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Michelle Loftin Thesis Proper Format 12-3 AS.pdfMichelle Loftin (17592504) 03 January 2024 (has links)
<p dir="ltr">Papilledema is the swelling of the optic disc resulting from increased cranial pressure. The diagnosis of papilledema is important not only to treat pathologies of the eye, but it also can be an important indicator for underlying brain pathology since the subarachnoid space surrounding the optic nerve is contiguous with the brain. Therefore increased pressure from the brain from pathologies such as hydrocephalus can be transmitted to the posterior eye. To study papilledema, a reproducible post hemorrhagic hydrocephalic rat model was used to study the changes of the retina, optic disc and optic nerve when exposed to high intracranial pressure. Multiple changes were noted in the post hemorrhagic hydrocephalic model including decreased thickness of the ganglion cell complex, decreased retinal thickness in the periphery in females, increased retinal thickness close to the optic nerve in males, increased optic disc width and diameter along with a decrease number of retinal ganglion cells. These findings were similar to findings in human patients with papilledema. Therefore, future studies are indicated using the post hemorrhagic hydrocephalic rat model to further understand the mechanism of papilledema progression and the use of possible therapeutics.</p>
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Effects of divergent water colours on Amazon fish evolution / 水色の違いがアマゾン川の魚の進化に及ぼす影響Elio, De Almeida Borghezan 25 March 2024 (has links)
京都大学 / 新制・課程博士 / 博士(理学) / 甲第25149号 / 理博第5056号 / 新制||理||1721(附属図書館) / 京都大学大学院理学研究科生物科学専攻 / (主査)准教授 杉浦 秀樹, 教授 村山 美穂, 教授 平田 聡 / 学位規則第4条第1項該当 / Doctor of Agricultural Science / Kyoto University / DFAM
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Functional diversity in colour vision of fishSabbah, Shai 14 May 2012 (has links)
The overall objective of this thesis was to understand better the mechanisms that shape the diversity in colour vision of fish, and to explore the adaptive significance of this divergence. Among the vertebrates, teleost fish show the greatest diversity in colour vision systems. The cichlid model system illustrates that the visual system of fish may differ among species, sexes, individuals, and life stages of individuals. The large number of available cone opsin genes, which have resulted from multiple opsin gene duplications, facilitates this high degree of variation in the mechanisms of colour vision. In general, cichlids possessed complements of four to five cone pigments, and these complements varied across species, sexes, and individuals. Additionally, lens transmission, cone pigment expression, post-receptoral sensitivity, and retinal circuitry differed across life stages of individuals. My results suggest that the diversification of colour vision across species and across life stages of individuals contributes to sensory adaptations that enhance both the contrast of zooplanktonic prey, and the detection of optical signals from conspecifics. Therefore, both natural and sexual selection may have worked in concert to shape colour vision in fish. Since light is more complex under water than on land, fish required four to six cone classes to reconstruct the colour signals reflected from aquatic objects. This suggests that the large number of cone pigments in fish have likely evolved to enhance the reconstruction of the complex colour-signals in aquatic environments. Taken together, these findings improve our understanding of the variable nature of fish colour vision, and, more generally, help unravel the evolution of photoreceptors and colour vision. / Thesis (Ph.D, Biology) -- Queen's University, 2012-05-14 13:16:50.276
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Alterações sensoriais e motoras associadas ao envelhecimento e controle postural de idosos /Toledo, Diana Rezende de. January 2008 (has links)
Orientador: José Angelo Barela / Banca: Fabio Viadanna Serrão / Banca: Eliane Mauerberg de Castro / Resumo: O avanço da idade vem acompanhado de muitas alterações estruturais, funcionais e comportamentais. Como um bom desempenho do controle postural depende da integridade dos sistemas sensoriais e motor, as deteriorações que ocorrem nestes sistemas com o envelhecimento poderiam influenciar o desempenho de controle postural em indivíduos idosos. Entretanto, ainda não estão claras quais alterações funcionais nos sistemas sensoriais e motor são provocadas pelo envelhecimento por si só, bem como a relação entre estas alterações e as mudanças no desempenho de controle postural de adultos idosos. Assim, o objetivo deste estudo foi avaliar o desempenho dos sistemas sensoriais e motor e do controle postural de adultos idosos e investigar a relação entre as alterações destes sistemas e o controle postural