We could predict good responders to vagus nerve stimulation: a surrogate marker by slow cortical potential shift / 脳波の緩電位変化は迷走神経刺激療法の治療効果の代替マーカーとなる

Borgil, Bayasgalan

24 November 2017

京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第20755号 / 医博第4285号 / 新制||医||1024(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 伊佐 正, 教授 宮本 享, 教授 井上 治久 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

EEG

vagus nerve stimulation

slow cortical potentials

surrogate marker

long time constant

490

Remembering my friends: Medial prefrontal and hippocampal contributions to the self-reference effect on face memories in a social context / 社会的文脈での顔記憶に対する自己参照効果の基盤となる内側前頭前野と海馬の役割

Yamawaki, Rie

23 January 2018

京都大学 / 0048 / 新制・課程博士 / 博士(人間健康科学) / 甲第20813号 / 人健博第50号 / 新制||人健||4(附属図書館) / 京都大学大学院医学研究科人間健康科学系専攻 / (主査)教授 三谷 章, 教授 二木 淑子, 教授 村井 俊哉 / 学位規則第4条第1項該当 / Doctor of Human Health Sciences / Kyoto University / DGAM

fMRI

encoding

self-reference effect

medial prefrontal cortex

cortical midline structure

hippocampus

social context

498

Cortical Morphology and Neuropsychological Performance in Idiopathic Childhood Epilepsy

Fujiwara, Hisako

02 October 2018

No description available.

Neurology

Childhood Absence Epilepsy

Cortical Morphology

Neuropsychological Performance

Análisis de los flujos de deposición global, trascolación, escorrentía cortical y deposición seca en el encinar mediterráneo de L'Avic (Sierra de Prades, Tarragona)

Bellot, Juan

03 February 1989

No description available.

Hidrología forestal

Deposición global

Precipitación incidente

Trascolación

Escorrentía cortical

Encinar

L'Avic

Ecología

The Role of Pals1 in Brain Development and Microcephaly

Sterling, Noelle, 0000-0002-0663-5088

January 2023

Microcephaly is a debilitating condition in which children are born with small brains. It can be caused by a variety of factors including maternal infection, harmful substance exposure, and genetic mutation. Cerebral cortical development is often severely disrupted in human microcephaly patients. In order to form the billions of neurons which exist in the cortex, efficient and correct neural progenitor division, differentiation, and migration are key. As the center of higher brain function in mammals, reduction in cortical mass is associated with the developmental delays that are symptomatic of microcephaly. Recently, a number of microcephaly causes have been linked to P53-mediated apoptosis of neural cells. The tumor suppressor protein P53 is upregulated in response to mitotic cycle stress, and its activation can trigger cell cycle arrest or apoptotic cell death. In microcephaly, P53 can become activated by mitotic stress and trigger apoptosis to cause the loss of cortical cell numbers that leads to microcephaly. Microcephaly has often been linked to mutations in mitotic proteins that alter neural progenitor division. However, the apical polarity complex Protein Associated with Lin-7 1 (PALS1) – known as membrane palmitoylated protein (MPP)5 in people – has recently been implicated in human microcephaly. PALS1 is integral to establishing polarity in neural progenitors. Deletion of Pals1 in mouse models has also resulted in microcephaly characterized by smaller brains and a global reduction in cortical cell numbers. Interestingly, a cellular phenomenon known as entosis can be caused by polarity disruptions in epithelial cells, and P53 activation has been shown to cause entosis in MDCK cell culture. While entosis is mainly associated with cancer cells, it is a form of competitive cell cannibalism that can eliminate unfit cells from a population. The loss of PALS1 from the developing cortex is known to result in apical polarity complex disruption and microcephaly in mouse models. However, the mechanism by which the loss of PALS1 results in cortical abrogation has yet to be determined. In Chapter 1 of this dissertation, I begin by reviewing cortical development. The normal progression of cortical cells from neural progenitors to fully differentiated neurons is explained in detail. Neural progenitor mitosis in particular is addressed in detail. Furthermore, an overview of microcephaly is provided to address the similarities between known causes of microcephaly. Next, I review the polarity complex proteins and their roles in cortical development. I compare and contrast the cortical phenotypes that have been described when each of the polarity complex proteins has been genetically deleted from the mouse cortex. I go on to review studies that have shown P53-mediated apoptosis in microcephaly in order to address the phenotypic features of microcephaly that are or are not caused by P53 activation. Finally, I provide a brief history of entosis. As a newly discovered cellular process in neural progenitors, the overview of entosis highlights what is known about cell cannibalism and the contexts in which it occurs. Following this background, I describe the experimental aims, hypotheses, and methods for this project in Chapter 2. In Chapter 3, I describe our investigation of three human patients with mutations in the Pals1 gene. One of the patients, possessing a heterozygous de novo nonsense mutation in Pals1 (or MPP5), was diagnosed with microcephaly. In order to model this patient’s phenotype, we generated a heterozygous conditional knockout of Pals1 from the entire mouse nervous system with Nestin-Cre. Through behavioral analysis of these mice, I demonstrate that they are hyperactive and blind, mimicking the microcephaly patient’s symptoms. Furthermore, via analysis of the mouse cortex, I show that heterozygous deletion of Pals1 results in severe microcephaly in mice with a global reduction in cortical cell numbers at both adult and embryonic stages. Importantly, I determine that Pals1 deletion does not result in proliferation or migration defects in the mouse cortex. Instead, loss of PALS1 results in massive apoptotic cell death that affects every cell type produced in the developing cortex. In Chapter 4, I detail our investigation into the mechanism underlying cell death in the PALS1-deficient cortex. By studying dividing neural progenitors at the apical surface in both Emx1-Cre and hGFAP-Cre drive Pals1 conditional knockout models, I demonstrate an as yet undescribed neural progenitor phenotype called entosis. As has been shown in cancer cells, neural progenitor entosis is dynamic and reliant on Rho-ROCK activity to occur. Furthermore, entosis produces observable cell-in-cell structures that persist through outer cell division and cause mitotic delay. I go on to demonstrate P53 activation in Pals1 deficient mouse cortices, and show that genetic deletion of Trp53 significantly rescues microcephaly. Trp53 deletion significantly restores all cortical cell types in addition to ameliorating entosis and mitotic length. This study suggests that P53 activation is a major mechanism by which PALS1 loss results in microcephaly. Overall, these studies show that deletion of Pals1 in mice can mimic microcephaly found in a human patient with a Pals1 mutation. Furthermore, PALS1 loss promotes P53-mediated cortical cell apoptosis. These studies provide the first description of entosis in neural progenitors, and suggest that entosis could be a mechanism for unfit cell removal in the developing cortex. Furthermore, I provide evidence that ROCK inhibition can fully rescue the presence of entosis in PALS1-deficient neural progenitors, and that genetic deletion of Trp53 significantly restores microcephaly pathology after PALS1 loss. These studies open up a field of research into the causes and effects of entosis in neural progenitors, and provide further evidence that apoptotic cell death in microcephaly is largely mediated by P53 activation. / Biomedical Sciences

