Your search keyword '"Guimarães-Silva S"' showing total 5 results

1. Inhibition of return, gap effect and saccadic reaction time to a visual target

Author

L. Klausner-de-Oliveira, Luiz G. Gawryszewski, T.S. Portugal, and Guimarães-Silva S

Subjects

Adult, Male, Gap effect, medicine.medical_specialty, Physiology, Immunology, Biophysics, Audiology, Biochemistry, Inhibition of return, medicine, Reaction Time, Saccades, Humans, Covert orienting, Attention, General Pharmacology, Toxicology and Pharmaceutics, Saccadic reaction time, lcsh:QH301-705.5, Visual attention, Cued speech, lcsh:R5-920, General Neuroscience, Cell Biology, General Medicine, Fixation point, Saccadic masking, lcsh:Biology (General), Facilitation, Visual Perception, Female, Cues, Visual Fields, Psychology, lcsh:Medicine (General)

Abstract

Simple manual reaction time (MRT) to a visual target (S2) is shortened when a non-informative cue (S1) is flashed at the S2 location shortly before the onset of S2 (early facilitation). Afterwards, MRT to S2 appearing at the S1 location is lengthened (inhibition of return - IOR). Similar results have been obtained for saccadic reaction time (SRT). Moreover, when there is a temporal gap between offset of the fixation point (FP) and onset of a target (gap paradigm), SRT is shorter than SRT in an overlap paradigm (FP remains on). In the present study, we determined SRT to S2 (10 degrees) after presenting S1 at the same eccentricity (10 degrees) or at a parafoveal position (2 degrees) in the same or in the opposite hemifield. In addition, we employed both gap and overlap paradigms. Twelve subjects were asked not to respond to S1 (2 degrees or 10 degrees) to the right or to the left of FP, but to respond by making a saccadic movement in response to S2. We obtained the following results: 1) a 40-ms gap effect, 2) an interaction between gap effect and IOR, 3) a 39-ms delay (IOR) when S2 appeared at the cued (S1) position, and 4) a smaller (17 ms) but significant inhibition when S1 occurred at 2 degrees in the ipsilateral hemifield. Thus, a parafoveal (2 degrees) S1 elicits an inhibition of SRT towards ipsilateral peripheral targets. Since an inhibition of the ipsilateral hemifield by a 1 degree eccentric cue has been reported to occur when manual responses are employed, we suggest that the postulated functional link between covert and overt orienting of attention is also valid for parafoveal cues.

Published

2004

2. Recognition of hand shape drawings on vertical and horizontal display

Author

Luiz G. Gawryszewski, Allan Pablo Lameira, Antônio Pereira Júnior, Guimarães-Silva S, and Cinthya Werneck-Galvão

Subjects

Which hand, Communication, manual reaction time, Horizontal and vertical, business.industry, General Neuroscience, Plan (drawing), handedness recognition, Task (project management), Visual recognition, visual representations, Neuropsychology and Physiological Psychology, Motor imagery, motor imagery, Computer vision, Artificial intelligence, sensorimotor representations, business, Psychology

Abstract

visual recognition of body parts activates somato-motor representations in the brain. In the present study, we investigate the influence of the plane in which hand drawings are displayed (Vertical or Horizontal) on mental rotations evoked by a handedness recognition task. Sixteen right-handed volunteers participated in an experiment where the task was to evaluate the handedness of drawings of the human hand presented in different perspectives and orientations while the Manual Reaction Time (MRT) was measured. For eight volunteers, the hand drawings were displayed on a vertical screen monitor, while for the remainder a mirror was employed and the same drawings appeared on the horizontal plan. Our main finding was that there are no differences in MRTs among the drawings displayed vertically or horizontally, with some exceptions. However, the MRTs were longer when the hands in the drawings assumed configurations that were more awkward to perform using real movements. These results show that the implicit movements involved with handedness recognition are mainly dependent on biomechanical constraints for distal (hand), but not proximal (shoulder) movements. Keywords: handedness recognition, motor imagery, manual reaction time, visual representations, sensorimotor representations.

