31 |
Multiple-object memory requires the hippocampusYim, Tonia Tan-Ling, University of Lethbridge. Faculty of Arts and Science January 2007 (has links)
This thesis investigates the role of the hippocampus in object memory. Currently,
the role of the hippocampus in object recognition is unclear, with some studies
demonstrating a delay-dependent impairment after hippocampal damage, others showing
no impairment. The present thesis used the novel object recognition task and its variants
to investigate various types of object memory in hippocampal lesion rats. In the first
study, impairments were observed in discriminating object order and associating objects
with contexts, while no impairment was observed in novel object recognition. In the
second study, it was found that encountering another object shortly prior to or after
encountering a target object impairs the recognition of the target object. In a control
procedure, encountering a novel context either shortly before or after encountering the
target object did not impair object recognition. In sum, in the absence of the hippocampus,
object memory becomes vulnerable to interference, rendering rats unable to discern
memories of multiple objects. The present thesis concludes that the hippocampus
discriminates multiple objects via pattern separation. A stimulus-response model relating
the role of the hippocampus to object memory is proposed. / vii, 150 leaves : ill. ; 29 cm. --
|
32 |
A diffusion tensor imaging study of age-related changes in the white matter structural integrity in a common chimpanzeeErrangi, Bhargav Kumar 15 April 2009 (has links)
Diffusion Tensor Magnetic Resonance Imaging was used to examine the age-related changes in white matter structural integrity in the common chimpanzee. Fractional Anisotropy(FA), a measure derived from the diffusion tensor data is sensitive to developmental and pathological changes in axonal density, myelination, size and coherence of organization of fibers within a voxel and thus reflects the white matter structural integrity. There is substantial evidence that white matter structural integrity decreases with age in humans. The long-term goal of this study is to compare the age-related changes in the white matter structural integrity among humans and chimpanzess to provide potential insights into the unique features of human aging. Different methods, including Region Of Interest (ROI) analysis, Tract Based Spatial Statistics (TBSS) are used to describe age-related changes in FA in a group of 21 chimpanzees. Strengths and limitations of these methods were discussed.
|
33 |
Mechanism and consequences of extracellular adenosine accumulation in the hypoxic hippocompal slice / David Doolette.Doolette, David January 1995 (has links)
Bibliography: 197-226 p. / xiv, 226 p. : ill. ; 30 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Examines the alterations in electrophysiological function during hypoxia in the rat hippocampal slice, in particular those alterations induced by extracellular accumulation of adenosine. / Thesis (Ph.D.)--University of Adelaide, Faculty of Science, 1996
|
34 |
The effect of exercise and relaxation training on blood pressure of elderly hypertensivesVan Niekerk, Charlotte 11 February 2014 (has links)
M.A. (Psychology) / Please refer to full text to view abstract
|
35 |
Neuropsychological deficits in patients with chronic hypertensionVan Niekerk, Charlotte 28 July 2014 (has links)
D.Litt. et Phil. (Psychology) / The aim of this study was to investigate the effect that hypertension has on brain function. A neuropsychological test battery comprising of the following tests was employed as a multivariate measure of brain dysfunction in a quasiexperimental, matched group design: a) The Complex Figure Test of Rey (copy, immediate recall and delayed recall), b) the Logical Memory Test, c) the Digits Span Test, d) the Verbal Paired Associate Learning Subtest, e) the Controlled Oral Word Generation Test, fr the Trail Making Test, and the Digit Symbol Substitution Subtest, This permitted a comparison in brain functioning between a group of hypertensive and a group of normotensive participants that were matched according to age, handedness, level of education and sex. The matching of variables increased the sensitivity of the study by controlling extraneous variables and ensured that the groups were compatible on the paired variables. The results were statistically analyzed by employing the Mann-Whitney U statistic for small groups and the Chi-square statistic on the measured variables. Further, content analysis was employed to test for significant differences in strategies of coping, immediate recall and delayed recall of the Complex Figure of Rey. The results indicated that: 1. there were significant differences in attention and concentration, motor functioning, perceptual abilities, information processing, memory, and planning and organisation between the two groups, with the hypertensive group obtaininq significantly lower scores on test measuring these variables; and 2. there were no significant differences in the verbal abilities (word fluency) of the two groups. The results support previous research, finding indications of vocal lesions located across the brains of people suffering from hypertension. Practical implications of the results are discussed and recommendations for future research have been made...