Neurosciences

Developmental biology

Genetics

Cortical development

Entosis

Microcephaly

p53

Pals1

Polarity complex proteins

Reversible decortication and habituation of reactions to novelty.

Nadel, Lynn.

January 1965

No description available.

Cerebral cortex -- Physiology.

Rats -- Behavior.

Spreading cortical depression.

Psychology.

Habituation (Neuropsychology).

Statistical Examination of Myelinated Cortical Thickness in Bipolar Disorder

Zaharieva, Nadejda

11 1900

The human cerebral cortex, the outermost layer of the brain, is typically considered in imaging studies to consist of grey matter (GM), with white matter (WM) lying below it. With better imaging techniques, a third tissue type, found between GM and WM, can be identified. This layer contains myelinated axons and is found in the cortex, thus we call it intracortical myelin (ICM), or myelinated grey matter (GMm). We examined the cortical thickness measurements in female patients with bipolar I or II disorders (BD) versus healthy controls. Previous studies have only examined the thickness of the entire cortex, the GM. We developed a processing pipeline and a statistical tool for examining the ICM thickness between two groups. Results show that there are potential differences in GMm between BD and control groups. Further regional and statistical analysis is required to identify the regions of greatest difference, and to confirm significant differences between BD and control groups. / Thesis / Master of Science (MSc)

neuroscience

neuroimaging

MRI

bipolar disorder

statistics

myelin

ICM

cortex

cortical myelin

image processing

A MORPHOLOGICAL STUDY OF THE PRIMARY MOTOR CORTEX IN HUMANS USING HIGH RESOLUTION ANATOMICAL MAGNETIC RESONANCE IMAGING (MRI) / A MORPHOLOGICAL STUDY OF THE PRIMARY MOTOR CORTEX USING MRI

