHOR]

Published

2020

17. StartReact increases the probability of muscle activity and distance in severe/moderate stroke survivors during two-dimensional reaching task.

Author

Rahimi, Marziye and Honeycutt, Claire F.

Subjects

*MUSCLES, *STROKE, *PROBABILITY theory, *DISTANCES, *TASKS

Abstract

StartReact elicits faster, larger, and more appropriate muscle activation in stroke survivors but has been only cursorily studied to date during multi-jointed reaching. Our objective was to evaluate StartReact on unrestricted, two-dimensional point-to-point reaching tasks post-stroke. Data from 23 individuals with stroke were collected during point-to-point reaching. Voluntary and StartReact trials were compared between mild, severe/moderate, and the unimpaired arm. StartReact showed an increase in probability of muscle activity, larger muscle activity amplitude, and faster muscle activity onset. Despite changes in muscle activity, metrics of movement (distance, final error, linear deviation) were not different between StartReact and Voluntary trials except in severe/moderate stroke who had larger reaching distances during StartReact. While StartReact impacted many metrics of muscle activity, the most profound effect was on the probability of muscle activity increasing 34% compared to voluntary which allowed severe/moderate subjects to increase reaching distance but did not translate to decrease in final error suggesting that the additional movement was not always directed towards the appropriate target. These results indicate that SR has the capacity to activate paralyzed muscle in severe/moderate patients, but future studies are needed to explore the possible use of SR in the rehabilitation. [ABSTRACT FROM AUTHOR]

Published

2020

18. Impaired posture, movement preparation, and execution during both paretic and nonparetic reaching following stroke.

Author

Chieh-ling Yang, Creath, Robert A., Magder, Laurence, Rogers, Mark W., and Waller, Sandy McCombe

Abstract

Posture and movement planning, preparation, and execution of a goal-directed reaching movement are impaired in individuals with stroke. No studies have shown whether the deficits are generally impaired or are specific to the lesioned hemisphere/paretic arm. This study utilized StartReact (SR) responses elicited by loud acoustic stimuli (LAS) to investigate the preparation and execution of anticipatory postural adjustments (APAs) and reach movement response during both paretic and nonparetic arm reaching in individuals with stroke and in age-matched healthy controls. Subjects were asked to get ready after receiving a warning cue and to reach at a "go" cue. An LAS was delivered at -500, -200, and 0 ms relative to the go cue. Kinetic, kinematic, and electromyographic data were recorded to characterize APA-reach movement responses. Individuals with stroke demonstrated systemwide deficits in posture and in movement planning, preparation, and execution of APA-reach sequence as shown by significant reduction in the incidence of SR response and impaired APA-reach performance, with greater deficits during paretic arm reaching. Use of trunk compensation strategy as characterized by greater involvement of trunk and pelvic rotation was utilized by individuals with stroke during paretic arm reaching compared with nonparetic arm reaching and healthy controls. Our findings have implications for upper extremity and postural control, suggesting that intervention should include training not only for the paretic arm but also for the nonparetic arm with simultaneous postural control requirements to improve the coordination of the APA-reach performance and subsequently reduce instability while functional tasks are performed during standing. NEW & NOTEWORTHY Our study is the first to show that nonparetic arm reaching also demonstrates impairment in posture and movement planning, preparation, and execution when performed during standing by individuals with stroke. In addition, we found compensatory trunk and pelvic rotations were used during a standing reach task for the paretic arms. The findings have clinical implications for upper extremity and postural rehabilitation, suggesting that training should include the nonparetic arms and incorporate simultaneous postural control demands. [ABSTRACT FROM AUTHOR]

Published

2019

19. A Timeline of Motor Preparatory State Prior to Response Initiation: Evidence from Startle.

Author

Smith, Victoria, Maslovat, Dana, Drummond, Neil M., and Carlsen, Anthony N.

Subjects

*RESPONSE inhibition, *WRIST

Abstract

Highlights • A startling acoustic stimulus (SAS) was used to probe motor preparatory state. • The SAS was presented during the 500-ms foreperiod of a simple reaction time (RT) task. • The number of responses elicited by the SAS plateaued 400 ms after the warning signal. • For a simple RT task with a short foreperiod, response preparation can take 300–400 ms. Abstract Response preparation in simple reaction time (RT) tasks has been modeled as an increase in neural activation to a sub-threshold level, which is maintained until the go-signal. However, the amount of time required for response preparation following a warning signal (WS) is currently unclear, as experiments typically employ long foreperiods to ensure maximal preparation. The purpose of the present experiments was to examine the time course of motor preparation in a simple RT task when given a limited amount of time to engage in preparatory processing. In Experiment 1, participants completed wrist extension movements in a simple RT paradigm with a short (500 ms) fixed foreperiod, and a long (8.5–10.5 s) inter-trial interval. To probe response preparation, a startling acoustic stimulus (SAS), which involuntarily triggers the release of sufficiently prepared responses, was randomly presented during the foreperiod at one of six equally spaced time points between 0 and 500 ms prior to the go-signal. Results showed that the long inter-trial interval was not always effective at preventing participants from engaging in preparatory processing between trials; thus, in Experiment 2 participants performed wrist flexion or extension movements in an instructed delay paradigm, where the required movement was cued by the WS. Results showed that the proportion of startle trials where the intended response was elicited by the SAS at short latency significantly increased until 100 ms prior to the go-signal, indicating response preparation can take up to 300–400 ms following the WS in a simple RT task with a short fixed foreperiod. [ABSTRACT FROM AUTHOR]

Published

2019

20. Startle evokes nearly identical movements in multi-jointed, two-dimensional reaching tasks.

Author

Ossanna, Meilin R., Zong, Xi, Ravichandran, Vengateswaran J., and Honeycutt, Claire F.

Subjects

*ELBOW, *SHOULDER, *STARTLE reaction, *DEGREES of freedom, *KINEMATICS

Abstract

StartReact is the ability of the startle reflex to involuntarily release a planned movement in the presence of a loud acoustic stimulus resulting in muscle activity patterns and kinematics that are tightly regulated and scaled with the intended action. Previous studies demonstrated startReact's robustness during simple single-joint reaching tasks and found no difference between startReact and voluntary movements for movement kinematics and muscle activation patterns. However, startReact has not been evaluated during multi-joint reaching movements with multiple degrees of freedom. It is unclear if startReact would evoke accurate and precise multi-joint reaching movements in an unrestricted workspace. Furthermore, if tested more rigorously, multi-joint startReact movement kinematics and muscle activation patterns might not be truly equivalent despite showing no difference through traditional ANOVAs. A previous study found multi-joint startReact was possible during unrestricted elbow and shoulder movement when reaching to a forward target. Therefore, we hypothesized that startReact would evoke similar multi-joint reaching movements for movement accuracy and muscle activation patterns when compared to voluntary movements in a multi-directional workspace. Expanding upon the previous study, our study uses a larger workspace and fully evaluates movement kinematics and muscle activations patterns. Results confirmed our hypothesis and found startReact movements were readily evoked in all directions. StartReact responses presented stereotypically earlier muscle activation, but the relative timing of agonist/antagonist firing pairs between startReact and voluntary movements remained similar. Results demonstrate that startReact is robustly present and equivalent in multi-joint reaching tasks and has potential clinical use for evaluating healthy and impaired movement. [ABSTRACT FROM AUTHOR]

Published

2019

21. Neurophysiological analysis of the clinical pull test.

Author

Joy Lynn Tan, Perera, Thushara, McGinley, Jennifer L., Yohanandan, Shivanthan Arthur Curtis, Brown, Peter, and Thevathasan, Wesley

Subjects

*POSTURE, *REFLEXES, *MEDICAL practice, *NEUROPHYSIOLOGY, *AUDITORY cortex, *STIMULUS & response (Psychology)

