EXAMINING THE RELATIONSHIP BETWEEN THE GUT MICROBIOME AND CENTRAL NERVOUS SYSTEM INFLAMMATION IN RATS WITH FETAL ALCOHOL SYNDROME

Sarah G Moh (15348556)

26 April 2023

<p>  Fetal Alcohol Syndrome (FAS) is the most serious form of Fetal Alcohol Spectrum Disorders (FASD) and the most prevalent neurodevelopmental disorder in North America. Patients with FAS may exhibit cognitive problems with working memory, manipulating information, and reduced executive functioning. Additionally, previous studies exhibited that stress responses are affected by prenatal alcohol consumption Gut microbiota compositions can also influence stress responses and memory, as several studies have shown strong relationships between the enteric gut system and the brain. However, few studies have examined how prenatal alcohol exposure’s effects on the gut microbiome and neuroinflammatory responses. For this study, pregnant HsdBlu:LE Long Evans rats were treated with either a dry diet, liquid diet, or liquid diet with alcohol. On day 28 and 42 after birth, three male and three female adolescent pups from each treatment group had their gut microbiome (fecal samples) analyzed through 16S rRNA amplicon sequencing. Brain histology staining of the cortex and hippocampus regions was also done to evaluate changes in the CNS through microglial counts and morphology analysis. There were no significant differences in alpha diversity of the fecal microbiome between groups of pups based on prenatal alcohol exposure (PAE), sex, age, the interaction of PAE and sex, or in the morphology of cortex microglia. However, analysis of beta diversity using Bray-Curtis dissimilarity and weighted UniFrac suggested distinct microbial communities between the treatment groups based on PAE and the interaction of PAE, sex, and the interaction between PAE and sex. Microglial count comparisons by PAE or sex were only statistically different in the cortex (p ≤ 0.005). The significance of this study suggests that there are some associations between the gut microbiome and CNS inflammation in rats with PAE. Based on these findings, 11 future studies may implement therapeutics such as antibiotics or probiotics to mitigate cognitive or neural symptoms of FASD affected individuals. </p>

Sequence analysis

Microbial ecology

Microbiology not elsewhere classified

Alcohol

Fetal alcolohol spectrum disorders

Microglia

CNS inflammation

Gut Microbiome

Microbiome sequencing

Changes in Sympathetic Preganglionic Neurons and Associated Glial Cells following Injury

Coulibaly, Aminata P.

17 August 2010

No description available.

Biology

Biomedical Research

Cellular Biology

Molecular Biology

Choline acetyltransferase

chat

cervical sympathetic trunk

cst

preganglionic neurons

intermediolateral cell column

IML

spinal cord

activating transcription factor-3

ATF-3

distal axonal injury

transection

astrocytes

microglia

In Vivo Observations of Resident Microglia and Blood Derived Macrophages in the Brain and Spinal Cord

Evans, Teresa Ann

11 June 2014

No description available.

Neurosciences

Immunology

Microglia

Macrophages

Monocytes

CNS Immune Response

Spinal Cord Injury

Two Photon

Cellular Interactions

Autoimmune Encephalomyelitis

CX3CR1

Thy-1

In Vivo Imaging

Dorsal Column Crush Injury

Laminectomy

Irradiation Bone Marrow Chimera

Therapeutic suppression of mutant SOD1 by AAV9-mediated gene therapy approach in Amyotrophic Lateral Sclerosis

Likhite, Shibi B.

January 2014

No description available.

Biology

Biomedical Research

Immunology

Molecular Biology

Neurosciences

Neurobiology

Neurology

Virology

Amyotrophic Lateral Sclerosis, ALS

Superoxide Dismutase 1, SOD1

Adeno-associated vector 9, AAV9

short hairpin RNA, shRNA

Astrocytes

Neuroinflamation

Galectin 1, Gal1

Microglia

TLR4-activated microglia have divergent effects on oligodendrocyte lineage cells

Goldstein, Evan Zachary

28 December 2016

No description available.

Biology

Biomedical Research

Immunology

Medicine

Molecular Biology

Neurobiology

Neurosciences

Oligodendrocyte

Oligodendrocyte progenitor cell

Oligodendrogenesis

Inflammation

Toll-like receptor 4

Colony stimulating factor 3

Interleukin-7

Iron

Ferritin

Microglia

Astrocyte

Neuron

Neuroimmunology

Neuroscience

Loss of Perineuronal Net in ME7 Prion Disease

Franklin, S.L., Love, S., Greene, J.R., Betmouni, S.

