Retinal Drusen
Optic Disk Drusen
Macular Degeneration
Bruch Membrane
Geographic Atrophy
Photography
Retinal Pigment Epithelium
Fluorescein Angiography
Pigment Epithelium of Eye
Fundus Oculi
Diagnostic Techniques, Ophthalmological
Choroid
Tomography, Optical Coherence
Macula Lutea
Lipofuscin
Vitronectin is a constituent of ocular drusen and the vitronectin gene is expressed in human retinal pigmented epithelial cells. (1/196)
Age-related macular degeneration (AMD) leads to dysfunction and degeneration of retinal photoreceptor cells. This disease is characterized, in part, by the development of extracellular deposits called drusen. The presence of drusen is correlated with the development of AMD, although little is known about drusen composition or biogenesis. Drusen form within Bruch's membrane, a stratified extracellular matrix situated between the retinal pigmented epithelium and choriocapillaris. Because of this association, we sought to determine whether drusen contain known extracellular matrix constituents. Antibodies directed against a battery of extracellular matrix molecules were screened on drusen-containing sections from human donor eyes, including donors with clinically documented AMD. Antibodies directed against vitronectin, a plasma protein and extracellular matrix component, exhibit intense and consistent reactivity with drusen; antibodies to the conformationally distinct, heparin binding form of human vitronectin are similarly immunoreactive. No differences in vitronectin immunoreactivity between hard and soft drusen, or between macular and extramacular regions, have been observed. RT-PCR analyses revealed that vitronectin mRNA is expressed in the retinal pigmented epithelium (RPE)-choroidal complex and cultured RPE cells. These data document that vitronectin is a major constituent of human ocular drusen and that vitronectin mRNA is synthesized locally. Based on these data, we propose that vitronectin may participate in the pathogenesis of AMD. (+info)Increase in the advanced glycation end product pentosidine in Bruch's membrane with age. (2/196)
PURPOSE: To determine whether there is an age-related increase of pentosidine in human Bruch's membranes and to localize pentosidine and carboxymethyllysine (CML), two well-characterized, advanced glycation end products (AGEs) in aged human Bruch's membranes and choroid in vivo. METHODS: Human Bruch's membrane samples were isolated from the retinal pigment epithelium (RPE) and choroid and subjected to reversed-phase high-performance liquid chromatography to determine pentosidine content. A polyclonal anti-pentosidine antibody and a monoclonal antibody specific for carboxymethyllysine were used to localize AGEs in 20-month-old nondiabetic, 82-year-old nondiabetic, and 82-year-old diabetic globes. RESULTS: Human Bruch's membranes (n = 20) showed a linear age-dependent increase in pentosidine that reached approximately 0.17 millimoles pentosidine per mole hydroxyproline in late life (r = 0.896; P < 0.001). Immunohistochemical evaluation showed evidence of pentosidine in Bruch's membrane, choroidal extracellular matrix, and vessel walls in the 82-year-old nondiabetic and diabetic globes. A similar staining pattern was found with the anti-CML antibody. Basal laminar deposits and drusen stained with both antibodies in the elderly nondiabetic eye. In contrast, neither antibody stained the 20-month-old tissue. CONCLUSIONS: We provide biochemical and immunohistochemical evidence for the formation of pentosidine and CML structures in human Bruch's membrane and choroid with age. These changes could promote aging of the RPE-Bruch's membrane-choroid complex. (+info)Early drusen formation in the normal and aging eye and their relation to age related maculopathy: a clinicopathological study. (3/196)
AIM: To describe the early formation of drusen and their relation to normal aging changes at the macula and to the development of age related maculopathy (ARM). METHOD: Histopathological features of 353 eyes without histological evidence of ARM are described and correlated with the clinical appearance. In addition, 45 of these eyes were examined by transmission electron microscopy. RESULTS: Drusen were detected histopathologically in 177 (50%) eyes but were seen clinically in only 34% of these. Drusen were mainly small hard drusen with an occasional soft distinct drusen: no soft indistinct drusen were seen. Only those drusen deposits larger than 25-30 microns in diameter were detectable clinically. Preclinical drusen in eyes with only an occasional drusen were seen on electron microscopy as entrapment sites of coated membrane bound bodies which formed adjacent to the inner collagenous zone of Bruch's membrane. In contrast, preclinical drusen deposits in eyes with many drusen were seen as accumulations of amorphous material which