Application of in vivo methodologies to investigation of biological structure, function and xenobiotic response in see-through medaka (Oryzias latipes)

Hardman, Ron C., Kullman, Seth. W., Hinton, David E.

January 2007

No description available.

medaka

liver

toxicity

hepatobiliary

in vivo imaging

Watching the Brain Learn and Unlearn: Effects of Tutor Song Experience and Deafening on Synaptic Inputs to HVC Projection Neurons

Tschida, Katherine Anne

January 2011

<p>The ability of young children to vocally imitate the speech of adults is critical for speech learning. Vocal imitation requires exposure to an external auditory model and the use of auditory feedback to adaptively modify vocal output to match the model. Despite the importance of vocal imitation to human communication and social behavior, it remains unclear how these two types of sensory experience, model exposure and feedback, act on sensorimotor networks controlling the learning and production of learned vocalizations. Using a combination of longitudinal in vivo imaging of neuronal structure and electrophysiological measurements of neuronal function, I addressed the questions of where, when, and how these two types of sensory experience act on sensorimotor neurons important to singing and song learning in zebra finches. The major finding of these experiments is that synaptic inputs onto neurons in HVC, a sensorimotor nucleus important to singing and song learning, are sensitive to tutor song experience and deafening. Thus, these findings for the first time link auditory experiences important to vocal imitation to synaptic reorganization in sensorimotor neurons important to behavior.</p> / Dissertation

Neurosciences

imitation

in vivo imaging

songbirds

vocal learning

Ultrahigh Resolution Optical Coherence Tomography for Non-invasive Imaging of Outer Retina Degeneration in Rat Retina

Hariri, Sepideh

January 2013

This project initiated with the aim for improving the ultrahigh resolution optical coherence tomography (UHR-OCT) system performance by considering the limitations to the axial OCT resolution for in vivo imaging of human and animal retina. To this end, a computational model was developed to simulate the effect of wavelength-dependant water absorption on the detected spectral shape of the broad-bandwidth light source used in UHR-OCT at 1060nm wavelength region, which effectively determines the axial OCT resolution in the retina. For experimental verification of the computational model, a custom built light source with a re-shaped spectrum (Superlum Inc.) was interfaced to the state-of-the-art UHR-OCT system. About 30% improvement of the axial OCT resolution in the rat retina and ~12% improvement of the axial OCT resolution in the human retina was achieved compared to the case of the almost Gaussian shaped spectrum of the standard, commercially available SLD. Although water absorption in the 1060nm spectral region strongly affects the sample beam, selecting a suitable light source with specific spectral shape can compensate for the undesired water absorption effect and thus result in significantly improved axial resolution in in vivo OCT retinal images. To demonstrate the advantages of the state-of-the-art OCT technology for non invasive retinal imaging, an established animal model of outer retina degeneration (sodium iodate (NaIO3)-induced retina degeneration) was employed for longitudinal monitoring of the degeneration and investigation of possible early and dynamic signs of damage undetected by other imaging modalities. The long-term (up to 3 months) and short-term (up to 12 hours) effect of sodium iodate toxicity on the layered structure of retina was monitored longitudinally and in vivo for the first time using OCT. An initial acute swelling of the retina, followed by progressive disruption and degeneration of outer retina was observed as a result of sodium iodate-induced damage. Changes in the thickness and optical reflectivity of individual retinal layers were extracted from the OCT images to quantify the changes occurring at different stages of the disease model. Results from this project present the theoretical and practical limits to the highest axial OCT resolution achievable for retina imaging in the 1060nm spectral range both in small animals and humans, and provided a framework for future development of novel light sources. Furthermore, UHR-OCT imaging was shown to be an effective and valuable modality for in vivo, non invasive investigation of retina degenerative disease.

optical coherence tomography

retina degeration

in vivo imaging

rat retina

Physics

Lymphatic Drainage from the Mouse Eye and the Effect of Latanoprost

Tam, Alex Lai Chi

28 November 2013

Glaucoma is a leading cause of world blindness, often associated with elevated eye pressure. Current glaucoma treatments aim to lower eye pressure by improving aqueous humor outflow from the eye. Ocular lymphatics have been demonstrated to contribute to aqueous humor outflow in human and sheep. It is not known whether any glaucoma drugs target this lymphatic drainage. The mouse is a valuable model with similar aqueous humor dynamics and pharmacology as human. Using in vivo hyperspectral fluorescence imaging combined with intracameral quantum dot injection, we identified an ocular lymphatic drainage in mouse. Immunofluorescence and confocal microscopy revealed lymphatic channels in the ciliary body, sclera, and orbit that may be responsible for this lymphatic drainage. We showed that latanoprost, a prostaglandin F2&alpha; analog widely used to treat glaucoma, increases this ocular lymphatic drainage. Our findings provide the framework for future development of novel glaucoma drugs that stimulate the ocular lymphatic drainage.