January 2008

No / Microglial activation and behavioral abnormalities occur before neuronal loss in experimental murine prion disease; the behavioral changes coincide with a reduction in synaptic plasticity. Because synaptic plasticity depends on an intact perineuronal net (PN), a specialized extracellular matrix that surrounds parvalbumin (PV)-positive GABAergic (gamma-aminobutyric acid [GABA]) inhibitory interneurons, we investigated the temporal relationships between microglial activation and loss of PN and PV-positive neurons in ME7 murine prion disease. Anesthetized C57Bl/6J mice received bilateral intracerebral microinjections of ME7-infected or normal brain homogenate into the dorsal hippocampus. Microglial activation, PrP accumulation, the number of PV-positive interneurons, and Wisteria floribunda agglutinin-positive neurons (i.e. those with an intact PN) were assessed in the ventral CA1 and subiculum at 4, 8, 12, 16, and 20 weeks postinjection. Hippocampal areas and total neuron numbers in the ventral CA1 and subiculum were also determined. Loss of PN coincided with early microglial activation and with a reduction in synaptic plasticity. No significant loss of PV-positive interneurons was observed. Our findings suggest that the substrate of the earliest synaptic and behavioral abnormalities in murine prion disease may be inflammatory microglia-mediated degradation of the PN.

Animals

Disease models

Disease progression

Encephalitis

Extracellular matrix

Female

Gliosis

Hippocampus

Interneurons

Mice

Inbred C57BL

Microglia

Nerve degeneration

Neural pathways

Neuronal plasticity

Parvalbumins

Plant lectins

PrPSc proteins

Prion diseases

Receptors

N-acetylglucosamine

Staining and labelling

Gamma-aminobutyric acid

REF 2014

Hipertensão arterial e disfunção autonômica induzidas por dieta hiperlipídica: papel do CART e de fatores inflamatórios em núcleos autonômicos do sistema nervoso central. / High blood pressure and autonomic dysfunction induced by high-fat diet: role of CART and inflammatory factors in central autonomic network.

Chaar, Laiali Jurdi El

27 June 2016

Obesidade é fator de risco para a hipertensão arterial e os mecanismos envolvidos nesta doença não são totalmente esclarecidos. Camundongos C57BL/6J e transgênicos com com deleção em neurônios e glia da via inflamatória do receptor toll-like-NF&#954;B foram submetidos à dieta hiperlipídica (HL) por 8 e 15 semanas e avaliados parâmetros metabólicos, pressão arterial, frequência cardíaca, atividade do sistema nervoso autônomo, fatores inflamatórios e neuropeptídeos no hipotálamo e no tronco encefálico. Os camundongos expostos HL desenvolveram hipertensão arterial acompanhada de disfunção autonômica e aumento de CART no DMH. Os animais transgênicos quando submetidos à dieta HL desenvolveram um quadro de obesidade, porém não apresentaram hipertensão arterial e disfunção autonômica. Além disso, o grupo de animais HL aumentou o RNAm de CCL5 no hipotálamo e de CD86 no tronco-encefálico e a densidade de microglia no NTS caudal. Os resultados sugerem novos mecanismos para a hipertensão e disfunção autonômica secundárias à ingestão de dieta hiperlipídica mostrando o papel do CART o DMH e o envolvimento da via inflamatória do TLR-NF&#954;B em neurônios e glia nos mecanismos desta patologia. / Obesity is a risk factor for high blood pressure and the mechanisms involved in this disease are not fully clarified. C57BL/6J and transgenic mice with toll-like-NF&#954;B receptor inflammatory- pathway deletion in neurons and glia were fed with high-fat diet (HL) for 8 or 15 weeks and assessed metabolic parameters, blood pressure, heart rate, autonomic nervous system activity, inflammatory factors and neuropeptides in the hypothalamus and brainstem. The HL mice developed hypertension accompanied with autonomic dysfunction and increased CART in DMH. Transgenic animals when submitted to HL diet developed obesity, but not showed high blood pressure and autonomic dysfunction. In addition, HL animals had increased CCL5 mRNA in hypothalamus, CD86 mRNA in brainstem and micróglia density in caudal NTS. The results suggest new mechanisms for hypertension and autonomic dysfunction secondary to intake of high-fat diet by showing CART role in DMH and the involvement of the inflammatory pathway TLR-NF&#954;B in neurons and glia.

