A longitudinal study of brain structure in the early stages of schizophrenia

Whitford, Thomas James

January 2007

Doctor of Philosophy (PhD) / Schizophrenia is a severe mental illness that affects approximately 1% of the population worldwide, and which typically has a devastating effect on the lives of its sufferers. The characteristic symptoms of the disease include hallucinations, delusions, disorganized thought and reduced emotional expression. While many of the early theories of schizophrenia focused on its psychosocial foundations, more recent theories have focused on the neurobiological underpinnings of the disease. This thesis has four primary aims: 1) to use magnetic resonance imaging (MRI) to identify the structural brain abnormalities present in patients suffering from their first episode of schizophrenia (FES), 2) to elucidate whether these abnormalities were static or progressive over the first 2-3 years of patients’ illness, 3) to identify the relationship between these neuroanatomical abnormalities and patients’ clinical profile, and 4) to identify the normative relationship between longitudinal changes in neuroanatomy and electrophysiology in healthy participants, and to compare this to the relationship observed between these two indices in patients with FES. The aim of Chapter 2 was to use MRI to identify the neuroanatomical changes that occur over adolescence in healthy participants, and to identify the normative relationship between the neuroanatomical changes and electrophysiological changes associated with healthy periadolescent brain maturation. MRI and electroencephalographic (EEG) scans were acquired from 138 healthy participants between the ages of 10 and 30 years. The MRI scans were segmented into grey matter (GM) and white matter (WM) images, before being parcellated into the frontal, temporal, parietal and occipital lobes. Absolute EEG power was calculated for the slow-wave, alpha and beta frequency bands, for the corresponding cortical regions. The age-related changes in regional tissue volumes and regional EEG power were inferred with a regression model. The results indicated that the healthy participants experienced accelerated GM loss, EEG power loss and WM gain in the frontal and parietal lobes between the ages of 10 and 20 years, which decelerated between the ages of 20 and 30 years. A linear relationship was also observed between the maturational changes in regional GM volumes and EEG power in the frontal and parietal lobes. These results indicate that the periadolescent period is a time of great structural and electrophysiological change in the healthy human brain. The aim of Chapter 3 was to identify the GM abnormalities present in patients with FES, both at the time of their first presentation to mental health services (baseline), and over the first 2-3 years of their illness (follow-up). MRI scans were acquired from 41 patients with FES at baseline, and 47 matched healthy control subjects. Of these participants, 25 FES patients and 26 controls returned 2-3 years later for a follow-up scan. The analysis technique of voxel-based morphometry (VBM) was used in conjunction with the Statistical Parametric Mapping (SPM) software package in order to identify the regions of GM difference between the groups at baseline. The related analysis technique of tensor-based morphometry (TBM) was used to identify subjects’ longitudinal GM change over the follow-up interval. Relative to the healthy controls, the FES patients were observed to exhibit widespread GM reductions in the frontal, parietal and temporal cortices and cerebellum at baseline, as well as more circumscribed regions of GM increase, particularly in the occipital lobe. Furthermore, the FES patients lost considerably more GM over the follow-up interval than the controls, particularly in the parietal and temporal cortices. These results indicate that patients with FES exhibit significant structural brain abnormalities very early in the course of their illness, and that these abnormalities progress over the first few years of their illness. Chapter 4 employed the same methodology to investigate the white matter abnormalities exhibited by the FES subjects relative to the controls, both at baseline and over the follow-up interval. Compared to controls, the FES patients exhibited volumetric WM deficits in the frontal and temporal lobes at baseline, as well as volumetric increases at the fronto-parietal junction bilaterally. Furthermore, the FES patients lost considerably more WM over the follow-up interval than did the controls in the middle and inferior temporal cortex bilaterally. While there is substantial evidence indicating that abnormalities in the maturational processes of myelination play a significant role in the development of WM abnormalities in FES, the observed longitudinal reductions in WM were consistent with the death of a select population of temporal lobe neurons over the follow-up interval. The aim of Chapter 5 was to investigate the clinical correlates of the GM abnormalities exhibited by the FES patients at baseline. The volumes of four distinct cerebral regions where 31 patients with FES exhibited reduced GM volumes relative to 30 matched controls were calculated and correlated with patients’ scores on three primary symptom dimensions: Disorganization, Reality Distortion and Psychomotor Poverty. The results indicated that the greater the degree of atrophy exhibited by the FES patients in three of these four ‘regions-of-reduction’, the less severe their degree of Reality Distortion. These results suggest that an excessive amount of GM atrophy may in fact preclude the formation of hallucinations or highly systematized delusions in patients with FES. The aim of Chapter 6 was to identify the relationship between the longitudinal changes in brain structure and brain electrophysiology exhibited by 19 FES patients over the first 2-3 years of their illness, and to compare it to the normative relationship between the two indices reported in Chapter 2. The methodology employed for the parcellation of the MRI and EEG data was identical to Chapter 2. The results indicated that, in contrast to the healthy controls, the longitudinal reduction in GM volume exhibited by the FES patients was not associated with a corresponding reduction in EEG power in any brain lobe. In contrast, EEG power was observed to be maintained or even to increase over the follow-up interval in these patients. These results were consistent with the FES patients experiencing an abnormal elevation of neural synchrony. Such an abnormality in neural synchrony could potentially form the basis of the dysfunctional neural connectivity that has been widely proposed to underlie the functional deficits present in patients with schizophrenia. The primary aim of Chapter 7 was to assimilate the findings from the preceding empirical chapters with the theoretical framework provided in the literature, into an integrated and testable model of schizophrenia. The model emphasized dysfunctions in brain maturation, specifically in the normative processes of synaptic ‘pruning’ and axonal myelination, as playing a key role in the development of disintegrated neural activity and the subsequent onset of schizophrenic symptoms. The model concluded with the novel proposal that disintegrated neural activity arises from abnormal elevations in the synchrony of synaptic activity in patients with first-episode schizophrenia.