lymphatics

mouse

eye

quantum dots

in vivo imaging

latanoprost

0381

Lymphatic Drainage from the Mouse Eye and the Effect of Latanoprost

Tam, Alex Lai Chi

28 November 2013

Glaucoma is a leading cause of world blindness, often associated with elevated eye pressure. Current glaucoma treatments aim to lower eye pressure by improving aqueous humor outflow from the eye. Ocular lymphatics have been demonstrated to contribute to aqueous humor outflow in human and sheep. It is not known whether any glaucoma drugs target this lymphatic drainage. The mouse is a valuable model with similar aqueous humor dynamics and pharmacology as human. Using in vivo hyperspectral fluorescence imaging combined with intracameral quantum dot injection, we identified an ocular lymphatic drainage in mouse. Immunofluorescence and confocal microscopy revealed lymphatic channels in the ciliary body, sclera, and orbit that may be responsible for this lymphatic drainage. We showed that latanoprost, a prostaglandin F2&alpha; analog widely used to treat glaucoma, increases this ocular lymphatic drainage. Our findings provide the framework for future development of novel glaucoma drugs that stimulate the ocular lymphatic drainage.

lymphatics

mouse

eye

quantum dots

in vivo imaging

latanoprost

0381

In vivo imaging of cortical porosity by synchrotron phase contrast micro computed tomography

2013 August 1900

Cortical bone is a dynamic tissue which undergoes adaptive and pathological changes throughout life. An improved understanding of the spatio-temporal process of remodeling holds great promise for improving our understanding of bone development, maintenance and senescence. The use of micro-computed tomography (µCT) on living animals is relatively new and allows the three dimensional quantification of change in trabecular bone microarchitecture over time. The use of in vivo µCT is limited by the radiation dose created by the x-ray beam, with commercially available in vivo systems generally operating in the 10-20 um resolution range and delivering an absorbed dose between 0.5-1 Gy. Because dose scales to the power of four with resolution, in vivo imaging of the cortical canal network, which requires a higher resolution, has not been achieved. I hypothesized that using synchrotron propagation phase contrast µCT, cortical porosity could be imaged in vivo in rats at a dose on the same level as those used currently for trabecular bone analysis. Using the BMIT-BM beamline, I determined the optimal propagation distance and used ion chamber and lithium fluoride crystal thermoluminescent dosimetry to measure the absorbed dose of my in vivo protocol as well as several ex vivo protocols using synchrotron phase contrast µCT at 5 µm, 10 µm, and 11.8 µm and conventional desktop in vivo protocols using commercial µCT systems. Using synchrotron propagation phase contrast µCT, I scanned the forelimb of two adult Sprague-Dawley rats and measured an absorbed dose of 2.53 Gy. Using two commercial µCT system, I measured doses between 1.2-3.6 Gy for protocols at 18µm that are in common use. This thesis represents the first in vivo imaging of rat cortical porosity and demonstrates that an 11.8 µm resolution is enough to visualize cortical porosity in rats, with a dose within the scope of those used for imaging trabecular bone in vivo.

Cortical bone

Ultrahigh Resolution Optical Coherence Tomography for Non-invasive Imaging of Outer Retina Degeneration in Rat Retina