Autonomic nervous system

Brainstem

Cluster of differentiation 86 (CD86)

Dieta hiperlipídica

fator nuclear kappa B (NF&#954;B)

Grupo de diferenciação 86 (CD86)

High-fat diet

Hipertensão arterial

Hipotálamo

Hypothalamus

Inflamação

Inflammation

Microglia

Microglia

Neurogenic hypertension

Obesidade

Obesity

Receptor Toll-like

Sistema nervoso autônomo

Sistema nervoso simpático

Toll-like receptor

Tronco encefálico

Hipertensão arterial e disfunção autonômica induzidas por dieta hiperlipídica: papel do CART e de fatores inflamatórios em núcleos autonômicos do sistema nervoso central. / High blood pressure and autonomic dysfunction induced by high-fat diet: role of CART and inflammatory factors in central autonomic network.

Laiali Jurdi El Chaar

27 June 2016

Obesidade é fator de risco para a hipertensão arterial e os mecanismos envolvidos nesta doença não são totalmente esclarecidos. Camundongos C57BL/6J e transgênicos com com deleção em neurônios e glia da via inflamatória do receptor toll-like-NF&#954;B foram submetidos à dieta hiperlipídica (HL) por 8 e 15 semanas e avaliados parâmetros metabólicos, pressão arterial, frequência cardíaca, atividade do sistema nervoso autônomo, fatores inflamatórios e neuropeptídeos no hipotálamo e no tronco encefálico. Os camundongos expostos HL desenvolveram hipertensão arterial acompanhada de disfunção autonômica e aumento de CART no DMH. Os animais transgênicos quando submetidos à dieta HL desenvolveram um quadro de obesidade, porém não apresentaram hipertensão arterial e disfunção autonômica. Além disso, o grupo de animais HL aumentou o RNAm de CCL5 no hipotálamo e de CD86 no tronco-encefálico e a densidade de microglia no NTS caudal. Os resultados sugerem novos mecanismos para a hipertensão e disfunção autonômica secundárias à ingestão de dieta hiperlipídica mostrando o papel do CART o DMH e o envolvimento da via inflamatória do TLR-NF&#954;B em neurônios e glia nos mecanismos desta patologia. / Obesity is a risk factor for high blood pressure and the mechanisms involved in this disease are not fully clarified. C57BL/6J and transgenic mice with toll-like-NF&#954;B receptor inflammatory- pathway deletion in neurons and glia were fed with high-fat diet (HL) for 8 or 15 weeks and assessed metabolic parameters, blood pressure, heart rate, autonomic nervous system activity, inflammatory factors and neuropeptides in the hypothalamus and brainstem. The HL mice developed hypertension accompanied with autonomic dysfunction and increased CART in DMH. Transgenic animals when submitted to HL diet developed obesity, but not showed high blood pressure and autonomic dysfunction. In addition, HL animals had increased CCL5 mRNA in hypothalamus, CD86 mRNA in brainstem and micróglia density in caudal NTS. The results suggest new mechanisms for hypertension and autonomic dysfunction secondary to intake of high-fat diet by showing CART role in DMH and the involvement of the inflammatory pathway TLR-NF&#954;B in neurons and glia.

Dieta hiperlipídica

fator nuclear kappa B (NF&#954;B)

Grupo de diferenciação 86 (CD86)

Hipertensão arterial

Hipotálamo

Inflamação

Microglia

Obesidade

Receptor Toll-like

Sistema nervoso autônomo

Sistema nervoso simpático

Tronco encefálico

Autonomic nervous system

Brainstem

Cluster of differentiation 86 (CD86)