appeared hyalinised by light microscopy. A distinct feature were rows of dense hyalinised microdrusen (1-2 microns in diameter), over which larger globular hyalinised drusen formed. CONCLUSION: Histological and ultrastructural examination can recognise and distinguish the earliest drusen formed as a result of normal aging from those associated with ARM. In eyes without diffuse deposits, histologically all drusen were of the hard hyalinised variety or their derivatives; no soft drusen composed of membranous debris were found. These findings support and explain those of other authors who do not consider the presence of a few small hard drusen to be a risk factor for the development of ARM. (+info)Histopathology of age-related macular degeneration. (4/196)
Age-related macular degeneration is a diffuse condition involving the retinal pigment epithelium, the photoreceptor cell layer, and perhaps the choriocapillaris. The early morphologic change is the development of basal deposits of two distinct types. This phase is not ophthalmoscopically detectable but psychophysical testing may demonstrate reduced function. The process becomes detectable with the occurrence of secondary changes in the pigment epithelium, soft drusen formation, and choroidal neovascularization. A reparative response results in disciform scars. The various morphologic forms of age-related macular degeneration are interrelated. (+info)Molecular composition of drusen as related to substructural phenotype. (5/196)
Age-related macular degeneration (AMD) is characterized in part by the deposition of extracellular deposits, including drusen, in the aging macula. A number of clinical studies have revealed a strong association between the number, size, and degree of confluency of drusen and AMD. Although a number of distinct morphological classes, or phenotypes, of drusen can be resolved at the ultrastructural level, very little is known about the compositional and etiological relationship between these phenotypes. A number of recent studies have begun to provide insight into the composition of drusen at the light microscopic level of resolution. Out of 33 extracellular matrix proteins evaluated, vitronectin was identified in hard and soft drusen [FASEB J 1999; 13:477-84]. Drusen have also been found to contain carbohydrate moieties which are labeled by wheat germ agglutinin (WGA), and Limax flavus agglutinin (LFA). We have recently extended these histochemical, immunohistochemical, and biochemical investigations to examine the relationship between substructural drusen phenotype and composition. The initial results of these observations, generated from a repository of human donor eyes processed within four hours of death, are reported herein. Five distinct substructural drusen phenotypes were identified in tissue sections from eyes of approximately 400 donors; all five phenotypes were observed in eyes from donors with and without clinically documented AMD. Interestingly, no strict relationship between size (one important discriminator between "hard" and "soft" drusen class) and morphology was noted for four out of the five drusen phenotypes. Sections from the same donors were incubated with antibodies directed against vitronectin and with the lectins WGA and LFA, three probes recently shown to label hard and soft drusen at the light microscopic level of resolution. As anticipated, all of these probes bound to all phenotypes of drusen examined. These data suggest that different phenotypes of drusen, although they may differ significantly with respect to their substructural morphology, may possess a similar complement of extracellular matrix-associated proteins and saccharides. Ongoing investigations are directed toward determining whether there exist specific drusen constituents, not yet identified, that impart phenotypic and/or ontogenic specificity to drusen. It is anticipated that a more complete understanding of drusen composition, as it relates to phenotype, will provide significant new insight into the biology and etiology of various clinically manifested forms of AMD. (+info)The genetics of age-related macular degeneration. (6/196)
Age-related macular degeneration (AMD) is increasingly recognized as a complex genetic disorder in which one or more genes contribute to an individual's susceptibility for developing the condition. Twin and family studies as well as population-based genetic epidemiologic methods have convincingly demonstrated the importance of genetics in AMD, though the extent of heritability, the number of genes involved, and the phenotypic and genetic heterogeneity of the condition remain unresolved. The extent to which other hereditary macular dystrophies such as Stargardts disease, familial radial drusen (malattia leventinese), Best's disease, and peripherin/RDS-related dystrophy are related to AMD remains unclear. Alzheimer's disease, another late onset, heterogeneous degenerative disorder of the central nervous system, offers a valuable model for identifying the issues that confront AMD genetics. (+info)Subthreshold (retinal pigment epithelium) photocoagulation in macular diseases: a pilot study. (7/196)