Abstract

Postural reflexes are impaired in conditions such as Parkinson's disease, leading to difficulty walking and falls. In clinical practice, postural responses are assessed using the "pull test," where an examiner tugs the prewarned standing patient backward at the shoulders and grades the response. However, validity of the pull test is debated, with issues including scaling and variability in administration and interpretation. It is unclear whether to assess the first trial or only subsequent repeated trials. The ecological relevance of a forewarned backward challenge is also debated. We therefore developed an instrumented version of the pull test to characterize responses and clarify how the test should be performed and interpreted. In 33 healthy participants, "pulls" were manually administered and pull force measured. Trunk and step responses were assessed with motion tracking. We probed for the StartReact phenomenon (where preprepared responses are released early by a startling stimulus) by delivering concurrent normal or "startling" auditory stimuli. We found that the first pull triggers a different response, including a larger step size suggesting more destabilization. This is consistent with "first trial effects," reported by platform translation studies, where movement execution appears confounded by startle reflex-like activity. Thus, first pull test trials have clinical relevance and should not be discarded as practice. Supportive of ecological relevance, responses to repeated pulls exhibited StartReact, as previously reported with a variety of other postural challenges, including those delivered with unexpected timing and direction. Examiner pull force significantly affected the postural response, particularly the size of stepping. [ABSTRACT FROM AUTHOR]

Published

2018

22. A startling acoustic stimulus facilitates voluntary lower extremity movements and automatic postural responses in people with chronic stroke.

Author

Coppens, Milou J. M., Roelofs, Jolanda M. B., Donkers, Nicole A. J., Nonnekes, Jorik, Geurts, Alexander C. H., and Weerdesteyn, Vivian

Subjects

*STROKE patients, *MOTOR ability, *DORSIFLEXION, *BIOMECHANICS, *ANKLE

Abstract

A startling acoustic stimulus (SAS) involuntary releases prepared movements at accelerated latencies, known as the StartReact effect. Previous work has demonstrated intact StartReact in paretic upper extremity movements in people after stroke, suggesting preserved motor preparation. The question remains whether motor preparation of lower extremity movements is also unaffected after stroke. Here, we investigated StartReact effects on ballistic lower extremity movements and on automatic postural responses (APRs) following perturbations to standing balance. These APRs are particularly interesting as they are critical to prevent a fall following balance perturbations, but show substantial delays and poor muscle coordination after stroke. Twelve chronic stroke patients and 12 healthy controls performed voluntary ankle dorsiflexion movements in response to a visual stimulus, and responded to backward balance perturbations evoking APRs. Twenty-five percent of all trials contained a SAS (120 dB) simultaneously with the visual stimulus or balance perturbation. As expected, in the absence of a SAS muscle and movement onset latencies at the paretic side were delayed compared to the non-paretic leg and to controls. The SAS accelerated ankle dorsiflexion onsets in both the legs of the stroke subjects and in controls. Following perturbations, the SAS accelerated bilateral APR onsets not only in controls, but for the first time, we also demonstrated this effect in people after stroke. Moreover, APR inter- and intra-limb muscle coordination was rather weak in our stroke subjects, but substantially improved when the SAS was applied. These findings show preserved movement preparation, suggesting that there is residual (subcortical) capacity for motor recovery. [ABSTRACT FROM AUTHOR]

Published

2018

23. Engagement of the contralateral limb can enhance the facilitation of motor output by loud acoustic stimuli

Author

McInnes, Aaron Nicholas, Nguyen, An, Carroll, T.J., Lipp, Ottmar, Marinovic, Welber, McInnes, Aaron Nicholas, Nguyen, An, Carroll, T.J., Lipp, Ottmar, and Marinovic, Welber

Abstract

When intense sound is presented during light muscle contraction, inhibition of the corticomotoneuronal pathway is observed. During action preparation, this effect is reversed, with sound resulting in excitation of the corticomotoneuronal pathway. We investigated how the combined maintenance of a muscle contraction during preparation for a ballistic action impacts the magnitude of the facilitation of motor output by a loud acoustic stimulus (LAS), a phenomenon known as the StartReact effect. Participants executed ballistic wrist flexion movements and a LAS was presented simultaneously with the imperative signal in a subset of trials. We examined whether the force level or muscle used to maintain a contraction during preparation for the ballistic response impacted reaction time and/or the force of movements triggered by the LAS. These contractions were sustained either ipsilaterally or contralaterally to the ballistic response. The magnitude of facilitation by the LAS was greatest when low-force flexion contractions were maintained in the limb contralateral to the ballistic response during preparation. There was little change in facilitation when contractions recruited the contralateral extensor muscle or when they were sustained in the same limb that executed the ballistic response. We conclude that a larger network of neurons that may be engaged by a contralateral sustained contraction prior to initiation may be recruited by the LAS, further contributing to the motor output of the response. These findings may be particularly applicable in stroke rehabilitation, where engagement of the contralesional side may increase the benefits of a LAS to the functional recovery of movement.

Published

2022

24. Investigating Motor Preparation in Synchronous Hand and Foot Movements Under Reactive vs. Predictive Control

Author

Bui, Allison

Subjects

Motor preparation, Reactive control, Predictive control, StartReact, Synchronous movements

Abstract

Synchronizing hand and foot movements under reactive versus predictive control results in differential timing structures between the responses. Under reactive control, where the movement is externally triggered, the electromyographic (EMG) responses are synchronized, resulting in the hand displacement preceding the foot. Under predictive control, where the movement is self-paced, the motor commands are organized such that the displacement onset occurs relatively synchronously, requiring the EMG onset of the foot to precede that of the hand. The current study used a startling acoustic stimulus (SAS), which is known to involuntarily trigger a prepared response, to investigate whether these results are due to differences in the pre-programmed timing initiation structure of the responses. Participants (n=17) performed isolated and synchronous movements of the right heel and right hand under both reactive and predictive modes of control. The reactive condition involved a simple reaction time (RT) task where participants performed the required movement in response to a visual go-signal. The predictive condition involved an anticipation-timing task where participants initiated the required movement coincidently with a sweeping clock hand reaching a target. On a subset of trials, a SAS (114 dB) was presented 150 ms prior to the imperative stimulus. Results from the SAS trials revealed that while the differential timing structures between the responses was maintained under both reactive and predictive control, the EMG onset asynchrony under predictive control was significantly smaller following the SAS. Additionally, there was no difference in the effect of the SAS when the movements were performed in isolation versus synchronously. Together, these results suggest that the timing between the responses, which differs between the two control modes, is pre-programmed; however, under predictive control, an increase in cortical activation from the SAS may have shortened the between-limb delay.

Published

2022

25. Fractionation of muscle activity in rapid responses to startling cues.

Author

Dean, Lauren R. and Baker, Stuart N.

Subjects

*DOSE fractionation, *PEPTIDE fractionation, *MUSCLES, *RESPONSES (Liturgy), *MOVEMENT education

Abstract

Movements in response to acoustically startling cues have shorter reaction times than those following less intense sounds; this is known as the StartReact effect. The neural underpinnings for StartReact are unclear. One possibility is that startling cues preferentially invoke the reticulospinal tract to convey motor commands to spinal motoneurons. Reticulospinal outputs are highly divergent, controlling large groups of muscles in synergistic patterns. By contrast the dominant pathway in primate voluntary movement is the corticospinal tract, which can access small groups of muscles selectively. We therefore hypothesized that StartReact responses would be less fractionated than standard voluntary reactions. Electromyogram recordings were made from 15 muscles in 10 healthy human subjects as they carried out 32 varied movements with the right forelimb in response to startling and nonstartling auditory cues. Movements were chosen to elicit a wide range of muscle activations. Multidimensional muscle activity patterns were calculated at delays from 0 to 100 ms after the onset of muscle activity and subjected to principal component analysis to assess fractionation. In all cases, a similar proportion of the total variance could be explained by a reduced number of principal components for the startling and the nonstartling cue. Muscle activity patterns for a given task were very similar in response to startling and nonstartling cues. This suggests that movements produced in the StartReact paradigm rely on similar contributions from different descending pathways as those following voluntary responses to nonstartling cues. [ABSTRACT FROM AUTHOR]

Published

2017

26. Foreknowledge of an impending startling stimulus does not affect the proportion of startle reflexes or latency of StartReact responses.

