Your search keyword '"melanopsin retinal ganglion cells"' showing total 20 results

1. Chromatic pupillometry for evaluating melanopsin retinal ganglion cell function in Alzheimer's disease and other neurodegenerative disorders: a review.

Author

Romagnoli, Martina, Amore, Giulia, Avanzini, Pietro, Carelli, Valerio, and La Morgia, Chiara

Subjects

RAPID eye movement sleep, RETINAL ganglion cells, ALZHEIMER'S disease, PUPILLOMETRY, NEURODEGENERATION, MELANOPSIN

Abstract

The evaluation of pupillary light reflex (PLR) by chromatic pupillometry may provide a unique insight into specific photoreceptor functions. Chromatic pupillometry refers to evaluating PLR to different wavelengths and intensities of light in order to differentiate outer/inner retinal photoreceptor contributions to the PLR. Different protocols have been tested and are now established to assess in-vivo PLR contribution mediated by melanopsin retinal ganglion cells (mRGCs). These intrinsically photosensitive photoreceptors modulate the non-image-forming functions of the eye, which are mainly the circadian photoentrainment and PLR, via projections to the hypothalamic suprachiasmatic and olivary pretectal nucleus, respectively. In this context, chromatic pupillometry has been used as an alternative and non-invasive tool to evaluate the mRGC system in several clinical settings, including hereditary optic neuropathies, glaucoma, and neurodegenerative disorders such as Parkinson's disease (PD), idiopathic/isolated rapid eye movement sleep behavior disorder (iRBD), and Alzheimer's disease (AD). The purpose of this article is to review the key steps of chromatic pupillometry protocols for studying in-vivo mRGC-system functionality and provide the main findings of this technique in the research setting on neurodegeneration. mRGC-dependent pupillary responses are short-wavelength sensitive, have a higher threshold of activation, and are much slower and sustained compared with rod- and cone-mediated responses, driving the tonic component of the PLR during exposure to high-irradiance and continuous light stimulus. Thus, mRGCs contribute mainly to the tonic component of the post-illumination pupil response (PIPR) to bright blue light flash that persists after light stimulation is switched off. Given the role of mRGCs in circadian photoentrainment, the use of chromatic pupillometry to perform a functional evaluation of mRGcs may be proposed as an early biomarker of mRGC-dysfunction in neurodegenerative disorders characterized by circadian and/or sleep dysfunction such as AD, PD, and its prodromal phase iRBD. The evaluation by chromatic pupillometry of mRGC-system functionality may lay the groundwork for a new, easily accessible biomarker that can be exploited also as the starting point for future longitudinal cohort studies aimed at stratifying the risk of conversion in these disorders. [ABSTRACT FROM AUTHOR]

Published

2024

2. Melanopsin Retinal Ganglion Cells

Author

Lucas, Robert, Kuehni, Rolf, Section editor, and Shamey, Renzo, editor

Published

2023

3. Chromatic pupillometry for evaluating melanopsin retinal ganglion cell function in Alzheimer’s disease and other neurodegenerative disorders: a review

Author

Martina Romagnoli, Giulia Amore, Pietro Avanzini, Valerio Carelli, and Chiara La Morgia

Subjects

chromatic pupillometry, melanopsin retinal ganglion cells, Alzheimer’s disease, pupil, post-illumination pupil response, neurodegeneration, Psychology, BF1-990

Abstract

The evaluation of pupillary light reflex (PLR) by chromatic pupillometry may provide a unique insight into specific photoreceptor functions. Chromatic pupillometry refers to evaluating PLR to different wavelengths and intensities of light in order to differentiate outer/inner retinal photoreceptor contributions to the PLR. Different protocols have been tested and are now established to assess in-vivo PLR contribution mediated by melanopsin retinal ganglion cells (mRGCs). These intrinsically photosensitive photoreceptors modulate the non-image-forming functions of the eye, which are mainly the circadian photoentrainment and PLR, via projections to the hypothalamic suprachiasmatic and olivary pretectal nucleus, respectively. In this context, chromatic pupillometry has been used as an alternative and non-invasive tool to evaluate the mRGC system in several clinical settings, including hereditary optic neuropathies, glaucoma, and neurodegenerative disorders such as Parkinson’s disease (PD), idiopathic/isolated rapid eye movement sleep behavior disorder (iRBD), and Alzheimer’s disease (AD). The purpose of this article is to review the key steps of chromatic pupillometry protocols for studying in-vivo mRGC-system functionality and provide the main findings of this technique in the research setting on neurodegeneration. mRGC-dependent pupillary responses are short-wavelength sensitive, have a higher threshold of activation, and are much slower and sustained compared with rod- and cone-mediated responses, driving the tonic component of the PLR during exposure to high-irradiance and continuous light stimulus. Thus, mRGCs contribute mainly to the tonic component of the post-illumination pupil response (PIPR) to bright blue light flash that persists after light stimulation is switched off. Given the role of mRGCs in circadian photoentrainment, the use of chromatic pupillometry to perform a functional evaluation of mRGcs may be proposed as an early biomarker of mRGC-dysfunction in neurodegenerative disorders characterized by circadian and/or sleep dysfunction such as AD, PD, and its prodromal phase iRBD. The evaluation by chromatic pupillometry of mRGC-system functionality may lay the groundwork for a new, easily accessible biomarker that can be exploited also as the starting point for future longitudinal cohort studies aimed at stratifying the risk of conversion in these disorders.