schizophrenia

magnetic resonance imaging (MRI)

electroencephalography (EEG)

longitudinal

voxel-based morphometry

grey matter

white matter

neuroanatomy

tensor-based morphometry

neurodevelopmental

neurodegenerative

Pravidla buněčného škálování mozku u hrabavých ptáků / Cellular scaling rules for brains of gallinaceous birds

Zhang, Yicheng

January 2018

Galliform birds (Galliformes) make up together with anseriform birds (Anseriformes) the clade Galloanserae, the sister group of Neoaves and the most basal clade of Neognathae. However, to date no quantitative data on cellular composition of their brains have been available. Here, I used the isotropic fractionator to determine numbers of neurons and non-neuronal cells in specific brain regions of 15 species of galliform birds. I find that cellular scaling rules for galliforms differ starkly from those for songbirds and parrots. When compared to these crown avian lineages, galliform birds feature lower degree of encephalization, a proportionally smaller telencephalon, small telencephalic and dominant cerebellar neuronal fractions, generally lower neuronal densities and larger glia/neuron ratios. Consequently, their brains and especially their forebrains harbor much smaller absolute numbers of neurons than those of equivalently sized songbird and parrots, the fact that undoubtedly constrains cognitive abilities of galliforms. However, this not to say that galliform birds are "bird brains" with low numbers of neurons and a limited ability to learn. Because they have high neuronal densities, their relatively small brains contain about equal numbers of neurons as brains of equivalently sized rodents and...

An Atlas of catfish brain - Steindachneridion parahybae (Teleostei: Siluriformes): a detailed cytoarchitectonic study of the different brain areas and nuclei as a basis for further morphological and functional studies / Um Atlas do encéfalo do catfish - Steindachneridion parahybae (Teleostei: Siluriformes): um estudo citoarquitetônico detalhado das diferentes áreas e núcleos do cérebro, como base para futuros estudos morfológicos e funcionais

