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Roles of glabrous skin receptors and sensorimotor memory in automatic control of precision grip when lifting rougher or more slippery objects (1984)

Johansson, R. S. ; Westling, G.

Springer

Experimental brain research 56 (1984), S. 550-564

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ISSN: 1432-1106

Keywords: Precision grip ; Motor control ; Human hand ; Sensory input ; Cutaneous mechanoreceptors ; Sensori-motor memory

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary To be successful, precision manipulation of small objects requires a refined coordination of forces excerted on the object by the tips of the fingers and thumb. The present paper deals quantitatively with the regulation of the coordination between the grip force and the vertical lifting force, denoted as the load force, while small objects were lifted, positioned in space and replaced by human subjects using the pinch grip. It was shown that the grip force changed in parallel with the load force generated by the subject to overcome various forces counteracting the intended manipulation. The balance between the two forces was adapted to the friction between the skin and the object providing a relatively small safety margin to prevent slips, i.e. the more slippery the object the higher the grip force at any given load force. Experiments with local anaesthesia indicated that this adaptation was dependent on cutaneous afferent input. Afferent information related to the frictional condition could influence the force coordination already about 0.1 s after the object was initially gripped, i.e. approximately at the time the grip and load forces began to increase in parallel. Further, “secondary”, adjustments of the force balance could occur later in response to small short-lasting slips, revealed as vibrations in the object. The new force balance following slips was maintained, indicating that the relationship between the two forces was set on the basis of a memory trace. Its updating was most likely accounted for by tactile afferent information entering intermittently at inappropriate force coordination, e.g. as during slips. The latencies between the onset of such slips and the appearance of the adjustments (0.06–0.08 s) clearly indicated that the underlying neural mechanisms operated highly automatically.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00237997

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2

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Development of human precision grip I: Basic coordination of force (1991)

Forssberg, H. ; Eliasson, A. C. ; Kinoshita, H. ; [et al.]

Springer

Experimental brain research 85 (1991), S. 451-457

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ISSN: 1432-1106

Keywords: Motor development ; Precision grip ; Motor programming ; Human hand

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary The coordination of manipulative forces was examined while children and adults repeatedly lifted a small object between the thumb and index finger. Grip force, load force (vertical lifting force), grip force rate and the vertical position of the test object were continuously measured. In adults, the force generation was highly automatized and was nearly invariant between trials. After a preload phase in which the grip was established, the grip and load forces increased in parallel under isometric conditions until the load force overcame the force of gravity and the object started to move. During this loading phase, the force rate profiles were essentially bell shaped and single peaked, suggesting that the force increases were programmed as one coordinated event. Children below the age of two exhibited a prolonged preload phase and a loading phase during which the grip and load forces did not increase in parallel. A major increase in grip force preceded the increase in load force, and at the start of the loading phase, the grip force was usually several Newtons (N). The force rate profiles were multi peaked with step-wise force increases most likely allowing peripheral feedback to play an important role in the control of the forces. After the age of two, the grip force increased less during the preload phase. The loading phase was more regularly characterized by a parallel increase of the grip force and load force and the duration of the various phases decreased. The older children programmed the forces in one force rate pulse indicating the emergence of an anticipatory strategy. Yet, the mature coordination of forces was not fully developed until several years later. It was concluded that the development of the precision grip was based upon the formation of a lift synergy coupling grip and load force generating circuits and that it seems to involve a transition from feedback control to feedforward control.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00229422

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3

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Responses in glabrous skin mechanoreceptors during precision grip in humans (1987)

Westling, G. ; Johansson, R. S.

Springer

Experimental brain research 66 (1987), S. 128-140

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ISSN: 1432-1106

Keywords: Precision grip ; Motor control ; Human hand ; Cutaneous mechanoreceptors ; Tactile sensibility