Published

2024

4. Chromatic Pupillometry Findings in Alzheimers Disease.

Author

Romagnoli, Martina, Stanzani Maserati, Michelangelo, De Matteis, Maddalena, Capellari, Sabina, Carbonelli, Michele, Amore, Giulia, Cantalupo, Gaetano, Zenesini, Corrado, Liguori, Rocco, Sadun, Alfredo, Carelli, Valerio, Park, Jason, and La Morgia, Chiara

Subjects

Alzheimer’s disease, chromatic pupillometry, melanopsin retinal ganglion cells, post-illumination pupil response, pupil, pupillary light reflex

Abstract

Intrinsically photosensitive melanopsin retinal ganglion cells (mRGCs) are crucial for non-image forming functions of the eye, including the photoentrainment of circadian rhythms and the regulation of the pupillary light reflex (PLR). Chromatic pupillometry, using light stimuli at different wavelengths, makes possible the isolation of the contribution of rods, cones, and mRGCs to the PLR. In particular, post-illumination pupil response (PIPR) is the most reliable pupil metric of mRGC function. We have previously described, in post-mortem investigations of AD retinas, a loss of mRGCs, and in the remaining mRGCs, we demonstrated extensive morphological abnormalities. We noted dendrite varicosities, patchy distribution of melanopsin, and reduced dendrite arborization. In this study, we evaluated, with chromatic pupillometry, the PLR in a cohort of mild-moderate AD patients compared to controls. AD and controls also underwent an extensive ophthalmological evaluation. In our AD cohort, PIPR did not significantly differ from controls, even though we observed a higher variability in the AD group and 5/26 showed PIPR values outside the 2 SD from the control mean values. Moreover, we found a significant difference between AD and controls in terms of rod-mediated transient PLR amplitude. These results suggest that in the early stage of AD there are PLR abnormalities that may reflect a pathology affecting mRGC dendrites before involving the mRGC cell body. Further studies, including AD cases with more severe and longer disease duration, are needed to further explore this hypothesis.

Published

2020

5. Chromatic Pupillometry Findings in Alzheimer’s Disease

Author

Martina Romagnoli, Michelangelo Stanzani Maserati, Maddalena De Matteis, Sabina Capellari, Michele Carbonelli, Giulia Amore, Gaetano Cantalupo, Corrado Zenesini, Rocco Liguori, Alfredo A. Sadun, Valerio Carelli, Jason C. Park, and Chiara La Morgia

Subjects

chromatic pupillometry, Alzheimer’s disease, melanopsin retinal ganglion cells, pupillary light reflex, post-illumination pupil response, pupil, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Intrinsically photosensitive melanopsin retinal ganglion cells (mRGCs) are crucial for non-image forming functions of the eye, including the photoentrainment of circadian rhythms and the regulation of the pupillary light reflex (PLR). Chromatic pupillometry, using light stimuli at different wavelengths, makes possible the isolation of the contribution of rods, cones, and mRGCs to the PLR. In particular, post-illumination pupil response (PIPR) is the most reliable pupil metric of mRGC function. We have previously described, in post-mortem investigations of AD retinas, a loss of mRGCs, and in the remaining mRGCs, we demonstrated extensive morphological abnormalities. We noted dendrite varicosities, patchy distribution of melanopsin, and reduced dendrite arborization. In this study, we evaluated, with chromatic pupillometry, the PLR in a cohort of mild-moderate AD patients compared to controls. AD and controls also underwent an extensive ophthalmological evaluation. In our AD cohort, PIPR did not significantly differ from controls, even though we observed a higher variability in the AD group and 5/26 showed PIPR values outside the 2 SD from the control mean values. Moreover, we found a significant difference between AD and controls in terms of rod-mediated transient PLR amplitude. These results suggest that in the early stage of AD there are PLR abnormalities that may reflect a pathology affecting mRGC dendrites before involving the mRGC cell body. Further studies, including AD cases with more severe and longer disease duration, are needed to further explore this hypothesis.