desta população. Vinte adultos idosos (68,9±3,7 anos) (GAI) e 20 adultos jovens (21,9±2,1 anos) (GAJ) foram submetidos a avaliações sensoriais, motoras e de controle portural. As avaliações sensoriais foram compostas por avaliação visual (acuidade e sensibilidade ao contraste) e somatossensorial (sensibilidade cutânea e sensibilidade ao movimento passivo). As avaliações motoras consistiram de medidas de torque articular e de latência de ativação muscular após perturbação da superfície de suporte. As avaliações de controle postural consistiram de medidas de oscilação corporal durante manutenção da postura ereta (em semi-tandem stance), resolução de conflito sensorial (movimentação discreta de uma sala móvel) e acoplamento entre informação visual e oscilação corporal (movimentação periódica, ...(Resumo completo, clicar acesso eletrônico abaixo) / Abstract: With aging, individuals exhibit several structural, functional and behavioral changes. As a good postural control performance depends on the integrity of the sensory and motor systems, deterioration of these systems occurring with aging could influence the postural control performance of older adults. However, it is still unclear which sensory and motor functional changes are due to aging per se, neither the relationship between these changes and the changes of the performance of postural control in older adults. Therefore, the purpose of this study was to examine the performance of the sensory and motor systems and postural control in older adults and to investigate the relationship between changes in these systems and postural control in this population. Twenty older adults (68,9±3,7 years) (GAI) and 20 young adults (21,9±2,1 years) (GAJ) were submitted to sensory, motor and postural control assessments. Sensory assessments were composed of visual (acuity and contrast sensitivity) and somatosensory assessments (tactile sensitivity of and sensitivity to passive motion). Motor assessments consisted of measurements of joint torque and muscular activity latency after displacement of support surface. Postural control assessments consisted of measuring the body oscillation during maintenance of the upright stance (semi-tandem stance), the resolution of a sensory conflict (discrete movement of a moving room) and the coupling between visual information...(Complete abastract, click electronic access below) / Mestre
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ELECTROPHYSIOLOGICAL AND BEHAVIORAL MEASURES OF TACTILE AND AUDITORY PROCESSING IN CHILDREN WITH AUTISM SPECTRUM DISORDERGirija Suhas Kadlaskar (9161390) 29 July 2020 (has links)
<p>Touch plays a key role in facilitating social communication and is often presented in conjunction with auditory stimuli such as speech. Individuals with autism spectrum disorder (ASD) frequently show atypical behavioral responsivity to both tactile and auditory stimuli, which is associated with increased ASD symptomatology. However, as discussed throughout Chapter 1, the neural mechanisms associated with responsivity to tactile and auditory stimuli in ASD are not fully understood. For example, some have argued that differences in responding to tactile and auditory stimuli may be attributed to sensory and perceptual factors, whereas others suggest that these differences could be related to atypicalities in allocation of attention to incoming stimuli. In Chapter 2, I address these competing hypotheses by examining early and late ERP components (indicative of perceptual and attentional processing respectively) in response to tactile and auditory stimuli. Next, despite the evidence suggesting that touch plays a role in modulating attention in typical development (TD), it is unclear whether touch cues affect the response of the phasic alerting network – a subcomponent of attention – in ASD and TD, and whether the alerting response may be atypical in children with ASD. In Chapter 3, I address this gap in the literature by examining whether tactile cues presented at different intervals before auditory targets facilitate reaction times differently in children with ASD and TD. Lastly, because prior research has shown associations between sensory and attentional processes and ASD symptomatology, in Chapters 2 and 3, I examine the associations of neural and behavioral indices of tactile and auditory processing with ASD symptomatology and language skills in children with ASD and TD. </p><p>In Chapter 2, I show that children in both the ASD and TD groups do not exhibit differences in both early and later neurological responses to tactile and auditory stimuli, suggesting that under certain experimentally-controlled conditions, behavioral differences to tactile and auditory stimuli may not be attributable to atypicalities in perceiving or attending to the incoming sensory input. However, neural responsivity to tactile and auditory stimuli is linked with sensory