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary Impulses in single tactile units innervating the human glabrous skin were recorded percutaneously from the median nerve using tungsten electrodes. The units were classified as belonging to one of the four categories: fast adapting with small receptive fields (FA I), fast adapting with large receptive fields (FA II), slowly adapting with small fields (SA I), and slowly adapting with large fields (SA II). A small test object was lifted, positioned in space and replaced using the precision grip between fingers and thumb. The grip force, the load force (vertical lifting force), the vertical movements of the object and vibrations (accelerations) in the object were recorded. After being virtually silent between lifts, the FA I units whose fields contacted the object became highly active during the initial period of grip force increase (initial response). This was also true for most SA I units. Accordingly, most of the skin deformation changes took place at low grip forces (below ca. 1 N). Later, while the load and grip forces increased in parallel during isometric conditions, the FA I and SA I units continued firing but generally at declining impulse rates. As long as the object was held in the air, the SA I units generally maintained firing with a tendency to adaptation. A minority of the FA I unit also discharged, especially during periods of pronounced physiological muscle tremor. The SA I units usually became silent when the grip and load forces in parallel declined to zero during isometric conditions after the object had contacted the table. However, during the very release of the grip the FA I units and some SA I units showed brief burst discharges (release response). The FA II units responded distinctly to the mechanical transients associated with the start of the vertical movement and especially with the sudden cessation of movement at the terminal table contact. FA II units whose end organs were remotely located in relation to the skin areas in contact with the object also responded. Most FA II units also discharged at the initial touch and at the release of the object, albeit less reliably than the type I units. In addition to weak dynamic responses during the phase of isometric force increase, the SA II units showed comparatively strong tonic responses while the object was held during static conditions. High firing rates also were maintained during long-lasting lifts. Moreover, it was established that the signals in SA II afferents were related to the three dimensional force profile in the grip. The results are discussed with regard to the possible implications for the control of precise manipulative movements.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00236209

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Mechanoreceptor activity from the human face and oral mucosa (1988)

Johansson, R. S. ; Trulsson, M. ; Olsson, K. Å. ; [et al.]

Springer

Experimental brain research 72 (1988), S. 204-208

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ISSN: 1432-1106

Keywords: Mechanoreceptors ; Man ; Face ; Infraorbital nerve ; Microneurography ; Trigeminal nerve ; Tactile sensibility ; Cutaneous sensibility ; Oral mucosa

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary The feasibility of adopting the microneurography technique (Vallbo and Hagbarth 1968) as a tool to investigate the mechanoreceptive innervation of peri- and intra-oral tissues was explored. Multi-unit activity and impulses in single nerve fibers were recorded from the infraorbital nerve in healthy volunteers. The innervation territories of individual nerve fascicles were mapped. These varied considerably but most fascicle fields comprised the corner of the mouth. Twenty-four single mechanoreceptive units were recorded. Eighteen innervated the skin of the face, and six innervated the mucous membranes of the lips or cheeks. A majority of the mechanoreceptive afferent units were slowly adapting with small and well defined receptive fields. It is suggested that the various slowly adapting responses may originate from two different types of afferent units. No afferents showed response properties similar to typical Pacinian-corpuscle afferents.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00248518

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5

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Coordinated isometric muscle commands adequately and erroneously programmed for the weight during lifting task with precision grip (1988)

Johansson, R. S. ; Westling, G.

Springer

Experimental brain research 71 (1988), S. 59-71

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ISSN: 1432-1106

Keywords: Precision grip ; Motor control ; Human hand ; Somatosensory input ; Long latency reflexes ; Motor programs ; Sensorimotor memory ; Mechanoreceptors

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary Small objects were lifted from a table, held in the air, and replaced using the precision grip between the index finger and thumb. The adaptation of motor commands to variations in the object's weight and sensori-motor mechanisms responsible for optimum performance of the transition between the various phases of the task were examined. The lifting movement involved mainly a flexion of the elbow joint. The grip force, the load force (vertical lifting force) and the vertical position were measured. Electromyographic activity (e.m.g.) was recorded from four antagonist pairs of hand/arm muscles primarily influencing the grip force or the load force. In the lifting series with constant weight, the force development was adequately programmed for the current weight during the loading phase (i.e. the phase of parallel increase in the load and grip forces during isometric conditions before the lift-off). The grip and load force rate trajectories were mainly single-peaked, bell-shaped and roughly proportional to the final force. In the lifting series with unexpected weight changes between lifts, it was established that these force rate profiles were programmed on the basis of the previous weight. Consequently, with lifts programmed for a lighter weight the object did not move at the end of the continuous force increase. Then the forces increased in a discontinous fashion until the force of gravity was overcome. With lifts programmed for a heavier weight, the high load and grip force rates at the moment the load force overcame the force of gravity caused a pronounced positional overshoot and a high grip force peak, respectively. In these conditions the erroneous programmed commands were automatically terminated by somatosensory signals elicited by the start of the movement. A similar triggering by somatosensory information applied to the release of programmed motor commands accounting for the unloading phase (i.e. the parallel decrease in the grip and load forces after the object contacted the table following its replacement). These commands were always adequately programmed for the weight.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00247522

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6

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Programmed and triggered actions to rapid load changes during precision grip (1988)

Johansson, R. S. ; Westling, G.