BACKGROUND: Subthreshold (retinal pigment epithelium) photocoagulation is a new photocoagulation method, which treats the retinal pigment epithelium (RPE) and avoids damage to the neural retina. The initial results in this prospective pilot study on various macular diseases are presented. METHODS: 12 patients with diabetic maculopathy (group I), 10 with soft drusen (group II), and four with central serous retinopathy (CSR) (group III) were treated and followed up for 1 year. Treatment was achieved using a train of repetitive short laser pulses (1.7 micros) of a green Nd:YLF laser (parameters: 527 nm, 100 and 500 pulses, repetition rate: 500 Hz, spot size: 160 microm, energies: 70-100 microJ). Laser energy was based on the visibility of test lesions on fluorescein angiography (50-130 microJ). Patients were examined at various times by ophthalmoscopy, fluorescein and ICG angiography, and infrared imaging. RESULTS: After 6 months hard exudates disappeared in six out of nine patients in group I and leakage disappeared in six out of 12 diabetic patients. In group II drusen were less in seven out of 10 patients. In group III serous detachment disappeared in three out of four cases. Visual acuity was stable in all cases. None of the laser lesions was clinically visible immediately. After 1 day most lesions were visible as yellowish RPE depigmentation. After 3 months some of the lesions were visible as hyperpigmented areas but most were not. Fluorescein angiography showed leakage only in the first week. Infrared imaging showed that most lesions can be visualised in groups I and II after a period longer than 1 week as hyperreflective areas. CONCLUSION: This study showed that subthreshold (RPE) photocoagulation is effective in some cases of diabetic maculopathy, drusens, and in CSR. Visibility of laser burns is not always necessary in the treatment of macular diseases presented here. Infrared imaging is an effective and non-invasive way of visualising subthreshold (RPE) laser burns. (+info)Autofluorescence distribution associated with drusen in age-related macular degeneration. (8/196)
PURPOSE: To determine whether drusen in patients with age-related maculopathy and macular degeneration (ARM/AMD) are associated with focal changes in retinal pigment epithelium (RPE) lipofuscin fluorescence. METHOD: A new autofluorescence imaging device was used to study lipofuscin distribution associated with individual drusen in 20 patients with ARM/AMD. Paired monochromatic and autofluorescence fundus images were used for detailed analysis of the topography of autofluorescence at specific sites containing drusen. In four eyes, image analysis was used to compare the spatial distribution of the autofluorescence with the location of drusen and to quantify the autofluorescence distribution over individual drusen (54 drusen). REsuLTs. A specific pattern of autofluorescence was frequently found to be spatially associated with hard drusen and soft drusen between 60 and 175 microm in size. The pattern is characterized by a central area of decreased autofluorescence surrounded, in most cases, by an annulus of increased autofluorescence. The location of this pattern was highly correlated with the position of individual distinct drusen. The central low autofluorescence focus was on average 16% below the surrounding background, and the annulus, when present, was on average 6% more fluorescent than the background. Soft drusen larger than 175 microm and confluent soft drusen show either multifocal areas of low autofluorescence or a more heterogeneous distribution. CONCLUSIoNs. Autofluorescence imaging permits measurement of RPE lipofuscin at specific sites. RPE overlying drusen have altered autofluorescence, suggesting changes in RPE health. (+info)Retinal drusen are yellow-white, deposits of extracellular material that accumulate beneath the retina, most commonly in the macula. They are a common age-related finding and can also be seen in various other conditions such as inherited retinal diseases. Drusen can vary in size and number, and their presence is often associated with an increased risk of developing age-related macular degeneration (AMD), a leading cause of vision loss in older adults. However, not all individuals with drusen will develop AMD, and the significance of drusen depends on factors such as size, number, and location. It's important to monitor drusen and have regular eye examinations to assess any changes or progression that may indicate a higher risk for developing AMD.
