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17. On the choice of grasp type and location when handing over an object

Author

Cini, F., Ortenzi, V., Corke, P., Controzzi, M., Cini, F., Ortenzi, V., Corke, P., and Controzzi, M.

Abstract

The human hand is capable of performing countless grasps and gestures that are the basis for social activities. However, which grasps contribute the most to the manipulation skills needed during collaborative tasks, and thus which grasps should be included in a robot companion, is still an open issue. Here, we investigated grasp choice and hand placement on objects during a handover when subsequent tasks are performed by the receiver and when in-hand and bimanual manipulation are not allowed. Our findings suggest that, in this scenario, human passers favor precision grasps during such handovers. Passers also tend to grasp the purposive part of objects and leave “handles” unobstructed to the receivers. Intuitively, this choice allows receivers to comfortably perform subsequent tasks with the objects. In practice, many factors contribute to a choice of grasp, e.g., object and task constraints. However, not all of these factors have had enough emphasis in the implementation of grasping by robots, particularly the constraints introduced by a task, which are critical to the success of a handover. Successful robotic grasping is important if robots are to help humans with tasks. We believe that the results of this work can benefit the wider robotics community, with applications ranging from industrial cooperative manipulation to household collaborative manipulation.

Published
2019

22. Restoring natural sensory feedback in real-time bidirectional hand prostheses

Author

Raspopovic, S, Capogrosso, M, Petrini, Fm, Bonizzato, M, Rigosa, J, Di Pino, G, Carpaneto, J, Controzzi, M, Boretius, T, Fernandez Marquez, Eduardo Marco, Granata, Giuseppe, Oddo, Cm, Citi, L, Ciancio, Al, Cipriani, C, Carrozza, Mc, Jensen, W, Guglielmelli, E, Stieglitz, T, Rossini, Paolo Maria, Micera, S., Fernandez Marquez, Eduardo Marcos (ORCID:0000-0001-5535-1412), Rossini, Paolo Maria (ORCID:0000-0003-2665-534X), Raspopovic, S, Capogrosso, M, Petrini, Fm, Bonizzato, M, Rigosa, J, Di Pino, G, Carpaneto, J, Controzzi, M, Boretius, T, Fernandez Marquez, Eduardo Marco, Granata, Giuseppe, Oddo, Cm, Citi, L, Ciancio, Al, Cipriani, C, Carrozza, Mc, Jensen, W, Guglielmelli, E, Stieglitz, T, Rossini, Paolo Maria, Micera, S., Fernandez Marquez, Eduardo Marcos (ORCID:0000-0001-5535-1412), and Rossini, Paolo Maria (ORCID:0000-0003-2665-534X)

Abstract

Hand loss is a highly disabling event that markedly affects the quality of life. To achieve a close to natural replacement for the lost hand, the user should be provided with the rich sensations that we naturally perceive when grasping or manipulating an object. Ideal bidirectional hand prostheses should involve both a reliable decoding of the user's intentions and the delivery of nearly "natural" sensory feedback through remnant afferent pathways, simultaneously and in real time. However, current hand prostheses fail to achieve these requirements, particularly because they lack any sensory feedback. We show that by stimulating the median and ulnar nerve fascicles using transversal multichannel intrafascicular electrodes, according to the information provided by the artificial sensors from a hand prosthesis, physiologically appropriate (near-natural) sensory information can be provided to an amputee during the real-time decoding of different grasping tasks to control a dexterous hand prosthesis. This feedback enabled the participant to effectively modulate the grasping force of the prosthesis with no visual or auditory feedback. Three different force levels were distinguished and consistently used by the subject. The results also demonstrate that a high complexity of perception can be obtained, allowing the subject to identify the stiffness and shape of three different objects by exploiting different characteristics of the elicited sensations. This approach could improve the efficacy and "life-like" quality of hand prostheses, resulting in a keystone strategy for the near-natural replacement of missing hands.

Published
2014

29. Cognitive vision system for control of dexterous prosthetic hands: experimental evaluation.

Author

Dosen S, Cipriani C, Kostic M, Controzzi M, Carrozza MC, Popovic DB, Dosen, Strahinja, Cipriani, Christian, Kostić, Milos, Controzzi, Marco, Carrozza, Maria C, and Popović, Dejan B

Abstract

Background: Dexterous prosthetic hands that were developed recently, such as SmartHand and i-LIMB, are highly sophisticated; they have individually controllable fingers and the thumb that is able to abduct/adduct. This flexibility allows implementation of many different grasping strategies, but also requires new control algorithms that can exploit the many degrees of freedom available. The current study presents and tests the operation of a new control method for dexterous prosthetic hands.Methods: The central component of the proposed method is an autonomous controller comprising a vision system with rule-based reasoning mounted on a dexterous hand (CyberHand). The controller, termed cognitive vision system (CVS), mimics biological control and generates commands for prehension. The CVS was integrated into a hierarchical control structure: 1) the user triggers the system and controls the orientation of the hand; 2) a high-level controller automatically selects the grasp type and size; and 3) an embedded hand controller implements the selected grasp using closed-loop position/force control. The operation of the control system was tested in 13 healthy subjects who used Cyberhand, attached to the forearm, to grasp and transport 18 objects placed at two different distances.Results: The system correctly estimated grasp type and size (nine commands in total) in about 84% of the trials. In an additional 6% of the trials, the grasp type and/or size were different from the optimal ones, but they were still good enough for the grasp to be successful. If the control task was simplified by decreasing the number of possible commands, the classification accuracy increased (e.g., 93% for guessing the grasp type only).Conclusions: The original outcome of this research is a novel controller empowered by vision and reasoning and capable of high-level analysis (i.e., determining object properties) and autonomous decision making (i.e., selecting the grasp type and size). The automatic control eases the burden from the user and, as a result, the user can concentrate on what he/she does, not on how he/she should do it. The tests showed that the performance of the controller was satisfactory and that the users were able to operate the system with minimal prior training. [ABSTRACT FROM AUTHOR]