Published

2008

3. Hand posture and motor imagery: a body-part recognition study.

Author

Lameira AP, Guimarães-Silva S, Ferreira FM, Lima LV, Pereira A Jr., and Gawryszewski LG

Abstract

Objective: Recognition of body parts activates specific somatosensory representations in a way that similar to motor imagery. These representations are implicitly activated to compare the body with the stimulus. In the present study, we investigate the influence of proprioceptive information relating to body posture on the recognition of body parts (hands). It proposes that this task could be used for rehabilitation of neurological patients. Methods: Ten right-handed volunteers participated in this experiment. The task was to recognize the handedness of drawings of a hand that were presented in different perspectives and several orientations. For drawings of a right hand, the volunteers pressed the right key, and for drawings of a left hand, they pressed the left key. The volunteers underwent two sessions: one with their hands in a prone posture and the other with their hands in a supine posture. Results: The manual reaction time was longer for perspectives and orientations for which the real movement was difficult to achieve. This showed that, during the task, motor representations were activated to compare the body with the stimulus. Furthermore, the subject's posture had an influence in relation to specific perspectives and orientations, Conclusions: These results showed that motor representations are activated to compare the body with the stimulus, and that the position of the hand influences this resonance between the stimulus and the body part. [ABSTRACT FROM AUTHOR]

Published

2008

4. Hand posture effects on handedness recognition as revealed by the simon effect.

Author

Lameira AP, Gawryszewski LG, Guimarães-Silva S, Ferreira FM, Vargas CD, Umiltà C, and Pereira A

Abstract

We investigated the influence of hand posture in handedness recognition, while varying the spatial correspondence between stimulus and response in a modified Simon task. Drawings of the left and right hands were displayed either in a back or palm view while participants discriminated stimulus handedness by pressing either a left or right key with their hands resting either in a prone or supine posture. As a control, subjects performed a regular Simon task using simple geometric shapes as stimuli. Results showed that when hands were in a prone posture, the spatially corresponding trials (i.e., stimulus and response located on the same side) were faster than the non-corresponding trials (i.e., stimulus and response on opposite sides). In contrast, for the supine posture, there was no difference between corresponding and non-corresponding trials. Control experiments with the regular Simon task showed that the posture of the responding hand had no influence on performance. When the stimulus is the drawing of a hand, however, the posture of the responding hand affects the spatial correspondence effect because response location is coded based on multiple reference points, including the body of the hand.

Published

2009

5. Inhibition of return, gap effect and saccadic reaction time to a visual target.

Author

Guimarães-Silva S, Gawryszewski LG, Portugal TS, and Klausner-de-Oliveira L

Subjects

Adult, Cues, Female, Humans, Male, Visual Perception physiology, Attention physiology, Reaction Time physiology, Saccades physiology, Visual Fields physiology

Abstract

Simple manual reaction time (MRT) to a visual target (S2) is shortened when a non-informative cue (S1) is flashed at the S2 location shortly before the onset of S2 (early facilitation). Afterwards, MRT to S2 appearing at the S1 location is lengthened (inhibition of return - IOR). Similar results have been obtained for saccadic reaction time (SRT). Moreover, when there is a temporal gap between offset of the fixation point (FP) and onset of a target (gap paradigm), SRT is shorter than SRT in an overlap paradigm (FP remains on). In the present study, we determined SRT to S2 (10 degrees) after presenting S1 at the same eccentricity (10 degrees) or at a parafoveal position (2 degrees) in the same or in the opposite hemifield. In addition, we employed both gap and overlap paradigms. Twelve subjects were asked not to respond to S1 (2 degrees or 10 degrees) to the right or to the left of FP, but to respond by making a saccadic movement in response to S2. We obtained the following results: 1) a 40-ms gap effect, 2) an interaction between gap effect and IOR, 3) a 39-ms delay (IOR) when S2 appeared at the cued (S1) position, and 4) a smaller (17 ms) but significant inhibition when S1 occurred at 2 degrees in the ipsilateral hemifield. Thus, a parafoveal (2 degrees) S1 elicits an inhibition of SRT towards ipsilateral peripheral targets. Since an inhibition of the ipsilateral hemifield by a 1 degree eccentric cue has been reported to occur when manual responses are employed, we suggest that the postulated functional link between covert and overt orienting of attention is also valid for parafoveal cues.

Published

2004