responsivity and social skills in all children. Specifically, reduced early contralateral activation to tactile stimuli is related to increased tactile symptoms, and reduced early amplitudes to auditory oddball stimuli are associated with impairments in reciprocal social communication in children with ASD as well as when examined across all children, and greater tendency of overall sensory hyper-reactivity. Additionally, in the TD group, greater later amplitudes to touch and auditory oddball stimuli are related to differences in reciprocal social communication and sensory reactivity respectively, indicating that patterns of allocation of attention may be related to ASD-like traits in typical development. Lastly, there is an association between greater sensitivity to changes to a stream of auditory stimuli and expressive language skills in all children. These results suggest that, although there are no group differences between neurological responses to tactile and auditory stimuli in ASD and TD, individual neural differences may be related to sensory and socio-communicative skills in all children. </p><p>In Chapter 3, I show that although children with ASD responded more slowly than children with TD, both groups displayed faster reaction times as a result of tactile cues before auditory targets, suggesting equivalent phasic alerting in response to tactile stimuli. Longer intervals between cues and targets benefitted children in both groups resulting in faster reaction times. Contrary to my hypotheses, touch-related behavioral facilitation was not associated with ASD symptomatology and language skills. </p>Taken together, the results of these studies suggest that, at least in certain contexts and with certain cues, children with ASD may show typical neurological processing in response to tactile and auditory stimuli, and that touch may facilitate the response of the alerting network similarly in ASD and TD. Therefore, everyday behavioral differences in response to tactile and auditory stimuli may be related to the specific nature of the stimuli as well as social contexts in which such stimuli are more likely to be encountered. Differences between processing rich and dynamic sensory stimuli experienced in the outside world vs experimentally-controlled sensory stimuli presented in the laboratory settings are discussed in Chapter 4. Additionally, I argue that individual responses expected in social vs non-social experimental settings may affect neural and behavioral responses in individuals with ASD. Finally, future research directions are discussed.
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Characterization of Biomimetic Spinal Cord Stimulations for Restoration of Sensory FeedbackSidnee Lynn Zeiser (18415227) 03 June 2024 (has links)
<p dir="ltr">Sensory feedback is a critical component for controlling neuroprosthetic devices and brain-machine interfaces (BMIs). A lack of sensory pathways can result in slow, coarse movements when using either of these technologies and, in addition, the user is unable to fully interact with the environment around them. Spinal cord stimulation (SCS) has shown potential for restoring these pathways, but traditional stimulation patterns with constant parameters fail to reproduce the complex neural firing necessary for conveying sensory information. Recent studies have proposed various biomimetic stimulation patterns as a more effective means of evoking naturalistic neural activity and, in turn, communicating meaningful sensory information to the brain. Unlike conventional patterns, biomimetic waveforms vary in frequency, amplitude, or pulse-width over the duration of the stimulation. To better understand the role of these parameters in sensory perception, this thesis worked to investigate the effects of SCS patterns utilizing stochastic frequency modulation, linear frequency modulation, and linear amplitude modulation. By calculating sensory detection thresholds and just-noticeable differences, the null hypothesis for stochastically-varied frequency and linear amplitude modulation techniques was rejected.</p>
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Rôle du système du trijumeau dans la locomotion chez le nouveau-né d’opossum (Monodelphis domestica)Adadja, Thierry Ayiwanou 05 1900 (has links)