Springer

Experimental brain research 71 (1988), S. 72-86

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ISSN: 1432-1106

Keywords: Precision grip ; Motor control ; Human hand ; Somatosensory input ; Long-latency reactions ; Anticipatory mechanisms ; Sensori-motor memory

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary A test object (grip apparatus) was held at its upper part using a precision grip. Small balls were dropped into a target cup at the bottom of the apparatus. The grip force, the load force (vertical lifting force) and the vertical movement were measured. Electromyographic activity (e.m.g.) was recorded from four antagonist pairs of hand/arm muscles primarily influencing the grip force or the load force. The balls were dropped either by the subject during a bimanual task, or unexpectedly by the experimenter. When the subject dropped the ball, preparatory actions occurred before the rapid increase in the vertical load caused by the impact. These actions appeared ca. 150 ms prior to the impact and involved a grip force increase and a lifting movement of the grip apparatus. The e.m.g. activity increased in all eight of the hand and arm muscles, indicating a general stiffening of the hand/arm system prior to the impact. Furthermore, the preparatory actions were programmed adequately for the size of the load force step at the impact, i.e. an adequate safety margin to prevent slips was preserved during the critical period of the impact. Thus, variations in this step caused by changes in (i) the weight of ball, (ii) the weight of the grip apparatus and (iii) the length of the drop were adequately taken into account during the programming of these actions. In addition, the frictional condition between the skin and the grip surface was also taken into account. The relevant sensory information apparently was obtained during the handling of the ball and the grip apparatus prior to the drop. There were also task-related automatic muscle responses triggered by the impact. These responses, which also served to stiffen the hand/arm system, were most pronounced during unexpected load changes, but they appeared too late to prevent slips. However, if no overall slip occurred, the triggered responses were functional in the sense that they helped to quickly restore the safety margin and the vertical position of the object.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00247523

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7

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Signals in tactile afferents from the fingers eliciting adaptive motor responses during precision grip (1987)

Johansson, R. S. ; Westling, G.

Springer

Experimental brain research 66 (1987), S. 141-154

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ISSN: 1432-1106

Keywords: Precision grip ; Motor control ; Human hand ; Cutaneous mechanoreceptors ; Exteroceptive reflexes ; Sensori-motor memory

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary While human subjects lift small objects using the precision grip between the tips of the fingers and thumb the ratio between the grip force and the load force (i.e. the vertical lifting force) is adapted to the friction between the object and the skin. The present report provides direct evidence that signals in tactile afferent units are utilized in this adaptation. Tactile afferent units were readily excited by small but distinct slips between the object and the skin revealed as vibrations in the object. Following such afferent slip responses the force ratio was upgraded to a higher, stable value which provided a safety margin to prevent further slips. The latency between the onset of the a slip and the appearance of the ratio change (74 ±9 ms) was about half the minimum latency for intended grip force changes triggered by cutaneous stimulation of the fingers. This indicated that the motor responses were automatically initiated. If the subjects were asked to very slowly separate their thumb and the opposing finger while the object was held in air, grip force reflexes originating from afferent slip responses appeared to counteract the voluntary command, but the maintained upgrading of the force ratio was suppressed. In experiments with weak electrical cutaneous stimulation delivered through the surfaces of the object it was established that tactile input alone could trigger the upgrading of the force ratio. Although, varying in responsiveness, each of the three types of tactile units which exhibit a pronounced dynamic sensitivity (FA I, FA II and SA I units) could reliably signal these slips. Similar but generally weaker afferent responses, sometimes followed by small force ratio changes, also occurred in the FA I and the SA I units in the absence of detectable vibrations events. In contrast to the responses associated with clear vibratory events, the weaker afferent responses were probably caused by localized frictional slips, i.e. slips limited to small fractions of the skin area in contact with the object. Indications were found that the early adjustment to a new frictional condition, which may appear soon (ca. 0.1–0.2 s) after the object is initially gripped, might depend on the vigorous responses in the FA I units during the initial phase of the lifts (see Westling and Johansson 1987). The role of the tactile input in the adaptation of the force coordination to the frictional condition is discussed.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00236210

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8

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Factors influencing the force control during precision grip (1984)

Westling, G. ; Johansson, R. S.