Author

Drummond, Neil, Leguerrier, Alexandra, and Carlsen, Anthony

Subjects

*STIMULUS & response (Psychology), *STARTLE reaction, *STERNOCLEIDOMASTOID muscle, *ANXIETY, *MOTOR ability, *PHYSIOLOGY

Abstract

During a simple reaction time (RT) task, movements can be initiated early and involuntarily through presentation of a loud startling acoustic stimulus (SAS), a phenomenon termed the StartReact effect. In order to infer that activity in startle-related structures led to the early response triggering, it is important to observe a concurrent startle reflex in sternocleidomastoid. It is generally accepted that to consistently elicit a startle reflex, the SAS must be both intense and unpredictable. However, it remains unclear what effect explicit foreknowledge of an impending SAS has on the effectiveness of a SAS to elicit a startle reflex when preparing a motor response. To test this, participants completed two separate blocks of a simple RT task (counterbalanced order), where the control auditory go-signal was replaced with a SAS on 20 % of trials. In an unwarned block, knowledge of the trial type (SAS vs. control) was not provided in advance, while in a warned block, the trial type was forewarned. Results revealed that while foreknowledge of an impending SAS reduced the magnitude of the startle reflex, it did not affect the proportion of startle reflexes elicited or the magnitude of the StartReact effect. An increase in control trial RT was observed during the unwarned block, but only when it was performed first. These results indicate that preparation of a motor response leads to sufficiently increased activation in startle-related neural structures such that even with explicit knowledge of an upcoming SAS, participants are unable to proactively gate the upcoming sensory input. [ABSTRACT FROM AUTHOR]

Published

2017

27. A systematic review with meta-analysis of the StartReact effect on motor responses in stroke survivors and healthy individuals

Author

Mara DeLuca, Daniel Low, Veena Kumari, Andrew Parton, Jessica Davis, and Amir A. Mohagheghi

Subjects

reaction time, Reflex, Startle, neurorehabilitation, Electromyography, Physiology, General Neuroscience, Stroke Rehabilitation, StartReact, stroke, Stroke, Acoustic Stimulation, Humans, Survivors, stroke rehabilitation

Abstract

Control of limb movements may be impaired after stroke due to the loss of connectivity between the cerebral cortex and spinal cord. A notion to improve motor function in stroke survivors is to use alternate motor fibers, such as the reticulospinal tract (RST), which originate from the brainstem and terminate at different levels of spinal cord. One way of targeting the RST is to use a “StartReact” protocol to foster premature release of a preplanned movement in response to a startling stimulus. Our aim was to find support for the preservation of such StartReact effect in stroke survivors. We conducted a systematic review with meta-analysis of literature published in English up to September 2020, to explore differences in motor responses to startling stimuli in StartReact effects. Protocol of the study was registered (PROSPERO Registration No. CRD42020191581). PubMed, Google Scholar, Web of Science, PsycINFO, and Science Direct were searched for relevant literature. The meta-analysis contained six studies involving a total of 151 stroke and healthy participants. Muscle onset latency data were extracted from the qualifying studies and compared using RevMan. StartReact effect was present in both stroke and healthy groups, represented by shortened muscle onset latency when startling stimulus was present. There was considerable heterogeneity of the outcome measures, which was attributed to the range of motor impairments among stroke survivors and methodologies used. Our findings support the notion of preservation of preprogramming ability and suitability of RST and StartReact effect for motor rehabilitation following stroke.

Published

2022

28. Interactions between stretch and startle reflexes produce task-appropriate rapid postural reactions

Author

Jonathan eShemmell

Subjects

Motor Cortex, movement preparation, startle response, Long-latency stretch reflex, StartReact, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571, Neurology. Diseases of the nervous system, RC346-429

Abstract

Neural pathways underpinning startle reflex and limb stretch reflexes evolved independently and have served vastly different purposes. In their most basic form, the pathways responsible for these reflex responses are relatively simple processing units that produce a motoric response that is proportional to the stimulus received. It is becoming clear however, that rapid responses to external stimuli produced by human and non-human primates are context-dependent in a manner similar to voluntary movements. This mini review discusses the nature of startle and stretch reflex interactions in human and non-human primates and the involvement of the primary motor cortex in their regulation.

Published

2015

29. Impaired motor preparation and execution during standing reach in people with chronic stroke.

Author

McCombe Waller, Sandy, Yang, Chieh-ling, Magder, Laurence, Yungher, Don, Gray, Vicki, and Rogers, Mark W.

Subjects

*HEMIPARESIS, *PHYSIOLOGY, *POSTURE, *STANDING position, *STROKE patients, *ELECTROMYOGRAPHY

Abstract

Movement preparation of both anticipatory postural adjustments (APAs) and goal directed movement during a standing reaching task in adults with chronic hemiparesis and healthy controls was investigated. Using a simple reaction time paradigm, while standing on two separate force platforms, subjects received a warning light cue to “get ready to reach” followed 2.5 s later by an imperative light cue to “reach as quickly as possible” with the paretic arm (matched arm for controls) to touch a target in front of them for a total of 90 trials. In 30 of the reaching trials a loud acoustic stimulus (LAS) of 123 dB was randomly − −200, or 0 ms relative to the “go” cue. APA (postural) responses were characterized by the onset and maximal posterior displacement of center of pressure (CoP) and onset/offset of electromyography (EMG) from tibialis anterior (TA), soleus (SOL), while reach was characterized by onset and maximal forward displacement of the reach hand and onset of the anterior (AD), biceps brachii (BB) and middle deltoid (MD). Subjects with stroke, demonstrated a marked reduction in the occurrence of the StartReact responses for both APA and forward reach at all LAS time points indicating movement preparation dysfunction. Movement execution during a cued reach showed significant delays in APA and reach onsets, significant reduction in the magnitude of APA (posterior CoP displacement) and reach excursion, and an increased latency between the APA and reach compared to controls. EMG activation patterns for the TA and SOL demonstrated co contraction compared to the temporally sequenced pattern of control subjects. When LAS was provided at the “go” there were earlier but not significant differences in APA onset latency compared to reaching without LAS and significant delays in reach onset latency when compared to control subjects with or without LAS. An early burst of EMG in biceps brachii muscles with a further delay of the reach onset compared to reaching without LAS may be indicative of interference of a classical startle reflex activating elbow flexors. Results indicated impairments in movement preparation of both APA’s and goal directed UE movement in individuals with stroke which impact the functional performance of reaching in the standing position. [ABSTRACT FROM AUTHOR]

Published

2016

30. Premovement inhibition can protect motor actions from interference by response irrelevant sensory stimulation.

Author

McInnes, Aaron Nicholas, Lipp, Ottmar V, Tresilian, James R, Vallence, Ann-Maree, Marinovic, Welber, McInnes, Aaron Nicholas, Lipp, Ottmar V, Tresilian, James R, Vallence, Ann-Maree, and Marinovic, Welber