Published

2020

6. Melanopsin Retinal Ganglion Cells and Pupil: Clinical Implications for Neuro-Ophthalmology

Author

Chiara La Morgia, Valerio Carelli, and Michele Carbonelli

Subjects

melanopsin retinal ganglion cells, light, pupil, neurodegeneration, optic nerve, optic neuropathies, Neurology. Diseases of the nervous system, RC346-429

Abstract

Melanopsin retinal ganglion cells (mRGCs) are intrinsically photosensitive RGCs that mediate many relevant non-image forming functions of the eye, including the pupillary light reflex, through the projections to the olivary pretectal nucleus. In particular, the post-illumination pupil response (PIPR), as evaluated by chromatic pupillometry, can be used as a reliable marker of mRGC function in vivo. In the last years, pupillometry has become a promising tool to assess mRGC dysfunction in various neurological and neuro-ophthalmological conditions. In this review we will present the most relevant findings of pupillometric studies in glaucoma, hereditary optic neuropathies, ischemic optic neuropathies, idiopathic intracranial hypertension, multiple sclerosis, Parkinson's disease, and mood disorders. The use of PIPR as a marker for mRGC function is also proposed for other neurodegenerative disorders in which circadian dysfunction is documented.

Published

2018

7. Melanopsin Retinal Ganglion Cells

Author

Lucas, Robert and Luo, Ming Ronnier, editor

Published

2016

8. Shared and Differential Retinal Responses against Optic Nerve Injury and Ocular Hypertension

Author

Manuel Vidal-Sanz, Caridad Galindo-Romero, Francisco J. Valiente-Soriano, Francisco M. Nadal-Nicolás, Arturo Ortin-Martinez, Giuseppe Rovere, Manuel Salinas-Navarro, Fernando Lucas-Ruiz, Maria C. Sanchez-Migallon, Paloma Sobrado-Calvo, Marcelino Aviles-Trigueros, María P. Villegas-Pérez, and Marta Agudo-Barriuso

Subjects

glaucoma, chronic ocular hypertension, acute ocular hypertension, axotomy, Brn3a retinal ganglion cells, melanopsin retinal ganglion cells, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Glaucoma, one of the leading causes of blindness worldwide, affects primarily retinal ganglion cells (RGCs) and their axons. The pathophysiology of glaucoma is not fully understood, but it is currently believed that damage to RGC axons at the optic nerve head plays a major role. Rodent models to study glaucoma include those that mimic either ocular hypertension or optic nerve injury. Here we review the anatomical loss of the general population of RGCs (that express Brn3a; Brn3a+RGCs) and of the intrinsically photosensitive RGCs (that express melanopsin; m+RGCs) after chronic (LP-OHT) or acute (A-OHT) ocular hypertension and after complete intraorbital optic nerve transection (ONT) or crush (ONC). Our studies show that all of these insults trigger RGC death. Compared to Brn3a+RGCs, m+RGCs are more resilient to ONT, ONC, and A-OHT but not to LP-OHT. There are differences in the course of RGC loss both between these RGC types and among injuries. An important difference between the damage caused by ocular hypertension or optic nerve injury appears in the outer retina. Both axotomy and LP-OHT induce selective loss of RGCs but LP-OHT also induces a protracted loss of cone photoreceptors. This review outlines our current understanding of the anatomical changes occurring in rodent models of glaucoma and discusses the advantages of each one and their translational value.

Published

2017

9. Shared and Differential Retinal Responses against Optic Nerve Injury and Ocular Hypertension.

Author

Vidal-Sanz, Manuel, Galindo-Romero, Caridad, Valiente-Soriano, Francisco J., Nadal-Nicolás, Francisco M., Ortin-Martinez, Arturo, Rovere, Giuseppe, Salinas-Navarro, Manuel, Lucas-Ruiz, Fernando, Sanchez-Migallon, Maria C., Sobrado-Calvo, Paloma, Aviles-Trigueros, Marcelino, Villegas-Pérez, María P., and Agudo-Barriuso, Marta

Subjects

OPTIC nerve injuries, OCULAR hypertension, GLAUCOMA

Abstract

Glaucoma, one of the leading causes of blindness worldwide, affects primarily retinal ganglion cells (RGCs) and their axons. The pathophysiology of glaucoma is not fully understood, but it is currently believed that damage to RGC axons at the optic nerve head plays a major role. Rodent models to study glaucoma include those that mimic either ocular hypertension or optic nerve injury. Here we review the anatomical loss of the general population of RGCs (that express Brn3a; Brn3a+RGCs) and of the intrinsically photosensitive RGCs (that express melanopsin; m+RGCs) after chronic (LP-OHT) or acute (A-OHT) ocular hypertension and after complete intraorbital optic nerve transection (ONT) or crush (ONC). Our studies show that all of these insults trigger RGC death. Compared to Brn3a+RGCs, m+RGCs are more resilient to ONT, ONC, and A-OHT but not to LP-OHT. There are differences in the course of RGC loss both between these RGC types and among injuries. An important difference between the damage caused by ocular hypertension or optic nerve injury appears in the outer retina. Both axotomy and LP-OHT induce selective loss of RGCs but LP-OHT also induces a protracted loss of cone photoreceptors. This review outlines our current understanding of the anatomical changes occurring in rodent models of glaucoma and discusses the advantages of each one and their translational value. [ABSTRACT FROM AUTHOR]