Published
2010
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30. Optimal integration of intraneural somatosensory feedback with visual information: a single-case study

Author

Marco Controzzi, Silvestro Micera, Thomas Stieglitz, Francesco Clemente, Gabriel Baud-Bovy, Ivo Strauss, Paolo Maria Rossini, Francesco Iberite, Giacomo Valle, Giuseppe Granata, G. Risso, Risso, G, Valle, G, Iberite, F, Strauss, I, Stieglitz, T, Controzzi, M, Clemente, F, Granata, G, Rossini, P M, Micera, S, and Baud-Bovy, G

Subjects
0301 basic medicine, Nervous system, Computer science, lcsh:Medicine, Artificial Limbs, Sensory system, Somatosensory system, Signal, Article, Single-Case Studies as Topic, 03 medical and health sciences, 0302 clinical medicine, Amputees, Feedback, Sensory, Sensation, medicine, Humans, Computer vision, Closing (morphology), lcsh:Science, Ulnar Nerve, Brain–computer interface, Haptic technology, Multidisciplinary, Electromyography, business.industry, lcsh:R, Brain-machine interface, Middle Aged, Electric Stimulation, Electrodes, Implanted, Forearm, Treatment Outcome, 030104 developmental biology, medicine.anatomical_structure, Sensory substitution, Brain-Computer Interfaces, Perception, Female, lcsh:Q, Artificial intelligence, business, 030217 neurology & neurosurgery
Abstract

Providing somatosensory feedback to amputees is a long-standing objective in prosthesis research. Recently, implantable neural interfaces have yielded promising results in this direction. There is now considerable evidence that the nervous system integrates redundant signals optimally, weighting each signal according to its reliability. One question of interest is whether artificial sensory feedback is combined with other sensory information in a natural manner. In this single-case study, we show that an amputee with a bidirectional prosthesis integrated artificial somatosensory feedback and blurred visual information in a statistically optimal fashion when estimating the size of a hand-held object. The patient controlled the opening and closing of the prosthetic hand through surface electromyography, and received intraneural stimulation proportional to the object’s size in the ulnar nerve when closing the robotic hand on the object. The intraneural stimulation elicited a vibration sensation in the phantom hand that substituted the missing haptic feedback. This result indicates that sensory substitution based on intraneural feedback can be integrated with visual feedback and make way for a promising method to investigate multimodal integration processes.

31. Restoration of grasping in an upper limb amputee using the myokinetic prosthesis with implanted magnets.

Author

Gherardini M, Ianniciello V, Masiero F, Paggetti F, D'Accolti D, La Frazia E, Mani O, Dalise S, Dejanovic K, Fragapane N, Maggiani L, Ipponi E, Controzzi M, Nicastro M, Chisari C, Andreani L, and Cipriani C

Subjects
Humans, Male, Muscle, Skeletal physiology, Upper Extremity, Hand physiology, Adult, Electromyography, Amputation Stumps physiopathology, Muscle Contraction physiology, Prosthesis Implantation, Artificial Limbs, Amputees rehabilitation, Hand Strength physiology, Prosthesis Design, Robotics instrumentation, Magnets
Abstract

The loss of a hand disrupts the sophisticated neural pathways between the brain and the hand, severely affecting the level of independence of the patient and the ability to carry out daily work and social activities. Recent years have witnessed a rapid evolution of surgical techniques and technologies aimed at restoring dexterous motor functions akin to those of the human hand through bionic solutions, mainly relying on probing of electrical signals from the residual nerves and muscles. Here, we report the clinical implementation of an interface aimed at achieving this goal by exploiting muscle deformation, sensed through passive magnetic implants: the myokinetic interface. One participant with a transradial amputation received an implantation of six permanent magnets in three muscles of the residual limb. A truly self-contained myokinetic prosthetic arm embedding all hardware components and the battery within the prosthetic socket was developed. By retrieving muscle deformation caused by voluntary contraction through magnet localization, we were able to control in real time a dexterous robotic hand following both a direct control strategy and a pattern recognition approach. In just 6 weeks, the participant successfully completed a series of functional tests, achieving scores similar to those achieved when using myoelectric controllers, a standard-of-care solution, with comparable physical and mental workloads. This experience raised conceptual and technical limits of the interface, which nevertheless pave the way for further investigations in a partially unexplored field. This study also demonstrates a viable possibility for intuitively interfacing humans with robotic technologies.

Published
2024
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32. An Instrumented Glove for Restoring Sensorimotor Function of the Hand Through Augmented Sensory Feedback.

