Motor Training Using Mental Workload (MWL) With an Assistive Soft Exoskeleton System: A Functional Near-Infrared Spectroscopy (fNIRS) Study for Brain–Machine Interface (BMI)

Asgher, Umer; Khan, Muhammad Jawad; Nizami, Muhammad Hamza Asif; Khalil, Khurram; Ahmad, Robiah; Ayaz, Yasar; Naseer, Noman

doi:10.3389/fnbot.2021.605751

Cited by 15 publications

(9 citation statements)

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“…MWL is the result of a combination of factors, such as the level of effort a person exerts during an assignment and physiological and psychological demands during the assignment (19,20), which is influenced by a combination of intrinsic mental stress and extrinsic environmental factors (21). Moreover, MWL is one of the most widely used concepts in human ergonomics research and practice (22,23) and can be used to scientifically assess how well an operator performs current occupational operational tasks such as flying and driving (24,25). Additionally, functional nearinfrared spectroscopy (fNIRS) has been used for non-invasive monitoring of operators' brain function during a variety of operational tasks, as it allows for more objective and sensitive measurement and assessment of the level of MWL than other methods, providing an important research method for brain and cognitive science (25)(26)(27)(28).…”

Section: Introductionmentioning

confidence: 99%

“…MWL is the result of a combination of factors, such as the level of effort a person exerts during an assignment and physiological and psychological demands during the assignment ( 19 , 20 ), which is influenced by a combination of intrinsic mental stress and extrinsic environmental factors ( 21 ). Moreover, MWL is one of the most widely used concepts in human ergonomics research and practice ( 22 , 23 ) and can be used to scientifically assess how well an operator performs current occupational operational tasks such as flying and driving ( 24 , 25 ). Additionally, functional near-infrared spectroscopy (fNIRS) has been used for non-invasive monitoring of operators’ brain function during a variety of operational tasks, as it allows for more objective and sensitive measurement and assessment of the level of MWL than other methods, providing an important research method for brain and cognitive science ( 25–28 ).…”

Section: Introductionmentioning

confidence: 99%

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Impacts of complex electromagnetic radiation and low-frequency noise exposure conditions on the cognitive function of operators

Peng

et al. 2023

Front. Public Health

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BackgroundBoth electromagnetic radiation (EMR) and low-frequency noise (LFN) are widespread and influential environmental factors, and operators are inevitably exposed to both EMR and LFN within a complex exposure environment. The potential adverse effects of such exposure on human health must be considered seriously. This study aimed to investigate the effects of EMR and LFN on cognitive function as well as their interaction effect, which remain unclear.MethodsSixty young male college students were randomly grouped and experiments were conducted with a 2 × 2 factorial design in a shielded chamber. Mental workload (MWL) levels of the study subjects were measured and assessed using the NASA-task load index (TLX) subjective scale, an n-back task paradigm, and the functional near-infrared spectroscopy (fNIRS) imaging technique.ResultsFor the 3-back task, the NASA-TLX subjective scale revealed a statistically significant main effect of LFN intensity, which enhanced the subjects’ MWL level (F = 8.716, p < 0.01). Behavioral performance revealed that EMR intensity (430.1357 MHz, 10.75 W/m2) and LFN intensity (0–200 Hz, 72.9 dB) had a synergistic interaction effect, and the correct response time was statistically significantly prolonged by the combined exposure (F = 4.343, p < 0.05). The fNIRS imaging technique revealed a synergistic interaction effect between operational EMR intensity and operational LFN intensity, with statistically significant effects on the activation levels in the left and right dorsolateral prefrontal cortex (DLPFC). The mean β values of DLPFC were significantly increased (L-DLPFC F = 5.391, p < 0.05, R-DLPFC F = 4.222, p < 0.05), and the relative concentrations of oxyhemoglobin in the DLPFC were also significantly increased (L-DLPFC F = 4.925, p < 0.05, R-DLPFC F = 9.715, p < 0.01).ConclusionWe found a statistically significant interaction effect between EMR (430.1357 MHz, 10.75 W/m2) and LFN (0–200 Hz, 72.9 dB) when simultaneously exposing subjects to both for 30 min. We conclude that exposure to this complex environment can cause a statistically significant increase in the MWL level of operators, and even alterations in their cognitive function.

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Section: Introductionmentioning

confidence: 99%

“…MWL is the result of a combination of factors, such as the level of effort a person exerts during an assignment and physiological and psychological demands during the assignment ( 19 , 20 ), which is influenced by a combination of intrinsic mental stress and extrinsic environmental factors ( 21 ). Moreover, MWL is one of the most widely used concepts in human ergonomics research and practice ( 22 , 23 ) and can be used to scientifically assess how well an operator performs current occupational operational tasks such as flying and driving ( 24 , 25 ). Additionally, functional near-infrared spectroscopy (fNIRS) has been used for non-invasive monitoring of operators’ brain function during a variety of operational tasks, as it allows for more objective and sensitive measurement and assessment of the level of MWL than other methods, providing an important research method for brain and cognitive science ( 25–28 ).…”