Springer

Experimental brain research 53 (1984), S. 277-284

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ISSN: 1432-1106

Keywords: Precision grip ; Human hand ; Motor control ; Sensory input ; Cutaneous mechanoreceptors

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary A small object was gripped between the tips of the index finger and thumb and held stationary in space. Its weight and surface structure could be changed between consecutive lifting trials, without changing its visual appearance. The grip force and the vertical lifting force acting on the object, as well as the vertical position of the object were continuously recorded. Likewise, the minimal grip force necessary to prevent slipping, was measured. The difference between this minimal force and the employed grip force, was defined as the safety margin to prevent slipping. It was found that the applied grip force was critically balanced to optimize the motor behaviour so that slipping between the skin and the gripped object did not occur and the grip force did not reach exeedingly high values. To achieve this motor control, the nervous system relied on a mechanism that measured the frictional condition between the surface structure of the object and the fingers. Experiments with local anaesthesia indicated that this mechanism used information from receptors in the fingers, most likely skin mechanoreceptors. In addition to friction, the control of the grip force was heavily influenced by the weight of the object and by a safety margin factor related to the individual subject. The frictional conditions during the previous trial could also, to some extent, influence the grip force.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00238156

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Mechanoreceptive afferent activity in the infraorbital nerve in man during speech and chewing movements (1988)

Johansson, R. S. ; Trulsson, M. ; Olsson, K. Å. ; [et al.]

Springer

Experimental brain research 72 (1988), S. 209-214

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ISSN: 1432-1106

Keywords: Mechanoreceptors ; Man ; Infraorbital nerve ; Microneurography ; Trigeminal nerve ; Speech gestures ; Mandibular movements ; Chewing ; Tactile sensibility ; Cutaneous sensibility ; Oral mucosa

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary The method of microneurography was used to record activity in trigeminal cutaneous and mucosal mechanoreceptive afferents during natural orofacial behaviors such as speech gestures, chewing, licking and swallowing. Multi-unit activity and impulses in single nerve fibers were recorded from the infraorbital nerve. It appeared that these mechanoreceptors respond to contact between the lips, air pressures generated for speech sounds, and to the deformation/strain changes of the facial skin and mucosa associated with various phases of voluntary lip and jaw movements. The relatively vigorous discharge of cutaneous and mucosal afferents during natural movements of the face are consistent with the claim that mechanoreceptors found within the facial skin provide proprioceptive information on facial movements.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00248519

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Control of grasp stability during pronation and supination movements (1999)

Johansson, R. S. ; Backlin, Jenny L. ; Burstedt, Magnus K. O.

Springer

Experimental brain research 128 (1999), S. 20-30

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ISSN: 1432-1106

Keywords: Key words Grasp stability ; Fingertip forces ; Human hand ; Manipulation ; Precision grip ; Grip force ; Rotational slip ; Torsional loads ; Somatosensory mechanisms ; Supination-pronation

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract We analyzed the control of grasp stability during a major manipulative function of the human hand: rotation of a grasped object by pronation and supination movement. We investigated the regulation of grip forces used to stabilize an object held by a precision grip between the thumb and index finger when subjects rotated it around a horizontal axis. Because the center of mass was located distal to the grip axis joining the fingertips, destabilizing torque tangential to the grasp surfaces developed when the grip axis rotated relative to the field of gravity. The torque load was maximal when the grip axis was horizontal and minimal when it was vertical. An instrumented test object, with a mass distribution that resulted in substantial changes in torque load during the rotation task, measured forces and torques applied by the digits. The mass distribution of the object was unpredictably changed between trials. The grip force required to stabilize the object increased directly with increasing torque load. Importantly, the grip force used by the subjects also changed in proportion to the torque load such that subjects always employed adequate safety margins against rotational slips, i.e., some 20–40% of the grip force. Rather than driven by sensory feedback pertaining to the torque load, the changes in grip force were generated as an integral part of the motor commands that accounted for the rotation movement. Subjects changed the grip force in parallel with, or even slightly ahead of, the rotation movement, whereas grip force responses elicited by externally imposed torque load changes were markedly delayed. Moreover, blocking sensory information from the digits did not appreciably change the coordination between movement and grip force. We thus conclude that the grip force was controlled by feedforward rather than by feedback mechanisms. These feedforward mechanisms would thus predict the consequences of the rotation movement in terms of changes in fingertip loads when the orientation of the grip axis changed in the field of gravity. Changes in the object’s center of mass between trials resulted in a parametric scaling of the motor commands prior to their execution. This finding suggests that the sensorimotor memories used in manipulation to adapt the motor output for the physical properties of environmental objects also encompass information related to an object’s center of mass. This information was obtained by somatosensory cues when subjects initially grasped the object with the grip axis vertical, i.e., during minimum tangential torque load.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/s002210050813

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