Retinal optical imaging of intrinsic signals

Naderian, Azadeh

11 1900

No description available.

Rétine

Imagerie intrinsèque

Modèle animal

Conception d’appareillage

Système imagerie

Électrorétinogramme

Photorécepteurs

Cellules bipolaires

Cellules ganglionnaires

Retina

Intrinsic imaging

Animal model

Imaging system

Electroretinogram

photoreceptors

Bipolar cells

Ganglion cells

Rôle de la leucocidine de Panton-Valentine dans l'infection oculaire staphylococcique : étude des cibles cellulaires et des conséquences inflammatoires tissulaires rétiniennes sur des modèles d'endophtalmie in vivo et ex vivo chez le lapin / Panton–Valentine leucocidin colocalized with retinal neurons cells and incited early retinal inflammation through rabbit endophthalmitis and retinal explant models

Liu, Xuanli

28 September 2018

Staphylococcus aureus est une bactérie responsable de nombreuses infections. Divers facteurs de virulence sont décrits comme ayant un rôle aggravant dans l’infection staphylococcique. La leucocidine de Panton-Valentine (LPV) en est un. Elle interagit par l’intermédiaire du récepteur de C5a (C5aR) avec les leucocytes et les cellules neuronales dans différents tissus, mais son action au niveau rétinien est méconnue. Nous avons recherché des cibles rétiniennes cellulaires de l’intoxination à la LPV et étudié ses conséquences cellulaires et inflammatoires précoces dans les tissus rétiniens. AINSI, deux modèles de lapins ont été créés : l'injection intravitréenne in vivo et les explants rétiniens ex vivo. Dans les deux modèles, les cellules ganglionnaires étaient les principales cibles cellulaires rétiniennes de la LPV et le seul type de neurones rétiniennes qui exprimait C5aR. Les cellules de Müller comme la microglie étaient activées. L’explant rétinien était facilement manipulé, ils peuvent servir à la recherche de la LPV sur la rétine. La LPV seule pourrait induire une inflammation rétinienne après avoir ciblé spécifiquement les cellules neuronales. / Staphylococcus aureus is responsible for many infections. It secretes various virulence factors aggravating the staphylococcal infections. Panton-Valentine leucocidin (PVL) is a virulent leukotoxin from S. aureus and presents active effects towards leukocytes and neuronal cells via the C5a receptor (C5aR). The effects of PVL on retina is little known. We explored PVL retinal cell target and early retinal inflammation and tried to find the processes of bacterial toxins aggravating bacterial endophthalmitis. We employed two different rabbit models to study the PVL effects on retina: intravitreal injection in vivo and retinal explant ex vivo. In the two models, retinal ganglion cells were the only retinal neurons which express C5aR and the major cell targets of PVL in retina. PVL induced retinal Müller and microglial cell activation. The retinal explants were easily manipulated and showed obvious cellular targets of PVL and glial cell activations, they can contribute to research the effects of PVL on retina in future. PVL alone without S. aureus could induce great retinal inflammation after targeting specifically retinal neurons.

Staphylococcus aureus

Leucocidine de Panton-Valentine

C5aR

Cellules ganglionnaires

Cellules de Müller

Microglie

Explant rétinien

Inflammation rétinienne

Staphylococcus aureus

Panton-Valentine leucocidin

C5aR

Retinal ganglion cells

Müller cell

Microglial cell

Retinal explant

Retinal inflammation

579.3

616.92

617.7

Sensory neuronal protection & improving regeneration after peripheral nerve injury