High-fat diet

Hypothalamus

Inflammation

Microglia

Neurogenic hypertension

Obesity

Toll-like receptor

Points quantiques : caractérisation et applications en sciences pharmaceutiques

Moquin, Alexandre

03 1900

L’imagerie médicale a longtemps été limitée à cause des performances médiocres des fluorophores organiques. Récemment la recherche sur les nanocristaux semi-conducteurs a grandement contribué à l’élargissement de la gamme d’applications de la luminescence dans les domaines de l’imagerie et du diagnostic. Les points quantiques (QDs) sont des nanocristaux de taille similaire aux protéines (2-10 nm) dont la longueur d’onde d’émission dépend de leur taille et de leur composition. Le fait que leur surface peut être fonctionnalisée facilement avec des biomolécules rend leur application particulièrement attrayante dans le milieu biologique. Des QDs de structure « coeur-coquille » ont été synthétisés selon nos besoins en longueur d’onde d’émission. Dans un premier article nous avons modifié la surface des QDs avec des petites molécules bi-fonctionnelles portant des groupes amines, carboxyles ou zwitterions. L’effet de la charge a été analysé sur le mode d’entrée des QDs dans deux types cellulaires. À l’aide d’inhibiteurs pharmacologiques spécifiques à certains modes d’internalisation, nous avons déterminé le mode d’internalisation prédominant. L’endocytose par les radeaux lipidiques représente le mode d’entrée le plus employé pour ces QDs de tailles similaires. D’autres modes participent également, mais à des degrés moindres. Des disparités dans les modes d’entrée ont été observées selon le ligand de surface. Nous avons ensuite analysé l’effet de l’agglomération de différents QDs sur leur internalisation dans des cellules microgliales. La caractérisation des agglomérats dans le milieu de culture cellulaire a été faite par la technique de fractionnement par couplage flux-force (AF4) associé à un détecteur de diffusion de la lumière. En fonction du ligand de surface et de la présence ou non de protéines du sérum, chacun des types de QDs se sont agglomérés de façon différente. À l'aide d’inhibiteur des modes d’internalisation, nous avons corrélé les données de tailles d’agglomérats avec leur mode d’entrée cellulaire. Les cellules microgliales sont les cellules immunitaires du système nerveux central (CNS). Elles répondent aux blessures ou à la présence d’inflammagènes en relâchant des cytokines pro-inflammatoires. Une inflammation non contrôlée du CNS peut conduire à la neurodégénérescence neuronale et est souvent observée dans les cas de maladies chroniques. Nous nous sommes intéressés au développement d’un nanosenseur pour mesurer des biomarqueurs du début de l’inflammation. Les méthodes classiques pour étudier l’inflammation consistent à mesurer le niveau de protéines ou molécules relâchées par les cellules stressées (par exemple monoxyde d’azote, IL-1β). Bien que précises, ces méthodes ne mesurent qu’indirectement l’activité de la caspase-1, responsable de la libération du l’IL-1β. De plus ces méthode ne peuvent pas être utilisées avec des cellules vivantes. Nous avons construit un nanosenseur basé sur le FRET entre un QD et un fluorophore organique reliés entre eux par un peptide qui est spécifiquement clivé par la caspase-1. Pour induire l’inflammation, nous avons utilisé des molécules de lipopolysaccharides (LPS). La molécule de LPS est amphiphile. Dans l’eau le LPS forme des nanoparticules, avec des régions hydrophobes à l’intérieure. Nous avons incorporé des QDs dans ces régions ce qui nous a permis de suivre le cheminement du LPS dans les cellules microgliales. Les LPS-QDs sont internalisés spécifiquement par les récepteurs TLR-4 à la surface des microglies. Le nanosenseur s’est montré fonctionnel dans la détermination de l’activité de la caspase-1 dans cellules microgliales activées par le LPS. Éventuellement, le senseur permettrait d’observer en temps réel l’effet de thérapies ciblant l’inflammation, sur l’activité de la caspase-1. / Medical imaging based on fluorescence has suffered from the poor photostability and mediocre performance of organic fluorophores. The discovery and subsequent improvements in nanocrystal synthesis and functionalization has greatly benefited the applications in medical imaging and the development of nanocrystal-based sensors for diagnostics. QDs are semi-conductor nanocrystals which have similar sizes as proteins (2-10 nm). They are highly luminescent, and can be made to emit at any desired wavelength by varying their size and composition. The surface of QDs can be easily functionalized with biomolecules. Hence, it is interesting to study how QDs interact in the biological world. Highly luminescent core-shell QDs emitting at different wavelengths were prepared according to our needs. In a first study, the surface of the QDs was modified with various small bi-functional thiolated ligands (carboxylated, aminated and zwitterionic). The modified-QDs of nearly identical sizes were administered in vitro to study the impact of surface charge and cell type on the mode and extent of cell uptake and elimination. Using specific inhibitors of cell uptake we determined which modes contributed to the internalization of the QDs. Endocytosis mediated by lipid rafts represented the predominant pathway for the internalization of QDs. However, other modes contributed to a lesser degree, depending on the surface ligand. We then analyzed the effect of QD agglomeration in cell culture media on its cellular uptake by microglia. Thorough characterization of QD agglomerate size distribution was conducted by asymmetrical flow field-flow fractionation (AF4) with a dynamic light scattering detector. Depending on the type of surface ligand and if serum proteins were present, the agglomeration pattern of the QDs was significantly different. With inhibitors of specific modes of cell uptake, we showed that the size distribution data, obtained by AF4, correlated with the modes of cell uptake. Microglia cells are immune cells of the central nervous system (CNS). They respond to injury or the presence of inflammagens by producing pro-inflammatory cytokine. Inflammation in the CNS may lead to loss of neurons, and can found in many chronic diseases. We were interested in building nanosensors to measure the onset of inflammation. Current methods to study inflammation consist in measuring levels of certain proteins or chemicals released by stressed cell (e.g. Western blot or ELISA assay for IL-1β). Although precise, these methods measure indirectly the activity of the enzyme responsible for releasing IL-1β, i.e. caspase-1. Moreover, these methods cannot be applied to live cells. We designed a sensor based on FRET between a QD and a dye linked by a peptide specifically cleaved by the caspase-1. To induce inflammation, we applied lipopolysaccharides (LPS), which are endotoxins present in Gram negative bacteria responsible for sceptic shock. The LPS form nanoparticles due to their amphiphilicity. The interior hydrophobic regions were used to load hydrophobic QDs, making the LPS luminescent. The microglia internalized LPS-QD predominantly through TLR-4 membrane receptors. We describe how the LPS induce inflammation and demonstrated the functionality of the QD-based sensor. Eventually, the sensor could be used to monitor in real time the action of therapeutics against inflammation.

