Brain structural and functional changes during the course of schizophrenia

Guo, Yu

January 2014

No description available.

616.89

Brain--Pathophysiology ; Schizophrenia

Bladder and brain function in children with severe nocturnal enuresis. / CUHK electronic theses & dissertations collection

January 2005

Conclusion. Impairment in bladder and brain functions was identified in children with severe NE. Post-treatment studies indicated that brain function normalized in parallel with amelioration of bladder dysfunction. Interaction between brain and bladder dysfunction is likely to have an important implication in the pathophysiology and resolution of NE. / Objective. To (1) investigate sleep pattern and cortical arousals in enuretic children; (2) assess brain and bladder function in enuretic children; (3) evaluate post-treatment brain and bladder functional changes in enuretic children and correlate these with the treatment outcomes. / Part II. Fifty-two patients with severe PNE and 15 normal controls were recruited. Bladder and brain functions (sleep arousal threshold, P300 ERPs latency and PPI of startle amplitude) in enuretic children were evaluated, and brain function was compared with normal controls. / Part II. Markedly reduced nocturnal FBC and impaired brain function were found in enuretic patients. Higher sleep arousal threshold was negatively correlated to lower FBC. Prolonged P300 ERPs and higher PPI of startle amplitude were positively correlated to a higher sleep arousal threshold. / Part III. NE episodes and bladder function were re-evaluated in 52 severely enuretic children (Part II) at 3 and 6 months on treatment. Brain function was re-evaluated in 41/52 enuretic children at 6 months on treatment. / Part III. Post-treatment FBC significantly increased, and sleep arousal threshold, number of awakenings, P300 ERPs latency and PPI of startle amplitude normalized in treatment responders. NE episodes reduction was significantly correlated to the improvement in FBC and brain function. Greater decrease in sleep arousal threshold was positively correlated to higher FBC increase. Higher P300 ERPs latency and PPI of startle amplitude reduction were positively correlated to greater decrease in sleep arousal threshold. / Patients and methods. Part I. Thirty-five children with refractory PNE and 21 normal controls were recruited. Overactive bladder contractions, NE episodes and volume in enuretic children, sleep stages and cortical arousals in all children were recorded. / Results. Part I. Underlying bladder dysfunction, abnormal sleep architecture and increased cortical arousal index were found in enuretic children. Cortical arousal index was positively correlated to the frequency of overactive bladder contractions. / Diao Mei. / "May 2005." / Adviser: Chung-Kwong Yeung. / Source: Dissertation Abstracts International, Volume: 67-07, Section: B, page: 3693. / Thesis (Ph.D.)--Chinese University of Hong Kong, 2005. / Includes bibliographical references (p. 135-159). / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Electronic reproduction. [Ann Arbor, MI] : ProQuest Information and Learning, [200-] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Abstract in English and Chinese. / School code: 1307.

Bladder--Pathophysiology

Brain--Pathophysiology

Enuresis

Brain--pathophysiology

Child

Nocturnal Enuresis

Urinary Bladder--pathophysiology

Executive function deficits in traumatic brain injury

LaRoux, Charlene I., 1979-

12 1900

xii, 98 p. : ill. (some col.) / The short and long term pathophysiology of traumatic brain injury (TBI) has not been fully elucidated. Individuals recently suffering a mild TBI (mTBI) or having a history of TBI frequently suffer deficits in their ability to maintain and allocate attention within and between tasks. This dissertation examines the influence of mild and chronic TBI on performance of task switching. We employed spatial and numerical task switching paradigms to assess the behavioral deficits in mTBI, and we used an internally generated switching and an externally cued switching task along with functional Magnetic Resonance Imaging (fMRI) to assess the long term deficits in executive function resulting from chronic TBI. In the first experiment, individuals with mTBI were identified and tested within the first 48 hours of injury and then at a set interval 5, 14, and 28 days post injury. In the second investigation, individuals with chronic TBI were tested at least 12 months after their most recent injury. Healthy gender, age, and education matched controls were also tested in both studies. This research demonstrated that mTBI subjects display deficits in switching behavior within 48 hours of injury that failed to resolve a month post-injury; however, these costs did not generalize across the switching task types. Chronic TBI subjects performed internally generated and externally cued switching paradigms with a degree of success equivalent to that of healthy controls but displayed larger amounts of activation and recruited more areas of the brain at lower levels of difficulty and did not increase recruitment in a stepwise fashion at higher levels of difficulty. Mild TBI causes significant deficits in task switching, but there is specificity in these deficits. Chronic TBI patients performed at a level equivalent to that of controls but displayed different patterns and degree of activation. Taken together, these findings indicate that there may be a specific time frame during which task switching shows behavioral deficits, after which the subject may compensate for these deficits to produce normalized performance. / Committee in Charge: Dr. Paul van Donkelaar, Chair; Dr. Li-Shan Chou; Dr. Ulrich Mayr; Dr. Marjorie Woollacott

