A Review of Smart Materials in Tactile Actuators for Information Delivery

As the largest organ in the human body, the skin provides the important sensory channel for humans to receive external stimulations based on touch. By the information perceived through touch, people can feel and guess the properties of objects, like weight, temperature, textures, and motion, etc. In fact, those properties are nerve stimuli to our brain received by different kinds of receptors in the skin. Mechanical, electrical, and thermal stimuli can stimulate these receptors and cause different information to be conveyed through the nerves. Technologies for actuators to provide mechanical, electrical or thermal stimuli have been developed. These include static or vibrational actuation, electrostatic stimulation, focused ultrasound, and more. Smart materials, such as piezoelectric materials, carbon nanotubes, and shape memory alloys, play important roles in providing actuation for tactile sensation. This paper aims to review the background biological knowledge of human tactile sensing, to give an understanding of how we sense and interact with the world through the sense of touch, as well as the conventional and state-of-the-art technologies of tactile actuators for tactile feedback delivery

Electrocutaneous stimulation to close the loop in myoelectric prosthesis control

Current commercially available prosthetic systems still lack sensory feedback and amputees are forced to maintain eye-contact with the prosthesis when interacting with their environment. Electrocutaneous stimulation is a promising approach to convey sensory feedback via the skin. However, when discussed in the context of prosthetic applications, it is often refused due to its supposed incompatibility with myocontrol. This dissertation now addresses electrocutaneous stimulation as means to provide sensory feedback to prosthesis users, and its implications on myoelectric control, possible use for improved or accelerated mastering of prosthesis control through closing of the control loop, as well as its potential in aiding in the embodiment of prosthetic components. First, a comparison of different paradigms for encoding sensory feedback variables in electrocutaneous stimulation patterns was done. For this, subject ability to employ spatially and intensity-coded electrocutaneous feedback in a simulated closed-loop control task was evaluated. The task was to stabilise an invisible virtual inverted pendulum under ideal feedforward control conditions (joystick). Pendulum inclination was either presented spatially (12 stimulation sites), encoded by stimulation strength (≧ 2 stimulation sites), or a combination of the two. The tests indicated that spatial encoding was perceived as more intuitive, but intensity encoding yielded better performance and lower energy expenditure. The second study investigated the detrimental influence of stimulation artefacts on myoelectric control of prostheses for a wide range of stimulation parameters and two prosthesis control approaches (pattern recognition of eight motion primitives, direct proportional control). Artefact blanking is introduced and discussed as a practical approach to handle stimulation artefacts and restore control performance back to the baseline. This was shown with virtual and applied artefact blanking (pattern recognition on six electromyographic channels), as well as in a practical task-related test with a real prosthesis (proportional control). The information transfer of sensory feedback necessary to master a routine grasping task using electromyographic control of a prosthesis was investigated in another study. Subjects controlled a real prosthesis to repeatedly grasp a dummy object, which implemented two different objects with previously unknown slip and fragility properties. Three feedback conditions (basic feedback on grasp success, visual grasp force feedback, tactile grasp force feedback) were compared with regard to their influence on subjects’ task performance and variability in exerted grasp force. It was found that online force feedback via a visual or tactile channel did not add significant advantages, and that basic feedback was sufficient and was employed by subjects to improve both performance and force variability with time. Importantly, there was no adverse effect of the additional feedback, either. This has important implications for other non-functional applications of sensory feedback, such as facilitation of embodiment of prosthetic devices. The final study investigated the impact of electrocutaneous stimulation on embodiment of an artificial limb. For this purpose, a sensor finger was employed in a rubber-hand-illusion-like experiment. Two independent groups (test, control), were compared with regard to two objective measures of embodiment: proprioceptive drift, and change in skin temperature. Though proprioceptive drift measures did not reveal differences between conditions, they indicated trends generally associated to a successful illusion. Additionally, significant changes in skin temperature between test and control group indicated that embodiment of the artificial digit could be induced by providing sensory substitution feedback on the forearm. In conclusion, it has been shown that humans can employ electrocutaneous stimulation feedback in challenging closed-loop control tasks. It was found that transition from simple intuitive encodings (spatial) to those providing better resolution (intensity) further improves feedback exploitation. Blanking and segmentation approaches facilitate simultaneous application of electrocutaneous stimulation and electromyographic control of prostheses, using both pattern recognition and classic proportional approaches. While it was found that force feedback may not aid in the mastering of routine grasping, the presence of the feedback was also found to not impede the user performance. This is an important implication for the application of feedback for non-functional purposes, such as facilitation of embodiment. Regarding this, it was shown that providing sensory feedback via electrocutaneous stimulation did indeed promote embodiment of an artificial finger, even if the feedback was applied to the forearm. Based on the results of this work, the next step should be integration of sensory feedback into commercial devices, so that all amputees can benefit from its advantages. Electrocutaneous stimulation has been shown to be an ideal means for realising this. Hitherto existing concerns about the compatibility of electrocutaneous stimulation and myocontrol could be resolved by presenting appropriate methods to deal with stimulation artefacts