Hariri, Sepideh

January 2013

This project initiated with the aim for improving the ultrahigh resolution optical coherence tomography (UHR-OCT) system performance by considering the limitations to the axial OCT resolution for in vivo imaging of human and animal retina. To this end, a computational model was developed to simulate the effect of wavelength-dependant water absorption on the detected spectral shape of the broad-bandwidth light source used in UHR-OCT at 1060nm wavelength region, which effectively determines the axial OCT resolution in the retina. For experimental verification of the computational model, a custom built light source with a re-shaped spectrum (Superlum Inc.) was interfaced to the state-of-the-art UHR-OCT system. About 30% improvement of the axial OCT resolution in the rat retina and ~12% improvement of the axial OCT resolution in the human retina was achieved compared to the case of the almost Gaussian shaped spectrum of the standard, commercially available SLD. Although water absorption in the 1060nm spectral region strongly affects the sample beam, selecting a suitable light source with specific spectral shape can compensate for the undesired water absorption effect and thus result in significantly improved axial resolution in in vivo OCT retinal images. To demonstrate the advantages of the state-of-the-art OCT technology for non invasive retinal imaging, an established animal model of outer retina degeneration (sodium iodate (NaIO3)-induced retina degeneration) was employed for longitudinal monitoring of the degeneration and investigation of possible early and dynamic signs of damage undetected by other imaging modalities. The long-term (up to 3 months) and short-term (up to 12 hours) effect of sodium iodate toxicity on the layered structure of retina was monitored longitudinally and in vivo for the first time using OCT. An initial acute swelling of the retina, followed by progressive disruption and degeneration of outer retina was observed as a result of sodium iodate-induced damage. Changes in the thickness and optical reflectivity of individual retinal layers were extracted from the OCT images to quantify the changes occurring at different stages of the disease model. Results from this project present the theoretical and practical limits to the highest axial OCT resolution achievable for retina imaging in the 1060nm spectral range both in small animals and humans, and provided a framework for future development of novel light sources. Furthermore, UHR-OCT imaging was shown to be an effective and valuable modality for in vivo, non invasive investigation of retina degenerative disease.

optical coherence tomography

retina degeration

in vivo imaging

rat retina

Physics

Etude de la physiopathologie des infections à alphavirus arthritogènes par une approche d’imagerie in vivo / Deciphering the physiopathology of arthritogenic alphaviral infections using in vivo bioluminescence imaging

Belarbi, Essia

19 April 2017

Les alphavirus arthritogènes de la rivière Ross (RRV) et du chikungunya (CHIKV) sont des arbovirus à l’origine de maladies inflammatoires musculosquelettiques chez l'homme. Ils sont largement distribués dans le monde et provoquent périodiquement des épidémies explosives. Les principaux signes cliniques lors d’une infection par un alphavirus arthritogène sont les myalgies, polyarthrites et arthralgies intenses pouvant persister plusieurs mois après l'infection. Les mécanismes de développement de l’infection et des manifestations persistantes sont peu connus. Pour étudier la pathogenèse de l'infection par RRV, nous avons généré un virus recombinant exprimant une nouvelle luciférase brillante et brillante. Nous avons montré que les monocytes humains, malgré une faible susceptibilité à l'infection in vitro par RRV, étaient capables de maintenir une réplication virale jusqu'à 45 jours post infection indiquant leur rôle potentiel dans les formes chroniques. Grâce un modèle expérimental de l’infection par RRV, nous avons suivi les phases aiguë et chronique de la maladie in vivo. Nous avons montré que les cinétiques de réplication du virus recombinant étaient proches de celles du virus parental. Nous avons également observé un tropisme musculaire et articulaire et une corrélation entre le signal bioluminescent et la charge virale confirmant ainsi la relevance de ce modèle. En étudiant la dissémination virale, nous avons montré que le Bindarit, une molécule anti-inflammatoire diminuant le développement de la maladie dans le modèle murin, induit une plus grande réplication dans le tissu cardiaque. Enfin, nous avons pu observer une réplication virale dans les tissus musculaires durant la phase chronique de la maladie et avons montré le rôle de la dose inoculée dans le développement de la persistance virale. Suite à un traitement immunosuppresseur, nous avons observé une légère augmentation du signal bioluminescent indiquant un contrôle de la réplication virale persistante par la réponse immunitaire adaptative. Ce nouveau modèle d’imagerie in vivo permet un suivi en temps réel de la dissémination virale permettant des études de pathogenèse et l'évaluation de stratégies thérapeutiques. / Ross River virus (RRV) and chikungunya virus (CHIKV) are mosquito-transmitted viruses that cause musculoskeletal inflammatory diseases in humans. They are widely distributed and periodically cause explosive epidemics. After infection with RRV, patients experience fever, maculopapular rash, myalgia and intense pain in the peripheral joints. Approximately 30% of patients develop a chronic form of the disease with myalgia and poly-arthralgia persisting for months to years after infection. The mechanisms underlying these persistent symptoms remain unclear. To study the dynamics and pathogenesis of RRV infection in vitro and in living animals, we generated a recombinant virus expressing a novel small and bright luciferase. First we showed that human monocytes, despite a low susceptibility to RRV infection, were able to maintain viral replication in vitro up to 45 days post infection. Then, using a murine model of RRV infection, we monitored the acute and chronic phases of the disease. We observed near native replication kinetics and a muscular/articular tropism after infection with our recombinant virus. Moreover, the bioluminescent signal correlated with the viral load further confirming the relevance of this new imaging model. After monitoring of the viral dissemination in live mice, we showed that Bindarit, an anti-inflammatory molecule known to prevent the development of the alphaviral disease in a mouse model, induces a higher replication in the cardiac tissue; thereby indicating that caution must be used before treatment of patients. We were also able to observe viral replication in the muscles during the chronic stage of the disease when using a low inoculation dose. Finally, following an immunosuppressive treatment, we observed a slight increase in the bioluminescent signal indicating a control of remnant viral replication by the adaptive immune response. This new model provides a non-invasive real-time assessment of viral replication and dissemination allowing pathogenesis studies and therapeutic strategies evaluation.