Executive function

Traumatic brain injury

Neurosciences

Physiology

Brain injury

Brain -- Pathophysiology

Effects of coadministration of D-Napvsipq [NAP] and D-Sallrsipa [SAL] on spatial learning after developmental alcohol exposure

Wagner, Jennifer Lynne

January 2013

Indiana University-Purdue University Indianapolis (IUPUI) / Despite warnings about the dangers of drinking during pregnancy, little progress has been made in reducing alcohol drinking among women of childbearing age. Even after the recognition of pregnancy, 15% of women continue to drink, 3% of which admit to binge drinking. Because we cannot stop women from drinking during pregnancy, and many children with fetal alcohol spectrum disorders (FASD) are adopted, there is a significant need to develop postnatal interventions that can improve the long-term outcome of children adversely affected by prenatal alcohol exposure. This thesis aims to evaluate one promising new treatment in the rehabilitation or rescue of specific learning deficits long after the damage has occurred. The treatment evaluated herein (40µg D-NAP + 40µg D-SAL) has long been used in the prevention of the detrimental effects of long-term and binge-like alcohol exposures in rodent models of fetal alcohol syndrome and FASD. Until recently this peptide treatment had only been shown to be effective in preventing some of the consequences of alcohol exposure when administered concurrently with the prenatal alcohol exposure. A recent report by Incerti and colleagues (2010c), however, reported that these peptides could completely reverse a profound spatial learning deficit induced by one episode of a heavy binge-like alcohol exposure (5.9g.kg in a single intraperitoneal injection) on gestational day 8 (G8) in C57BL/6 mice. In that report, the peptide treatment was administered starting in late adolescence, beginning three days prior to and throughout water maze training, and the profound deficits in their alcohol-placebo group were completely eliminated in the alcohol-peptide group. There are currently no FDA-approved treatments for FASD. An effective treatment for the cognitive and behavioral dysfunctions suffered by the 1% of people born today could potentially improve the lives of millions of children and adults. The first aim of this thesis was to determine whether the peptide treatment could reverse the significant spatial learning deficits we have demonstrated in adult C57BL/6 mice given high-dose binge-like alcohol exposure (2.5 g/kg in each of two intraperitoneal injections separated by two hours) on postnatal day (P)7. When administered three days prior to and throughout water maze testing (P67-76), the peptide treatment had no effect on spatial learning. The second aim sought to determine whether the same peptide treatment could reverse water maze spatial learning deficits in G8 binge-like exposure models, as reported by Incerti et al. (2010c). For this analysis, the first study used a different binge-like alcohol exposure model that is more commonly used than that employed by the Incerti et al. (2010c) study, namely administration of 2.8g/kg in each of two intraperitoneal injections separated by four hours (Sulik et al., 1981). This model has been shown to produce high peak blood alcohol concentrations and neuroanatomical aberrations in the hippocampal formation and septal regions (Parnell et al., 2009), which have been implicated in learning and memory. Surprisingly, this G8 binge-like alcohol exposure failed to produce a spatial learning deficit, undermining the usefulness of this model in evaluating the peptide effects. In direct contrast to the outcomes of Incerti et al. (2010c), the G8 Webster alcohol exposure was also unable to produce any deficits in acquisition of spatial learning in the Morris water maze. Surprisingly, neither of the heavy binge-like alcohol exposures on G8 were able to produce spatial learning deficits in the Morris water maze. The binge-like alcohol exposure on P7 did yield the expected spatial learning deficit, but the peptide treatment was unsuccessful in recovering water maze learning. These findings fail to support oral administration of 40µg D-NAP and 40 µg D-SAL as a potential therapy for postnatal alcohol-induced spatial learning deficits in adult mice.