Published

2017

10. Distribution of melanopsin positive neurons in pigmented and albino mice: Evidence for melanopsin interneurons in the mouse retina

Author

Francisco Javier Valiente-Soriano, Diego eGarcía-Ayuso, Arturo eOrtín-Martínez, Manuel eJiménez-López, Caridad eGalindo-Romero, María Paz Villegas-Pérez, Marta eAgudo-Barriuso, Anthony Alexander Vugler, and Manuel eVidal-Sanz

Subjects

interneuron, spatial distribution, Brn3a, melanopsin retinal ganglion cells, retinal topography, ciliary marginal zone, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571, Human anatomy, QM1-695

Abstract

Here we have studied the population of intrinsically photosensitive retinal ganglion cells (ipRGCs) in adult pigmented and albino mice. Our data show that although pigmented (C57Bl/6) and albino (Swiss) mice have a similar total number of ipRGCs, their distribution is slightly different: while in pigmented mice ipRGCs are more abundant in the temporal retina, in albinos the ipRGCs are more abundant in superior retina. In both strains, ipRGCs are located in the retinal periphery, in the areas of lower Brn3a+RGC density. Both strains also contain displaced ipRGCs (d-ipRGCs) in the inner nuclear layer that account for 14% of total ipRGCs in pigmented mice and 5% in albinos. Tracing from both superior colliculli shows that 98% (pigmented) and 97% (albino) of the total ipRGCs, become retrogradely labelled, while double immunodetection of melanopsin and Brn3a confirm that few ipRGCs express this transcription factor in mice. Rather surprisingly, application of a retrograde tracer to the optic nerve labels all ipRGCs, except for a sub-population of the d-ipRGCs (14% in pigmented and 28% in albino, respectively) and melanopsin positive cells residing in the ciliary marginal zone (CMZ) of the retina. In the CMZ, between 20% (pigmented) and 24% (albino) of the melanopsin positive cells are unlabelled by the tracer and we suggest that this may be because they fail to send an axon into the optic nerve. As such, this study provides the first evidence for a population of melanopsin interneurons in the mammalian retina.

Published

2014

11. Distribution of melanopsin positive neurons in pigmented and albino mice: evidence for melanopsin interneurons in the mouse retina.

Author

Valiente-Soriano, Francisco J., García-Ayuso, Diego, Ortín-Martínez, Arturo, Jiménez-López, Manuel, Galindo-Romero, Caridad, Villegas-Pérez, Maria Paz, Agudo-Barriuso, Marta, Vugler, Anthony A., and Vidal-Sanz, Manuel

Subjects

MELANOPSIN, INTERNEURONS, RETINAL ganglion cells, LABORATORY mice, HOMEOBOX proteins

Abstract

Here we have studied the population of intrinsically photosensitive retinal ganglion cells (ipRGCs) in adult pigmented and albino mice. Our data show that although pigmented (C57Bl/6) and albino (Swiss) mice have a similar total number of ipRGCs, their distribution is slightly different: while in pigmented mice ipRGCs are more abundant in the temporal retina, in albinos the ipRGCs are more abundant in superior retina. In both strains, ipRGCs are located in the retinal periphery, in the areas of lower Brn3a+RGC density. Both strains also contain displaced ipRGCs (d-ipRGCs) in the inner nuclear layer (INL) that account for 14% of total ipRGCs in pigmented mice and 5% in albinos. Tracing from both superior colliculli shows that 98% (pigmented) and 97% (albino) of the total ipRGCs, become retrogradely labeled, while double immunodetection of melanopsin and Brn3a confirms that few ipRGCs express this transcription factor in mice. Rather surprisingly, application of a retrograde tracer to the optic nerve (ON) labels all ipRGCs, except for a sub-population of the d-ipRGCs (14% in pigmented and 28% in albino, respectively) and melanopsin positive cells residing in the ciliary marginal zone (CMZ) of the retina. In the CMZ, between 20% (pigmented) and 24% (albino) of the melanopsin positive cells are unlabeled by the tracer and we suggest that this may be because they fail to send an axon into the ON. As such, this study provides the first evidence for a population of melanopsin interneurons in the mammalian retina. [ABSTRACT FROM AUTHOR]

Published

2014

12. Cellular alterations of the human retina in Parkinson’s disease and their use as early biomarkers

Author

Cuenca, Nicolás, Lax, Pedro, Universidad de Alicante. Departamento de Fisiología, Genética y Microbiología, Ortuño-Lizarán, Isabel, Cuenca, Nicolás, Lax, Pedro, Universidad de Alicante. Departamento de Fisiología, Genética y Microbiología, and Ortuño-Lizarán, Isabel