Electrotactile feedback applications for hand and arm interactions: A systematic review, meta-analysis, and future directions

Haptic feedback is critical in a broad range of human-machine/computer-interaction applications. However, the high cost and low portability/wearability of haptic devices remain unresolved issues, severely limiting the adoption of this otherwise promising technology. Electrotactile interfaces have the advantage of being more portable and wearable due to their reduced actuators' size, as well as their lower power consumption and manufacturing cost. The applications of electrotactile feedback have been explored in human-computer interaction and human-machine-interaction for facilitating hand-based interactions in applications such as prosthetics, virtual reality, robotic teleoperation, surface haptics, portable devices, and rehabilitation. This paper presents a technological overview of electrotactile feedback, as well a systematic review and meta-analysis of its applications for hand-based interactions. We discuss the different electrotactile systems according to the type of application. We also discuss over a quantitative congregation of the findings, to offer a high-level overview into the state-of-art and suggest future directions. Electrotactile feedback systems showed increased portability/wearability, and they were successful in rendering and/or augmenting most tactile sensations, eliciting perceptual processes, and improving performance in many scenarios. However, knowledge gaps (e.g., embodiment), technical (e.g., recurrent calibration, electrodes' durability) and methodological (e.g., sample size) drawbacks were detected, which should be addressed in future studies.Comment: 18 pages, 1 table, 8 figures, under review in Transactions on Haptics. This work has been submitted to the IEEE for possible publication. Copyright may be transferred without notice, after which this version may no longer be accessible.Upon acceptance of the article by IEEE, the preprint article will be replaced with the accepted versio

The temporal pattern of impulses in primary afferents analogously encodes touch and hearing information

An open question in neuroscience is the contribution of temporal relations between individual impulses in primary afferents in conveying sensory information. We investigated this question in touch and hearing, while looking for any shared coding scheme. In both systems, we artificially induced temporally diverse afferent impulse trains and probed the evoked perceptions in human subjects using psychophysical techniques. First, we investigated whether the temporal structure of a fixed number of impulses conveys information about the magnitude of tactile intensity. We found that clustering the impulses into periodic bursts elicited graded increases of intensity as a function of burst impulse count, even though fewer afferents were recruited throughout the longer bursts. The interval between successive bursts of peripheral neural activity (the burst-gap) has been demonstrated in our lab to be the most prominent temporal feature for coding skin vibration frequency, as opposed to either spike rate or periodicity. Given the similarities between tactile and auditory systems, second, we explored the auditory system for an equivalent neural coding strategy. By using brief acoustic pulses, we showed that the burst-gap is a shared temporal code for pitch perception between the modalities. Following this evidence of parallels in temporal frequency processing, we next assessed the perceptual frequency equivalence between the two modalities using auditory and tactile pulse stimuli of simple and complex temporal features in cross-sensory frequency discrimination experiments. Identical temporal stimulation patterns in tactile and auditory afferents produced equivalent perceived frequencies, suggesting an analogous temporal frequency computation mechanism. The new insights into encoding tactile intensity through clustering of fixed charge electric pulses into bursts suggest a novel approach to convey varying contact forces to neural interface users, requiring no modulation of either stimulation current or base pulse frequency. Increasing control of the temporal patterning of pulses in cochlear implant users might improve pitch perception and speech comprehension. The perceptual correspondence between touch and hearing not only suggests the possibility of establishing cross-modal comparison standards for robust psychophysical investigations, but also supports the plausibility of cross-sensory substitution devices

Evaluation of sensitivity, motor and pain thresholds across the menstrual cycle through medium-frequency transcutaneous electrical nerve stimulation

OBJECTIVES: The aim of this study was to identify variations in nervous thresholds in different phases of the menstrual cycle in eumenorrheic women and users of oral contraceptives. METHOD: An observational study was performed including 56 volunteers, consisting of 30 eumenorrheic women who were non-users of oral contraceptives and 26 users of oral contraceptives. An electrical stimulator was employed to assess their nervous thresholds, with pulses applied at a fixed frequency of 2,500 Hz, modulated at 50 Hz, with phase variances of 20 μs, 50 μs and 100 μs. Sensitivity, motor and pain thresholds were evaluated during five menstrual cycle phases: phase 1 - menstrual, phase 2 - follicular, phase 3 - ovulatory, phase 4 - luteal and phase 5 - premenstrual. RESULTS: The results indicated low sensitivity thresholds of 100 μs for non-users of oral contraceptives and 50 μs for oral contraceptive users in phase 5. Low motor thresholds of 20 μs, 50 μs and 100 μs were observed for non-users of oral contraceptives in phase 5, while that of oral contraceptive users was 100 μs. Finally, a low pain threshold of 100 μs was observed in phase 5, but only in the oral contraceptive group. CONCLUSION: Nervous thresholds vary systematically across the phases of the menstrual cycle, with or without the use of oral contraceptives. These variations should be taken into account during research performed in women