Author

Vendrame E, Cappello L, Mori T, Baldi R, Controzzi M, and Cipriani C

Subjects
Humans, Male, Adult, Female, Young Adult, Psychomotor Performance physiology, Touch physiology, Vibration, Equipment Design, Pilot Projects, Feedback, Sensory physiology, Hand physiology, Hand Strength physiology, Healthy Volunteers, Wearable Electronic Devices, Feasibility Studies
Abstract

The loss of sensitivity of the upper limb due to neurological injuries severely limits the ability to manipulate objects, hindering personal independence. Non-invasive augmented sensory feedback techniques are used to promote neural plasticity hence to restore the grasping function. This work presents a wearable device for restoring sensorimotor hand functions based on Discrete Event-driven Sensory Control policy. It consists of an instrumented glove that, relying on piezoelectric sensors, delivers short-lasting vibrotactile stimuli synchronously with the relevant mechanical events (i.e., contact and release) of the manipulation. We first performed a feasibility study on healthy participants (20) that showed overall good performances of the device, with touch-event detection accuracy of 96.2% and a response delay of 22 ms. Later, we pilot tested it on two participants with limited sensorimotor functions. When using the device, they improved their hand motor coordination while performing tests for hand motor coordination assessment (i.e., pick and place test, pick and lift test). In particular, they exhibited more coordinated temporal correlations between grip force and load force profiles and enhanced performances when transferring objects, quantitatively proving the effectiveness of the device.

Published
2024
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33. A highly integrated bionic hand with neural control and feedback for use in daily life.

Author

Ortiz-Catalan M, Zbinden J, Millenaar J, D'Accolti D, Controzzi M, Clemente F, Cappello L, Earley EJ, Mastinu E, Kolankowska J, Munoz-Novoa M, Jönsson S, Cipriani C, Sassu P, and Brånemark R

Subjects
Humans, Feedback, Bionics, Titanium, Feedback, Sensory physiology, Electrodes, Implanted, Quality of Life, Robotics
Abstract

Restoration of sensorimotor function after amputation has remained challenging because of the lack of human-machine interfaces that provide reliable control, feedback, and attachment. Here, we present the clinical implementation of a transradial neuromusculoskeletal prosthesis-a bionic hand connected directly to the user's nervous and skeletal systems. In one person with unilateral below-elbow amputation, titanium implants were placed intramedullary in the radius and ulna bones, and electromuscular constructs were created surgically by transferring the severed nerves to free muscle grafts. The native muscles, free muscle grafts, and ulnar nerve were implanted with electrodes. Percutaneous extensions from the titanium implants provided direct skeletal attachment and bidirectional communication between the implanted electrodes and a prosthetic hand. Operation of the bionic hand in daily life resulted in improved prosthetic function, reduced postamputation, and increased quality of life. Sensations elicited via direct neural stimulation were consistently perceived on the phantom hand throughout the study. To date, the patient continues using the prosthesis in daily life. The functionality of conventional artificial limbs is hindered by discomfort and limited and unreliable control. Neuromusculoskeletal interfaces can overcome these hurdles and provide the means for the everyday use of a prosthesis with reliable neural control fixated into the skeleton.

Published
2023
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34. Marine Robotics for Deep-Sea Specimen Collection: A Taxonomy of Underwater Manipulative Actions.

Author

Mazzeo A, Aguzzi J, Calisti M, Canese S, Angiolillo M, Allcock AL, Vecchi F, Stefanni S, and Controzzi M

Subjects
Equipment Design, Hand Strength, Humans, Species Specificity, Specimen Handling, Robotics methods
Abstract

In order to develop a gripping system or control strategy that improves scientific sampling procedures, knowledge of the process and the consequent definition of requirements is fundamental. Nevertheless, factors influencing sampling procedures have not been extensively described, and selected strategies mostly depend on pilots' and researchers' experience. We interviewed 17 researchers and remotely operated vehicle (ROV) technical operators, through a formal questionnaire or in-person interviews, to collect evidence of sampling procedures based on their direct field experience. We methodologically analyzed sampling procedures to extract single basic actions (called atomic manipulations). Available equipment, environment and species-specific features strongly influenced the manipulative choices. We identified a list of functional and technical requirements for the development of novel end-effectors for marine sampling. Our results indicate that the unstructured and highly variable deep-sea environment requires a versatile system, capable of robust interactions with hard surfaces such as pushing or scraping, precise tuning of gripping force for tasks such as pulling delicate organisms away from hard and soft substrates, and rigid holding, as well as a mechanism for rapidly switching among external tools.

Published
2022
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35. Marine Robotics for Deep-Sea Specimen Collection: A Systematic Review of Underwater Grippers.

Author

Mazzeo A, Aguzzi J, Calisti M, Canese S, Vecchi F, Stefanni S, and Controzzi M

Subjects
Equipment Design, Hand Strength, Specimen Handling, Technology, Robotics
Abstract

The collection of delicate deep-sea specimens of biological interest with remotely operated vehicle (ROV) industrial grippers and tools is a long and expensive procedure. Industrial grippers were originally designed for heavy manipulation tasks, while sampling specimens requires dexterity and precision. We describe the grippers and tools commonly used in underwater sampling for scientific purposes, systematically review the state of the art of research in underwater gripping technologies, and identify design trends. We discuss the possibility of executing typical manipulations of sampling procedures with commonly used grippers and research prototypes. Our results indicate that commonly used grippers ensure that the basic actions either of gripping or caging are possible, and their functionality is extended by holding proper tools. Moreover, the approach of the research status seems to have changed its focus in recent years: from the demonstration of the validity of a specific technology (actuation, transmission, sensing) for marine applications, to the solution of specific needs of underwater manipulation. Finally, we summarize the environmental and operational requirements that should be considered in the design of an underwater gripper.