Abstract

En la presente Tesis Doctoral se describen los cambios celulares que ocurren en la retina en la enfermedad de Parkinson y su posible uso como biomarcadores tempranos de la enfermedad. Los pacientes con enfermedad de Parkinson poseen acumulaciones de alfa sinucleína fosforilada en la retina similares a las que se encuentran en el cerebro de los mismos pacientes. De hecho, la cantidad de alfa-sinucleína fosforilada en la retina correlaciona con la cantidad de alfa-sinucleína fosforilada en el cerebro, con el estadio de progresión de la enfermedad y con la severidad de los síntomas motores. Además, en la retina de enfermos de párkinson se describe una degeneración de las células ganglionares melanopsínicas de la retina, lo que podría explicar las alteraciones en los ritmos circadianos y los desórdenes del sueño que aparecen en pacientes. Finalmente, también se muestra la degeneración de las células amacrinas dopaminérgicas, que se reducen en un 45%. Este fallo en el sistema dopaminérgico de la retina provoca alteraciones morfológicas en las células amacrinas AII, sus principales postsinápticas, y podría explicar algunas alteraciones visuales descritas en la enfermedad como la disminución de la sensibilidad al contraste o de la agudeza visual. En global, los resultados muestran que la retina reproduce los procesos degenerativos que ocurren en el cerebro en la enfermedad de Parkinson y, por tanto, que es un tejido idóneo para el estudio de la enfermedad. Además, el estudio de la retina aporta información sobre el estadio de la enfermedad y puede ser empleado como un biomarcador temprano que ayude al diagnóstico y seguimiento de la misma.

Published

2019

13. Cellular alterations of the human retina in Parkinson’s disease and their use as early biomarkers

Author

Ortuño-Lizarán, Isabel, Cuenca, Nicolás, Lax, Pedro, and Universidad de Alicante. Departamento de Fisiología, Genética y Microbiología

Subjects

Alpha-synuclein, Parkinson’s disease, Biología Celular, Melanopsin retinal ganglion cells, Retina, Human, Dopaminergic amacrine cells

Abstract

En la presente Tesis Doctoral se describen los cambios celulares que ocurren en la retina en la enfermedad de Parkinson y su posible uso como biomarcadores tempranos de la enfermedad. Los pacientes con enfermedad de Parkinson poseen acumulaciones de alfa sinucleína fosforilada en la retina similares a las que se encuentran en el cerebro de los mismos pacientes. De hecho, la cantidad de alfa-sinucleína fosforilada en la retina correlaciona con la cantidad de alfa-sinucleína fosforilada en el cerebro, con el estadio de progresión de la enfermedad y con la severidad de los síntomas motores. Además, en la retina de enfermos de párkinson se describe una degeneración de las células ganglionares melanopsínicas de la retina, lo que podría explicar las alteraciones en los ritmos circadianos y los desórdenes del sueño que aparecen en pacientes. Finalmente, también se muestra la degeneración de las células amacrinas dopaminérgicas, que se reducen en un 45%. Este fallo en el sistema dopaminérgico de la retina provoca alteraciones morfológicas en las células amacrinas AII, sus principales postsinápticas, y podría explicar algunas alteraciones visuales descritas en la enfermedad como la disminución de la sensibilidad al contraste o de la agudeza visual. En global, los resultados muestran que la retina reproduce los procesos degenerativos que ocurren en el cerebro en la enfermedad de Parkinson y, por tanto, que es un tejido idóneo para el estudio de la enfermedad. Además, el estudio de la retina aporta información sobre el estadio de la enfermedad y puede ser empleado como un biomarcador temprano que ayude al diagnóstico y seguimiento de la misma.

Published

2019

14. Photosensitive ganglion cells: A diminutive, yet essential population.

Author

Vidal-Villegas B, Gallego-Ortega A, Miralles de Imperial-Ollero JA, Martínez de la Casa JM, García Feijoo J, and Vidal-Sanz M

Subjects

Circadian Rhythm, Retinal Rod Photoreceptor Cells, Vision, Ocular, Retinal Cone Photoreceptor Cells, Retinal Ganglion Cells

Abstract

Our visual system has evolved to provide us with an image of the scene that surrounds us, informing us of its texture, colour, movement, and depth with an enormous spatial and temporal resolution, and for this purpose, the image formation (IF) dedicates the vast majority of our retinal ganglion cell (RGC) population and much of our cerebral cortex. On the other hand, a minuscule proportion of RGCs, in addition to receiving information from classic cone and rod photoreceptors, express melanopsin and are intrinsically photosensitive (ipRGC). These ipRGC are dedicated to non-image-forming (NIF) visual functions, of which we are unaware, but which are essential for aspects related to our daily physiology, such as the timing of our circadian rhythms and our pupillary light reflex, among many others. Before the discovery of ipRGCs, it was thought that the IF and NIF functions were distinct compartments regulated by different RGCs, but this concept has evolved in recent years with the discovery of new types of ipRGCs that innervate subcortical IF regions, and therefore have IF visual functions. Six different types of ipRGCs are currently known. These are termed M1-M6, and differ in their morphological, functional, molecular properties, central projections, and visual behaviour responsibilities. A review is presented on the melanopsin visual system, the most active field of research in vision, for which knowledge has grown exponentially during the last two decades, when RGCs giving rise to this pathway were first discovered., (Copyright © 2020 Sociedad Española de Oftalmología. Published by Elsevier España, S.L.U. All rights reserved.)