Andreone Teles Medrado

14 August 2015

In the present Master\'s Dissertation, a detailed cytoarchtectonic study of the brain of the juvenile catfish - Steindachneridion parahybae, has been performed. The animals used for this Atlas were juvenile specimens of one hundred days post-fertilization. The coronal (transverse) sections (5µm-thick) were obtained by using a rotary microtome, stained with cresyl-violet and examined under a photomicroscopy with the help of a digital system of analysis. Some criteria have been used to classify the different cell masses of the catfish brain: (i) characteristic size, shape and intensity of the staining from the perykarya; (ii) packing density and distribution pattern of the cell bodies; (iii) neuropil surrounding the cell groups and (iv) consistency of cell groups in both hemispheres and different brains of catfish. Thus, around one hundred and thirty nuclei have been described in the catfish brain, which are distributed in four main region that are from rostral to caudal: telencephalon, diencephalon, mesencephalon and rhombencephalon. Although we have observed important similarities between the brain of catfish and other teleosts, we have also noticed some differences in the characteristics and placement of several nuclei in relation to other teleosts, or even when compared to the brain of species of the same Order, the Siluriformes. Some of these differences could be related with the age of the animals studied here, but probably represent species-specific differences because the brain of adult catfish specimens has a great similarity in cytoarchitecture and overall organization compared to younger animals. The main outcome of this study has been the availability of a complete Atlas of the brain of catfish, which has been used to localize precisely the distribution of cells and fibers of the Gonadotropin-releasing hormone in the brain. This Atlas will also represent a valuable tool for future endocrine analyses, allowing the precise mapping of the different neurohormones in the brain of catfish, as well as for the study of neural connections among different brain areas / Esta Dissertação de Mestrado, apresenta-se estruturalmente como um Atlas, em que é apresentado um detalhado estudo citoarquitetônico do encéfalo de catfish- Steindachneridion parahybae. Para a realização deste, foram utilizados 7 juvenis de 100 dias após a eclosão, analisados por técnicas rotineiras de histologia, cujas secções coronais(transversais) - 5&um;m de espessura-, foram obtidas utilizando-se de um micrótomo rotativo, coradas com violeta de cresil e examinadas a partir de sistema digital de análise. Alguns critérios foram utilizados para classificar as diferentes massas de células do cérebro catfish, tais como: (i) o tamanho característico, forma e intensidade da coloração do pericário; (ii) padrão de densidade de agrupamento e distribuição dos corpos celulares; (iii) a presença de neurópilos ao redor dos desses agrupamentos celulares e (iv) a consistência/coerência destes agrupamentos em ambos os hemisférios dos diferentes encéfalos, então analisados. Dessa forma, são descritos aproximadamente130 massas celulares para o encéfalo de S. parahybae, as quais estão distribuídas em quatro principais regiões que, da parte rostral para caudal, são: telencéfalo, diencéfalo, mesencéfalo e rombencéfalo. Embora são observadas semelhanças entre o cérebro de S. parahybae e de outros teleósteos, nota-se, também, certas diferenças quanto às características e/ou localização das massas celulares em relação ao encéfalo de outros teleósteos, ou mesmo quando comparado com o cérebro de espécies da mesma ordem, Siluriformes. Algumas destas diferenças pode estar relacionada com a idade dos animais estudados, no entanto,também podem representar diferenças espécie-específicas, uma vez que o encéfalo adultos de S. parahybae apresentam grande similaridade citoarquitetônica, além da organização geral do encéfalo, previamente observadas em animais acima dos 100 dias após a eclosão. Portanto, como resultado deste estudo tem-se a disponibilidade de um Atlas completo do encéfalo de S. parahybae, o qual representa uma ferramenta valiosa para o estudo das conexões neurais entre diferentes áreas do encéfalo, bem como para futuras análises endócrinas, permitindo o mapeamento preciso de neuro-hormônios nesta espécie, como demonstrado ao longo deste estudo, para o hormônio liberador de gonadotropinas

Cérebro

Fisiologia

Histologia

Imuno-histoquímica

Neuroanatomia

Neuroendocrinologia

Neurônios

Sistema nervoso central

Steindachneridion parahybae

Brain

Central nervous system

Histology

Immunohistochemistry

Neuroanatomy

Neuroendocrinology

Neurons

Physiology

Steindachneridion parahybae

Anatomia microcirúrgica da região do sulco limitante inferior da ínsula / Microsurgical anatomy of the inferior insular limiting sulcus