Abstract

KEY POINTS: Suppression of corticospinal excitability is reliably observed during preparation for a range of motor actions, leading to the belief that this preparatory inhibition is a physiologically obligatory component of motor preparation. The neurophysiological function of this suppression is uncertain. We restricted the time available for participants to engage in preparation and found no evidence for preparatory inhibition. The function of preparatory inhibition can be inferred from our findings that sensory stimulation can disrupt motor output in the absence of preparatory inhibition, but enhance motor output when inhibition is present. These findings suggest preparatory inhibition may be a strategic process which acts to protect prepared actions from external interference. Our findings have significant theoretical implications for preparatory processes. Findings may also have pragmatic benefit in that acoustic stimulation could be used therapeutically to facilitate movement, but only if the action can be prepared well in advance. ABSTRACT: Shortly before movement initiation, the corticospinal system undergoes a transient suppression. This phenomenon has been observed across a range of motor tasks, suggesting that it may be an obligatory component of movement preparation. We probed whether this was also the case when the urgency to perform a motor action was high, in a situation where little time was available to engage in preparatory processes. We controlled the urgency of an impending motor action by increasing or decreasing the foreperiod duration in an anticipatory timing task. Transcranial magnetic stimulation (TMS; experiment one) or a loud acoustic stimulus (LAS; experiment two) were used to examine how corticospinal and subcortical excitability were modulated during motor preparation. Preparatory inhibition of the corticospinal tract was absent when movement urgency was high, though motor actions were initiated on time. In contrast, subcortical circui

Published

2021

31. Quantitative evaluation of trunk function and the StartReact effect during reaching in patients with cervical and thoracic spinal cord injury

Author

Raimon Jane, Loreto García-Alen, Josep Valls-Solé, Hatice Kumru, Yolanda Castillo-Escario, Joan Vidal, Universitat Politècnica de Catalunya. Doctorat en Enginyeria Biomèdica, Universitat Politècnica de Catalunya. Departament d'Enginyeria de Sistemes, Automàtica i Informàtica Industrial, and Universitat Politècnica de Catalunya. BIOSPIN - Biomedical Signal Processing and Interpretation

Subjects

Spinal cord--Diseases, electromyography, medicine.medical_specialty, Equilibri (Fisiologia), Equilibrium (Physiology), Movement, Biomedical Engineering, Electromyography, smartphone, trunk, Cellular and Molecular Neuroscience, Physical medicine and rehabilitation, medicine, Sitting balance, Humans, In patient, Telèfons intel·ligents, Muscle, Skeletal, Spinal cord injury, Postural Balance, Spinal Cord Injuries, medicine.diagnostic_test, business.industry, StartReact, medicine.disease, Trunk, spinal cord injury, Medul·la espinal -- Ferides i lesions -- Pacients -- Rehabilitació, Spinal cord--Wounds and injuries, accelerometer, Smartphones, TRUNK TILTING, Cortical control, sitting balance, business, Lesions medul·lars, Ciències de la salut [Àrees temàtiques de la UPC], Thoracic spinal cord injury

Abstract

Reproducció del document publicat a: https://doi.org/10.1088/1741-2552/ac19d3, Objective. Impaired trunk stability is frequent in spinal cord injury (SCI), but there is a lack of quantitative measures for assessing trunk function. Our objectives were to: (a) evaluate trunk muscle activity and movement patterns during a reaching task in SCI patients, (b) compare the impact of cervical (cSCI) and thoracic (tSCI) injuries in trunk function, and (c) investigate the effects of a startling acoustic stimulus (SAS) in these patients. Approach. Electromyographic (EMG) and smartphone accelerometer data were recorded from 15 cSCI patients, nine tSCI patients, and 24 healthy controls, during a reaching task requiring trunk tilting. We calculated the response time (RespT) until pressing a target button, EMG onset latencies and amplitudes, and trunk tilt, lateral deviation, and other movement features from accelerometry. Statistical analysis was applied to analyze the effects of group (cSCI, tSCI, control) and condition (SAS, non-SAS) in each outcome measure. Main results. SCI patients, especially those with cSCI, presented significantly longer RespT and EMG onset latencies than controls. Moreover, in SCI patients, forward trunk tilt was accompanied by significant lateral deviation. RespT and EMG latencies were remarkably shortened by the SAS (the so-called StartReact effect) in tSCI patients and controls, but not in cSCI patients, who also showed higher variability. Significance. The combination of EMG and smartphone accelerometer data can provide quantitative measures for the assessment of trunk function in SCI. Our results show deficits in postural control and compensatory strategies employed by SCI patients, including delayed responses and higher lateral deviations, possibly to improve sitting balance. This is the first study investigating the StartReact responses in trunk muscles in SCI patients and shows that the SAS significantly accelerates RespT in tSCI, but not in cSCI, suggesting an increased cortical control exerted by these patients., This work was developed in the framework of the joint project 'Biomedical signal interpretation to study motor impairment, neurological disorders and novel personalised neurorehabilitation therapies', between the Fundación Institut Guttmann and the Institute for Bioengineering of Catalonia. This work was supported in part by a fellowship from 'La Caixa' Foundation (ID 100010434) with fellowship code LCF/BQ/DE18/11670019, in part by the Secretaria d'Universitats i Recerca de la Generalitat de Catalunya under Grant GRC 2017 SGR 01770, in part by the Agencia Estatal de Investigación, the Spanish Ministry of Science, Innovation and Universities, and the European Regional Development Fund under Grant RTI2018 098472-B-I00, in part by the CERCA Program/Generalitat de Catalunya, in part by H2020-ERA-NET Neuron under Grant AC16/00034, in part by La Marató de TV3 2017 under Grant 201713.31, and in part by Premi Beca 'Mike Lane' 2019—Castellers de la Vila de Gràcia. The authors declare no competing interests.

Published

2021

32. What startles tell us about control of posture and gait.

Author

Nonnekes, Jorik, Carpenter, Mark G., Inglis, J. Timothy, Duysens, Jacques, and Weerdesteyn, Vivian

Subjects

*POSTURE, *GAIT in humans, *STARTLE reaction, *REFLEXES, *HUMAN behavior, *MOTOR ability

Abstract

Recently, there has been an increase in studies evaluating startle reflexes and StartReact, many in tasks involving postural control and gait. These studies have provided important new insights. First, several experiments indicate a superimposition of startle reflex activity on the postural response during unexpected balance perturbations. Overlap in the expression of startle reflexes and postural responses emphasizes the possibility of, at least partly, a common substrate for these two types of behavior. Second, it is recognized that the range of behaviors, susceptible to StartReact, has expanded considerably. Originally this work was concentrated on simple voluntary ballistic movements, but gait initiation, online step adjustments and postural responses can be initiated earlier by a startling stimulus as well, indicating advanced motor preparation of posture and gait. Third, recent experiments on StartReact using TMS and patients with corticospinal lesions suggest that this motor preparation involves a close interaction between cortical and subcortical structures. In this review, we provide a comprehensive overview on startle reflexes, StartReact, and their interaction with posture and gait. [ABSTRACT FROM AUTHOR]

Published

2015

33. Startling acoustic stimuli can evoke fast hand extension movements in stroke survivors.

Author

Honeycutt, Claire Fletcher, Tresch, Ursina Andrea, and Perreault, Eric Jon

Subjects

*STROKE patients, *ACOUSTIC stimulation, *MOTOR ability, *STIMULUS & response (Biology), *SKELETAL muscle, *ELBOW, *NEUROPHYSIOLOGY

Abstract

Objective A startling loud acoustic stimulus can involuntarily elicit planned movements, a phenomenon referred to as startReact. Following stroke, startReact elbow flexion in stroke survivors are improved from voluntary movements. Specifically, startReact elbow flexion in unimpaired individuals is not statistically different from stroke survivors in terms of onset latency and muscle activation patterns. As hand movements are particularly impacted by stroke, our objective was to determine if startReact was intact in the hand following stroke. Methods Data were collected in 8 stroke survivors and 10 age-matched subjects performing hand extension following two non-startling acoustic stimuli representing “get ready” and “go” respectively. Randomly, the “go” was replaced with a startling acoustic stimulus. We hypothesized that (1) startReact would be intact during hand extension in stroke survivors and that (2) the latency of movement would be the same as in age-matched subjects. Results We found that startReact was intact in stroke subjects and further that the onset latency of these movements was not different from age-matched subjects. Conclusions We conclude that startReact is intact in the hand following stroke. Significance An intact startReact response indicates that this reflex may be an attractive therapeutic target for initiating hand extension in stroke survivors. [ABSTRACT FROM AUTHOR]