L’opossum Monodelphis domestica naît très immature et grimpe sans aide de la mère, du sinus urogénital à une mamelle où il va s’attacher pour poursuivre son développement. Des informations sensorielles sont nécessaires pour guider le nouveau-né vers la mamelle et les candidats les plus probables sont le toucher, l’équilibre et l’olfaction. Pour tester l’action des différents systèmes sur la motricité chez l’opossum nouveau-né, des régions céphaliques du trijumeau, du vestibulaire et de l’olfaction ont été stimulées électriquement sur des préparations in vitro en comparaison avec une stimulation seuil T (intensité minimale de la stimulation à la moelle épinière cervicale induisant le mouvement des membres antérieurs). Par comparaison, un mouvement similaire était induit par des stimulations à ~2T du ganglion du trijumeau, à ~20 T du complexe vestibulaire, et à ~600 T des bulbes olfactifs. L’étude de l'innervation de la peau faciale et des voies relayant les informations du trijumeau vers la moelle épinière (ME) a été approfondie en utilisant de l’immunohistochimie pour les neurofilament-200 et du traçage rétrograde avec du Texas-Red couplé à des Dextrans Aminés. De nombreuses fibres nerveuses ont été révélées dans le derme de plusieurs régions de la tête. Quelques cellules du ganglion trigéminal projettent à la ME rostrale, mais la majorité projette vers la médulla caudale où se trouvent les neurones secondaires du trijumeau ou des cellules réticulospinales. Les résultats de cette étude indiquent une influence significative des systèmes du trijumeau et du vestibulaire, mais pas de l'olfaction, sur le mouvement des membres antérieurs des opossums nouveau-nés. / The opossum Monodelphis domestica is born very immature and crawls, unaided by the mother, from the urogenital opening to a nipple where it attaches and pursues its development. Sensory information is needed to guide the newborn to a nipple and studies suggest that the vestibular, trigeminal, and olfactory systems are likely candidates. The trigeminal, vestibular and olfactory regions of the brain were electrically stimulated to test their relative effectiveness at eliciting forelimb movement in newborn opossums, using in vitro preparations of brain-spinal cord with the limbs attached. The minimal stimulation of the cervical spinal cord needed to induce forelimb movement was considered as threshold (T). Similar movement were obtained with stimulations of the trigeminal ganglion at ~2T and of the vestibular complex at ~20 T and at ~600 T for the olfactory bulb. Neurofilament-200 immunohistochemistry and retrograde tracing with Texas-Red conjugated Dextran Amines were used to study trigeminal innervation of the facial skin and pathways by which trigeminal inputs may be relayed to the spinal cord. Numerous nerve fibers were observed in the snout dermis, elsewhere in the head skin. Some trigeminal ganglion cells project to the upper spinal cord, but more project to the caudal medulla where they could contact secondary trigeminal neurons or reticular cells projecting to the spinal cord. These results support a significant influence of the trigeminal and the vestibular systems, but not of olfaction, on forelimb movement of neonatal opossums.
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Rôle du système du trijumeau dans la locomotion chez le nouveau-né d’opossum (Monodelphis domestica)Adadja, Thierry Ayiwanou 05 1900 (has links)
L’opossum Monodelphis domestica naît très immature et grimpe sans aide de la mère, du sinus urogénital à une mamelle où il va s’attacher pour poursuivre son développement. Des informations sensorielles sont nécessaires pour guider le nouveau-né vers la mamelle et les candidats les plus probables sont le toucher, l’équilibre et l’olfaction. Pour tester l’action des différents systèmes sur la motricité chez l’opossum nouveau-né, des régions céphaliques du trijumeau, du vestibulaire et de l’olfaction ont été stimulées électriquement sur des préparations in vitro en comparaison avec une stimulation seuil T (intensité minimale de la stimulation à la moelle épinière cervicale induisant le mouvement des membres antérieurs). Par comparaison, un mouvement similaire était induit par des stimulations à ~2T du ganglion du trijumeau, à ~20 T du complexe vestibulaire, et à ~600 T des bulbes olfactifs. L’étude de l'innervation de la peau faciale et des voies relayant les informations du trijumeau vers la moelle épinière (ME) a été approfondie en utilisant de l’immunohistochimie pour les neurofilament-200 et du traçage rétrograde avec du Texas-Red couplé à des Dextrans Aminés. De nombreuses fibres nerveuses ont été révélées dans le derme de plusieurs régions de la tête. Quelques cellules du ganglion trigéminal projettent à la ME rostrale, mais la majorité projette vers la médulla caudale où se trouvent les neurones secondaires du trijumeau ou des cellules réticulospinales. Les résultats de cette étude indiquent une influence significative des systèmes du trijumeau et du vestibulaire, mais pas de l'olfaction, sur le mouvement des membres antérieurs des opossums nouveau-nés. / The opossum Monodelphis domestica is born very immature and crawls, unaided by the mother, from the urogenital opening to a nipple where it attaches and pursues its development. Sensory information is needed to guide the newborn to a nipple and studies suggest that the vestibular, trigeminal, and olfactory systems are likely candidates. The trigeminal, vestibular and olfactory regions