Eduardo Santamaria Carvalhal Ribas

10 October 2017

INTRODUÇÃO: O acesso cirúrgico ao corno temporal do ventrículo lateral (CTVL) é realizado para tratamento de lesões temporais mediais, dentre as quais se destaca a esclerose hipocampal que leva à epilepsia, e pode ser realizado através das superfícies lateral ou inferior do lobo temporal ou pelo sulco lateral do cérebro (fissura silviana). O parênquima cerebral subcortical localizado entre o sulco limitante inferior da ínsula (SLI) e o CTVL é composto por importantes feixes de fibras brancas, os quais podem eventualmente ser lesionados nos acessos cirúrgicos trans-silvianos. OBJETIVO: Descrever a localização dos principais feixes de fibras brancas na região entre o SLI e o CTVL. MÉTODOS: Os principais feixes de fibras brancas subcorticais foram examinados em 14 hemisférios cerebrais cadavéricos adultos utilizando a técnica de dissecção de Klingler, sendo possível descrever suas posições em relação à extremidade anterior do SLI (nomeado de Ponto Temporal do Límen - PTL). RESULTADOS: Os principais feixes de fibras identificados profundamente ao SLI formam um arranjo multilaminar e podem ser divididos de acordo com a profundidade em que são encontrados. As fibras de associação curta da cápsula extrema, que continuam em direção aos opérculos, formam a camada subcortical mais superficial e foram encontradas sob todo o SLI. As fibras da cápsula externa são encontradas mais profundamente, em uma camada formada por três principais feixes em uma disposição anteroposterior sequencial: o fascículo uncinado (encontrado desde o PTL até 10,0 ± 2.2 mm posteriormente), o fascículo fronto-occipital inferior (encontrado entre 10,0 ± 2,2 mm e 35,5 ± 2,7 mm posterior ao PTL) e fibras claustro-corticais (encontradas desde 35,5 ± 2,7 mm posterior ao PTL até o final desse sulco). A extensão lateral da comissura anterior está logo abaixo dessa camada e suas fibras foram encontradas entre 8,4 ± 1,8 mm e 22,0 ± 6,8 mm posterior ao PTL. A camada mais profunda é formada pelas fibras da cápsula interna/corona radiata, onde se destacam as radiações ópticas cujas fibras foram encontradas entre 10,6 ± 3,4 mm e 34,5 ± 3,5 mm posterior ao PTL. CONCLUSÕES: O fascículo uncinado é aproximadamente encontrado sob o terço anterior do segmento anterior do SLI (entre o PTL e o corpo geniculado lateral), enquanto o fascículo fronto-occipital inferior e as fibras da radiação óptica são encontrados sob os dois terços posteriores deste segmento. Os resultados sugerem que na abordagem trans-silviana transinsular, uma incisão através do SLI, começando no PTL e se estendendo até 6 mm posteriormente, irá atravessar o fascículo uncinado, mas não o fascículo fronto-occipital inferior e as radiações ópticas / INTRODUCTION: The surgical approach to the temporal horn of the lateral ventricle (CTVL) is performed for treatment of medial temporal lesions, among which hippocampal sclerosis leading to epilepsy is emphasized, and can be performed through the lateral or inferior surfaces of the temporal lobe or through the sylvian fissure. The subcortical cerebral parenchyma located between the inferior limiting sulcus of the insula (SLI) and the CTVL is composed of important white matter fiber bundles, which may eventually be injured in transsylvian surgical approaches. OBJECTIVES: To describe the location of the main white matter fiber bundles in the region between SLI and CTVL. METHODS: The main subcortical white matter fiber bundles were examined in 14 adult cadaveric cerebral hemispheres using the Klingler dissection technique, and it was possible to describe their positions in relation to the anterior end of the SLI (named Temporal Limen Point - PTL). RESULTS: The main white matter fiber bundles identified deeply to the SLI form a multi-laminar arrangement that can be understood according to the depth in which they are found. The short association fibers of the extreme capsule, which continue toward the opercula, form the most superficial subcortical layer and were found underneath all the SLI. The external capsule fibers were found more deeply, in a layer formed by three main fiber bundles organized in a sequential anterior-posterior disposition: the uncinate fascicle (found from the PTL to 10.0 ± 2.2 mm posteriorly), the inferior fronto-occipital fascicle (found between 10.0 ± 2.2 mm and 35.5 ± 2.7 mm posterior to the PTL) and claustrocortical fibers (found from 35.5 ± 2.7 mm posterior to PTL to the end of this sulcus). The lateral extension of the anterior commissure was below this layer and its fibers were found between 8.4 ± 1.8 mm and 22.0 ± 6.8 mm posterior to the PTL. The deepest layer is formed by the fibers of the internal capsule/corona radiata, where the optical radiation fibers were distinguished and found between 10.6 ± 3.4 mm and 34.5 ± 3.5 mm posterior to the PTL. CONCLUSIONS: The uncinate fascicle is approximately found under the anterior third of the anterior SLI segment (between the PTL and the lateral geniculate body), while the inferior fronto-occipital fascicle and fibers of the optical radiation are found under the posterior two thirds of this segment. The results suggest that at the transsylvian-transinsular approach, an incision at the SLI, from the PTL to 6 mm posteriorly, will cross the uncinate fascicle, but not the inferior fronto-occipital fascicle and optical radiation fibers

Cérebro

Lobo temporal

Microcirurgia

Neuroanatomia

Substância branca

Ventrículos cerebrais

Vias neurais

Cerebral ventricles

Cerebrum

Microsurgery

Neural pathways

Neuroanatomy

Temporal lobe

White matter

Connectivity and Processing in the Macaque Cerebral Cortex / Connectivité et traitement de l'information dans le cortex cérébral du macaque