Published

2015

34. Interactions between stretch and startle reflexes produce task-appropriate rapid postural reactions.

Author

Shemmell, Jonathan

Subjects

STRETCH reflex, STARTLE reaction, NEURAL pathways, ANTERIOR corticospinal tract, POSTURAL muscles, MOTOR cortex

Abstract

Neural pathways underpinning startle reflex and limb stretch reflexes evolved independently and have served vastly different purposes. In their most basic form, the pathways responsible for these reflex responses are relatively simple processing units that produce a motoric response that is proportional to the stimulus received. It is becoming clear however, that rapid responses to external stimuli produced by human and non-human primates are context-dependent in a manner similar to voluntary movements. This mini review discusses the nature of startle and stretch reflex interactions in human and non-human primates and the involvement of the primary motor cortex in their regulation. [ABSTRACT FROM AUTHOR]

Published

2015

35. Deficits in startle-evoked arm movements increase with impairment following stroke.

Author

Honeycutt, Claire Fletcher and Perreault, Eric Jon

Subjects

*ARM physiology, *STARTLE reaction, *DISABILITIES, *STROKE, *ELBOW physiology, *PSYCHOLOGY of movement, *MEDICAL databases

Abstract

Objective The startle reflex elicits involuntary release of planned movements (startReact). Following stroke, startReact flexion movements are intact but startReact extension movements are impaired by task-inappropriate flexor activity impeding arm extension. Our objective was to quantify deficits in startReact elbow extension movements, particularly how these deficits are influenced by impairment. Methods Data were collected in 8 stroke survivors performing elbow extension following two non-startling acoustic stimuli representing "get ready" and "go", respectively. Randomly, the "go" was replaced with a startling acoustic stimulus. We hypothesized that task-inappropriate flexor activity originates from unsuppressed classic startle reflex. We expected that increasing damage to the cortex (increasing impairment) would relate to increasing task-inappropriate flexor activity causing poor elbow extension movement and target acquisition. Results Task-inappropriate flexor activity increased with impairment resulting in larger flexion deflections away from the subjects' intended target corresponding to decreased target acquisition. Conclusions We conclude that the task-inappropriate flexor activity likely results from cortical or corticospinal damage leading to an unsuppressed or hypermetric classic startle reflex that interrupts startReact elbow extension. Significance Given startReact's functional role in compensation during environmental disturbances, our results may have important implications for our understanding deficits in stroke survivor's response to unexpected environmental disturbances. [ABSTRACT FROM AUTHOR]

Published

2014

36. Cortical involvement in the StartReact effect.

Author

Stevenson, A.J.T., Chiu, C., Maslovat, D., Chua, R., Gick, B., Blouin, J.-S., and Franks, I.M.

Subjects

*STERNOCLEIDOMASTOID muscle, *PREFRONTAL cortex, *REACTION time, *CONSONANTS, *PARAPLEGIA, *TRANSCRANIAL magnetic stimulation, *ELECTROMYOGRAPHY

Abstract

Highlights: [•] Subjects performed a simple reaction time (RT) task in response to an auditory cue. [•] Transcranial magnetic stimulation (TMS) was applied on control and startle trials. [•] TMS induced a cortical silent period and delayed both control and startle RTs. [•] For a cortically dependent speech RT task, startling stimulus also sped response. [•] Results indicate cortical involvement in response triggering by startling stimulus. [ABSTRACT FROM AUTHOR]

Published

2014

37. Reduced StartReact effect and freezing of gait in Parkinson's disease: two of a kind?

Author

Nonnekes, Jorik, Geurts, Alexander, Oude Nijhuis, Lars, van Geel, Karin, Snijders, Anke, Bloem, Bastiaan, and Weerdesteyn, Vivian

Subjects

*GAIT disorders, *MOVEMENT disorders, *BRAIN stem, *ANKLE, *RETICULAR formation

Abstract

Freezing of gait (FOG) is a disabling feature of Parkinson's disease. Emerging evidence suggests that dysfunction of the pedunculopontine nucleus (PPN) and pontomedullary reticular formation (pmRF) plays a role in the causation of FOG. These brainstem structures can be examined by the StartReact paradigm, which utilizes a startling stimulus to accelerate reaction times (StartReact). Here, we examined gait initiation in PD patients with and without FOG using this paradigm. Twenty-six patients with Parkinson's disease (12 freezers and 14 non-freezers) and 15 controls performed two tasks: rapid gait initiation in response to an imperative 'go' signal; and a control condition, involving a simple reaction-time task involving ankle dorsiflexion. During both tasks, a startling acoustic stimulus was combined with the imperative signal in 25 % of trials. In controls, the startle accelerated gait initiation and shortened the onset latency of tibialis anterior responses during ankle dorsiflexion. This acceleration was intact in non-freezers, but was significantly attenuated in the freezers. Independent of the occurrence of a startle, freezers showed a reduced length of the first step compared to non-freezers and controls. The diminished StartReact effect in freezers probably reflects deficient representation or release of motor programs at the brainstem reticular level due to dysfunction of the PPN, the pmRF, or both. These brainstem structures are presumably involved in integrating anticipatory postural adjustments with subsequent stepping movements. We suggest that with time-varying demands, these structures may no longer be able to coordinate the integration of anticipatory postural adjustments with steps, leading to FOG episodes. [ABSTRACT FROM AUTHOR]

Published

2014

38. Understanding the dual-task costs of walking: a StartReact study

Author

Teodoro Solis-Escalante, Vivian Weerdesteyn, Valeria Dibilio, Claudia Barthel, Jorik Nonnekes, and Bastiaan R. Bloem

Subjects

Adult, Male, Reflex, Startle, medicine.medical_specialty, Walking, Motor Activity, Stimulus (physiology), Sitting, Extensor carpi radialis muscle, Executive Function, Young Adult, Physical medicine and rehabilitation, Reaction Time, medicine, Humans, Muscle, Skeletal, Gait, Electromyography, General Neuroscience, Startle, StartReact, Disorders of movement Donders Center for Medical Neuroscience [Radboudumc 3], Dual-task, Female, Psychology, Psychomotor Performance, Research Article

Abstract

Contains fulltext : 220586.pdf (Publisher’s version ) (Open Access) The need to perform multiple tasks more or less simultaneously is a common occurrence during walking in daily life. Performing tasks simultaneously typically impacts task performance negatively. Hypothetically, such dual-task costs may be explained by a lowered state of preparation due to competition for attentional resources, or alternatively, by a 'bottleneck' in response initiation. Here, we investigated both hypotheses by comparing 'StartReact' effects during a manual squeezing task under single-task (when seated) and dual-task (when walking) conditions. StartReact is the acceleration of reaction times by a startling stimulation (a startling acoustic stimulus was applied in 25% of trials), attributed to the startling stimulus directly releasing a pre-prepared movement. If dual-task costs are due to a lowered state of preparation, we expected trials both with and without an accompanying startling stimulus to be delayed compared to the single-task condition, whereas we expected only trials without a startling stimulus to be delayed if a bottleneck in response initiation would underlie dual-task costs. Reaction times of the manual squeezing task in the flexor digitorum superficialis and extensor carpi radialis muscle were significantly delayed (approx. 20 ms) when walking compared to the seated position. A startling acoustic stimulus significantly decreased reaction times of the squeezing task (approx. 60 ms) both when walking and sitting. Dual-task costs during walking are, therefore, likely the result of lowered task preparation because of competition for attentional resources.