points quantiques (QDs)

internalisation cellulaire

localisation intracellulaire

fractionnement par couplage flux-force

distribution de taille

milieu de culture cellulaire

sérum

microglies

phagocytose

nanosenseur

quantum dot

QD cell internalization

sub-cellular localization

size distribution

cell culture media

serum

microglia

phagocytosis

nanosensor

Strategies for revascularizing the ischemic retina

Sitaras, Nicholas

07 1900

Les rétinopathies ischémiques (RI) sont la cause majeure de cécité chez les personnes âgées de moins de 65 ans. Il existe deux types de RIs soit la rétinopathie du prématuré (ROP) ainsi que la rétinopathie diabétique (RD). Les RIs sont décrites en deux phases soit la phase de vasooblitération, marquée par une perte importante de vaisseaux sanguins, et une phase de néovascularisation secondaire à lʼischémie menant à une croissance pathologique de vaisseaux. Cette seconde phase peut générer des complications cliniques telles quʼun oedème dans lʼhumeur vitré ainsi que le détachement de la rétine chez les patients déjà atteints dʼune RI. Les traitements approuvés pour les RIs visent à réduire la formation des vaisseaux pathologiques ou lʼoedème; mais ceux-ci malheureusement ne règlent pas les problèmes sous-jacents tels que la perte vasculaire et lʼischémie. La rétine est un tissu hautement vascularisé qui contribue à lʼirrigation et à lʼhoméostasie des neurones. Lʼinteraction neurovasculaire, comprenant de neurones, vaisseaux et cellules gliales, contribue au maintien de cette homéostasie. Durant le développement, les neurones et les cellules gliales jouent un rôle important dans la vascularisation de la rétine en sécrétant des facteurs qui stimulent l'angiogenèse. Cependant, nos connaissances sur lʼinteraction neurovasculaire dans les RIs sont limitées. En identifiant les interactions importantes entre les cellules composant cette unité neurovasculaire dans la rétine, nous pourrons viser des cibles qui engendreront une revascularisation seine afin de diminuer les signes pathologiques chez les patients atteints dʼune RI. Les travaux présentés dans cette thèse visent à mieux expliquer cette interaction neurovasculaire en soulignant des concepts importants propres aux RIs. En utilisant un modèle de rétinopathie induite par lʼoxygène chez la souris, qui reproduit les caractéristiques importantes de la ROP (et en certaines instances, la RD), nous identifions quelques molécules clés jouant un rôle significatif dans les RIs soit la sémaphorine 3A (sema3A), lʼIL-1β, ainsi que le récepteur PAR2. Nos résultats démontrent que Sema3A, sécrétée par les cellules ganglionnaires rétiniennes (CGRs) durant une ischémie, empêche la revascularisation normale et que cette expression est induite par lʼIL-1β provenant des microglies activées. En bloquant Sema3A directement ou via lʼinhibition de lʼIL- 1β, nous remarquons une revascularisation seine ainsi quʼune diminution importante des vaisseaux pathologiques. Cela nous indique que Sema3A est impliquée dans la guidance vasculaire et quʼelle contribue à la pathogenèse des RIs. Lʼactivation de façon exogène de PAR2, identifié aussi comme régulateur du récepteur de lʼIL-1β (IL- 1RI) sur les CGRs, se traduit par une diminution séquentielle de lʼIL-1RI et de Sema3A ce qui mène également à une revascularisation seine. En conclusion, ces travaux soulignent lʼimportance de lʼinteraction neurovasculaire ainsi que la guidance vasculaire dans les RIs. Ils renforcent lʼimportance de la communication entre neurone, vaisseau et microglie dans la pathogenèse des RIs. Finalement, nous identifions quelques molécules clés qui pourront servir comme cibles afin de lutter contre lʼischémie qui cause des problèmes vasculaires chez les patients atteints dʼune RI. / Ischemic retinopathies (IRs), namely, retinopathy of prematurity (ROP) and