Published
2022
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36. A database of high-density surface electromyogram signals comprising 65 isometric hand gestures.

Author

Malešević N, Olsson A, Sager P, Andersson E, Cipriani C, Controzzi M, Björkman A, and Antfolk C

Subjects
Adult, Artificial Limbs, Electrodes, Female, Forearm physiology, Humans, Isometric Contraction, Male, Middle Aged, Movement physiology, Muscle, Skeletal physiology, Prosthesis Design, Electromyography, Gestures, Hand physiology
Abstract

Control of contemporary, multi-joint prosthetic hands is commonly realized by using electromyographic signals from the muscles remaining after amputation at the forearm level. Although this principle is trying to imitate the natural control structure where muscles control the joints of the hand, in practice, myoelectric control provides only basic hand functions to an amputee using a dexterous prosthesis. This study aims to provide an annotated database of high-density surface electromyographic signals to aid the efforts of designing robust and versatile electromyographic control interfaces for prosthetic hands. The electromyographic signals were recorded using 128 channels within two electrode grids positioned on the forearms of 20 able-bodied volunteers. The participants performed 65 different hand gestures in an isometric manner. The hand movements were strictly timed using an automated recording protocol which also synchronously recorded the electromyographic signals and hand joint forces. To assess the quality of the recorded signals several quantitative assessments were performed, such as frequency content analysis, channel crosstalk, and the detection of poor skin-electrode contacts.

Published
2021
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37. The Grasp Strategy of a Robot Passer Influences Performance and Quality of the Robot-Human Object Handover.

Author

Ortenzi V, Cini F, Pardi T, Marturi N, Stolkin R, Corke P, and Controzzi M

Abstract

Task-aware robotic grasping is critical if robots are to successfully cooperate with humans. The choice of a grasp is multi-faceted; however, the task to perform primes this choice in terms of hand shaping and placement on the object. This grasping strategy is particularly important for a robot companion, as it can potentially hinder the success of the collaboration with humans. In this work, we investigate how different grasping strategies of a robot passer influence the performance and the perceptions of the interaction of a human receiver. Our findings suggest that a grasping strategy that accounts for the subsequent task of the receiver improves substantially the performance of the human receiver in executing the subsequent task. The time to complete the task is reduced by eliminating the need of a post-handover re-adjustment of the object. Furthermore, the human perceptions of the interaction improve when a task-oriented grasping strategy is adopted. The influence of the robotic grasp strategy increases as the constraints induced by the object's affordances become more restrictive. The results of this work can benefit the wider robotics community, with application ranging from industrial to household human-robot interaction for cooperative and collaborative object manipulation., (Copyright © 2020 Ortenzi, Cini, Pardi, Marturi, Stolkin, Corke and Controzzi.)

Published
2020
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38. Neural feedback strategies to improve grasping coordination in neuromusculoskeletal prostheses.

Author

Mastinu E, Engels LF, Clemente F, Dione M, Sassu P, Aszmann O, Brånemark R, Håkansson B, Controzzi M, Wessberg J, Cipriani C, and Ortiz-Catalan M

Subjects
Artificial Limbs, Feedback, Sensory, Humans, Motor Activity, Neuromuscular Diseases rehabilitation, Neuromuscular Diseases surgery, Qualitative Research, Feedback, Physiological, Hand Strength, Prostheses and Implants, Psychomotor Performance
Abstract

Conventional prosthetic arms suffer from poor controllability and lack of sensory feedback. Owing to the absence of tactile sensory information, prosthetic users must rely on incidental visual and auditory cues. In this study, we investigated the effect of providing tactile perception on motor coordination during routine grasping and grasping under uncertainty. Three transhumeral amputees were implanted with an osseointegrated percutaneous implant system for direct skeletal attachment and bidirectional communication with implanted neuromuscular electrodes. This neuromusculoskeletal prosthesis is a novel concept of artificial limb replacement that allows to extract control signals from electrodes implanted on viable muscle tissue, and to stimulate severed afferent nerve fibers to provide somatosensory feedback. Subjects received tactile feedback using three biologically inspired stimulation paradigms while performing a pick and lift test. The grasped object was instrumented to record grasping and lifting forces and its weight was either constant or unexpectedly changed in between trials. The results were also compared to the no-feedback control condition. Our findings confirm, in line with the neuroscientific literature, that somatosensory feedback is necessary for motor coordination during grasping. Our results also indicate that feedback is more relevant under uncertainty, and its effectiveness can be influenced by the selected neuromodulation paradigm and arguably also the prior experience of the prosthesis user.

Published
2020
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39. Hand Control With Invasive Feedback Is Not Impaired by Increased Cognitive Load.