Alphavirus

Physiopathologie

Imagerie in vivo

Bioluminescence

Alphavirus

Physiopathology

In vivo imaging

Bioluminescence

Targeting Early Vascular Dysfunction Following Spinal Cord Injury

Chen, Chen

10 1900

Indiana University-Purdue University Indianapolis (IUPUI) / The vascular network highly coordinates with the central nervous system (CNS) on exchanging oxygen, nutrients and information transfer. The resemblance of the two systems at anatomical, cellular, and molecular levels also demonstrates their interdependence. The spinal cord is an integrated part of the CNS. Traumatic spinal cord injury (SCI) causes rapid systemic vascular responses and local neural tissue damage at the initial phase. The early disruption of the spinal vasculature breaks the supply-and-demand balance and facilitates the deterioration of the spinal cord tissue and functional deficits. Therefore, it is important to dissect the mechanism underlying vascular injury-mediated histological and functional consequences in order to develop potential therapeutic strategies. To visualize dynamic vascular changes after an acute SCI, a novel duo-color in vivo imaging technique was successfully developed in adult rats at the cervical level. This technique overcomes previous technical hurdles allowing real-time observation of vascular changes in live animals. Correlated with histological measures, in vivo vascular outcomes revealed a temporospatial relationship with neuronal and axonal loss, myelin disruption, inflammation, and glial responses. For the first time, we defined a “transitional zone” where significant blood vessel dilation and vascular leakage were observed simultaneously with vascular changes occurred at the injury epicenter acutely after SCI. These vascular changes at the transitional zone happened before any other cellular damage after SCI, suggesting a time window to prevent further neuronal damage in this region. Targeting the observed vascular leakage can work as a proof of concept that early vascular dysfunction contributes to the secondary neural tissue damage. Indeed, intravenous delivery of ferulic acid conjugated with glycol chitosan (FA-GC) to the injured sites immediate after SCI resulted in reduced vascular leakage, ventral horn neuronal loss, and partial recovery of forelimb function following a clinically-relevant contusive SCI at the 7th cervical spinal cord level. In conclusion, this work elucidated a novel role and mechanism of early vascular damage in the “transitional zone” prior to the secondary damage of neural tissue in this region and provided a novel treatment strategy for early neuroprotection and functional recovery. / 2021-11-04

in vivo imaging

Neuroprotection

Rodent model

Spinal cord injury

Vascular

Red to Near-Infrared Luminescent Materials Activated by Transition Metals for in vivo Imaging and Telecommunication Application / バイオイメージングまたは光通信応用を目指した遷移金属賦活赤色・近赤外発光材料に関する研究

Zhuang, Yixi

24 March 2014

京都大学 / 0048 / 新制・課程博士 / 博士(人間・環境学) / 甲第18361号 / 人博第674号 / 新制||人||162(附属図書館) / 25||人博||674(吉田南総合図書館) / 31219 / 京都大学大学院人間・環境学研究科相関環境学専攻 / (主査)教授 田部 勢津久, 教授 加藤 立久, 教授 杉山 雅人 / 学位規則第4条第1項該当 / Doctor of Human and Environmental Studies / Kyoto University / DGAM

Optical materials

photoluminescence

persistent luminescence

in vivo imaging

telecommunication

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