18 research outputs found
Severe Scene Learning Impairment, but Intact Recognition Memory, after Cholinergic Depletion of Inferotemporal Cortex Followed by Fornix Transection
To examine the generality of cholinergic involvement in visual memory in primates, we trained macaque monkeys either on an object-in-place scene learning task or in delayed nonmatching-to-sample (DNMS). Each monkey received either selective cholinergic depletion of inferotemporal cortex (including the entorhinal cortex and perirhinal cortex) with injections of the immunotoxin ME20.4-saporin or saline injections as a control and was postoperatively retested. Cholinergic depletion of inferotemporal cortex was without effect on either task. Each monkey then received fornix transection because previous studies have shown that multiple disconnections of temporal cortex can produce synergistic impairments in memory. Fornix transection mildly impaired scene learning in monkeys that had received saline injections but severely impaired scene learning in monkeys that had received cholinergic lesions of inferotemporal cortex. This synergistic effect was not seen in monkeys performing DNMS. These findings confirm a synergistic interaction in a macaque monkey model of episodic memory between connections carried by the fornix and cholinergic input to the inferotemporal cortex. They support the notion that the mnemonic functions tapped by scene learning and DNMS have dissociable neural substrates. Finally, cholinergic depletion of inferotemporal cortex, in this study, appears insufficient to impair memory functions dependent on an intact inferotemporal cortex
Plasticity in the Working Memory System: Life Span Changes and Response to Injury
Working memory acts as a key bridge between perception, long-term memory, and action. The
brain regions, connections, and neurotransmitters that underlie working memory undergo dramatic
plastic changes during the life span, and in response to injury. Early life reliance on deep
gray matter structures fades during adolescence as increasing reliance on prefrontal and parietal
cortex accompanies the development of executive aspects of working memory. The rise and
fall of working memory capacity and executive functions parallels the development and loss of
neurotransmitter function in frontal cortical areas. Of the affected neurotransmitters, dopamine and
acetylcholine modulate excitatory-inhibitory circuits that underlie working memory, are important
for plasticity in the system, and are affected following preterm birth and adult brain injury.
Pharmacological interventions to promote recovery of working memory abilities have had limited
success, but hold promise if used in combination with behavioral training and brain stimulation.
The intense study of working memory in a range of species, ages and following injuries has led
to better understanding of the intrinsic plasticity mechanisms in the working memory system.
The challenge now is to guide these mechanisms to better improve or restore working memory
function
An Open Resource for Non-human Primate Imaging.
Non-human primate neuroimaging is a rapidly growing area of research that promises to transform and scale translational and cross-species comparative neuroscience. Unfortunately, the technological and methodological advances of the past two decades have outpaced the accrual of data, which is particularly challenging given the relatively few centers that have the necessary facilities and capabilities. The PRIMatE Data Exchange (PRIME-DE) addresses this challenge by aggregating independently acquired non-human primate magnetic resonance imaging (MRI) datasets and openly sharing them via the International Neuroimaging Data-sharing Initiative (INDI). Here, we present the rationale, design, and procedures for the PRIME-DE consortium, as well as the initial release, consisting of 25 independent data collections aggregated across 22 sites (total = 217 non-human primates). We also outline the unique pitfalls and challenges that should be considered in the analysis of non-human primate MRI datasets, including providing automated quality assessment of the contributed datasets
Prefrontal interactions and decision making
The prefrontal cortex (PFC) is an area of the brain which controls many higher-level functions including decision making. Much research has been carried out on the function of PFC subregions but much of it is disparate due to the wide range of techniques and species used. There were two main aims of this thesis. First, I proposed to investigate the connections and functions of the PFC and related regions, and the role of some ofthese in effort-based decision making. Second, I hoped to use complementary techniques to compare across humans, monkeys and rats, and to combine my findings to increase our understanding of decision making. I used diffusion-weighted imaging to investigate the connections of PFC regions with other brain areas, and compared the results in humans and monkeys. The connections of each PFC region had a unique pattern which was similar between the species, indicating how each region may function. I then carried out a detailed study investigating the role of one PFC subregion, the medial frontal cortex (MFC), and its interactions with the dopaminergic midbrain in effort-based decision making, as we do not fully know how such regions interact with the rest of the brain when making decisions. I showed the MFC had a particular cognitive role in decision ml;lking with respect to the location of a reward-guided action. Finally I studied effort-based responding in the human brain using functional magnetic resonance imaging. This study revealed a network of regions involved in acting for a reward, and that the anterior cingulate cortex (ACC) may have a role in integrating factors which constitute the value of an action. Overall my results suggest that the MFC and ACC have specific roles in effort-based decision making, which can be further understood by comparing their connections with those ofother PFC regions.EThOS - Electronic Theses Online ServiceGBUnited Kingdo