Author

Valle G, D'Anna E, Strauss I, Clemente F, Granata G, Di Iorio R, Controzzi M, Stieglitz T, Rossini PM, Petrini FM, and Micera S

Abstract

Recent experiments have shown that neural stimulation can successfully restore sensory feedback in upper-limb amputees improving their ability to control the prosthesis. However, the potential advantages of invasive sensory feedback with respect to non-invasive solutions have not been yet identified. Our hypothesis was that a difference would appear when the subject cannot focus all the attention to the use of the prosthesis, but some additional activities require his/her cognitive attention, which is a quite common situation in real-life conditions. To verify this hypothesis, we asked a trans-radial amputee, equipped with a bidirectional hand prosthesis, to perform motor tasks also in combination with a cognitive task. Sensory feedback was provided via intraneural (invasive) or electro-tactile (non-invasive) stimulation. We collected also data related to self-confidence. While both approaches were able to significantly improve the motor performance of the subject when no additional cognitive effort was asked, the manual accuracy was not affected by the cognitive task only when intraneural feedback was provided. The highest self-confidence was obtained when intraneural sensory feedback was provided. Our findings show that intraneural sensory feedback is more robust to dual tasks than non-invasive feedback. This is the first direct comparison between invasive and non-invasive approaches for restoring sensory feedback and it could suggest an advantage of using invasive solutions. Clinical Trial Registration: www.ClinicalTrials.gov, identifier NCT02848846., (Copyright © 2020 Valle, D’Anna, Strauss, Clemente, Granata, Di Iorio, Controzzi, Stieglitz, Rossini, Petrini and Micera.)

Published
2020
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40. Grip control and motor coordination with implanted and surface electrodes while grasping with an osseointegrated prosthetic hand.

Author

Mastinu E, Clemente F, Sassu P, Aszmann O, Brånemark R, Håkansson B, Controzzi M, Cipriani C, and Ortiz-Catalan M

Subjects
Amputees, Electromyography instrumentation, Electromyography methods, Feedback, Sensory, Female, Hand Strength, Humans, Male, Reproducibility of Results, Artificial Limbs, Electrodes, Implanted, Psychomotor Performance physiology
Abstract

Background: Replacement of a lost limb by an artificial substitute is not yet ideal. Resolution and coordination of motor control approximating that of a biological limb could dramatically improve the functionality of prosthetic devices, and thus reduce the gap towards a suitable limb replacement., Methods: In this study, we investigated the control resolution and coordination exhibited by subjects with transhumeral amputation who were implanted with epimysial electrodes and an osseointegrated interface that provides bidirectional communication in addition to skeletal attachment (e-OPRA Implant System). We assessed control resolution and coordination in the context of routine and delicate grasping using the Pick and Lift and the Virtual Eggs Tests. Performance when utilizing implanted electrodes was compared with the standard-of-care technology for myoelectric prostheses, namely surface electrodes., Results: Results showed that implanted electrodes provide superior controllability over the prosthetic terminal device compared to conventional surface electrodes. Significant improvements were found in the control of the grip force and its reliability during object transfer. However, these improvements failed to increase motor coordination, and surprisingly decreased the temporal correlation between grip and load forces observed with surface electrodes. We found that despite being more functional and reliable, prosthetic control via implanted electrodes still depended highly on visual feedback., Conclusions: Our findings indicate that incidental sensory feedback (visual, auditory, and osseoperceptive in this case) is insufficient for restoring natural grasp behavior in amputees, and support the idea that supplemental tactile sensory feedback is needed to learn and maintain the motor tasks internal model, which could ultimately restore natural grasp behavior in subjects using prosthetic hands.

Published
2019
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41. Intraneural sensory feedback restores grip force control and motor coordination while using a prosthetic hand.

Author

Clemente F, Valle G, Controzzi M, Strauss I, Iberite F, Stieglitz T, Granata G, Rossini PM, Petrini F, Micera S, and Cipriani C

Subjects
Electric Stimulation Therapy instrumentation, Electric Stimulation Therapy methods, Electrodes, Implanted, Female, Hand, Humans, Longitudinal Studies, Middle Aged, Prosthesis Design instrumentation, Amputees rehabilitation, Artificial Limbs, Feedback, Sensory physiology, Hand Strength physiology, Prosthesis Design methods, Psychomotor Performance physiology
Abstract

Objective: Tactile afferents in the human hand provide fundamental information about hand-environment interactions, which is used by the brain to adapt the motor output to the physical properties of the object being manipulated. A hand amputation disrupts both afferent and efferent pathways from/to the hand, completely invalidating the individual's motor repertoire. Although motor functions may be partially recovered by using a myoelectric prosthesis, providing functionally effective sensory feedback to users of prosthetics is a largely unsolved challenge. While past studies using invasive stimulation suggested that sensory feedback may help in handling fragile objects, none explored the underpinning, relearned, motor coordination during grasping. In this study, we aimed at showing for the first time that intraneural sensory feedback of the grip force (GF) improves the sensorimotor control of a transradial amputee controlling a myoelectric prosthesis., Approach: We performed a longitudinal study testing a single subject (clinical trial registration number NCT02848846). A stacking cups test (CUP) performed over two weeks aimed at measuring the subject's ability to finely regulate the GF applied with the prosthesis. A pick and lift test (PLT), performed at the end of the study, measured the level of motor coordination, and whether the subject transferred the motor skills learned in the CUP to an alien task., Main Results: The results show that intraneural sensory feedback increases the subject's ability in regulating the GF and allows for improved performance over time. Additionally, the PLT demonstrated that the subject was able to generalize and transfer her manipulation skills to an unknown task and to improve her motor coordination., Significance: Our findings suggest that intraneural sensory feedback holds the potential of restoring functionally effective tactile feedback. This opens up new possibilities to improve the quality of life of amputees using a neural prosthesis.