Encoding tactile frequency and intensity information in the temporal pattern of afferent nerve impulses

Using our hands to interact with the world around us produces complex vibrations travelling across the skin. These complex waves are transduced by tactile afferent neurons whose impulse patterns convey information about the external world. A major question in this field is how important the timing of these afferent impulses is in shaping perception. We have the means to investigate this question by artificially inducing impulse patterns using brief mechanical and electrical stimuli, allowing us to study the neural coding of vibrotactile sensory information. Our lab has used this to show that when mechanical pulses evoked impulse trains grouped into periodic bursts, perceived frequency corresponded to the duration of the silent inter-burst gap interval, rather than the periodicity or the mean impulse rate. In this thesis, we induced controlled impulse trains, while measuring the perceptual responses of human subjects using psychophysical methods to assess the dimensions of frequency and intensity. As electrical stimulation has broad utility in prosthetic applications, we first verified that the same perceived frequency as predicted by the burst gap was elicited with electrical pulses in subjects within the low frequency flutter range. We then tested whether this same coding mechanism also applied outside the flutter frequency range by conducting further experiments with higher pulse rates. We found that burst gap coding correctly predicted perceived frequencies above flutter, suggesting a generalised temporal processing strategy that operates on tactile afferent inputs spanning a broad range of frequencies. Next, we investigated perceived intensity where stimulus pulse rate was varied without changes in afferent population recruitment or in perceived frequency by using bursts of pulsatile stimuli. Increasing the number of pulses within a burst caused a significant increase in perceived intensity when electrical stimulation was used. Mechanical pulses with the same burst groupings did not produce a comparable intensity increase, possibly due to minimal variations in the population firing rate. These new insights into the encoding of tactile information through temporal patterning in peripheral impulse patterns may allow the multiplexing of frequency and intensity sensations with a fixed stimulation amplitude for use in neural interfaces to deliver sensory feedback information

Engineering data compendium. Human perception and performance. User's guide

The concept underlying the Engineering Data Compendium was the product of a research and development program (Integrated Perceptual Information for Designers project) aimed at facilitating the application of basic research findings in human performance to the design and military crew systems. The principal objective was to develop a workable strategy for: (1) identifying and distilling information of potential value to system design from the existing research literature, and (2) presenting this technical information in a way that would aid its accessibility, interpretability, and applicability by systems designers. The present four volumes of the Engineering Data Compendium represent the first implementation of this strategy. This is the first volume, the User's Guide, containing a description of the program and instructions for its use

Estudio de modelos propuestos para el nervio mediano sano y con síndrome de túnel carpiano : Study of proposed models for the healthy median nerve and with carpal tunnel syndrome

En este documento se muestra de forma detallada la revisión de modelos teóricos  para el nervio mediano, observando el estado de un nervio con mielina y  sin mielina, con las variables que cada autor genera para profundizar en los análisis que exponen, para de esta forma entrar a detallar los parámetros más relevantes que se observan en la literatura con las causas probables de la generación del síndrome del túnel carpiano en la sociedad laboral, de igual forma se muestra de forma resumida la parte anatómica que recorre el nervio mediano, para finalmente concluir que los parámetros de mayor relevancia son la frecuencia por los efectos capacitivos, la intensidad de corriente, la duración, latencia y velocidad de conducción. Trabajo realizado en el grupo de investigación LIDER de la Universidad Distrital Francisco José de Caldas. &nbsp

Design and development of new tactile softness displays for minimally invasive surgery

Despite an influential shortcoming of minimally invasive sugary (MIS), which is the lack of tactile feedback to the surgeon, MIS has increasingly been used in various types of surgeries. Restoring the missing tactile feedback, especially information which can be obtained by the palpation of tissue, such as detection of embedded lump and softness characterization is important in MIS. The present study aims to develop tactile feedback systems both graphically and physically. In graphical rendering approach, the proposed system receives signals from the previously fabricated piezoelectric softness sensors which are integrated with an MIS grasper. After processing the signals, the tactile information is displayed by means of a color coding method. Using the graphical images, the softness of the grasped objects can visually be differentiated. A physical tactile display system is also designed and fabricated. This system simulates non-linear material properties of different soft objects. The system consists of a linear actuator, force and position sensors and processing software. A PID controller is used to control the motion of a linear actuator according to the properties of the simulated material and applied force. Graphical method was also examined to render the tactile information of embedded lumps within a soft tissue/object. The necessary information on the size and location of the hidden features are collected using sensorized MIS graspers. The information is then processed and graphically rendered to the surgeon. Using the proposed system surgeons can identify presence, location and approximate size of hidden lumps by grasping the target object with a reasonable accuracy. Finally, in order to determine the softness of the grasped object, another novel approach is taken by the design and fabrication of a smart endoscopic tool equipped with sensors for measuring the applied force and the angle of the grasper jaws. Using this method, the softness/compliance of the grasped object can be estimated and presented to the surgeo