|
36 |
Characteristics of Primary Cilia and Centrosomes in Neuronal and Glial Lineages of the Adult BrainBhattarai, Samip Ram 05 1900 (has links)
Primary cilia are sensory organelles that are important for initiating cell division in the brain, especially through sonic hedgehog (Shh) signaling. Several lines of evidence suggest that the mitogenic effect of Shh requires primary cilia. Proliferation initiated by Shh signaling plays key roles in brain development, in neurogenesis in the adult hippocampus, and in the generation of glial cells in response to cortical injury. In spite of the likely involvement of cilia in these events, little is known about their characteristics. Centrosomes, which are associated with primary cilia, also have multiple influences on the cell cycle, and they are important in assembling microtubules for the maintenance of the cell’s cytoskeleton and cilia. The cilia of terminally differentiated neurons have been previously examined with respect to length, incidence, and receptors present. However, almost nothing is known about primary cilia in stem cells, progenitors, or differentiated glial cells. Moreover, it is not known how the properties of cilia and centrosomes may vary with cell cycle or proliferative potential, in brain or other tissues. This dissertation focuses first on neurogenesis in the hippocampal subgranular zone (SGZ). The SGZ is one of the few brain regions in mammals that gives rise to a substantial number of new neurons throughout adulthood. The neuron lineage contains a progression of identifiable precursor cell types with different proliferation rates. This present study found that primary cilia were present in every cell type in the neuronal lineage in SGZ. Cilium length and incidence were positively correlated among these cell types. Ciliary levels of adenylyl cyclase type III (ACIII) levels relative to ADP-ribosylation factor-like protein 13b (Arl13b) was higher in neurons than in precursor cells and glia, and also changed with the cell cycle. G-protein coupled receptors, SstR3, MCHR1, and Gpr161 receptors were only found in neuronal cilia. The levels and distribution of three centrosomal proteins, γ-tubulin, pericentrin and cenexin in neurons was different from the distributions in precursors and glia. The second focus of study is glial responses to injury in the neocortex, which has been widely studied as an injury model. This study found that in the normal adult somatosensory cortex, primary cilia were present in astrocytes and polydendrocytes but not in microglia. Following injury, the incidence of primary cilia decreased in astrocytes. Also, a new cell type expressing GFAP, NG2 and Olig2 was seen 3 days following injury, but was not present in normal mice. The characteristics of primary cilia and centrosome described here suggest that in stem cells and progenitors their characteristics may be well suited for proliferation, whereas in neurons, the cilia and centrosomes are important for other sensory functions.
|
37 |
Discovery of Multiple Venous Portal Systems in the Mammalian BrainYao, Yifan January 2023 (has links)
There are two distinct communication systems in the brain, term wiring and volume transmission (Agnati et al., 2010). Volume transmission refers to a way of communication lacking any wire-like channel connecting the source of signal and its target. This way of signaling is the focus of the current thesis. Portal systems are one aspect of volume transmission in which they provide a pathway for diffusible signaling between bodily fluids (blood and cerebrospinal fluid) and the nervous system. A portal system entails two capillary beds linked by connecting veins. This connection allows signals from one capillary bed to be transported to a target in high concentrations without being diluted in the systemic circulation (Dorland, 2020).
For the past decades, the only identified portal system in the brain is pituitary portal system (Popa, 1930; Popa & Fielding, 1933). Here, hypothalamic neurosecretions are released into the fenestrated capillaries of median eminence, a circumventricular organ, and transported to the capillaries of anterior pituitary via portal veins. The median eminence, due to its location on the surface of the ventricle and its contact to the cerebrospinal fluid, is categorized as a circumventricular organ. According to the classification (Oldfield & McKinley, 2015), there are three sensory circumventricular organs in the brain, all are characterized by fenestrated capillaries allowing contact between brain parenchyma and blood. For this reason, the circumventricular organs are known as “windows to the brain” (Gross et al., 1987). Whether other circumventricular organs also form portal systems is unknown. This thesis examines whether sensory circumventricular organs, specifically the organum vascular organ of the lamina terminals, the subfornical organ and the area postrema, bear portal systems. Although there have been prior studies of the vascularity of these CVOs in many species (reviewed in Duvernoy and Risold (2007)), the tissue preparation methods available limited the possibility of tracking small vessels over relatively large volumes in these structures.