of the brain were electrically stimulated to test their relative effectiveness at eliciting forelimb movement in newborn opossums, using in vitro preparations of brain-spinal cord with the limbs attached. The minimal stimulation of the cervical spinal cord needed to induce forelimb movement was considered as threshold (T). Similar movement were obtained with stimulations of the trigeminal ganglion at ~2T and of the vestibular complex at ~20 T and at ~600 T for the olfactory bulb. Neurofilament-200 immunohistochemistry and retrograde tracing with Texas-Red conjugated Dextran Amines were used to study trigeminal innervation of the facial skin and pathways by which trigeminal inputs may be relayed to the spinal cord. Numerous nerve fibers were observed in the snout dermis, elsewhere in the head skin. Some trigeminal ganglion cells project to the upper spinal cord, but more project to the caudal medulla where they could contact secondary trigeminal neurons or reticular cells projecting to the spinal cord. These results support a significant influence of the trigeminal and the vestibular systems, but not of olfaction, on forelimb movement of neonatal opossums.
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Intensity adaptation in the cricket auditory systemZiehm, Ulrike 24 April 2013 (has links)
Die Intensität verhaltensrelevanter Signale variiert oft über viele Größenordnungen. Gleichzeitig müssen sensorische Systeme in der Lage sein, über den gesamten relevanten Bereich feine Intensitätsunterschiede aufzulösen. Auf neuronaler Ebene ergibt sich bei Nutzung eines Feuerratencodes aus diesen Anforderungen ein grundsätzlicher Konflikt, da neuronale Antwortbereiche beschränkt sind. Eine Lösung, die in vielen Sinnessystemen beschrieben wurde, ist die Verschiebung von Intensität-Kennlinien, so dass der gesamte Antwortbereich des Neurons zur Verfügung steht, um schnelle Abweichungen vom Mittelwert zu kodieren. Diese Arbeit versucht anhand mathematischer Modelle zu beantworten, wie die Verschiebung von Kennlinien in einem neuronalen Netzwerk entstehen könnte. Ausgangspunkt ist eine Rezeptorpopulation mit Intensitätsbereichsaufteilung und einem begrenzten Verschiebungsbereich der Kennlinien von Einzelrezeptoren, die auf ein Output-Neuron konvergieren. Diese Organisation wurde vom auditorischen System der Grille inspiriert. Modelle, die auf einer Kombination aus einer sättigenden Nichtlinearität und Spike-Frequenz-Adaptation basieren, reproduzieren die Verschiebung der Kennlinien entlang der Intensitäts-Achse. Diese Modelle sind in der Intensitätsdiskriminierung dem Rezeptormodell und der Summe von Rezeptorantworten über große Intensitätsbereiche deutlich überlegen. Die Kennlinien dieser Modelle besitzen zudem weitere Eigenschaften, die in ihrer Kombination übereinstimmend in verschiedenen sensorischen Systemen beschrieben wurden: Insbesondere erklären sie eine zusätzliche scheinbare Verschiebung entlang der Antwortachse, unterschiedliche Steigungen der verschobenen Kennlinien, sowie Steigungsänderungen innerhalb einzelner Kennlinien. Die einfachen, abstrakt formulierten Modelle ermöglichen ein tieferes Verständnis adaptiver Mechanismen über das Modellsystem Grille hinaus. / Intensities of behaviourally relevant signals often vary over many orders of magnitude. At the same time, sensory systems need to ensure high sensitivity to minute intensity differences across the full intensity range. These demands conflict on the neuronal level due to the boundedness of neuronal response ranges. To solve this dilemma, intensity response curves in many sensory system were found to shift towards the actual mean intensity so that the full response range can be used to encode fast fluctuations around the slowly varying mean. Using mathematical models, this study approaches the question how shifts of intensity response curves might arise in small neural networks. The starting point is a population of receptors with stacked response thresholds and limited capacity of adaptive shift that converge onto one output neuron. This organization was inspired by the auditory system of the cricket. A combination of a static saturating non-linearity and spike-frequency adaptation reproduced the desired shift of response curves along the intensity axis. With respect to intensity discrimination, these models are superior to the receptor model and the sum of receptor responses over a wide range of absolute intensities. The response curves generated by these model also displayed details of response curve behaviour consistently observed in numerous experimental studies. In particular, they explain an apparent shift along the response axis, different slopes of the shifted response curves, and changes in the slope within individual response curves. The simple, abstract models allow for a deeper understanding of adaptive mechanisms beyond the auditory system of the cricket.