diabetic retinopathy (DR), are the major cause of blindness in persons under the age of 65. IRs are biphasic disorders described by an initial vasoobliterative phase marked by a persistent microvascular degeneration, which leads to ischemia. Retinal ischemia, secondary to vessel loss, incites a second neovascularization phase represented by an aberrant, misdirected neovessel formation into the vitreous, which can cause adverse clinical complications including vitreous hemorrhaging and tractional retinal detachment. While current treatments aim at reducing vitreous/retinal hemorrhaging and/or pathological pre-retinal neovascularization, these regimens fail to address the underlying problem; that is, microvascular decay and retinal ischemia. The retina is a highly metabolic tissue that requires a significant amount of nutrients and oxygen. This is supplied by an intricate and highly regulated vascular network required to maintain homeostasis and proper function. The intricate cellular interactions in the neurovascular unit – the consortium of vessel, neurons and support glia – are required for regulating and maintaining homeostasis under normal conditions. However, the understanding of how this unit functions under ischemic stress, that which is seen in patients suffering from IRs, is not well defined. The present work underlines several important concepts of neurovascular coupling in IRs in efforts to identify potential therapeutic agents that may help curb retinal ischemia by stimulating normal revascularization. Using a mouse model of oxygen-induced retinopathy (OIR), which reproduces the salient features of ROP (and in some instances DR), we identified key players involved in generating the pathophysiological signatures associated with IRs; namely, semaphorin3A (Sema3A), interleukin-1β (IL-1β) and protease-activated receptor 2 (PAR2). Our results show that neuronal-derived Sema3A, secreted by ischemic retinal ganglion cells (RGCs), acts as a potent vaso-repulsive molecules that impedes normal revascularization. Activated microglia contribute to this process by secreting IL-1β, which induces paracrine release of Sema3A expression contributing to microvascular decay as well as pathological pre-retinal neovascularization. Inhibition of Sema3A or IL-1β translates to rapid revascularization and, as a result, a significant reduction in pathological neovessel formation. These results demonstrate that Sema3A is directly involved in vascular guidance and precipitates the pathophysiological features associated with IRs. PAR2, found on RGCs, was also identified as a key regulatory mechanism involved in dampening IL-1β induced Sema3A mediated vascular decay by reducing IL-1 receptor (IL-1RI). Exogenous activation of neuronal PAR2 translates to a sequential reduction of both IL-1RI and Sema3A resulting in accelerated revascularization and consequentially pre-retinal neovascularization. In conclusion, these studies highlight the importance of neurovascular coupling associated with IRs. Herein, we demonstrate the consorted interaction between neuron, vessel and glia and its impact on shaping the retinal vasculature during disease. Moreover, we underscore the significant impact of neuronal guidance cues in manifesting the salient vascular features of IRs. Finally, we identify key players that may serve as potential therapeutic avenues in curbing retinal ischemia in efforts to reduce vascular complications associated with IRs.

sémaphorin 3A

récepteur activé par protéase 2

vaisseaux

cellules ganglionnaires rétiniennes

microglies

vasooblitération

néovascularisation

revascularisation

rétinopathies ischémiques

Semaphorin 3A

Interleukin-1B

Protease-activated receptor 2

Vessels

Retinal ganglion cells

Microglia

Vaso-obliteration

Neovascularization

Revascularization

Ischemic retinopathies