Gariel, Marie-Alice

11 January 2017

Pour comprendre comment le cortex cérébral extrait du sens et produit des actions à partir des informations sensorielles, il est nécessaire de comprendre à la fois son architecture et ses états dynamiques. Dans la présente thèse nous avons abordé cette relation structure-fonction au niveau des aires cérébrales, leurs connections et leurs interactions au sein du réseau cortical. Les aires sont connectées entre elles par deux grands types de projections axonales. D'une part, les connections « feedforward » (littéralement « antéroactives ») transmettent l'information des aires sensorielles aux aires de plus haut niveau dans la hiérarchie corticale et dont l'activité sous-tend des représentations plus abstraites. À l'inverse, les connections feedback (rétroactives) relient des aires dans la direction descendante de la hiérarchie corticale, vers les aires sensorielles primaires. Pour explorer les rôles respectifs des connections feedforward et feedback nous avons utilisé une triple approche. Premièrement, nous avons mis en évidence une asymétrie fonctionnelle très nette entre propagation feedforward et feedback grâce à des enregistrements et de la microstimulation électrique dans les aires V1 et V4 de macaques en comportement. D'autre part, nous avons étudié les propriétés globales du réseau cortical grâce à une riche base de données de connectivité basée sur des injections de traceurs fluorescents, et décrit une propriété générale et fondamentale de l'organisation corticale. Enfin, nous avons combiné des propriétés anatomiques des aires corticales et les données de connectivité dans un modèle dynamique à grande échelle du cortex / To understand how the cerebral cortex does what it does, it is necessary to elucidate both how its dynamic states are correlated with the functions it performs, and how it is organised. Many functional and anatomical gradients have been described that reflect the hierarchical abstraction at the heart of cortical computation. It was showed that two flavours of cortical connections exist, and that in the visual cortex they happen to transport information in opposite directions along this gradient. It was also hypothesised that other modalities exhibit the same type of gradient in their respective domains. However, studying requires knowledge of the architecture at different levels (such as the cortical column) and a causal understanding of the functional properties of these types of connections. First, we have studied the dynamics of both feedforward and feedback propagation in the visual system of awake, behaving macaque monkeys. Using the causal method of electrical microstimulation and recording, we have found a dynamic signature of each type of projections and an asymmetry in the way each type of input interacts with ongoing activity in a given visual area. Secondly, thanks to a rich and systematic data set in the macaque, we have found a fundamental organisational principle of the embedded and weighted cortical network that holds also in the more detailed level of neuronal connections inside an area. Finally, we have combined known anatomical gradients with actual inter-areal connectivity into a dynamic model, and here we show how it relates to both the ordering of areas along a hierarchical gradient and the wiring diagram of the cortical network

Cortex cérebral

Macaque

Électrophysiologie

Microstimulation

Neuroanatomie

Graphique cortical

Modélisation

Populationde neurones

Cerebral cortex

Macaque

Electrophysiology

Electricalmicrostimulation

Neuroanatomy

Cortical graph

Modelling

Neuronal population dynamics

612.8

An investigation into the neuroprotective effects of dehydroepiandrosterone

Palvie, Stefanie Michelle

January 2006

Dehydroepiandrosterone, a C-19 steroid, is found endogenously with the highest circulating serum levels. It is converted to important steroids such as the sex hormones oestrogen and testosterone. DHEA has come under the spotlight as a purported “fountain of youth” due to its well-characterised age-related decline. The supplementation of DHEA in both the elderly and those with a pathophysiological deficiency has been shown to be of benefit, particularly with regard to wellbeing and depression. The role of DHEA in the periphery has not been elucidated beyond its role as a precursor hormone in sex steroid biosynthesis, though it has been established as a neuroactive neurosteroid, capable of exerting neuroprotective effects in the brain. Since the importance of free radicals in aging and neurodegeneration is well established, investigations were conducted on the ability of DHEA to inhibit free radical generation or scavenge existing free radicals. DHEA was able to significantly inhibit quinolinic acid-induced lipid peroxidation, a measure of membrane damage, over a range of concentrations, although the reduction did not appear to be dose-dependent. This was observed in both in vitro and in vivo studies. Thus, the ability of a compound to reduce the degree of lipid peroxidation may indicate its value as a neuroprotectant. However, DHEA did not significantly reduce cyanide induced generation of the superoxide free radical, suggesting that DHEA is not an effective free radical scavenger of the superoxide anion and that the reduction in lipid peroxidation does not occur through a scavenging mechanism. Apoptosis is a physiological process which is necessary for development and homeostasis. However, this form of programmed cell death can be initiated through various mechanisms and too much apoptotic cell death results in deleterious effects in the body. DHEA was shown not to induce apoptosis. Even the lowest concentration of DHEA investigated in this thesis shows a remarkable decrease in the degree of apoptosis caused by intrahippocampal chemical insult by the neurotoxin quinolinic acid. Cresyl violet was used to visualise tissue for histological examination which revealed that DHEA is able to preserve the normal healthy morphology of hippocampal cells which have been exposed to quinolinic acid. Cells maintained their integrity and showed little evidence of swelling associated with necrosis. Organ culture studies were performed by assessing the impact of DHEA on several pineal metabolites. The study revealed that DHEA exerted an effect on the metabolism of indoleamines in the pineal gland. Melatonin, the chief pineal hormone, did not appear to be affected while the concentrations of N-acetylserotonin, serotonin and methoxytryptamine showed significant alterations. Thus, the neuroprotective mechanism of DHEA does not appear to be mediated by an increase in the presence of melatonin. The biological importance of metal ions in neurodegeneration is also well established and thus the potential interaction between DHEA and metal ions was considered as a mechanism of action. Spectroscopic and electrochemical analyses were performed to determine whether DHEA is able to interact with metal ions as a ligand. These reveal that DHEA does not form a strong bond with the metals investigated, namely copper (II) and iron (III), but that a weak interaction is evident. These investigations were conducted in a rodent model, which has neither large amounts of endogenous DHEA, nor the enzymatic infrastructure present in humans. Thus, the theory that DHEA exerts its effects through downstream metabolic products is unlikely. However, these investigations reveal that there is merit in the statement that DHEA itself is a neuroprotective molecule, and confirm that the further investigation of DHEA is an advisable strategy in the war against neurodegeneration and aging.