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Alterações sensoriais e motoras associadas ao envelhecimento e controle postural de idososToledo, Diana Rezende de [UNESP] 18 July 2008 (has links) (PDF)
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toledo_dr_me_rcla.pdf: 1180963 bytes, checksum: 1b7f7f71b036e62aaab6c4903057aae6 (MD5) / Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP) / O avanço da idade vem acompanhado de muitas alterações estruturais, funcionais e comportamentais. Como um bom desempenho do controle postural depende da integridade dos sistemas sensoriais e motor, as deteriorações que ocorrem nestes sistemas com o envelhecimento poderiam influenciar o desempenho de controle postural em indivíduos idosos. Entretanto, ainda não estão claras quais alterações funcionais nos sistemas sensoriais e motor são provocadas pelo envelhecimento por si só, bem como a relação entre estas alterações e as mudanças no desempenho de controle postural de adultos idosos. Assim, o objetivo deste estudo foi avaliar o desempenho dos sistemas sensoriais e motor e do controle postural de adultos idosos e investigar a relação entre as alterações destes sistemas e o controle postural desta população. Vinte adultos idosos (68,9±3,7 anos) (GAI) e 20 adultos jovens (21,9±2,1 anos) (GAJ) foram submetidos a avaliações sensoriais, motoras e de controle portural. As avaliações sensoriais foram compostas por avaliação visual (acuidade e sensibilidade ao contraste) e somatossensorial (sensibilidade cutânea e sensibilidade ao movimento passivo). As avaliações motoras consistiram de medidas de torque articular e de latência de ativação muscular após perturbação da superfície de suporte. As avaliações de controle postural consistiram de medidas de oscilação corporal durante manutenção da postura ereta (em semi-tandem stance), resolução de conflito sensorial (movimentação discreta de uma sala móvel) e acoplamento entre informação visual e oscilação corporal (movimentação periódica,... / With aging, individuals exhibit several structural, functional and behavioral changes. As a good postural control performance depends on the integrity of the sensory and motor systems, deterioration of these systems occurring with aging could influence the postural control performance of older adults. However, it is still unclear which sensory and motor functional changes are due to aging per se, neither the relationship between these changes and the changes of the performance of postural control in older adults. Therefore, the purpose of this study was to examine the performance of the sensory and motor systems and postural control in older adults and to investigate the relationship between changes in these systems and postural control in this population. Twenty older adults (68,9±3,7 years) (GAI) and 20 young adults (21,9±2,1 years) (GAJ) were submitted to sensory, motor and postural control assessments. Sensory assessments were composed of visual (acuity and contrast sensitivity) and somatosensory assessments (tactile sensitivity of and sensitivity to passive motion). Motor assessments consisted of measurements of joint torque and muscular activity latency after displacement of support surface. Postural control assessments consisted of measuring the body oscillation during maintenance of the upright stance (semi-tandem stance), the resolution of a sensory conflict (discrete movement of a moving room) and the coupling between visual information...(Complete abastract, click electronic access below)
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