Section: Introductionmentioning

confidence: 99%

Impacts of complex electromagnetic radiation and low-frequency noise exposure conditions on the cognitive function of operators

Peng

et al. 2023

Front. Public Health

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Sensors and Actuation Technologies in Exoskeletons: A Review

Tiboni

Borboni

Vérité

et al. 2022

Sensors

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Exoskeletons are robots that closely interact with humans and that are increasingly used for different purposes, such as rehabilitation, assistance in the activities of daily living (ADLs), performance augmentation or as haptic devices. In the last few decades, the research activity on these robots has grown exponentially, and sensors and actuation technologies are two fundamental research themes for their development. In this review, an in-depth study of the works related to exoskeletons and specifically to these two main aspects is carried out. A preliminary phase investigates the temporal distribution of scientific publications to capture the interest in studying and developing novel ideas, methods or solutions for exoskeleton design, actuation and sensors. The distribution of the works is also analyzed with respect to the device purpose, body part to which the device is dedicated, operation mode and design methods. Subsequently, actuation and sensing solutions for the exoskeletons described by the studies in literature are analyzed in detail, highlighting the main trends in their development and spread. The results are presented with a schematic approach, and cross analyses among taxonomies are also proposed to emphasize emerging peculiarities.

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“…Additionally, exoskeleton robots can also be controlled using a performance-based method, in which assistive forces are adjusted to support the user's movement based on his or her motor performance (e.g., InMotion 2.0 system) (Krebs et al, 2003 ). Brain-controlled exoskeletons have been used as brain-computer interfaces (BCIs) in assistive exoskeleton robots to decode brain processes from brain signals, such as electroencephalography (EEG) (Hong and Khan, 2017 ; Choi et al, 2020 ) or hemodynamic signals (Khan and Hong, 2017 ; Asgher et al, 2021 ), and convert them into output motor commands (e.g., BCI-Manus system). Determining the effects of robot-assisted rehabilitation requires a deeper understanding of the mechanisms underlying human-robot interactions.…”

Section: Introductionmentioning

confidence: 99%

“…Movement-related cortical potentials have also been successfully decoded from EEG-based signals in the rmPFC (Min et al, 2017 ; Koizumi et al, 2018 ). These signals are useful in controlling brain-controlled exoskeletons designed to augment the user's sensorimotor functions (Agashe et al, 2016 ; Hong and Khan, 2017 ; Khan and Hong, 2017 ; Liu et al, 2018 ; Asgher et al, 2021 ). Moreover, a limited number of studies have been conducted to investigate the effect of robot-assisted tasks on cortical reorganization (Youssofzadeh et al, 2016 ; Saita et al, 2017 , 2018 ; Memar and Esfahani, 2018 ; Berger et al, 2019 ; Peters et al, 2020 ).…”

Section: Introductionmentioning

confidence: 99%

Involvement of the Rostromedial Prefrontal Cortex in Human-Robot Interaction: fNIRS Evidence From a Robot-Assisted Motor Task

Watanabe

Ogawa

et al. 2022

Front. Neurorobot.

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Assistive exoskeleton robots are being widely applied in neurorehabilitation to improve upper-limb motor and somatosensory functions. During robot-assisted exercises, the central nervous system appears to highly attend to external information-processing (IP) to efficiently interact with robotic assistance. However, the neural mechanisms underlying this process remain unclear. The rostromedial prefrontal cortex (rmPFC) may be the core of the executive resource allocation that generates biases in the allocation of processing resources toward an external IP according to current behavioral demands. Here, we used functional near-infrared spectroscopy to investigate the cortical activation associated with executive resource allocation during a robot-assisted motor task. During data acquisition, participants performed a right-arm motor task using elbow flexion-extension movements in three different loading conditions: robotic assistive loading (ROB), resistive loading (RES), and non-loading (NON). Participants were asked to strive for kinematic consistency in their movements. A one-way repeated measures analysis of variance and general linear model-based methods were employed to examine task-related activity. We demonstrated that hemodynamic responses in the ventral and dorsal rmPFC were higher during ROB than during NON. Moreover, greater hemodynamic responses in the ventral rmPFC were observed during ROB than during RES. Increased activation in ventral and dorsal rmPFC subregions may be involved in the executive resource allocation that prioritizes external IP during human-robot interactions. In conclusion, these findings provide novel insights regarding the involvement of executive control during a robot-assisted motor task.

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Motor Training Using Mental Workload (MWL) With an Assistive Soft Exoskeleton System: A Functional Near-Infrared Spectroscopy (fNIRS) Study for Brain–Machine Interface (BMI)

Cited by 15 publications

References 125 publications

Impacts of complex electromagnetic radiation and low-frequency noise exposure conditions on the cognitive function of operators

Impacts of complex electromagnetic radiation and low-frequency noise exposure conditions on the cognitive function of operators

Sensors and Actuation Technologies in Exoskeletons: A Review

Involvement of the Rostromedial Prefrontal Cortex in Human-Robot Interaction: fNIRS Evidence From a Robot-Assisted Motor Task

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