Optic disk drusen are small, calcified deposits that form within the optic nerve head, also known as the optic disc. They are made up of protein and calcium salts and can vary in size and number. These deposits can be seen on ophthalmic examination using an instrument called an ophthalmoscope.
Optic disk drusen are typically asymptomatic and are often discovered during routine eye examinations. However, in some cases, they may cause visual disturbances or even vision loss if they compress the optic nerve fibers. They can also increase the risk of developing other eye conditions such as glaucoma.
Optic disk drusen are more commonly found in individuals with a family history of the condition and tend to occur in younger people, typically before the age of 40. While there is no cure for optic disk drusen, regular eye examinations can help monitor any changes in the condition and manage any associated visual symptoms or complications.
Macular degeneration, also known as age-related macular degeneration (AMD), is a medical condition that affects the central part of the retina, called the macula. The macula is responsible for sharp, detailed vision, which is necessary for activities such as reading, driving, and recognizing faces.
In AMD, there is a breakdown or deterioration of the macula, leading to gradual loss of central vision. There are two main types of AMD: dry (atrophic) and wet (exudative). Dry AMD is more common and progresses more slowly, while wet AMD is less common but can cause rapid and severe vision loss if left untreated.
The exact causes of AMD are not fully understood, but risk factors include age, smoking, family history, high blood pressure, obesity, and exposure to sunlight. While there is no cure for AMD, treatments such as vitamin supplements, laser therapy, and medication injections can help slow its progression and reduce the risk of vision loss.
The Bruch membrane is a thin, layered structure that separates the retina from the choroid in the eye. It is composed of five layers: the basement membrane of the retinal pigment epithelium (RPE), the inner collagenous layer, the elastic layer, the outer collagenous layer, and the basement membrane of the choriocapillaris. The Bruch membrane provides structural support to the RPE and serves as a barrier between the retina and the choroid, allowing for the selective transport of nutrients and waste products. It also plays a role in maintaining the health of the photoreceptors in the retina. Damage to the Bruch membrane is associated with age-related macular degeneration (AMD), a leading cause of vision loss in older adults.
Geographic atrophy is a medical term used to describe a specific pattern of degeneration of the retinal pigment epithelium (RPE) and the underlying choroidal tissue in the eye. This condition is often associated with age-related macular degeneration (AMD), which is a leading cause of vision loss in older adults.
In geographic atrophy, there are well-defined areas of RPE and choroidal atrophy that appear as pale, irregularly shaped patches in the central part of the retina known as the macula. These patches can grow larger over time and may lead to progressive vision loss. The exact cause of geographic atrophy is not fully understood, but it is thought to be related to oxidative stress, inflammation, and other age-related changes in the eye.
Currently, there are no effective treatments for geographic atrophy, although research is ongoing to find new ways to slow or halt its progression. Regular eye exams and monitoring by an ophthalmologist are important for people with AMD or geographic atrophy to help detect any changes in their vision and manage their condition effectively.
I'm sorry for any confusion, but "photography" is not a term typically used in medical definitions. Photography refers to the art, application, or process of creating images by recording light or other electromagnetic radiation, either electronically by means of an image sensor, or chemically by means of a light-sensitive material such as photographic film.
If you're looking for a medical term related to imaging, there are several terms that might be relevant, such as:
1. Radiography: This is a technique using X-rays to visualize the internal structures of the body.
2. Ultrasonography: Also known as ultrasound, this is a diagnostic imaging technique using high-frequency sound waves to create images of the inside of the body.
3. Computed Tomography (CT): A type of imaging that uses X-rays to create detailed cross-sectional images of the body.
4. Magnetic Resonance Imaging (MRI): A type of imaging that uses magnetic fields and radio waves to create detailed images of the organs and tissues within the body.