Published
2019
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42. A closed-loop hand prosthesis with simultaneous intraneural tactile and position feedback.

Author

D'Anna E, Valle G, Mazzoni A, Strauss I, Iberite F, Patton J, Petrini FM, Raspopovic S, Granata G, Di Iorio R, Controzzi M, Cipriani C, Stieglitz T, Rossini PM, and Micera S

Abstract

Current myoelectric prostheses allow transradial amputees to regain voluntary motor control of their artificial limb by exploiting residual muscle function in the forearm. However, the overreliance on visual cues resulting from a lack of sensory feedback is a common complaint. Recently, several groups have provided tactile feedback in upper limb amputees using implanted electrodes, surface nerve stimulation, or sensory substitution. These approaches have led to improved function and prosthesis embodiment. Nevertheless, the provided information remains limited to a subset of the rich sensory cues available to healthy individuals. More specifically, proprioception, the sense of limb position and movement, is predominantly absent from current systems. Here, we show that sensory substitution based on intraneural stimulation can deliver position feedback in real time and in conjunction with somatotopic tactile feedback. This approach allowed two transradial amputees to regain high and close-to-natural remapped proprioceptive acuity, with a median joint angle reproduction precision of 9.1° and a median threshold to detection of passive movements of 9.5°, which was comparable with results obtained in healthy participants. The simultaneous delivery of position information and somatotopic tactile feedback allowed both amputees to discriminate the size and compliance of four objects with high levels of performance (75.5%). These results demonstrate that tactile information delivered via somatotopic neural stimulation and position information delivered via sensory substitution can be exploited simultaneously and efficiently by transradial amputees. This study paves a way to more sophisticated bidirectional bionic limbs conveying richer, multimodal sensations., (Copyright © 2019 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published
2019
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43. Six-Month Assessment of a Hand Prosthesis with Intraneural Tactile Feedback.

Author

Petrini FM, Valle G, Strauss I, Granata G, Di Iorio R, D'Anna E, Čvančara P, Mueller M, Carpaneto J, Clemente F, Controzzi M, Bisoni L, Carboni C, Barbaro M, Iodice F, Andreu D, Hiairrassary A, Divoux JL, Cipriani C, Guiraud D, Raffo L, Fernandez E, Stieglitz T, Raspopovic S, Rossini PM, and Micera S

Subjects
Adult, Amputation, Traumatic physiopathology, Female, Hand innervation, Humans, Male, Middle Aged, Time Factors, Amputation, Traumatic rehabilitation, Artificial Limbs, Feedback, Sensory physiology, Hand physiology, Implantable Neurostimulators, Touch physiology
Abstract

Objective: Hand amputation is a highly disabling event, which significantly affects quality of life. An effective hand replacement can be achieved if the user, in addition to motor functions, is provided with the sensations that are naturally perceived while grasping and moving. Intraneural peripheral electrodes have shown promising results toward the restoration of the sense of touch. However, the long-term usability and clinical relevance of intraneural sensory feedback have not yet been clearly demonstrated., Methods: To this aim, we performed a 6-month clinical study with 3 transradial amputees who received implants of transverse intrafascicular multichannel electrodes (TIMEs) in their median and ulnar nerves. After calibration, electrical stimulation was delivered through the TIMEs connected to artificial sensors in the digits of a prosthesis to generate sensory feedback, which was then used by the subjects while performing different grasping tasks., Results: All subjects, notwithstanding their important clinical differences, reported stimulation-induced sensations from the phantom hand for the whole duration of the trial. They also successfully integrated the sensory feedback into their motor control strategies while performing experimental tests simulating tasks of real life (with and without the support of vision). Finally, they reported a decrement of their phantom limb pain and a general improvement in mood state., Interpretation: The promising results achieved with all subjects show the feasibility of the use of intraneural stimulation in clinical settings. ANN NEUROL 2019;85:137-154., (© 2018 American Neurological Association.)

Published
2019
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44. Restoring Natural Forearm Rotation in Transradial Osseointegrated Amputees.

Author

Boni I, Millenaar J, Controzzi M, and Ortiz-Catalan M

Subjects
Adult, Biomechanical Phenomena, Humans, Male, Prosthesis Design, Psychomotor Performance, Radius, Range of Motion, Articular, Rotation, Supination, Ulna, Amputation, Surgical rehabilitation, Amputees rehabilitation, Forearm, Osseointegration
Abstract

Osseointegrated transradial prostheses have the potential to preserve the natural range of wrist rotation, which improves the performance of activities of daily living and reduces compensatory movements that potentially lead to secondary health problems over time. This is possible by enabling the radius and the ulna bone to move with respect to each other, restoring the functionality of the original distal-radioulnar joint. In this paper, we report on psychophysics tests performed on an osseointegrated transradial amputee with the aim to understand the extent of mobility of the implants that is required to preserve the natural forearm rotation. Based on these experiments, we designed and developed an attachment device between the implants and the hand prosthesis that serves as an artificial distal radio-ulnar joint. This device was fitted on an osseointegrated transradial amputee and its functionality assessed by means of the Southampton Hand Assessment Procedure (SHAP) and the Minnesota Manual Dexterity test (MMDT). We found that the axial rotation of the implants is required to preserve forearm rotation, to distribute loads equally over the two implants (60% radius - 40% ulna), and to enable loading of the implants without unpleasant feelings for the patient. Higher function was recorded when our attachment device enabled forearm rotation: SHAP from 61 to 71, MMDT from 258s to 231s. Natural forearm rotation can be successfully restored in transradial amputees by using osseointegration and our novel mechanical attachment to the hand prosthesis.