Published

2020

39. Startling Acoustic Stimulation Has Task-Specific Effects on Intracortical Facilitation and Inhibition at Rest and During Visually Guided Isometric Elbow Flexion in Healthy Individuals.

Author

Chen YT, Li S, Zhang Y, Zhou P, and Li S

Subjects

Humans, Acoustic Stimulation, Evoked Potentials, Motor physiology, Transcranial Magnetic Stimulation methods, Neural Inhibition, Electromyography, Muscle, Skeletal physiology, Elbow, Motor Cortex physiology

Abstract

Startling acoustic stimulation (SAS) causes a transient effect on the primary motor cortex (M1) nonreflexively. It reduces the cortical excitability at rest, but not during voluntary contraction. However, the effect of SAS on intracortical activity is not clear. The purpose of this study was to investigate the SAS effect on short-interval intracortical inhibition and intracortical facilitation using transcranial magnetic stimulation (TMS). Eleven healthy individuals performed isometric elbow flexion at 10% of maximum voluntary contraction on the dominant side with a real-time visual target (i.e., M1 preactivation) or at rest. TMS was delivered to the M1 ipsilateral to elbow flexion without or with SAS delivered 90 ms prior to TMS. There were three TMS delivery conditions: (a) single pulse, (b) short-interval intracortical inhibition, and (c) intracortical facilitation. TMS-induced motor-evoked potential (MEP) was compared between predetermined TMS and SAS conditions at rest and during ipsilateral voluntary contraction. We confirmed that SAS decreased the MEP amplitude at rest, but not during M1 preactivation. SAS caused task-specific effects on intracortical excitability. Specifically, SAS increased intracortical facilitation at rest and during voluntary contraction. However, SAS decreased short-interval intracortical inhibition only during M1 preactivation. Collectively, our results suggest that SAS transiently influences the motor cortex excitability, possibly via its activation of higher centers, to achieve a visually guided goal-directed task.

Published

2022

40. Retrospective composite analysis of StartReact data indicates sex differences in simple reaction time are not attributable to response preparation.

Author

Sadler, Christin M., Peters, Kathleen J., Santangelo, Cassandra M., Maslovat, Dana, and Carlsen, Anthony N.

Subjects

*STARTLE reaction, *DATA analysis, *RETROSPECTIVE studies, *SUPPLY chain management

Abstract

Simple reaction time (RT) can vary by sex, with males generally displaying faster RTs than females. Although several explanations have been offered, the possibility that response preparation differences may underlie the effect of sex on simple RT has not yet been explored. A startling acoustic stimulus (SAS) can involuntarily trigger a prepared motor response (i.e., StartReact effect), and as such, RT latencies on SAS trials and the proportion of these trials demonstrating startle-reflex EMG in the sternocleidomastoid (SCM) muscle are used as indirect measures of response preparation. The present study employed a retrospective analysis of composite individual participant data (IPD) from 25 datasets published between 2006 and 2019 to examine sex differences in response preparation. Linear mixed effects models assessed the effect of sex on control and SAS RT as well as the proportion of SAS trials with SCM activation while controlling for study design. Results indicated significantly longer control RT in female participants as compared to males (p =.017); however, there were no significant sex differences in SAS RT (p =.441) or the proportion of trials with startle reflex activity (p =.242). These results suggest that sex differences in simple RT are not explained by variations in levels of response preparation but instead may be the result of differences in perceptual processing and/or response initiation processes. • Reaction time in human males is typically shorter than in females, which could be due to sex differences in motor preparation. • A composite analysis of StartReact data replicated reaction time sex differences in control trials, but not startle trials. • These results suggest that reaction time differences are due to stimulus detection and/or response initiation processes. [ABSTRACT FROM AUTHOR]

Published

2022

41. Startle effects on saccadic responses to emotional target stimuli.

Author

Deuter, Christian E., Schilling, Thomas M., Kuehl, Linn K., Blumenthal, Terry D., and Schachinger, Hartmut

Subjects

*SACCADIC eye movements, *STARTLE reaction, *ELECTROMYOGRAPHY, *REFLEXES, *ACOUSTIC stimulation

Abstract

Startle stimuli elicit various physiological and cognitive responses. This study investigated whether acoustic startle stimuli affect saccadic reactions in an emotional pro- or antisaccade task. Startle probes were presented either 500 ms before or simultaneous with an imperative stimulus that indicated whether a saccade towards or away from positive, neutral, or negative peripheral target pictures had to be performed. Valence interacted with saccade direction according to an approach-avoidance pattern of gaze behavior, with delayed prosaccades to negative targets and antisaccades away from positive targets. Acoustic startle stimuli preceding the presentation of peripheral target pictures speeded up the initiation saccades, irrespective of stimulus valence. Results indicate a speeding of cognitive-motor processing by preceding startle stimuli. [ABSTRACT FROM AUTHOR]

Published

2013

42. Mechanisms of postural instability in hereditary spastic paraplegia.

Author

Nonnekes, Jorik, Niet, Mark, Nijhuis, Lars, Bot, Susanne, Warrenburg, Bart, Bloem, Bastiaan, Geurts, Alexander, and Weerdesteyn, Vivian

Subjects

*POSTURE disorders, *FAMILIAL spastic paraplegia, *ACOUSTIC stimulation, *PROPRIOCEPTION, *POSTURAL balance, *LEG muscles

Abstract

Hereditary spastic paraplegia (HSP) is characterized by progressive lower extremity spasticity and weakness, due to retrograde axonal degeneration of the corticospinal tract and posterior spinal columns. HSP patients fall frequently. We hypothesized that delayed postural responses contribute to their balance impairments. To distinguish between a delay in afferent and efferent signals, we combined postural responses with a startling acoustic stimulus (SAS). The SAS triggers a postural response directly, bypassing afferent proprioceptive input. We performed two experiments. First, 18 HSP patients and nine healthy controls stood on a balance platform and were instructed to counteract forward and backward balance perturbations, without taking a step or grabbing a handrail. Second, 12 HSP patients and nine controls received backward perturbations, while a SAS accompanied onset of platform motion in 25 % of trials. HSP patients were less successful than controls in maintaining balance following backward and forward perturbations. Furthermore, latencies of postural responses were significantly delayed in HSP-patients, by 34 ms in gastrocnemius following forward, and by 38 ms in tibialis anterior following backward perturbations. A SAS accelerated postural responses in all participants, but more so in HSP patients whose latencies were normalized. Our results suggest that delayed postural responses in HSP patients contribute to their balance problems. Combining balance perturbations with a SAS restored normal latencies, suggesting that conduction of efferent signals (presumably by the reticulospinal tract) is normal. We therefore suggest that the delayed postural responses in HSP are caused by slowed conduction time via the posterior spinal columns. [ABSTRACT FROM AUTHOR]

Published

2013

43. Are postural responses to backward and forward perturbations processed by different neural circuits?

Author

Nonnekes, J., Scotti, A., Oude Nijhuis, L.B., Smulders, K., Queralt, A., Geurts, A.C.H., Bloem, B.R., and Weerdesteyn, V.