5. Nuclear Medicine: This is a branch of medical imaging that uses small amounts of radioactive material to diagnose and treat diseases.
If you have any questions related to medical definitions or topics, feel free to ask!
The retinal pigment epithelium (RPE) is a single layer of cells located between the photoreceptor cells of the retina and the choroid, which is a part of the eye containing blood vessels. The RPE plays a crucial role in maintaining the health and function of the photoreceptors by providing them with nutrients, removing waste products, and helping to regulate the light-sensitive visual pigments within the photoreceptors.
The RPE cells contain pigment granules that absorb excess light to prevent scattering within the eye and improve visual acuity. They also help to form the blood-retina barrier, which restricts the movement of certain molecules between the retina and the choroid, providing an important protective function for the retina.
Damage to the RPE can lead to a variety of eye conditions, including age-related macular degeneration (AMD), which is a leading cause of vision loss in older adults.
Fluorescein angiography is a medical diagnostic procedure used in ophthalmology to examine the blood flow in the retina and choroid, which are the inner layers of the eye. This test involves injecting a fluorescent dye, Fluorescein, into a patient's arm vein. As the dye reaches the blood vessels in the eye, a specialized camera takes rapid sequences of photographs to capture the dye's circulation through the retina and choroid.
The images produced by fluorescein angiography can help doctors identify any damage to the blood vessels, leakage, or abnormal growth of new blood vessels. This information is crucial in diagnosing and managing various eye conditions such as age-related macular degeneration, diabetic retinopathy, retinal vein occlusions, and inflammatory eye diseases.
It's important to note that while fluorescein angiography is a valuable diagnostic tool, it does carry some risks, including temporary side effects like nausea, vomiting, or allergic reactions to the dye. In rare cases, severe adverse reactions can occur, so patients should discuss these potential risks with their healthcare provider before undergoing the procedure.
The pigment epithelium of the eye, also known as the retinal pigment epithelium (RPE), is a layer of cells located between the photoreceptor cells of the retina and the choroid, which is the vascular layer of the eye. The RPE plays a crucial role in maintaining the health and function of the photoreceptors by providing them with nutrients, removing waste products, and helping to regulate the light that enters the eye.
The RPE cells contain pigment granules that absorb excess light, preventing it from scattering within the eye and improving visual acuity. They also help to create a barrier between the retina and the choroid, which is important for maintaining the proper functioning of the photoreceptors. Additionally, the RPE plays a role in the regeneration of visual pigments in the photoreceptor cells, allowing us to see in different light conditions.
Damage to the RPE can lead to various eye diseases and conditions, including age-related macular degeneration (AMD), which is a leading cause of vision loss in older adults.
"Fundus Oculi" is a medical term that refers to the back part of the interior of the eye, including the optic disc, macula, fovea, retinal vasculature, and peripheral retina. It is the area where light is focused and then transmitted to the brain via the optic nerve, forming visual images. Examinations of the fundus oculi are crucial for detecting various eye conditions such as diabetic retinopathy, macular degeneration, glaucoma, and other retinal diseases. The examination is typically performed using an ophthalmoscope or a specialized camera called a retinal camera.
Diagnostic techniques in ophthalmology refer to the various methods and tests used by eye specialists (ophthalmologists) to examine, evaluate, and diagnose conditions related to the eyes and visual system. Here are some commonly used diagnostic techniques:
1. Visual Acuity Testing: This is a basic test to measure the sharpness of a person's vision. It typically involves reading letters or numbers from an eye chart at a specific distance.
2. Refraction Test: This test helps determine the correct lens prescription for glasses or contact lenses by measuring how light is bent as it passes through the cornea and lens.
3. Slit Lamp Examination: A slit lamp is a microscope that allows an ophthalmologist to examine the structures of the eye, including the cornea, iris, lens, and retina, in great detail.
4. Tonometry: This test measures the pressure inside the eye (intraocular pressure) to detect conditions like glaucoma. Common methods include applanation tonometry and non-contact tonometry.