McKay Hart, Andrew

January 2003

Peripheral nerve trauma is a common cause of considerable functional morbidity, and healthcare expenditure. Particularly in the ~15% of injuries unsuitable for primary repair, standard clinical management results in inadequate sensory restitution in the majority of cases, despite the rigorous application of complex microsurgical techniques. This can largely be explained by the failure of surgical management to adequately address the neurobiological hurdles to optimal regeneration. Most significant of these is the extensive sensory neuronal death that follows injury, and which is accompanied by a reduction in the regenerative potential of axotomised neurons, and in the supportive capacity of the Schwann cell population if nerve repair is delayed. The present study aimed to accurately delineate the timecourse of neuronal death, in order to identify a therapeutic window during which clinically applicable neuroprotective strategies might be adopted. It then proceeded to investigate means to increase the regenerative capacity of chronically axotomised neurons, and to augment the Schwann cells’ ability to promote that regenerative effort. Unilateral sciatic nerve transection in the rat was the model used, initially assessing neuronal death within the L4&5 dorsal root ganglia by a combination of morphology, TdT uptake nick-end labelling (TUNEL), and statistically unbiased estimation of neuronal loss using the stereological optical disector technique. Having identified 2 weeks, and 2 months post-axotomy as the most biologically relevant timepoints to study, the effect upon neuronal death of systemic treatment with acetyl-L-carnitine (ALCAR 10, or 50mg/kg/day) or N-acetyl-cysteine (NAC 30, or 150mg/kg/day) was determined. A model of secondary nerve repair was then adopted; either 2 or 4 months after unilateral sciatic nerve division, 1cm gap repairs were performed using either reversed isografts, or poly-3-hydroxybutyrate (PHB) conduits containing an alginate-fibronectin hydrogel. Six weeks later nerve regeneration and the Schwann cell population were quantified by digital image analysis of frozen section immunohistochemistry. Sensory neuronal death begins within 24 hours of injury, but takes 1 week to translate into significant neuronal loss. The rate of neuronal death peaks 2 weeks after injury, and neuronal loss is essentially complete by 2 months post-axotomy. Nerve repair is incompletely neuroprotective, but the earlier it is performed the greater the benefit. Two clinically safe pharmaceutical agents, ALCAR & NAC, were found to virtually eliminate sensory neuronal death after peripheral nerve transection. ALCAR also enhanced nerve regeneration independently of its neuroprotective role. Plain PHB conduits were found to be technically simple to use, and supported some regeneration, but were not adequate in themselves. Leukaemia inhibitory factor enhanced nerve regeneration, though cultured autologous Schwann cells (SC’s) were somewhat more effective. Both were relatively more efficacious after a 4 month delay in nerve repair. The most profuse regeneration was found with recombinant glial growth factor (rhGGF-2) in repairs performed 2 months after axotomy, with results that were arguably better than were obtained with nerve grafts. A similar conclusion can be drawn from the result found using both rhGGF-2 and SC’s in PHB conduits 4 months after axotomy. In summary, these findings reinforce the significance of sensory neuronal death in peripheral nerve trauma, and the possibility of its` limitation by early nerve repair. Two agents for the adjuvant therapy of such injuries were identified, that can virtually eliminate neuronal death, and enhance regeneration. Elements in the creation of a bioartificial nerve conduit to replace, or surpass autologous nerve graft for secondary nerve repair are presented.

Neurosciences

cell death

TUNEL

optical disection

dorsal root ganglion

peripheral nerve

nerve conduit

Schwann cell

glial growth factor

leukaemia inhibitory factor

acetyl-L-carnitine

N-acetyl-cysteine

Neurovetenskap

Neurology

Neurologi

Anti-Apoptosis and Regeneration in the Visual System: Effects of BAG1 (Bcl-2-associated athanogene-1) / Antiapoptosis und Regeneration in den optischen System: Effekte von Bcl-2-associated-athanogene-1

Planchamp, Anne-Véronique

01 November 2007

No description available.

570 Biowissenschaften, Biologie

WA 000 Biologie

Allgemeines

Mathematics and Natural Science

Apoptose

Regeneration

BAG1

ROCK

Retinalganglionzellen

Adeno-assoziierten Viren

Apoptosis

regeneration

BAG1 (Bcl-2-associated-athanogene-1)

