Your search keyword '"*SPATIAL memory"' showing total 5 results

1. Neonatal Hippocampal Damage Impairs Specific Food/Place Associations in Adult Macaques.

Author

Glavis-Bloom, Courtney, Alvarado, Maria C., and Bachevalier, Jocelyne

Subjects

*HIPPOCAMPUS diseases, *SPATIAL memory, *FOOD preferences, *NEUROTOXICOLOGY, *SHORT-term memory, *LABORATORY monkeys

Abstract

This study describes a novel spatial memory paradigm for monkeys and reports the effects of neonatal damage to the hippocampus on performance in adulthood. Monkeys were trained to forage in eight boxes hung on the walls of a large enclosure. Each box contained a different food item that varied in its intrinsic reward value, as determined from food preference testing. Monkeys were trained on a spatial and a cued version of the task. In the spatial task, the boxes looked identical and remained fixed in location whereas in the cued task, the boxes were individuated with colored plaques and changed location on each trial. Ten adult Rhesus macaques (5 neonatal sham-operated and 5 with neonatal neurotoxic hippocampal lesions) were allowed to forage once daily until they preferentially visited boxes containing preferred foods. The data suggest that all monkeys learned to discriminate preferred from nonpreferred food locations, but that monkeys with neonatal hippocampal damage committed significantly more working memory errors than controls in both tasks. Furthermore, following selective satiation, controls altered their foraging pattern to avoid the satiated food, whereas lesioned animals did not, suggesting that neonatal hippocampal lesions prohibit learning of specific food-place associations. We conclude that whereas an intact hippocampus is necessary to form specific item-in-place associations, in its absence, cortical areas may support more broad distinctions between food types that allow monkeys to discrim-inate places containing highly preferred foods. [ABSTRACT FROM AUTHOR]

Published

2013

2. Spatial Memory Deficits in a Virtual Radial Arm Maze in Amnesic Participants With Hippocampal Damage.

Author

Goodrich-Hunsaker, Naomi J. and Hopkins, Ramona O.

Subjects

*MEMORY, *AMNESIA, *HIPPOCAMPUS (Brain), *LABORATORY rodents, *PSYCHOLOGY of learning

Abstract

Extensive research with laboratory animals indicates that the hippocampus is crucial for the formation and use of spatial memory. Hippocampal lesions in rodents impair spatial memory on radial arm maze tasks. It is unknown whether amnesic patients with hippocampal damage would exhibit similar impairments on a virtual version of a radial arm maze. To evaluate the importance of the hippocampus in spatial learning and memory, we tested amnesic participants with hippocampal damage in a virtual radial arm maze environment. The virtual radial arm maze required participants to learn and remember 4 rewarded arms of 8 total arms. Spatial learning and memory were assessed using the participants' ability to use salient distal cues in the virtual room to remember the 4 rewarded arms. Amnesic participants' latencies were longer and distance traveled was greater to the rewarded arms compared with nonamnesic participants. Amnesic participants made more errors than nonamnesic participants by either entering nonrewarded arms or by revisiting previously entered arms. These data are analogous to previous animal research. Overall, the human hippocampus is necessary for spatial memory and navigation in a virtual radial arm maze task. [ABSTRACT FROM AUTHOR]

Published

2010

3. Effects of Captivity and Memory-Based Experiences on the Hippocampus in Mountain Chickadees.

Author

laDage, Lara D., Roth II, Timothy C., Fox, Rebecca A., and Pravosudov, Vladimir V.