Published
2018
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45. Humans adjust their grip force when passing an object according to the observed speed of the partner's reaching out movement.

Author

Controzzi M, Singh H, Cini F, Cecchini T, Wing A, and Cipriani C

Subjects
Adult, Algorithms, Feedback, Sensory physiology, Female, Humans, Male, Psychomotor Performance physiology, Robotics, Young Adult, Biomechanical Phenomena physiology, Hand Strength physiology, Social Perception
Abstract

The way an object is released by the passer to a partner is fundamental for the success of the handover and for the experienced fluency and quality of the interaction. Nonetheless, although its apparent simplicity, object handover involves a complex combination of predictive and reactive control mechanisms that were not fully investigated so far. Here, we show that passers use visual-feedback based anticipatory control to trigger the beginning of the release, to launch the appropriate motor program, and adapt such predictions to different speeds of the receiver's reaching out movements. In particular, the passer starts releasing the object in synchrony with the collision with the receiver, regardless of the receiver's speed, but the passer's speed of grip force release is correlated with receiver speed. When visual feedback is removed, the beginning of the passer's release is delayed proportionally with the receiver's reaching out speed; however, the correlation between the passer's peak rate of change of grip force is maintained. In a second study with 11 participants receiving an object from a robotic hand programmed to release following stereotypical biomimetic profiles, we found that handovers are experienced as more fluent when they exhibit more reactive release behaviours, shorter release durations, and shorter handover durations. The outcomes from the two studies contribute understanding of the roles of sensory input in the strategy that empower humans to perform smooth and safe handovers, and they suggest methods for programming controllers that would enable artificial hands to hand over objects with humans in an easy, natural and efficient way.

Published
2018
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46. Biomimetic Intraneural Sensory Feedback Enhances Sensation Naturalness, Tactile Sensitivity, and Manual Dexterity in a Bidirectional Prosthesis.

Author

Valle G, Mazzoni A, Iberite F, D'Anna E, Strauss I, Granata G, Controzzi M, Clemente F, Rognini G, Cipriani C, Stieglitz T, Petrini FM, Rossini PM, and Micera S

Subjects
Amputees, Electrodes, Implanted, Feedback, Sensory physiology, Female, Hand Strength physiology, Humans, Male, Phantom Limb prevention & control, Proprioception physiology, Touch physiology, Artificial Limbs, Electric Stimulation Therapy methods, Models, Neurological
Abstract

Peripheral intraneural stimulation can provide tactile information to amputees. However, efforts are still necessary to identify encoding strategy eliciting percepts that are felt as both natural and effective for prosthesis control. Here we compared the naturalness and efficacy of different encoding strategies to deliver neural stimulation to trans-radial amputees implanted with intraneural electrodes. Biomimetic frequency modulation was perceived as more natural, while amplitude modulation enabled better performance in tasks requiring fine identification of the applied force. Notably, the optimal combination of naturalness and sensitivity of the tactile feedback can be achieved with "hybrid" encoding strategies based on simultaneous biomimetic frequency and amplitude neuromodulation. These strategies improved the gross manual dexterity of the subjects during functional task while maintaining high levels of manual accuracy. They also improved prosthesis embodiment, reducing abnormal phantom limb perceptions ("telescoping effect"). Hybrid strategies are able to provide highly sensitive and natural percepts and should be preferred. VIDEO ABSTRACT., (Copyright © 2018 Elsevier Inc. All rights reserved.)

Published
2018
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47. Improving internal model strength and performance of prosthetic hands using augmented feedback.

Author

Shehata AW, Engels LF, Controzzi M, Cipriani C, Scheme EJ, and Sensinger JW

Subjects
Adult, Electromyography methods, Female, Hand physiopathology, Hand Strength physiology, Humans, Male, Artificial Limbs, Exoskeleton Device, Feedback, Sensory physiology, Robotics methods, Support Vector Machine
Abstract