In the present work, to preserve the blood vessel structure, brain clearing and light sheet microscopy were combined to acquire volumetric images of the regions containing the circumventricular organs. In vivo two-photon microscopy was used to study the blood flow of the sensory circumventricular organs and the adjacent neuropil. The results indicate that organum vasculosum of the lamina terminalis is connected to the brain’s clock located in the suprachiasmatic nucleus by portal vessels. The direction of blood flow is from the suprachiasmatic nucleus to the organum vasculosum of the lamina terminalis, and speed of blood flow is faster during the night compared to the day. Volumetric imaging of the suprachiasmatic nucleus also shows portal veins emerging from the rostral shell region of this nucleus. Also, the subfornical organ connects to the septofimbrial nucleus and the triangular nucleus of the septum via portal veins.
The arrangement of the vasculature of the area postrema differs from the other sensory CVOs: the AP and the nucleus of the solitary tract share a common capillary bed directly joining the vasculature of these morphologically distinct nuclei. In summary, there are multiple portal systems connecting the circumventricular organs. These newly discovered portal systems represent new pathways for diffusible signaling, bridging the systemic circulation, cerebrospinal fluid, circumventricular organs and the portal veins connected regions.
|
38 |
Towards a Computational Theory of the Brain: The Simplest Neural Models, and a Hypothesis for LanguageMitropolsky, Daniel January 2024 (has links)
Obtaining a computational understanding of the brain is one of the most important problems in basic science. However, the brain is an incredibly complex organ, and neurobiological research has uncovered enormous amounts of detail at almost every level of analysis (the synapse, the neuron, other brain cells, brain circuits, areas, and so on); it is unclear which of these details are conceptually significant to the basic way in which the brain computes. An essential approach to the eventual resolution of this problem is the definition and study of theoretical computational models, based on varying abstractions and inclusions of such details.
This thesis defines and studies a family of models, called NEMO, based on a particular set of well-established facts or well-founded assumptions in neuroscience: atomic neural firing, random connectivity, inhibition as a local dynamic firing threshold, and fully local plasticity. This thesis asks: what sort of algorithms are possible in these computational models? To the extent possible, what seem to be the simplest assumptions where interesting computation becomes possible? Additionally, can we find algorithms for cognitive phenomena that, in addition to serving as a "proof of capacity" of the computational model, otherwise reflect what is known about these processes in the brain? The major contributions of this thesis include:
1. The formal definition of the basic-NEMO and NEMO models, with an explication of their neurobiological underpinnings (that is, realism as abstractions of the brain).
2. Algorithms for the creation of neural \emph{assemblies}, or highly dense interconnected subsets of neurons, and various operations manipulating such assemblies, including reciprocal projection, merge, association, disassociation, and pattern completion, all in the basic-NEMO model. Using these operations, we show the Turing-completeness of the NEMO model (with some specific additional assumptions).
3. An algorithm for parsing a small but non-trivial subset of English and Russian (and more generally any regular language) in the NEMO model, with meta-features of the algorithm broadly in line with what is known about language in the brain.
4. An algorithm for parsing a much larger subset of English (and other languages), in particular handling dependent (embedded) clauses, in the NEMO model with some additional memory assumptions. We prove that an abstraction of this algorithm yields a new characterization of the context-free languages.
5. Algorithms for the blocks-world planning task, which involves outputting a sequence of steps to rearrange a stack of cubes in one order into another target order, in the NEMO model. A side consequence of this work is an algorithm for a chaining operation in basic-NEMO.