Subjects

*HIPPOCAMPUS (Brain), *BRAIN, *MEMORY, *CHICKADEES, *RESEARCH

Abstract

The complexity of an animal's physical environment is known to affect the hippocampus. Captivity may affect hippocampal anatomy and this may be attributable to the limited opportunities for memory-based experiences. This has tangential support, in that differential demands on memory can mediate changes in the hippocampus. What remains unclear is whether captivity directly affects hippocampal architecture and whether providing memory-based experiences in captivity can maintain hippocampal attributes comparable to wild-caught conspecifics. Using food-caching mountain chickadees (Poecile gambeli), we found that wild-caught individuals had larger hippocampal volumes relative to the rest of the telencephalon than captive birds with or without memory-based food-caching experiences, whereas there were no differences in neuron numbers or telencephalon volume. Also, there were no significant differences in relative hippocampal volume or neuron numbers between the captive birds with or without memory-based experiences. Our results demonstrate that captivity reduces hippocampal volume relative to the remainder of the telencephalon, but not at the expense of neuron numbers. Further, memory-based experiences in captivity may not be sufficient to maintain hippocampal volume comparable to wild-caught counterparts. [ABSTRACT FROM AUTHOR]

Published

2009

4. Chronic Stress Impairs Spatial Memory and Motivation for Reward Without Disrupting Motor Ability and Motivation to Explore.

Author

Kleen, Jonathan K., Sitomer, Matthew T., Killeen, Peter R., and Conrad, Cheryl D.

Subjects

*SHORT-term memory, *MOTOR ability, *MENTAL depression, *MOTIVATION (Psychology), *MEMORY

Abstract

This study uses an operant, behavioral model to assess the daily changes in the decay rate of short-term memory, motivation, and motor ability in rats exposed to chronic restraint. Restraint decreased reward-related motivation by 50% without altering memory decay rate or motor ability. Moreover, chronic restraint impaired hippocampal-dependent spatial memory on the Y maze (4-hr delay) and produced CA3 dendritic retraction without altering hippocampal-independent maze navigation (1-min delay) or locomotion. Thus, mechanisms underlying motivation for food reward differ from those underlying Y maze exploration, and neurobiological substrates of spatial memory, such as the hippocampus, differ from those that underlie short-term memory. Chronic restraint produces functional, neuromorphological, and physiological alterations that parallel symptoms of depression in humans. [ABSTRACT FROM AUTHOR]

Published

2006

5. Memory in Autistic Spectrum Disorder

Author

Sally Bigham, Jill Boucher, and Andrew R. Mayes

Subjects

Memory Disorders, Recall, Long-term memory, Emotions, Prefrontal Cortex, BF, Neuropsychological Tests, Hippocampus, Severity of Illness Index, Spatial memory, History and Philosophy of Science, Visual memory, Memory, Research Design, Face, Parietal Lobe, Explicit memory, Humans, Semantic memory, Autistic Disorder, Levels-of-processing effect, Psychology, General Psychology, Cognitive psychology, Recognition memory

Abstract

Behavioral evidence concerning memory in high-functioning forms of autism (HFA) and in moderately low-functioning autism (M-LFA) is reviewed and compared. Findings on M-LFA are sparse. However, it is provisionally concluded that memory profiles in HFA and M-LFA (relative to ability-matched controls) are similar, but that declarative memory impairments are more extensive in M-LFA than in HFA. Specifically, both groups have diminished memory for emotion- or person-related stimuli. Regarding memory for non-social stimuli, both groups probably have mental-age appropriate nondeclarative memory; and within declarative memory, both groups have mental-age appropriate immediate free recall of within-span or supra-span lists of unrelated items, as well as cued recall and paired associate learning. By contrast, recognition is largely unimpaired in HFA but moderately impaired in M-LFA; and free recall of meaningful or structured stimuli is moderately impaired in HFA but more severely impaired in M-LFA. Theoretical explanations of data on declarative memory in HFA identify problems in the integrative processing, or the consolidation and storage, of complex stimuli; or a specific problem of recollection. Proposed neural substrates include the following: disconnectivity of primary sensory and association areas; dysfunctions of medial prefrontal cortex, hippocampus or posterior parietal lobe; or combinations of these associated with neural disconnectivity. Hypothetically, perirhinal dysfunction might explain the more extensive declarative memory impairments in M-LFA. Foreseeable consequences of uneven memory abilities in HFA and M-LFA are outlined, including possible effects on language and learning in M-LFA. Finally, priorities for future research are identified, highlighting the urgent need for research on memory in lower-functioning individuals.

Published

2012