Your search keyword '"Fragaszy, Dorothy Munkenbeck"' showing total 2 results

1. 'Vision for action' in young children aligning multi-featured objects: Development and comparison with nonhuman primates

Author

Fragaszy, Dorothy Munkenbeck, Kuroshima, Hika, Stone, Brian W., and Ferrari, Pier Francesco

Subjects

Male, Primates, Matching (statistics), Relation (database), genetic structures, Computer science, Concept Formation, Spatial Learning, lcsh:Medicine, Child Development, Human–computer interaction, Concept learning, Animals, Humans, lcsh:Science, Vision, Ocular, Multidisciplinary, lcsh:R, Object (philosophy), eye diseases, Spatial relation, Action (philosophy), Feature (computer vision), Child, Preschool, Spatial learning, lcsh:Q, Female, Psychomotor Performance, Research Article

Abstract

Effective vision for action and effective management of concurrent spatial relations underlie skillful manipulation of objects, including hand tools, in humans. Children's performance in object insertion tasks (fitting tasks) provides one index of the striking changes in the development of vision for action in early life. Fitting tasks also tap children's ability to work with more than one feature of an object concurrently. We examine young children's performance on fitting tasks in two and three dimensions and compare their performance with the previously reported performance of adult individuals of two species of nonhuman primates on similar tasks. Two, three, and four year-old children routinely aligned a bar-shaped stick and a cross-shaped stick but had difficulty aligning a tomahawk-shaped stick to a matching cut-out. Two year-olds were especially challenged by the tomahawk. Three and four year-olds occasionally held the stick several inches above the surface, comparing the stick to the surface visually, while trying to align it. The findings suggest asynchronous development in the ability to use vision to achieve alignment and to work with two and three spatial features concurrently. Using vision to align objects precisely to other objects and managing more than one spatial relation between an object and a surface are already more elaborated in two year-old humans than in other primates. The human advantage in using hand tools derives in part from this fundamental difference in the relation between vision and action between humans and other primates.

Published

2015

2. Prehension in Cebus and Saimiri: I. Grip Type and Hand Preference.

Author

Costello, Michael B. and Fragaszy, Dorothy Munkenbeck

Subjects

*CEBUS apella, *MOTOR ability, *CAPUCHIN monkeys, *SQUIRREL monkeys, *MONKEYS, *ANIMAL ecology, *PRIMATES, *ABILITY, *ANIMAL populations, *ANIMAL behavior

Abstract

Prehension was examined in tufted capuchins (Cebus apella) and squirrel monkeys (Saimiri sciureus). Individual subjects were videotaped from frontal and sagittal planes while they grasped small objects presented in several ways (in view, out of view, embedded, moving). Capuchins used a precision grip in 30% of trials and in more than half of trials with stationary objects. Most (54%) of the precision grips used were opposition of the thumb to the index finger; however, eight other forms were also observed. Squirrel monkeys never used a precision grip. Data on hand preference, preliminary data on movement velocity, and preliminary observations of movement trajectories (up to the time of hand shaping prior to contact with the object) do not indicate significant differences across genera in these aspects of prehension. The presence of varied precision grips in capuchins and no form of precision grip in squirrel monkeys leads to two conclusions. First, a thumb classification of ‘opposable’ (vs. ‘pseudo-opposable’) is not essential for precision gripping. Capuchins, with pseudo-opposable thumbs, use precision grips routinely. Second, the fundamental difference between these genera, which accommodates precision gripping in capuchins, is the capacity in capuchins (but not in squirrel monkeys) to produce lateral pressure between opposing digits. The anatomy of the spinal pyramidal tract and neuromuscular interfacing in the hands may be more sensitive gauges of manual dexterity than the anatomy of the thumb. [ABSTRACT FROM AUTHOR]

Published

1988