6. Algorithms for several of the most basic and initial steps in language acquisition in the baby brain. This includes an algorithm for the learning of the simplest, concrete nouns and action verbs (words like "cat" and "jump") from whole sentences in basic-NEMO with a novel representation of word and contextual inputs. Extending the same model, we present an algorithm for an elementary component of syntax, namely learning the word order of 2-constituent intransitive and 3-constituent transitive sentences. These algorithms are very broadly in line with what is known about language in the brain.
|
39 |
Effects of adolescent stress on depressive- and anxiety-like behaviors and hippocampal mossy fibre-CA3 remodeling in the novelty-seeking phenotype: implications for epigenetic regulation of the BDNF geneUnknown Date (has links)
Experimentally naive rats show variance in their locomotor reactivity to novelty, some displaying higher (HR) while others displaying lower (LR) reactivity, associated with vulnerability to stress. LRHR phenotype is proposed as an antecedent to the development of stress hyper responsiveness. Results presented here show emergence of antidepressive-like behavior following peripubertal-juvenile exposure to chronic variable physical (CVP) and chronic variable social stress (CVS) in HR rats, and depressive-like behavior following CVP in the LRs. The antidepressive-like behavior in HR rats was accompanied by increased levels of acetylated Histone3 (acH3) and acetylated Histone4 (acH4) at the hippocampal brain-derived neurotrophic factor (BDNF) P2 and P4 promoters respectively. This effect may mediate increased mossy fibre (MF) terminal field size, particularly the suprapyramidal mossy fibre projection volume (SP-MF), in the HR animals following both stress regimens. These findings show that chronic variable stress during adolescence induces individual differences in molecular, neuromorphological and behavioral parameters between LRs and HRs, which provides further evidence that individual differences in stress responsiveness is an important factor in resistance or vulnerability to stress-induced depression and/or anxiety. / by Ozge Oztan. / Thesis (Ph.D.)--Florida Atlantic University, 2013. / Includes bibliography. / Mode of access: World Wide Web. / System requirements: Adobe Reader.
|
40 |
Time-frequency classification of gamma oscillatory activity in the frontoparietal system during working memoryUnknown Date (has links)
Working memory (WM) is a process that allows for the temporary and limited storage of information for an immediate goal or to be stored into a more permanent system. A large number of studies
have led to the widely accepted view that WM is mediated by the frontoparietal network (FPN), consisting
of areas in the prefrontal cortex (PFC) and posterior parietal cortex (PPC). Current evidence suggests that
task specific patterns of neuronal oscillatory activity within the FPN play a fundamental role in WM, and
yet specific spatio-temporal properties of this activity are not well characterized. This study utilized multisite
local field potential (LFP) data recorded from PFC and PPC sites in two macaque monkeys trained to
perform a rule-based, Oculomotor Delayed Match-to-Sample task. The animals were required to learn
which of two rules determined the correct match (Location matching or Identity matching). Following a
500 ms fixation period, a sample stimulus was presented for 500 ms, followed by a randomized delay
lasting 800-1200 ms in which no stimulus was present. At the end of the delay period, a match stimulus
was presented, consisting of two of three possible objects presented at two of three possible locations.
When the match stimulus appeared, the monkey made a saccadic eye movement to the target. The rule in
effect determined which object served as the target. Time-frequency plots of three spectral measures
(power, coherence, and Wiener Granger Causality (WGC) were computed from MultiVariate
AutoRegressive LFP time-series models estimated in a 100-ms window that was slid across each of three
analysis epochs (fixation, sample, and delay). Low (25- 55 Hz) and high gamma (65- 100 Hz) activity were investigated separately due to evidence that they may be functionally distinct. Within each epoch, recording sites in the PPC and PFC were classified into groups according to the similarity of their power t-f plots derived by a K-means clustering algorithm. From the power-based site groups, the corresponding coherence and WGC were analyzed. This classification procedure uncovered spatial, temporal, and frequency dynamics of FPN
involvement in WM and other co-occurring processes, such as sensory and target related processes. These processes were distinguishable by rule and performance accuracy across all three spectral measures- power,
coherence, and WGC. Location and Identity rule were distinguishable by the low and high-gamma range. / Includes bibliography. / Dissertation (Ph.D.)--Florida Atlantic University, 2014. / FAU Electronic Theses and Dissertations Collection
|
Page generated in 0.4113 seconds