Subjects

*POSTURAL muscles, *NEURAL circuitry, *PERTURBATION theory, *PARKINSONIAN disorders, *STARTLE reaction, *AUDITORY evoked response, *ELECTROMYOGRAPHY, *STANDARD deviations

Abstract

Highlights: [•] Balance was perturbed in 11 healthy subjects in forward and backward directions. [•] Twenty-five percent of trials were combined with a startling auditory stimulus (SAS). [•] The SAS accelerated and strengthened responses to backward perturbations only. [•] Backward and forward balance responses may involve different neural circuits. [•] Deficits in startle pathways could explain backward instability in Parkinsonism. [ABSTRACT FROM AUTHOR]

Published

2013

44. A block to pre-prepared movement in gait freezing, relieved by pedunculopontine nucleus stimulation.

Author

Thevathasan, Wesley, Pogosyan, Alek, Hyam, Jonathan A., Jenkinson, Ned, Bogdanovic, Marko, Coyne, Terry J., Silburn, Peter A., Aziz, Tipu Z., and Brown, Peter

Subjects

*GAIT disorders, *PARKINSONIAN disorders, *AUDITORY perception, *BRAIN stimulation, *POSTURE, *NEURAL stimulation, *REACTION time

Abstract

Gait freezing and postural instability are disabling features of Parkinsonian disorders, treatable with pedunculopontine nucleus stimulation. Both features are considered deficits of proximal and axial musculature, innervated predominantly by reticulospinal pathways and tend to manifest when gait and posture require adjustment. Adjustments to gait and posture are amenable to pre-preparation and rapid triggered release. Experimentally, such accelerated release can be elicited by loud auditory stimuli—a phenomenon known as ‘StartReact’. We observed StartReact in healthy and Parkinsonian controls. However, StartReact was absent in Parkinsonian patients with severe gait freezing and postural instability. Pedunculopontine nucleus stimulation restored StartReact proximally and proximal reaction times to loud stimuli correlated with gait and postural disturbance. These findings suggest a relative block to triggered, pre-prepared movement in gait freezing and postural instability, relieved by pedunculopontine nucleus stimulation. [ABSTRACT FROM AUTHOR]

Published

2011

45. Fractionation of muscle activity in rapid responses to startling cues

Author

Stuart N. Baker and Lauren R. Dean

Subjects

Adult, Male, 0301 basic medicine, reticulospinal tract, Reflex, Startle, Time Factors, Physiology, Movement, Electromyography, startle, 03 medical and health sciences, 0302 clinical medicine, Reaction Time, medicine, Humans, fractionation, Muscle activity, Muscle, Skeletal, Principal Component Analysis, medicine.diagnostic_test, Reflex startle, General Neuroscience, Motor commands, Reticulospinal tract, Middle Aged, StartReact, Evoked Potentials, Motor, 030104 developmental biology, Acoustic Stimulation, Right forelimb, Corticospinal tract, Female, Cues, Psychology, Neuroscience, Psychomotor Performance, 030217 neurology & neurosurgery, Research Article

Abstract

We demonstrate that the ability to activate muscles selectively is preserved during the very rapid reactions produced following a startling cue. This suggests that the contributions from different descending pathways are comparable between these rapid reactions and more typical voluntary movements., Movements in response to acoustically startling cues have shorter reaction times than those following less intense sounds; this is known as the StartReact effect. The neural underpinnings for StartReact are unclear. One possibility is that startling cues preferentially invoke the reticulospinal tract to convey motor commands to spinal motoneurons. Reticulospinal outputs are highly divergent, controlling large groups of muscles in synergistic patterns. By contrast the dominant pathway in primate voluntary movement is the corticospinal tract, which can access small groups of muscles selectively. We therefore hypothesized that StartReact responses would be less fractionated than standard voluntary reactions. Electromyogram recordings were made from 15 muscles in 10 healthy human subjects as they carried out 32 varied movements with the right forelimb in response to startling and nonstartling auditory cues. Movements were chosen to elicit a wide range of muscle activations. Multidimensional muscle activity patterns were calculated at delays from 0 to 100 ms after the onset of muscle activity and subjected to principal component analysis to assess fractionation. In all cases, a similar proportion of the total variance could be explained by a reduced number of principal components for the startling and the nonstartling cue. Muscle activity patterns for a given task were very similar in response to startling and nonstartling cues. This suggests that movements produced in the StartReact paradigm rely on similar contributions from different descending pathways as those following voluntary responses to nonstartling cues. NEW & NOTEWORTHY We demonstrate that the ability to activate muscles selectively is preserved during the very rapid reactions produced following a startling cue. This suggests that the contributions from different descending pathways are comparable between these rapid reactions and more typical voluntary movements.

Published

2017

46. Does height-induced threat modulate shortening of reaction times induced by a loud stimulus in a lateral stepping and a wrist extension task?

Author

Coppens, Milou J.M., Carpenter, Mark G., Inglis, J. Timothy, and Weerdesteyn, Vivian

Subjects

*POSTURAL balance, *GAIT in humans, *BODY movement, *REACTION time, *WRIST

Abstract

Introduction: The StartReact (SR) effect is the accelerated release of a prepared movement when a startling acoustic stimulus is presented at the time of the imperative stimulus (IS). SR paradigms have been used to study defective control of balance and gait in people with neurological conditions, but differences in emotional state (e.g. fear of failure) may be a potential confounder when comparing patients to healthy subjects. In this study, we aimed to gain insight in the effects of postural threat on the SR effect by manipulating surface height during a postural (lateral step) task and a non-postural (wrist extension) task.Methods: Eleven healthy participants performed a lateral step perpendicular to the platform edge, and 19 participants performed a wrist extension task while standing at the platform edge. Participants initiated the movement as fast as possible in response to an IS that varied in intensity across trials (80 dB to 121 dB) at both low and high platform height (3.2 m). For the lateral step task, we determined anticipatory postural adjustments (APA) and step onset latencies. For the wrist extension task, muscle onset latencies were determined. We used Wilcoxon signed-rank tests on the relative onset latencies between both heights, to identify whether the effect of height was different for IS intensities between 103 and 118 dB compared to 121 dB.Results: For both tasks, onset latencies were significantly shortened at 121 dB compared to 80 dB, regardless of height. In the lateral step task, the effect of height was larger at 112 dB compared to 121 dB. The absolute onset latencies showed that at 112 dB there was no such stimulus intensity effect at high as seen at low surface height. In the wrist extension task, no differential effects of height could be demonstrated across IS intensities.Conclusions: Postural threat had a significant, yet modest effect on shortening of RTs induced by a loud IS, with a mere 3 dB difference between standing on high versus low surface height. Interestingly, this effect of height was specific to the postural (i.e. lateral stepping) task, as no such differences could be demonstrated in the wrist extension task. This presumably reflects more cautious execution of the lateral step task when standing on height. The present findings suggest that applying stimuli of sufficiently high intensity (≥115 dB) appears to neutralize potential differences in emotional state when studying SR effects. [ABSTRACT FROM AUTHOR]

Published

2021

47. A startling acoustic stimulus facilitates voluntary lower extremity movements and automatic postural responses in people with chronic stroke

Author

Nicole A. J. Donkers, Jolanda M. B. Roelofs, Milou J. M. Coppens, Alexander C. H. Geurts, Vivian Weerdesteyn, and Jorik Nonnekes

Subjects

Male, Balance, medicine.medical_specialty, Reflex, Startle, Neurology, Movement, Stimulus (physiology), 050105 experimental psychology, 03 medical and health sciences, 0302 clinical medicine, Physical medicine and rehabilitation, All institutes and research themes of the Radboud University Medical Center, medicine, Ankle dorsiflexion, Humans, 0501 psychology and cognitive sciences, Chronic stroke, Postural Balance, Aged, Original Communication, business.industry, 05 social sciences, Startle, Middle Aged, Disorders of movement Donders Center for Medical Neuroscience [Radboudumc 3], StartReact, Motor coordination, Stroke, Standing balance, Acoustic Stimulation, Lower Extremity, Automatic postural responses, Chronic Disease, Balance perturbation, Motor recovery, Female, Neurology (clinical), business, 030217 neurology & neurosurgery