Published

2021

15. Shared and Differential Retinal Responses against Optic Nerve Injury and Ocular Hypertension

Author

María Paz Villegas-Pérez, Fernando Lucas-Ruiz, Giuseppe Rovere, Caridad Galindo-Romero, Arturo Ortín-Martínez, Francisco M. Nadal-Nicolás, Paloma Sobrado-Calvo, Marcelino Avilés-Trigueros, Manuel Vidal-Sanz, Francisco J. Valiente-Soriano, Manuel Salinas-Navarro, Marta Agudo-Barriuso, and M.C. Sánchez-Migallón

Subjects

Melanopsin, medicine.medical_specialty, genetic structures, medicine.medical_treatment, Population, Ocular hypertension, Glaucoma, Review, Retinal ganglion, lcsh:RC321-571, 03 medical and health sciences, 0302 clinical medicine, melanopsin retinal ganglion cells, Ophthalmology, medicine, education, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, chronic ocular hypertension, education.field_of_study, Retina, Brn3a retinal ganglion cells, business.industry, General Neuroscience, cone photoreceptors, retinal nerve fiber layer, medicine.disease, eye diseases, axotomy, medicine.anatomical_structure, glaucoma, 030221 ophthalmology & optometry, Optic nerve, sense organs, Axotomy, business, 030217 neurology & neurosurgery, Neuroscience, acute ocular hypertension

Abstract

Glaucoma, one of the leading causes of blindness worldwide, affects primarily retinal ganglion cells (RGCs) and their axons. The pathophysiology of glaucoma is not fully understood, but it is currently believed that damage to RGC axons at the optic nerve head plays a major role. Rodent models to study glaucoma include those that mimic either ocular hypertension or optic nerve injury. Here we review the anatomical loss of the general population of RGCs (that express Brn3a; Brn3a+RGCs) and of the intrinsically photosensitive RGCs (that express melanopsin; m+RGCs) after chronic (LP-OHT) or acute (A-OHT) ocular hypertension and after complete intraorbital optic nerve transection (ONT) or crush (ONC). Our studies show that all of these insults trigger RGC death. Compared to Brn3a+RGCs, m+RGCs are more resilient to ONT, ONC, and A-OHT but not to LP-OHT. There are differences in the course of RGC loss both between these RGC types and among injuries. An important difference between the damage caused by ocular hypertension or optic nerve injury appears in the outer retina. Both axotomy and LP-OHT induce selective loss of RGCs but LP-OHT also induces a protracted loss of cone photoreceptors. This review outlines our current understanding of the anatomical changes occurring in rodent models of glaucoma and discusses the advantages of each one and their translational value.

Published

2017

16. Adaptations of Cetacean Retinal Pigments to Aquatic Environments

Author

Phyllis R. Robinson and Jeffry I. Fasick

Subjects

0301 basic medicine, Melanopsin, Spectral power distribution, genetic structures, Color vision, visual pigment opsin, physiological, Ecology and Evolution, adaptation, Biology, cetaceans, 03 medical and health sciences, 0302 clinical medicine, Optics, melanopsin retinal ganglion cells, 14. Life underwater, aquatic organisms, Ecology, Evolution, Behavior and Systematics, Ecology, business.industry, eye diseases, Retinal pigments, Baleen, 030104 developmental biology, Spectral sensitivity, Aquatic environment, sense organs, business, 030217 neurology & neurosurgery, Photopic vision