Fetal Alcohol Spectrum Disorder

Spatial Learning

Morris Water Maze

Neurodegeneration

Alcoholism -- Pregnancy -- Research

Nervous system -- Degeneration

Fetal alcohol syndrome -- Research

Binge drinking

Space perception -- Pathophysiology

Spatial behavior -- Pathophysiology

Peptides -- Therapeutic use

Maze tests -- Research

Hippocampus (Brain) -- Pathophysiology

Septum (Brain) -- Pathophysiology

Cognitive psychology -- Research

Learning disabilities

Postnatal care -- Research

Mice as laboratory animals -- Research

Pathways to dementia: genetic predictors of cognitive and brain imaging endophenotypes in Alzheimer's disease

Ramanan, Vijay K

03 January 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Alzheimer's disease (AD) is a national priority, with nearly six million Americans affected at an annual cost of $200 billion and no available cure. A better understanding of the mechanisms underlying AD is crucial to combat its high and rising incidence and burdens. Most cases of AD are thought to have a complex etiology with numerous genetic and environmental factors influencing susceptibility. Recent genome-wide association studies (GWAS) have confirmed roles for several hypothesized genes and have discovered novel loci associated with disease risk. However, most GWAS-implicated genetic variants have displayed modest individual effects on disease risk and together leave substantial heritability and pathophysiology unexplained. As a result, new paradigms focusing on biological pathways have emerged, drawing on the hypothesis that complex diseases may be influenced by collective effects of multiple variants – of a variety of effect sizes, directions, and frequencies – within key biological pathways. A variety of tools have been developed for pathway-based statistical analysis of GWAS data, but consensus approaches have not been systematically determined. We critically review strategies for genetic pathway analysis, synthesizing extant concepts and methodologies to guide application and future development. We then apply pathway-based approaches to complement GWAS of key AD-related endophenotypes, focusing on two early, hallmark features of disease, episodic memory impairment and brain deposition of amyloid-β. Using GWAS and pathway analysis, we confirmed the association of APOE (apolipoprotein E) and discovered additional genetic modulators of memory functioning and amyloid-β deposition in AD, including pathways related to long-term potentiation, cell adhesion, inflammation, and NOTCH signaling. We also identified genetic associations to amyloid-β deposition that have classically been understood to mediate learning and memory, including the BCHE gene and signaling through the epidermal growth factor receptor. These findings validate the use of pathway analysis in complex diseases and illuminate novel genetic mechanisms of AD, including several pathways at the intersection of disease-related pathology and cognitive decline which represent targets for future studies. The complexity of the AD genetic architecture also suggests that biomarker and treatment strategies may require simultaneous targeting of multiple pathways to effectively combat disease onset and progression.

Alzheimer's disease (AD)

Genome-wide association study (GWAS)

Biological pathway analysis

Episodic memory

Amyloid plaque

Senile dementia

Brain -- Pathophysiology -- Research

Cognition -- Pathophysiology -- Research

Memory -- Pathophysiology -- Research

Cell adhesion -- Molecular aspects

Notch genes

Epidermal growth factor -- Research

Inflammation -- Molecular aspects

Phenotype -- Research

Molecular genetics -- Research

Epigenetic alteration by prenatal alcohol exposure in developing mouse hippocampus and cortex