5. Retinal Imaging: Several techniques are used to capture images of the retina, including fundus photography, fluorescein angiography, and optical coherence tomography (OCT). These tests help diagnose conditions like macular degeneration, diabetic retinopathy, and retinal detachments.
6. Color Vision Testing: This test evaluates a person's ability to distinguish between different colors, which can help detect color vision deficiencies or neurological disorders affecting the visual pathway.
7. Visual Field Testing: This test measures a person's peripheral (or side) vision and can help diagnose conditions like glaucoma, optic nerve damage, or brain injuries.
8. Pupillary Reactions Tests: These tests evaluate how the pupils respond to light and near objects, which can provide information about the condition of the eye's internal structures and the nervous system.
9. Ocular Motility Testing: This test assesses eye movements and alignment, helping diagnose conditions like strabismus (crossed eyes) or nystagmus (involuntary eye movement).
10. Corneal Topography: This non-invasive imaging technique maps the curvature of the cornea, which can help detect irregularities, assess the fit of contact lenses, and plan refractive surgery procedures.
The choroid is a layer of the eye that contains blood vessels that supply oxygen and nutrients to the outer layers of the retina. It lies between the sclera (the white, protective coat of the eye) and the retina (the light-sensitive tissue at the back of the eye). The choroid is essential for maintaining the health and function of the retina, particularly the photoreceptor cells that detect light and transmit visual signals to the brain. Damage to the choroid can lead to vision loss or impairment.
Optical coherence tomography (OCT) is a non-invasive imaging technique that uses low-coherence light to capture high-resolution cross-sectional images of biological tissues, particularly the retina and other ocular structures. OCT works by measuring the echo time delay of light scattered back from different depths within the tissue, creating a detailed map of the tissue's structure. This technique is widely used in ophthalmology to diagnose and monitor various eye conditions such as macular degeneration, diabetic retinopathy, and glaucoma.
The macula lutea, often simply referred to as the macula or fovea centralis, is a part of the eye that is responsible for central vision and color perception. It's located in the center of the retina, the light-sensitive tissue at the back of the eye. The macula contains a high concentration of pigments called xanthophylls, which give it a yellowish color and protect the photoreceptor cells in this area from damage by blue light.
The central part of the macula is called the fovea, which is a small depression that contains only cones, the photoreceptor cells responsible for color vision and high visual acuity. The fovea is surrounded by the parafovea and the perifovea, which contain both cones and rods, the photoreceptor cells responsible for low-light vision and peripheral vision.
Damage to the macula can result in a loss of central vision and color perception, a condition known as age-related macular degeneration (AMD), which is a leading cause of blindness in older adults. Other conditions that can affect the macula include macular edema, macular holes, and macular pucker.
Lipofuscin is a type of pigment that accumulates in the lysosomes (membrane-bound organelles found inside cells) of various tissues, particularly in nerve cells and heart muscle cells. It consists of cross-linked proteins and lipids that are resistant to degradation by enzymes. The accumulation of lipofuscin is a normal part of aging but can also be associated with certain diseases such as neurodegenerative disorders.
It's often referred to as "age pigment" because it tends to increase in amount with age, and its presence in tissues has been linked to oxidative stress and cellular damage caused by free radicals. Lipofuscin is autofluorescent, meaning that it emits light when excited by certain wavelengths of light, which can be useful for its detection and quantification in research and diagnostic settings.
Wet macular degeneration, also known as neovascular or exudative age-related macular degeneration (AMD), is a medical condition that affects the central part of the retina called the macula. It's characterized by the growth of new blood vessels (neovascularization) from the choroid layer behind the retina into the macula, which is not typical in healthy eyes. These abnormal blood vessels are fragile and prone to leakage, leading to the accumulation of fluid or blood in the macula, causing distortion or loss of central vision.
The wet form of AMD can progress rapidly and often leads to more severe visual loss compared to the dry form. It's essential to diagnose and treat wet AMD promptly to preserve as much vision as possible. Common treatments include anti-vascular endothelial growth factor (VEGF) injections, photodynamic therapy, or thermal laser treatment, depending on the specific case and individual patient factors.