Aging -- Physiological aspects

Steroid hormones

Dehydroepiandrosterone

Neurosciences

Neuroanatomy

Apoptosis

Pineal gland -- Physiology

Neurotoxic agents

Buněčné složení mozku zoborožců, šplhavců a srostloprstých ptáků / Cellular composition of brains for hornbills, woodpeckers and coraciiform birds

Stehlík, Patrik

January 2021

Recent comparative studies have shown that bird brains, although small, have a high processing capacity. The brains of parrots and songbirds have higher neuronal densities than brains of mammals; especially large parrots and corvids compete with or even outnumber primates by the number of telencephalic neurons. However, the processing capacity of the avian brain appears to differ significantly between various phylogenetic lineages. Basal groups such as galliform birds have much lower absolute numbers of neurons and lower neuronal densities than songbirds and parrots. In this Master thesis, I used the isotropic fractionator to determine numbers of neurons and non-neural cells in specific brain regions in 19 species of hornbills (Bucerotiformes), woodpeckers (Piciformes) and coraciiform birds (Coraciiformes). The brains of hornbills and woodpeckers (but not coraciiform birds) have numbers of neurons comparable to that of songbirds and parrots and significantly more neurons than equivalently sized brains of pigeons (Columbiformes) and galliform birds (Galliformes). In the crown groups, we can observe similar trends such as a higher degree of encephalization, a proportionally larger telencephalon and increasing percentage of telencephalic neurons. On the contrary, in pigeons and galliform birds, we can...