ROCK (Rho-associated kinase)

retinal ganglion cell

adeno-associated virus

42.15 Zellbiologie

Optic nerve regeneration in adult rat

Hu, Ying

January 2007

[Truncated abstract] There is limited intrinsic potential for repair in the adult human central nervous system (CNS). Dysfunction resulting from CNS injury is persistent and requires prolonged medical treatment and rehabilitation. The retina and optic nerve are CNSderived, and adult retinal ganglion cells (RGCs) and their axons are often used as a model in which to study the mechanisms associated with injury, neuroprotection and regeneration. In this study I investigated the effects of a variety of strategies on promoting RGC survival and axonal regeneration after optic nerve injury, including the use of reconstructed chimeric peripheral nerve (PN) grafts, gene therapy, and intraocular application of pharmacological agents and other factors . . . C3 transferase is an enzyme derived from Clostridium botulinum that inactivates Rho GTPase. Because SC myelin contains MAG and PN also contains CSPGs, I tested the effects of intraocular injection of a modified form of C3 (C3-11), provided by Dr Lisa McKerracher (CONFIDENTIAL data, under IP agreement with Bioaxone Therapeutic, Montreal) on RGC axonal regeneration into PN autografts. My results showed that there was significantly more RGC survival and axonal regeneration in PN autografts after repeated intraocular injection of C3. I also tested whether intraocular injections of CPT-cAMP and/or CNTF can act in concert with the C3 to further increase RGC survival and/or regeneration. Results showed that the effect of C3 and CPT-cAMP plus CNTF were synergistic and partially additive. The use of combination therapies therefore offers the best hope for robust and substantial regeneration. The overall results from my PhD project will help determine how best to reconstruct nerve pathways and use pharmacological interventions in the clinical treatment of CNS injury, hopefully leading to improved functional outcomes after neurotrauma.

Nervous system -- Regeneration

Retinal ganglion cells

Rats -- Nervous system

Ciliary neurotrophic factor

Neural regeneration

Neuroprotection and axonal regeneration after peripheral nerve injury

Welin, Dag,

January 2010

Diss. (sammanfattning) Umeå : Umeå universitet, 2010.

Melanopsin polymorphisms in seasonal affective disorder /

Roecklein, Kathryn Ariel.

January 2005

Thesis (M.S.)--Uniformed Services University of the Health Sciences, 2005. / Running title: Seasonal affective disorder and melanopsin. Typescript (photocopy).

Sound encoding in mutant mice with disrupted action potential generation

Yamanbaeva, Gulnara

21 August 2017

No description available.

570

WRB

PSD-95

AMPA receptors recycling

ßIV-spectrin

single unit in vivo recording

spiral ganglion neuron

in vivo electrophysiology

STED microscopy

inner hair cell ribbon synapse

otoferlin

cochlear nucleus neuron

action potential generation

sound encoding

Biologie (PPN619462639)

The impact of exposure to constant light and hyperoxia on the retina / L'impacte de l'exposition à une lumière constante et l'hyperoxie sur la rétine

Mehdi, Madah Khawn -i- Muhammad

04 April 2013

Les yeux forment des avant-postes visuels importants du cerveau. Comme les autres organes, la rétine sensorielle des yeux est vulnérable aux effets nocifs des facteurs environnementaux, tels que la lumière et l'oxygène. Dans ce travail, nous nous sommes concentrés sur l’impact de l’exposition à une lumière constante et l’hyperoxie prolongée sur l'architecture et la fonction rétinienne. Dans la première partie de notre étude, nous avons montré qu’ une exposition de sept jours à une lumière constante perturbe la phagocytose des bâtonnets et cônes et régule négativement leur renouvellement dans la « rétine riche en cônes " d’Arvicanthis ansorgei. Notre étude donne un aperçu sur la physiopathologie des cônes, ce qui représente la principale source de handicap visuel dans une variété de pathologies rétiniennes, y compris la rétinite pigmentaire (RP) et la dégénérescence maculaire liée à l'âge (DMLA). Dans la deuxième partie de notre étude, nous avons montré qu’ une exposition de cinq jours à l’hyperoxie entraîne chez les souris néonatales une perte significative de cellules ganglionnaires dans les régions périphériques de la rétine, et de cellules à mélanopsine (ipRGC). L’exposition prolongée à l’hyperoxie perturbe également la capacité de photoentrainment des animaux probablement due à la perte des ipRGC et la perte de la rhodopsine dans les segments externes des bâtonnets chez les animaux traités. / Eyes form important visual outposts of the brain. Just like other organs, sensory retina in the eyes is also vulnerable to the injurious effects of environmental factors; such as light and oxygen. In this work, we have focused on the impacts of constant prolonged light and hyperoxia on the retinal architecture and function. In the first part of our study, we show that seven days of constant light disrupts rod and cone phagocytosis and downregulates their turnover in the “cone rich retina” of Arvicanthis ansorgei. The study gives an insight on the cone pathophysiology, which represents the major source of visual handicap in a variety of retinal pathologies, including retinitis pigmentosa (RP) and age-related macular degeneration (AMD). In the second part of our study, we show that five days of hyperoxia treatment in the neonatal mice results in the significant loss of retinal ganglion cells in the peripheral regions; the loss of melanopsin expressing retinal ganglion cells (ipRGC) was found to be significant. Hyperoxia also affects the photoentrainment capability of the animals probably because of the loss of ipRGC and the loss of rhodopsin in the outer segments of the photoreceptors in the treated animals.