Abstract

The underwater environment places unique constraints on the vision of cetaceans compared to their terrestrial mammalian counterparts. Water absorbs and filters light affecting both the intensity and spectral distribution of light available for vision. Therefore, the aquatic environment restricts the spectral distribution of photons and limits the distance at which objects may be observed. The cetacean eye possesses numerous anatomical, cellular and molecular adaptations to the underwater light environment that increase photon capture in a light-limited environment. These adaptations include a powerful spherical lens, a unique corneal design allowing for acute vision in both air and water, as well as a blue reflective optic tapetum. There are also molecular adaptations that influence the spectral sensitivity of both the rod and cone visual pigments. The spectral sensitivities of cetacean retinae have been a focus of attention over the last two decades. While most terrestrial mammals have dichromatic color vision based on two classes of cone photoreceptors, all cetaceans lack cone based color vision. For example, the Delphinidae (dolphins), Phocoenidae (porpoises), and some members of Ziphidae (beaked whales) possess single rod and cone photoreceptor classes. Recently, rod monochromats were identified in Ziphidae, Physeteroidea, and almost all of the mysticete (baleen) whales. The absorbance spectra of cetacean rod visual pigments are spectrally tuned to the available radiance spectra at foraging depths with an inverse relationship observed between the wavelength of maximum sensitivity of the rod pigment and depth. This also holds true for the spectral tuning of long-wavelength sensitive cone visual pigments in cetaceans. Cetacean melanopsins, the visual pigment expressed in a small subset of ganglion cells in mammalian retinae, have only just recently been examined in the cetacean rod monochromats. Genetic analyses coupled with molecular modeling predict that cetacean melanopsins possess nearly identical absorption spectra compared to their terrestrial mammalian counterparts. However, it appears that the melanopsins from the cetacean rod monochromats may possess a mechanism that inhibits relatively rapid deactivation of the light-activated melanopsin. This mechanism would result in prolonged pupil constriction resulting in a very useful mechanism in the prevention of photobleaching of rod pigments under photopic conditions.

Published

2016

17. Chromatic Pupillometry Findings in Alzheimer's Disease.

Author

Romagnoli M, Stanzani Maserati M, De Matteis M, Capellari S, Carbonelli M, Amore G, Cantalupo G, Zenesini C, Liguori R, Sadun AA, Carelli V, Park JC, and La Morgia C

Abstract

Intrinsically photosensitive melanopsin retinal ganglion cells (mRGCs) are crucial for non-image forming functions of the eye, including the photoentrainment of circadian rhythms and the regulation of the pupillary light reflex (PLR). Chromatic pupillometry, using light stimuli at different wavelengths, makes possible the isolation of the contribution of rods, cones, and mRGCs to the PLR. In particular, post-illumination pupil response (PIPR) is the most reliable pupil metric of mRGC function. We have previously described, in post-mortem investigations of AD retinas, a loss of mRGCs, and in the remaining mRGCs, we demonstrated extensive morphological abnormalities. We noted dendrite varicosities, patchy distribution of melanopsin, and reduced dendrite arborization. In this study, we evaluated, with chromatic pupillometry, the PLR in a cohort of mild-moderate AD patients compared to controls. AD and controls also underwent an extensive ophthalmological evaluation. In our AD cohort, PIPR did not significantly differ from controls, even though we observed a higher variability in the AD group and 5/26 showed PIPR values outside the 2 SD from the control mean values. Moreover, we found a significant difference between AD and controls in terms of rod-mediated transient PLR amplitude. These results suggest that in the early stage of AD there are PLR abnormalities that may reflect a pathology affecting mRGC dendrites before involving the mRGC cell body. Further studies, including AD cases with more severe and longer disease duration, are needed to further explore this hypothesis., (Copyright © 2020 Romagnoli, Stanzani Maserati, De Matteis, Capellari, Carbonelli, Amore, Cantalupo, Zenesini, Liguori, Sadun, Carelli, Park and La Morgia.)

Published

2020

18. Melanopsin Retinal Ganglion Cells and Pupil: Clinical Implications for Neuro-Ophthalmology.

Author

La Morgia C, Carelli V, and Carbonelli M

Abstract

Melanopsin retinal ganglion cells (mRGCs) are intrinsically photosensitive RGCs that mediate many relevant non-image forming functions of the eye, including the pupillary light reflex, through the projections to the olivary pretectal nucleus. In particular, the post-illumination pupil response (PIPR), as evaluated by chromatic pupillometry, can be used as a reliable marker of mRGC function in vivo . In the last years, pupillometry has become a promising tool to assess mRGC dysfunction in various neurological and neuro-ophthalmological conditions. In this review we will present the most relevant findings of pupillometric studies in glaucoma, hereditary optic neuropathies, ischemic optic neuropathies, idiopathic intracranial hypertension, multiple sclerosis, Parkinson's disease, and mood disorders. The use of PIPR as a marker for mRGC function is also proposed for other neurodegenerative disorders in which circadian dysfunction is documented.

Published

2018

19. A STUDY OF THE SUSTAINED PUPIL RESPONSE UNDER A VARIETY OF LED ILLUMINATIONS

Author

Le Rohellec, Jean, Viénot, F, Anton, Jean-Luc, Nazarian, B, Attia, F, Merckel, F, Rosenfeld, F, Lavédrine, B, Centre de Recherche sur la Conservation (CRC ), Muséum national d'Histoire naturelle (MNHN)-Ministère de la Culture et de la Communication (MCC)-Centre National de la Recherche Scientifique (CNRS), Radiologie et imagerie médicale, Assistance Publique - Hôpitaux de Marseille (APHM)- Hôpital de la Timone [CHU - APHM] (TIMONE), Institut de Neurosciences de la Timone (INT), Aix Marseille Université (AMU)-Centre National de la Recherche Scientifique (CNRS), Agence nationale de sécurité sanitaire de l'alimentation, de l'environnement et du travail (ANSES), and Muséum national d'Histoire naturelle (MNHN)