Neue Aspekte der segmentalen Neuroanatomie des Lendenbereiches beim Hund

Bernigau, Dora

16 April 2013

Sowohl in der Human- als auch in der Veterinärmedizin existieren mittlerweile zahlreiche Therapieverfahren, die immer öfter komplementär zur Schulmedizin eingesetzt werden. Zu den in der Tiermedizin besonders häufig angewandten Verfahren zählen die Neuraltherapie und die Akupunktur. Aber auch die Transkutane Elektrische Nerven Stimulation (TENS) und die Stimulation myofaszialer Triggerpunkte werden zu den segmentalen Therapiemethoden gerechnet. Die Linderung chronischer Schmerzzustände steht beim Einsatz dieser Verfahren im Vordergrund. Muskuloskelettale Erkrankungen der Lendenwirbelsäule und Lendenregion sowie der Gliedmaßen stellen beim Hund eine häufige Indikation für den Einsatz eines neuraltherapeutischen Verfahrens dar. In diesem Zusammenhang wird die Regio lumbalis des Hundes sehr häufig für eine Therapie herangezogen. Die Wirkung einer neuraltherapeutischen Behandlung wird in diesem Bereich segmental über die Spinalnerven vermittelt. Ziel der vorliegenden Dissertation war es, die Regio lumbalis des Hundes insbesondere im Hinblick auf das Innervationsmuster der Hautnerven detailliert darzustellen. Die erhobenen Befunde sollten einen Beitrag zum besseren Verständnis der Wirkmechanismen der verschiedenen Therapietechniken leisten. Außerdem sollte nach einem möglichen morphologischen Korrelat zu den in der TCM definierten Akupunkturpunkten gesucht werden. Zu diesem Zweck wurden der Verlauf und die Verzweigung der Nerven des Lendenbereiches von n=12 formalinfixierten Hunden beginnend von der dorsalen Medianlinie dargestellt. Eine fotografische Dokumentation fand in drei Schichten statt: im Bereich der Fascia thoracolumbalis (a), auf Niveau der langen Rückenmuskulatur (b) und über den Procc. transversi (c). Des Weiteren wurde bei n=2 Tieren eine Präparation des subkutanen Innervationsmusters vorgenommen. Um die präparatorischen Ergebnisse interindividuell vergleichen zu können, wurden sog. Kaudalverschiebungsindizes entwickelt und für die einzelnen Spinalnerven berechnet. Spinalnerven, welche die Haut der Regio lumbalis innervierten, stammten aus den Rückenmarkssegmenten Th12 bis L5. Nervi cutanei der Dorsaläste besaßen alle Hunde, bei n=7 Tieren beteiligten sich auch Hautäste von Rr. ventrales aus den Segmenten L3 bis L5 an der Innervation des dorsalen Lendenbereiches. Die Anzahl der Hautnervenäste variierte individuell zwischen drei und sieben, wobei die Nerven bei den Tieren mit einer geringeren Anzahl aus den weiter kranial gelegenen Segmenten stammten. Der Verlauf, die Verzweigung sowie der Perforation der Nervi cutanei durch die Fascia thoracolumbalis zeigten eine sehr hohe individuelle Variabilität. Im Bereich der langen Rückenmuskulatur wurde dagegen ein vergleichbares und segmental regelmäßiges Innervationsmuster angetroffen. Bei der Präparation der subkutanen Nervenverläufe fiel ein sehr irreguläres und segmental nicht nachvollziehbares Muster auf. Bei allen untersuchten Hunden zeigten die Dorsaläste der Spinalnerven eine Kaudalverschiebung um mindestens eine Wirbelkörperlänge. Die in der vorliegenden Arbeit eingeführten Kaudalverschiebungsindizes ermöglichen einen interindividuellen Vergleich des Verlaufes der Spinalnerven der Regio lumbalis. Durch die errechneten Indizes ist eine graphische Darstellung und aussagekräftige Interpretation der morphologischen Ergebnisse gegeben. Die zum Teil hohe interindividuelle Variation im Innervationsmuster der Hautnerven des Lendenbereiches in den oberflächlichen Körperschichten lässt den Schluss zu, dass die Hautareale des Lendenbereiches nicht bei jedem Tier von demselben Spinalnerven innerviert werden. Das bedeutet, dass die Dermatome bei verschiedenen Individuen nicht identisch sind. Des Weiteren schließt die unterschiedliche Lokalisation der Nerven und ihrer Durchtrittstellen durch die Fascia thoracolumbalis ein morphologisches Korrelat zu den in der TCM festgelegten Akupunkturpunkten aus. Die bei allen Hunden regelmäßige Anordnung der Spinalnerven auf Niveau der langen Rückenmuskulatur deutet vielmehr darauf hin, dass ein in der Körperperipherie gesetzter Reiz unabhängig von einer genauen Punktlokalisation einen segmental in das Rückenmark vermittelten Effekt bei einer neuraltherapeutischen Behandlung zur Folge hat. Für eine erfolgreiche Therapie sind daher die profunde Kenntnis der Segmentanatomie sowie der neuroanatomischen Verschaltungswege unbedingt erforderlich. In Zukunft sollte mehr Augenmerk auf individuelle Unterschiede im Innervationsmuster gelegt werden, da diese einen möglichen Grund für die individuell variable oder auch ausbleibende Wirkung bei einer neuraltherapeutischen Behandlung darstellen können.

info:eu-repo/classification/ddc/636.089

ddc:636.089

Comparative neurotranscriptomics in mammals and birds

Belgard, Tildon Grant

January 2011

In this thesis I apply new sequencing technologies and analytical methods derived from genomics and computer science to the neuroanatomy of gene expression. The first project explores characteristics of gene expression across adult neocortical layers in a representative mammal – the mouse. Amongst the thousands of genes and transcripts differentially expressed across layers, I found common functional characteristics of genes that define certain layers, candidate cases of isoform switching, and over a thousand apparent long intergenic non-coding RNA transcripts. The second project compares patterns of gene expression in the structurally diverged adult derivatives of the pallium in mice and chickens. Overall, gene expression levels were moderately correlated between the two species. While expression patterns of ‘marker’ genes were only poorly conserved in these regions, there nevertheless was significant conservation of cross-species marker genes for homologous structures, cell types and functionally analogous regions. Many aspects of these data from both projects can now be easily browsed and searched from custom-built web interfaces. In addition to generating unprecedented genome-wide resources for the neuroscience community to explore the functional and structural dimensions of gene expression amongst different pallial regions in mammals and birds, this work also provides new insights into the widespread evolutionary shuffling of adult marker gene expression.