Rétine

Dégénérescence

Photorécepteurs

Cellules ganglionnaires

Cellules à mélanopsine

Rétinopathie prématuré

Lumière constante

Lumière prolongée

Phagocytose

Retina

Degeneration

Photoreceptors

Retinal ganglion cells

Melanopsin cells

Retinopathy of prematurity

Constant light

Prolonged light

Phagocytosis

572.8

573.8

612.84

"Análise comparativa das medidas de espessura da camada de fibras nervosas da retina de pacientes com atrofia em banda do nervo óptico e de indivíduos normais através da tomografia de coerência óptica e da polarimetria a laser" / A comparative analysis of the retinal nerve fiber layer thickness measurements in patients with band atrophy of the optic nerve and in normal controls using optical coherence tomography and scanning laser polarimetry

Bruno Campêlo Leal

07 July 2006

As afecções que acometem a via óptica anterior podem acarretar perda de fibras das células ganglionares retinianas, gerando alterações na camada de fibras nervosas da retina (CFNR). O objetivo deste trabalho foi o de comparar a capacidade da tomografia de coerência óptica (OCT-1), do OCT 3 (Stratus OCT) e do polarímetro de varredura a laser (GDx) em diferenciar olhos normais de olhos com atrofia em banda do nervo óptico e hemianopsia temporal, assim como, comparar o desempenho de tais tecnologias entre si. Foram estudados 37 indivíduos num total de 46 olhos divididos igualmente em dois grupos. O Stratus OCT, o OCT 1 e o GDx se mostraram capazes de identificar corretamente a redução global (average) da espessura da CFNR dos indivíduos com AB comparados com uma população normal. Observamos uma melhora progressiva das sensibilidades/especificidades e das AROC, com o desempenho melhor do OCT1 sobre o GDx e do Stratus OCT sobre o OCT 1 / Most diseases that affect the optic pathways present clinically with loss of one or more visual functions.When optic pathway injuries involve the anterior visual pathways they may cause loss of the retinal nerve fiber layer (RNFL) and "band atrophy" (BA). The purpose of this study was therefore to compare the ability of the optical coherence tomography (OCT) 1, the OCT 3 (Stratus OCT) and the scanning laser polarimetry (GDx) to differentiate normal eyes from eyes with BA of the optic nerve and temporal hemianopsia. Thirty-seven individuals in a total of 46 eyes divided equally in two groups were studied. Each one of the parameters, except the values from the nasal quadrant measured by the GDx, showed statistically significant difference when we compare normal patients with the BA group. The study also showed a gradual improvement of the sensibilities/specificities and of the AROC, with a better performance of the OCT1 compared to GDx and of the Stratus OCT compared to the OCT 1

Atrofia óptica/diagnóstico

Células do gânglio retiniano

Laser/uso diagnóstico

Retina

Técnicas de diagnóstico oftalmológico

Tomografia de coerência óptica

Diagnostic techniques ophthalmological

Laser/diagnostic use

Optic atrophy/diagnosis

Retina

Retinal ganglion cells

Tomography optical coherence