Gregory P. Slota scite author profile

When people transport handheld objects, they change the grip force with the object movement. Circular movement patterns were tested within three planes at two different rates (1.0, 1.5 Hz), and two diameters (20, 40 cm). Subjects performed the task reasonably well, matching frequencies and dynamic ranges of accelerations within expectations. A mathematical model was designed to predict the applied normal forces from kinematic data. The model is based on two hypotheses: (a) the grip force changes during movements along complex trajectories can be represented as the sum of effects of two basic commands associated with the parallel and orthogonal manipulation, respectively; (b) different central commands are sent to the thumb and virtual finger (Vf- four fingers combined). The model predicted the actual normal forces with a total variance accounted for of better than 98%. The effects of the two components of acceleration—along the normal axis and the resultant acceleration within the shear plane—on the digit normal forces are additive.

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An MRI-compatible hand sensory vibrotactile system

Wang¹,

Lakshminarayanan²,

Slota³

et al. 2014

Physiol. Meas.

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Recently, application of vibrotactile noise to the wrist or back of the hand has been shown to enhance fingertip tactile sensory perception (Enders et al 2013), supporting a potential for an assistive device worn at the wrist, that generates minute vibration to help the elderly or patients with sensory deficit. However, knowledge regarding the detailed physiological mechanism behind this sensory improvement in the central nervous system, especially in the human brain, is limited, hindering progress in development and use of such assistive devices. To enable investigation of the impact of vibrotactile noise on sensorimotor brain activity in humans, a magnetic resonance imaging (MRI)-compatible vibrotactile system was developed to provide vibrotactile noise during an MRI of the brain. The vibrotactile system utilizes a remote (outside the MR room) signal amplifier which provides a voltage from −40 V to +40 V to drive a 12 mm diameter piezoelectric vibrator (inside the MR room). It is portable and is found MRI-compatible to enable its use for neurologic investigation with MRI. The system was also found to induce improvement in fingertip tactile sensation, consistent with the previous study.

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Improvement of hand function using different surfaces and identification of difficult movement post stroke in the Box and Block Test

Slota¹,

Enders²,

Seo³

2014

Applied Ergonomics

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Gregory P. Slota

Paraspinal muscle reflex dynamics

Effects of seated whole-body vibration on postural control of the trunk during unstable seated balance

Grip forces during object manipulation: experiment, mathematical model, and validation

An MRI-compatible hand sensory vibrotactile system

Improvement of hand function using different surfaces and identification of difficult movement post stroke in the Box and Block Test

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