571.85

Modulation dopaminergique dans le système olfactif

Beauséjour, Philippe-Antoine

08 1900

Les figures de neuroanatomie de ce mémoire peuvent être téléchargées en haute résolution. / Une voie neuronale sous-tendant la locomotion induite par la détection d’odorants a été découverte chez la lamproie (Derjean et al., 2010). Le signal olfactif est relayé du bulbe olfactif médian au tubercule postérieur, puis à la région locomotrice mésencéphalique et enfin aux cellules réticulospinales qui activent les réseaux locomoteurs spinaux. Des études récentes démontrent que le bulbe olfactif médian est sous l’influence d’une inhibition GABAergique tonique qui régule les réponses des cellules réticulospinales à la stimulation du nerf olfactif (Daghfous et al., 2013). Des mécanismes de modulation supplémentaires pourraient exister dans le bulbe olfactif de Petromyzon marinus puisqu’il contient aussi des fibres dopaminergiques. Chez tous les vertébrés étudiés, la dopamine joue un rôle important dans le traitement olfactif. Des techniques anatomiques (traçage et immunofluorescence) et physiologiques (enregistrements intracellulaires) ont été utilisées pour étudier la modulation dopaminergique de la voie olfacto-motrice. L’immunofluorescence ciblant la dopamine a révélé des fibres plus nombreuses dans la partie médiane du BO et à proximité de neurones de projection et de fibres olfactives. De plus, aucun corps cellulaire immunopositif n’a été détecté dans le bulbe olfactif. L’enregistrement des réponses synaptiques des cellules réticulospinales à la stimulation du nerf olfactif a été réalisé dans le cerveau isolé in vitro. L’injection locale de dopamine dans le bulbe olfactif médian diminue de moitié l’amplitude de réponse. Sous l’effet d’un antagoniste des récepteurs GABAA dans le bain ou localement dans le bulbe olfactif médian, les dépolarisations soutenues enregistrées sont supprimées par l’injection de dopamine. Cependant, l’injection individuelle ou combinée dans le bulbe olfactif médian d’antagonistes sélectifs des récepteurs D1 ou D2, soit le SCH 23390 et l’éticlopride, demeure sans effet significatif sur les réponses olfacto-motrices, indiquant l’absence d’activité dopaminergique tonique. Pour localiser les neurones responsables de cette modulation, des injections de traceur axonal ont été combinées avec l’immunofluorescence ciblant la dopamine. Des cellules dopaminergiques projetant au BO médian ont été observées dans les noyaux dopaminergiques du tubercule postérieur et de l’hypothalamus périventriculaire. Dans l’ensemble, nos résultats montrent anatomiquement et physiologiquement la présence d’une innervation dopaminergique dans le bulbe olfactif médian qui a une action inhibitrice sur le traitement olfacto-moteur. / A neural substrate underlying odor-evoked locomotion was revealed in lampreys (Derjean et al., 2010), involving a neural pathway extending from the medial part of the olfactory bulb to the posterior tuberculum. The signal is then relayed to the mesencephalic locomotor region and eventually reaches reticulospinal cells that activate the spinal locomotor networks. Recent research in the lab (Daghfous et al., 2013) shows that the medial olfactory bulb, is under a tonic GABAergic inhibition gating reticulospinal cell responses to olfactory nerve stimulation. Additional modulatory mechanisms might exist in the olfactory bulb of Petromyzon marinus as it also contains dopaminergic fibers. In every vertebrate studied to date, dopamine plays an important role in olfactory processing. Anatomical (axonal tracers and immunofluorescence) and physiological (intracellular recordings) techniques were used to investigate the dopaminergic modulation of the olfacto-motor pathway. Dopamine immunofluorescence showed scarce innervation of the olfactory bulb that was most abundant in the medial part and in close vicinity to projection neurons and olfactory nerve fibers. Additionally, no dopamine-immunoreactive cell bodies were detected in the olfactory bulb. Synaptic responses of reticulospinal cells to olfactory nerve stimulation were recorded in the isolated brain. Local injection of dopamine in the medial olfactory bulb induces an almost two-fold decrease of the synaptic responses. When GABAA receptor antagonist GABAzine was also injected in the medial olfactory bulb, the effect of dopamine was much more evident and could suppress large bursts of action potentials. However, D1 (SCH 23390) and D2 (Eticlopride) receptor antagonists injection in the medial olfactory bulb failed to alter the amplitude of reticulospinal cell responses to olfactory nerve stimulation, indicating that this modulation is not tonic. To locate the neurons responsible for this modulation, tracer injections combined with dopamine immunofluorescence were performed. Dopaminergic cells projecting to the medial olfactory bulb were found in the dopaminergic nuclei of the posterior tuberculum and the periventricular hypothalamus. Altogether, our results show anatomically and physiologically the presence of a dopaminergic innervation within the medial olfactory bulb that mediates inhibitory effects on olfacto-motor signaling.

Couplage sensori-moteur

Bulbe olfactif

Dopamine

Nerf olfactif

Neurones de projection

Tubercule postérieur

Cellules réticulospinales

Neuroanatomie

Électrophysiologie

Sensori-motor coupling

Olfactory bulb

Olfactory nerve

Projection neurons

Posterior tuberculum

Reticulospinal neurons

Neuroanatomy

Electrophysiology