Chen, Yuanyuan

January 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Fetal alcohol spectrum disorders (FASD) is the leading neurodevelopment deficit in children born to women who drink alcohol during pregnancy. The hippocampus and cortex are among brain regions vulnerable to alcohol-induced neurotoxicity, and are key regions underlying the cognitive impairment, learning and memory deficits shown in FASD individuals. Hippocampal and cortical neuronal differentiation and maturation are highly influenced by both intrinsic transcriptional signaling and extracellular cues. Epigenetic mechanisms, primarily DNA methylation and histone modifications, are hypothesized to be involved in regulating key neural development events, and are subject to alcohol exposure. Alcohol is shown to modify DNA methylation and histone modifications through altering methyl donor metabolisms. Recent studies in our laboratory have shown that alcohol disrupted genome-wide DNA methylation and delayed early embryonic development. However, how alcohol affects DNA methylation in fetal hippocampal and cortical development remains elusive, therefore, will be the theme of this study. We reported that, in a dietary alcohol-intake model of FASD, prenatal alcohol exposure retarded the development of fetal hippocampus and cortex, accompanied by a delayed cellular DNA methylation program. We identified a programed 5-methylcytosine (5mC) and 5-hydroxylmethylcytosine (5hmC) cellular and chromatic re-organization that was associated with neuronal differentiation and maturation spatiotemporally, and this process was hindered by prenatal alcohol exposure. Furthermore, we showed that alcohol disrupted locus-specific DNA methylation on neural specification genes and reduced neurogenic properties of neural stem cells, which might contribute to the aberration in neurogenesis of FASD individuals. The work of this dissertation suggested an important role of DNA methylation in neural development and elucidated a potential epigenetic mechanism in the alcohol teratogenesis.

Epigenetics

Epigenetics -- Research -- Methodology

Alcohol -- Physiological effect

Cognition disorders -- Animal models

DNA -- Methylation -- Research

Histones -- Research

Neural stem cells

Developmental genetics

Genetic transcription

Neural basis and behavioral effects of dynamic resting state functional magnetic resonance imaging as defined by sliding window correlation and quasi-periodic patterns

Thompson, Garth John

20 September 2013

While task-based functional magnetic resonance imaging (fMRI) has helped us understand the functional role of many regions in the human brain, many diseases and complex behaviors defy explanation. Alternatively, if no task is performed, the fMRI signal between distant, anatomically connected, brain regions is similar over time. These correlations in “resting state” fMRI have been strongly linked to behavior and disease. Previous work primarily calculated correlation in entire fMRI runs of six minutes or more, making understanding the neural underpinnings of these fluctuations difficult. Recently, coordinated dynamic activity on shorter time scales has been observed in resting state fMRI: correlation calculated in comparatively short sliding windows and quasi-periodic (periodic but not constantly active) spatiotemporal patterns. However, little relevance to behavior or underlying neural activity has been demonstrated. This dissertation addresses this problem, first by using 12.3 second windows to demonstrate a behavior-fMRI relationship previously only observed in entire fMRI runs. Second, simultaneous recording of fMRI and electrical signals from the brains of anesthetized rats is used to demonstrate that both types of dynamic activity have strong correlates in electrophysiology. Very slow neural signals correspond to the quasi-periodic patterns, supporting the idea that low-frequency activity organizes large scale information transfer in the brain. This work both validates the use of dynamic analysis of resting state fMRI, and provides a starting point for the investigation of the systemic basis of many neuropsychiatric diseases.

fMRI

Dynamic analysis

Sliding window

Sliding windows

Resting state

Default mode

Functional connectivity

Functional network

Correlation

Coherence

Functional magnetic resonance imaging

Local field potentials

LFP

Band-limited power

BLP

Inter-individual

Intra-individual

Spontaneous activity

Brain

Primary somatosensory cortex

Rodent

Rat

Human

Simultaneous experiments

Neural basis

Glial basis

Neurons

Astrocytes

Vasomotion

Hemodynamic response

Dynamic

Spatiotemporal dynamics

Quasi-periodic patterns

Brain networks

Resting state networks

Anesthesia

Dexmedetomidine

Isoflurane

Awake

Global signal

Magnetic resonance imaging

Brain Pathophysiology

Brain mapping