Hashim, Eyesha

11 1900

Myeloarchitecture is a prominent feature that can identify the primary motor and sensory areas in the cerebral cortex and is increasingly imaged in magnetic resonance imaging (MRI) studies of cortical parcellation in humans. However, MRI studies of cortical myeloarchitecture are technically difficult for two reasons: the cortex is only a few millimeters thick, and intracortical contrast due to myelin is much smaller than the overall anatomical contrast between cortical tissue and underlying white matter that is typically utilized in imaging. The research in this thesis thus presents specific MRI protocols to visualize intracortical myelin, image processing protocols to delineate the heavily myelinated cortex from the adjacent typical cortex and the application of these techniques in the precentral motor cortex to study morphology of the highly myelinated dorso-medial part, consisting of Brodmann area (BA) 4 and part of BA 6. Optimization of the MRI protocols involved determining the sequence parameters for a T1-weighted MRI sequence to obtain maximal intracortical contrast at 0.7 mm isotropic resolution in imaging time of 15 min, based on T1 differences between cortex that is myelinated (GMm) or unmyelinated (GM). As part of the optimization, T1 values were measured in the following brain tissues: GM, GMm and white matter (WM). The optimization was carried out by simulating the MRI signal for a 3D, magnetization prepared, gradient echo sequence, using the measured T1 values in the analytical signal equations. It was found that lengthening the time delay at the end of each inner phase encoding loop increased the intracortical contrast. The optimization of MRI protocols also included implementing techniques to reduce radio frequency field (B1) inhomogeneities. It was found that dividing the optimized, T1-weighted MRI with a predominantly proton density weighted image resulted in a ratio image with significantly reduced B1 inhomogeneities. The goal of the image processing protocols developed in this thesis was to visualize the variation of intracortical myelin across the precentral motor cortex and to delineate its well-myelinated dorso-medial part. The myeloarchitectonic feature that was selected to visualize the variation in intracortical myelination was the thickness of GMm in the deeper parts of the cortex relative to the cortical thickness, referred to as the proportional myelinated thickness (p). To measure p, the following processing steps were performed. The ratio image was segmented into four tissues: GM, GMm, WM and cerebrospinal fluid (CSF) using fuzzy C-means clustering technique. Using a level set approach, thickness of the cortex was determined as the distance between the outer boundaries of GM and WM and thickness of GMm or myelinated thickness (m) was determined as the distance between the outer boundaries of GMm and WM. The proportional myelinated thickness p, was calculated as follows: p= m/t. The well-myelinated dorso-medial part of the precentral cortex, referred to as Mm, was distinguishable from the adjacent cortex when the proportional myelinated thickness was projected on the outer cortical surface. The optimized MRI and image processing techniques developed in this thesis were used to investigate cortical plasticity in amputees. Two morphological features of the myeloarchitecture over Mm, the mean proportional myelinated thickness and area, were measured in four lower limb amputees and four matched controls. A comparison of these morphological features showed no statistically significant difference (p < 0.05) between the two groups. / Thesis / Doctor of Philosophy (PhD)

Magnetic resonance imaging

Myelin

Primary motor cortex

Human

Longitudinal relaxation time

Cortical morphology

Association of Cortical Superficial Siderosis with Post-Stroke Epilepsy / 脳卒中後てんかんと脳表シデローシスの関連

Tanaka, Tomotaka

23 May 2023

京都大学 / 新制・論文博士 / 博士(医学) / 乙第13554号 / 論医博第2283号 / 新制||医||1067(附属図書館) / (主査)教授 村井 俊哉, 教授 永井 洋士, 教授 井上 治久 / 学位規則第4条第2項該当 / Doctor of Medical Science / Kyoto University / DFAM

cortical superficial siderosis

post-stroke epilepsy

risk models

hemosiderin

neuroimaging

490

Evaluation of ultrasonic shear wave propagation in cortical bone by axial transmission technique / アキシャルトランスミッション法による骨中を伝搬する横波超音波の評価 / アキシャル トランスミッションホウ ニヨル コッチュウ オ デンパン スル ヨコナミ チョウオンパ ノ ヒョウカ / アキシャルトランスミッション法による皮質骨中を伝搬する横波超音波の評価 / アキシャル トランスミッションホウ ニヨル ヒシツ コッチュウ オ デンパン スル ヨコナミ チョウオンパ ノ ヒョウカ

Leslie Vanessa Bustamante Diaz

19 September 2020

Quantitative Ultrasound (QUS) techniques with the advantages of an axial transmission measurement were applied to implement an ultrasonic system for cortical bone evaluation. This evaluation is focused on the measurement and characterization of shear waves propagating in the axial direction of the cortical layer of bone. Signals were analyzed in time and frequency domains. And, in order to understand the wave propagation phenomenon, and predict experimental results, simulations using the elastic Finite-difference-time-domain (FDTD) method were implemented considering isotropic and anisotropic bone models. Additionally, shear wave velocities using the axial method were verified by a simple thought transmission measurement. / 博士(工学) / Doctor of Philosophy in Engineering / 同志社大学 / Doshisha University

Quantitative Ultrasound

Cortical Bone

Axial Transmission

FDTD

Shear wave

Bone evaluation