Structural Variability Across the Primate Brain: A Cross-Species Comparison
A large amount of variability exists across human brains; revealed initially on a small scale by postmortem studies and, more recently, on a larger scale with the advent of neuroimaging. Here we compared structural variability between human and macaque monkey brains using grey and white matter magnetic resonance imaging measures. The monkey brain was overall structurally as variable as the human brain, but variability had a distinct distribution pattern, with some key areas showing high variability. We also report the first evidence of a relationship between anatomical variability and evolutionary expansion in the primate brain. This suggests a relationship between variability and stability, where areas of low variability may have evolved less recently and have more stability, while areas of high variability may have evolved more recently and be less similar across individuals. We showed specific differences between the species in key areas, including the amount of hemispheric asymmetry in variability, which was left-lateralized in the human brain across several phylogenetically recent regions. This suggests that cerebral variability may be another useful measure for comparison between species and may add another dimension to our understanding of evolutionary mechanisms
Differences in frontal network anatomy across primate species
The frontal lobe is central to distinctive aspects of human cognition and behavior. Some comparative studies link this to a larger frontal cortex and even larger frontal white matter in humans compared with other primates, yet others dispute these findings. The discrepancies between studies could be explained by limitations of the methods used to quantify volume differences across species, especially when applied to white matter connections. In this study, we used a novel tractography approach to demonstrate that frontal lobe networks, extending within and beyond the frontal lobes, occupy 66% of total brain white matter in humans and 48% in three monkey species: vervets (Chlorocebus aethiops), rhesus macaque (Macaca mulatta) and cynomolgus macaque (Macaca fascicularis), all male. The simian- human differences in proportional frontal tract volume were significant for projection, commissural, and both intralobar and interlobar association tracts. Among the long association tracts, the greatest difference was found for tracts involved in motor planning, auditory memory, top-down control of sensory information, and visuospatial attention, with no significant differences in frontal limbic tracts important for emotional processing and social behaviour. In addition, we found that a nonfrontal tract, the anterior commissure, had a smaller volume fraction in humans, suggesting that the disproportionally large volume of human frontal lobe connections is accompanied by a reduction in the proportion of some nonfrontal connections. These findings support a hypothesis of an overall rearrangement of brain connections during human evolution
NeuN(+) neuronal nuclei in non-human primate prefrontal cortex and subcortical white matter after clozapine exposure
Increased neuronal densities in subcortical white matter have been reported for some cases with schizophrenia. The underlying cellular and molecular mechanisms remain unresolved. We exposed 26 young adult macaque monkeys for 6months to either clozapine, haloperidol or placebo and measured by structural MRI frontal gray and white matter volumes before and after treatment, followed by observer-independent, flow-cytometry-based quantification of neuronal and non-neuronal nuclei and molecular fingerprinting of cell-type specific transcripts. After clozapine exposure, the proportion of nuclei expressing the neuronal marker NeuN increased by approximately 50% in subcortical white matter, in conjunction with a more subtle and non-significant increase in overlying gray matter. Numbers and proportions of nuclei expressing the oligodendrocyte lineage marker, OLIG2, and cell-type specific RNA expression patterns, were maintained after antipsychotic drug exposure. Frontal lobe gray and white matter volumes remained indistinguishable between antipsychotic-drug-exposed and control groups. Chronic clozapine exposure increases the proportion of NeuN(+) nuclei in frontal subcortical white matter, without alterations in frontal lobe volumes or cell type-specific gene expression. Further exploration of neurochemical plasticity in non-human primate brain exposed to antipsychotic drugs is warranted