Abstract

A startling acoustic stimulus (SAS) involuntary releases prepared movements at accelerated latencies, known as the StartReact effect. Previous work has demonstrated intact StartReact in paretic upper extremity movements in people after stroke, suggesting preserved motor preparation. The question remains whether motor preparation of lower extremity movements is also unaffected after stroke. Here, we investigated StartReact effects on ballistic lower extremity movements and on automatic postural responses (APRs) following perturbations to standing balance. These APRs are particularly interesting as they are critical to prevent a fall following balance perturbations, but show substantial delays and poor muscle coordination after stroke. Twelve chronic stroke patients and 12 healthy controls performed voluntary ankle dorsiflexion movements in response to a visual stimulus, and responded to backward balance perturbations evoking APRs. Twenty-five percent of all trials contained a SAS (120 dB) simultaneously with the visual stimulus or balance perturbation. As expected, in the absence of a SAS muscle and movement onset latencies at the paretic side were delayed compared to the non-paretic leg and to controls. The SAS accelerated ankle dorsiflexion onsets in both the legs of the stroke subjects and in controls. Following perturbations, the SAS accelerated bilateral APR onsets not only in controls, but for the first time, we also demonstrated this effect in people after stroke. Moreover, APR inter- and intra-limb muscle coordination was rather weak in our stroke subjects, but substantially improved when the SAS was applied. These findings show preserved movement preparation, suggesting that there is residual (subcortical) capacity for motor recovery.

Published

2018

48. Quantitative evaluation of trunk function and the StartReact effect during reaching in patients with cervical and thoracic spinal cord injury.

Author

Castillo-Escario Y, Kumru H, Valls-Solé J, García-Alen L, Jané R, and Vidal J

Subjects

Electromyography, Humans, Movement, Muscle, Skeletal, Postural Balance, Spinal Cord Injuries diagnosis

Abstract

Objective. Impaired trunk stability is frequent in spinal cord injury (SCI), but there is a lack of quantitative measures for assessing trunk function. Our objectives were to: (a) evaluate trunk muscle activity and movement patterns during a reaching task in SCI patients, (b) compare the impact of cervical (cSCI) and thoracic (tSCI) injuries in trunk function, and (c) investigate the effects of a startling acoustic stimulus (SAS) in these patients. Approach. Electromyographic (EMG) and smartphone accelerometer data were recorded from 15 cSCI patients, nine tSCI patients, and 24 healthy controls, during a reaching task requiring trunk tilting. We calculated the response time (RespT) until pressing a target button, EMG onset latencies and amplitudes, and trunk tilt, lateral deviation, and other movement features from accelerometry. Statistical analysis was applied to analyze the effects of group (cSCI, tSCI, control) and condition (SAS, non-SAS) in each outcome measure. Main results. SCI patients, especially those with cSCI, presented significantly longer RespT and EMG onset latencies than controls. Moreover, in SCI patients, forward trunk tilt was accompanied by significant lateral deviation. RespT and EMG latencies were remarkably shortened by the SAS (the so-called StartReact effect) in tSCI patients and controls, but not in cSCI patients, who also showed higher variability. Significance . The combination of EMG and smartphone accelerometer data can provide quantitative measures for the assessment of trunk function in SCI. Our results show deficits in postural control and compensatory strategies employed by SCI patients, including delayed responses and higher lateral deviations, possibly to improve sitting balance. This is the first study investigating the StartReact responses in trunk muscles in SCI patients and shows that the SAS significantly accelerates RespT in tSCI, but not in cSCI, suggesting an increased cortical control exerted by these patients., (Creative Commons Attribution license.)

Published

2021

49. A block to pre-prepared movement in gait freezing, relieved by pedunculopontine nucleus stimulation

Author

Alek Pogosyan, Wesley Thevathasan, Terry Coyne, Ned Jenkinson, Tipu Z. Aziz, Peter A. Silburn, Marko Bogdanovic, Jonathan A. Hyam, and Peter Brown

Subjects

Male, Reflex, Startle, Deep brain stimulation, medicine.medical_treatment, Deep Brain Stimulation, Statistics as Topic, Electromyography, Neuropsychological Tests, Statistics, Nonparametric, Gait (human), Motor system, medicine, Postural Balance, Pedunculopontine Tegmental Nucleus, Reaction Time, Humans, Corneal reflex, Freezing Reaction, Cataleptic, Gait Disorders, Neurologic, Pedunculopontine nucleus, Aged, Neurologic Examination, Analysis of Variance, medicine.diagnostic_test, Blinking, pedunculopontine nucleus, Parkinson Disease, Original Articles, Middle Aged, StartReact, gait freezing, Acoustic Stimulation, Sensation Disorders, Parkinson’s disease, Female, Neurology (clinical), Psychology, Neuroscience, human activities

Abstract

Gait freezing and postural instability are disabling features of Parkinsonian disorders, treatable with pedunculopontine nucleus stimulation. Both features are considered deficits of proximal and axial musculature, innervated predominantly by reticulospinal pathways and tend to manifest when gait and posture require adjustment. Adjustments to gait and posture are amenable to pre-preparation and rapid triggered release. Experimentally, such accelerated release can be elicited by loud auditory stimuli--a phenomenon known as 'StartReact'. We observed StartReact in healthy and Parkinsonian controls. However, StartReact was absent in Parkinsonian patients with severe gait freezing and postural instability. Pedunculopontine nucleus stimulation restored StartReact proximally and proximal reaction times to loud stimuli correlated with gait and postural disturbance. These findings suggest a relative block to triggered, pre-prepared movement in gait freezing and postural instability, relieved by pedunculopontine nucleus stimulation.

Published

2011

50. Impaired posture, movement preparation, and execution during both paretic and nonparetic reaching following stroke.

Author

Yang CL, Creath RA, Magder L, Rogers MW, and McCombe Waller S

Subjects

Aged, Anticipation, Psychological, Biomechanical Phenomena, Female, Goals, Humans, Male, Middle Aged, Paresis etiology, Psychomotor Performance, Stroke complications, Arm physiology, Cues, Movement, Paresis physiopathology, Posture, Stroke physiopathology

Abstract

Posture and movement planning, preparation, and execution of a goal-directed reaching movement are impaired in individuals with stroke. No studies have shown whether the deficits are generally impaired or are specific to the lesioned hemisphere/paretic arm. This study utilized StartReact (SR) responses elicited by loud acoustic stimuli (LAS) to investigate the preparation and execution of anticipatory postural adjustments (APAs) and reach movement response during both paretic and nonparetic arm reaching in individuals with stroke and in age-matched healthy controls. Subjects were asked to get ready after receiving a warning cue and to reach at a "go" cue. An LAS was delivered at -500, -200, and 0 ms relative to the go cue. Kinetic, kinematic, and electromyographic data were recorded to characterize APA-reach movement responses. Individuals with stroke demonstrated systemwide deficits in posture and in movement planning, preparation, and execution of APA-reach sequence as shown by significant reduction in the incidence of SR response and impaired APA-reach performance, with greater deficits during paretic arm reaching. Use of trunk compensation strategy as characterized by greater involvement of trunk and pelvic rotation was utilized by individuals with stroke during paretic arm reaching compared with nonparetic arm reaching and healthy controls. Our findings have implications for upper extremity and postural control, suggesting that intervention should include training not only for the paretic arm but also for the nonparetic arm with simultaneous postural control requirements to improve the coordination of the APA-reach performance and subsequently reduce instability while functional tasks are performed during standing. NEW & NOTEWORTHY Our study is the first to show that nonparetic arm reaching also demonstrates impairment in posture and movement planning, preparation, and execution when performed during standing by individuals with stroke. In addition, we found compensatory trunk and pelvic rotations were used during a standing reach task for the paretic arms. The findings have clinical implications for upper extremity and postural rehabilitation, suggesting that training should include the nonparetic arms and incorporate simultaneous postural control demands.

Published

2019