Subjects

[SPI.OTHER]Engineering Sciences [physics]/Other, [SDV.EE.SANT]Life Sciences [q-bio]/Ecology, environment/Health, [PHYS.PHYS.PHYS-OPTICS]Physics [physics]/Physics [physics]/Optics [physics.optics], [SCCO.NEUR]Cognitive science/Neuroscience, [SDV.NEU.NB]Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC]/Neurobiology, LED, Spectral power distribution, [SDV.NEU.SC]Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC]/Cognitive Sciences, [SPI.MAT]Engineering Sciences [physics]/Materials, [INFO.INFO-TI]Computer Science [cs]/Image Processing [eess.IV], Pupil visual response, [SDV.MHEP.OS]Life Sciences [q-bio]/Human health and pathology/Sensory Organs, Melanopsin retinal ganglion cells, [SPI.SIGNAL]Engineering Sciences [physics]/Signal and Image processing, [STAT.ME]Statistics [stat]/Methodology [stat.ME], [PHYS.PHYS.PHYS-HIST-PH]Physics [physics]/Physics [physics]/History of Physics [physics.hist-ph]

Abstract

International audience; The sustained pupil response of 9 observers has been recorded after 5 minutes adaptation to 5 spectrally different lights, at 100 and 210 lx. Warm white and Cool white commercial illuminations, and three metameric illuminations: incandescent light and two colour LED associations have been used. When the spectral power distribution of the light is strongly imbalanced with depletion around 480 nm, the selectivity of the pupil response, possibly due to weak excitation of the melanopsin retinal ganglion cells.

Published

2013

20. BDNF Rescues RGCs But Not Intrinsically Photosensitive RGCs in Ocular Hypertensive Albino Rat Retinas.

Author

Valiente-Soriano FJ, Nadal-Nicolás FM, Salinas-Navarro M, Jiménez-López M, Bernal-Garro JM, Villegas-Pérez MP, Agudo-Barriuso M, and Vidal-Sanz M

Subjects

Animals, Cell Death drug effects, Disease Models, Animal, Female, Intraocular Pressure drug effects, Intravitreal Injections, Lasers adverse effects, Ocular Hypertension physiopathology, Photoreceptor Cells, Vertebrate pathology, Rats, Rats, Sprague-Dawley, Retinal Ganglion Cells metabolism, Retinal Ganglion Cells pathology, Rod Opsins metabolism, Transcription Factor Brn-3A metabolism, Brain-Derived Neurotrophic Factor pharmacology, Ocular Hypertension drug therapy, Photoreceptor Cells, Vertebrate drug effects, Retina injuries, Retinal Ganglion Cells drug effects

Abstract

Purpose: To study the responses of the general population of retinal ganglion cells (Brn3a(+)RGCs) versus the intrinsically photosensitive RGCs (melanopsin-expressing RGCs [m(+)RGCs]) to ocular hypertension (OHT), the effects of brain-derived neurotrophic factor (BDNF) on the survival of axonally intact and axonally nonintact RGCs, and the correlation of vascular integrity with sectorial RGC loss., Methods: In Sprague-Dawley rats, 5 μg BDNF or vehicle was intravitreally injected into the left eye followed by laser photocoagulation of the limbal tissues. To identify RGCs with an active retrograde axonal transport, Fluorogold was applied to both superior colliculi 1 week before euthanasia (FG(+)RGCs). Retinas were dissected 12 or 15 days after lasering and immunoreacted against Brn3a (to identify all RGCs except m(+)RGCs), melanopsin, or RECA1 (inner retinal vasculature)., Results: Ocular hypertension resulted at 12 to 15 days in sectorial loss of FG(+)RGCs (78%-84%, respectively) while Brn3a(+)RGCs were significantly greater, indicating that a substantial proportion (approximately 21%-26%) of RGCs with their retrograde axonal transport impaired survive in the retina. Brain-derived neurotrophic factor increased the survival of Brn3a(+)RGCs to 81% to 67% at 12 to 15 days, respectively. The inner retinal vasculature showed no abnormalities that could account for the sectorial loss of RGCs. At 12 to 15 days, m(+)RGCs decreased to approximately 50% to 51%, but this loss was diffuse across the retina and was not prevented by BDNF., Conclusions: The responses of m(+)RGCs against OHT-induced retinal degeneration and neuroprotection differ from those of Brn3a(+)RGCs; while OHT induces similar loss of Brn3a(+)RGCs and m(+)RGCs, Brn3a(+)RGCs are lost in sectors and can be rescued with BDNF, but m(+)RGCs do not respond to BDNF and their loss is diffuse., (Copyright 2015 The Association for Research in Vision and Ophthalmology, Inc.)

Published

2015