Background: The loss of an arm presents a substantial challenge for upper limb amputees when performing activities of daily living. Myoelectric prosthetic devices partially replace lost hand functions; however, lack of sensory feedback and strong understanding of the myoelectric control system prevent prosthesis users from interacting with their environment effectively. Although most research in augmented sensory feedback has focused on real-time regulation, sensory feedback is also essential for enabling the development and correction of internal models, which in turn are used for planning movements and reacting to control variability faster than otherwise possible in the presence of sensory delays., Methods: Our recent work has demonstrated that audio-augmented feedback can improve both performance and internal model strength for an abstract target acquisition task. Here we use this concept in controlling a robotic hand, which has inherent dynamics and variability, and apply it to a more functional grasp-and-lift task. We assessed internal model strength using psychophysical tests and used an instrumented Virtual Egg to assess performance., Results: Results obtained from 14 able-bodied subjects show that a classifier-based controller augmented with audio feedback enabled stronger internal model (p = 0.018) and better performance (p = 0.028) than a controller without this feedback., Conclusions: We extended our previous work and accomplished the first steps on a path towards bridging the gap between research and clinical usability of a hand prosthesis. The main goal was to assess whether the ability to decouple internal model strength and motion variability using the continuous audio-augmented feedback extended to real-world use, where the inherent mechanical variability and dynamics in the mechanisms may contribute to a more complicated interplay between internal model formation and motion variability. We concluded that benefits of using audio-augmented feedback for improving internal model strength of myoelectric controllers extend beyond a virtual target acquisition task to include control of a prosthetic hand.

Published
2018
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48. Compliant Prosthetic Wrists Entail More Natural Use Than Stiff Wrists During Reaching, Not (Necessarily) During Manipulation.

Author

Kanitz G, Montagnani F, Controzzi M, and Cipriani C

Subjects
Activities of Daily Living, Adult, Algorithms, Biomechanical Phenomena, Electromyography, Healthy Volunteers, Humans, Male, Middle Aged, Orthotic Devices, Prosthesis Design, Shoulder, Torso, Young Adult, Artificial Limbs, Prostheses and Implants, Wrist
Abstract

Developing an artificial arm with functions equivalent to those of the human arm is one of the challenging goals of bioengineering. State-of-the-artprostheses lack several degrees of freedom and force the individuals to compensate for them by means of compensatory movements, which often result in residual limb pain and overuse syndromes. Passive wristsmay reduce such compensatory actions, nonethelessto date their actual efficacy, associated to conventional myoelectric hands is a matter of debate. We hypothesized that a transradial prosthesiswould allow a simpler operation if its wrist behaved compliant during the reaching and grasping phase, and stiff during the holding andmanipulation phase. To assess this, we compared a stiff and a compliant wrist and evaluating the extent of compensatory movements in the trunk and shoulder, with unimpaired subjects wearing orthoses, while performing nine activities of daily living taken from the southampton hand assessment procedure. Our findings show indeed that the optimal compliance for a prosthetic wrist is specific to the phase of the motor task: the compliant wrist outperforms the stiff wrist during the reaching phase, whereas the stiff wrist exhibits more natural movements during the manipulation phase of heavy objects. Hence, this paper invites rehabilitation engineers to develop wrists with switchable compliance.

Published
2018
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49. Electro-cutaneous stimulation on the palm elicits referred sensations on intact but not on amputated digits.

Author

D' Alonzo M, Engels LF, Controzzi M, and Cipriani C

Subjects
Adult, Amputation Stumps innervation, Electric Stimulation methods, Electrodes, Female, Fingers innervation, Fingers physiology, Hand innervation, Humans, Male, Phantom Limb diagnosis, Amputation Stumps physiopathology, Feedback, Sensory physiology, Hand physiology, Phantom Limb physiopathology, Touch physiology
Abstract

Objective: Grasping and manipulation control critically depends on tactile feedback. Without this feedback, the ability for fine control of a prosthesis is limited in upper limb amputees. Early studies have shown that non-invasive electro-cutaneous stimulation (ES) can induce referred sensations that are spread to a wider and/or more distant area, with respect to the electrodes. Building on this, we sought to exploit this effect to provide somatotopically matched sensory feedback to people with partial hand (digital) amputations., Approach: For the first time, this work investigated the possibility of inducing referred sensations in the digits by activating the palmar nerves. Specifically, we electrically stimulated 18 sites on the palm of non-amputees to evaluate the effects of sites and stimulation parameters on modality, magnitude, and location of the evoked sensations. We performed similar tests with partial hand amputees by testing those sites that had most consistently elicited referred sensations in non-amputees., Main Results: We demonstrated referred sensations in non-amputees from all stimulation sites in one form or another. Specifically, the stimulation of 16 of the 18 sites gave rise to reliable referred sensations. Amputees experienced referred sensations to unimpaired digits, just like non-amputees, but we were unable to evoke referred sensations in their missing digits: none of them reported sensations that extended beyond the tip of the stump., Significance: The possibility of eliciting referred sensations on the digits may be exploited in haptic systems for providing touch sensations without obstructing the fingertips or their movements. The study also suggests that the phenomenon of referred sensations through ES may not be exploited for partial hand prostheses, and it invites researchers to explore alternative approaches. Finally, the results seem to confirm previous studies suggesting that the stumps in partial hand amputees partially acquire the role of the missing fingertips, physiologically and cognitively.

Published
2018
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50. Corrections to "Treatment of the Partial Hand Amputation: An Engineering Perspective".

Author

Imbinto I, Peccia C, Controzzi M, Cutti AG, Davalli A, Sacchetti R, and Cipriani C

Abstract

In the above paper, by Imbinto et al. (IEEE Rev. Biomed. Eng., vol. 9, pp. 32-48, 2016), typographical errors appear in (1) (2) (3), whereas (4) is missing of a factor; all the equations are reported within Section III-C of the paper. The modifications are provided in this paper.

Published
2018
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