Retina Anatomy and Biochemistry PDF

Summary

This document provides a detailed overview of retina anatomy and biochemistry, covering topics like phototransduction, energy metabolism, and visual pathways. It's structured as a presentation or lecture notes.

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EPISCLERITIS AND
RETINAL ANATOMY
AND BIOCHEMISTRY
EPISCLERETIS

Episcleretis is an inflammation of the episclera ,a thin layer of vascular
layer of connective tissues that lies between the conjunctiva and the
sclera
Episcleretis is a benign recurrent inflammation involving inflammation
of the Tenon's capsule but not the underlying sclera
Most affects young adults female than male
EPISCLERITIS
ETIOLOGY

Not yet known
Found in association with gout and psoariasis
Has been considered hypersensitivity reaction to endogenous tubecular
Congestion of overlaying of Tenon's capsule and conjunctiva
SYMPTOMS OF EPISCLERETIS

Redness
Blurred vision thou its less common but can happen in some cases
Mild ocular discomfort described as gritty , burning ,foreign sensation
Many a times ,not accomplained by Any discomfort
Photophobia and lacrimation may occurs
 PATHOLOGY
There occurs localised lymphocytic infiltration of episcleral tissues
associated, associated with oedema
Also congestion of overlaying of Tenon's capsule and conjunctiva
 Signs
Examinations, two clinical types of episcleral are diffuse and nodular
Episclera is seen acutely inflamed in the involved area
In diffuse episcleritis the whole eye may be involved to some
extent.Maximum inflammation is confined to one or two quadrants
In nodular episcleritis a pink or purple nodule surrounded by injection is
seen, usually situated 2-3mm away from the limbus
SIGNS

Nodule is a firm ,tender and the overlying conjunctiva moves freely
Clinical course ; episcleritis runs a limited course of 10 days resolving
spontaneously
Recurrence are common and tend to occur in bouts..A fleeting type of
disease (episcleritis periodical may occurs)
May be confused with inflamed pinguela swelling, congestion due to
foreign body lodged in bulbar conjunctiva and very rarely with scleritis
 RETINAL ANATOMY

Retina is a thin delicate transparent membrane that is
the innermost tunic of the eye back
-It is a highly developed tissues of the eye appears
purplish red because of virtual of the rods and vascular
choroid
-Retina extends from the optic disc to the ora setta,
grossly it is into 2 distinct regions which is the
posterior pole and peripheral retina separated by the
retina
-Retinal equator is an imaginary which is considered to lie in line
with the exit of the four vena verticose

-posterior pole refers to the area of the retina posterior to the
retinal equator.The posterior pole of the retina includes distinct
area ,the optic disc and macula lutea.
-It can be examined slit lamp indirect biomicroscopy using +78D
and +90D lens and direct ophthalmoscope
 Optic disk is a pink coloured defined area of 1.5mm diameter.At the optic disk ,all the
retinal layers expect the nerve fibres which pass through the lamina cribosa to run into
the optic nerve
A depression seen in a disc called physiological cup The central retinary artery and vein
emerge through the centre of this cup
Macula lutea ,is called yellow spot.It is comparatively deeper red than the surrounding
fundus is situated at the posterior pole temporal to the optic disk about 5 ,5 mm in
diameter
It is most sensitive part of the retina,in it's centre is a shining pit is called the fovea
0.35mm diameter which is situated 3mm from temporal margin
MICROSCOPIC STRUCTURE

Pigmented epithelium
Outer most layer of the retina,consists of a single layer of cell containing
pigment firmly adherent to underlying basal lamina(Brunch membrane of the
choroid
Plays important role in photoreceptor renewal and recycling of vitamin A
Probably RPE cells have phagocytic action
Provides mechanical support to the processes of photoreceptors
They manufacture pigment which presumably has an optical function in
absorbing light
 LAYER OF RODS AND CONES

Rods and cones are the end organs of the vision are also photoreceptors.Layers of
rods and cones contains only the outer segments of the photoreceptors cells
arranged in a palisade manner
There are 120 million rods and6.5 million conea..Rods contains a photosensitive
substance visual purple rhodopsina and subserve the peripheral vision.
Cones also contain are photosensitive substance and are primarily responsible for
highly discrimination central vision.Photopoc vision and color vision
 MICROSCOPIC STRUCTURE

3.External limiting membrane-it is a fenestrated membrane through which
pass processes of the rods and cornea
4.outer nuclear layer it consists of the nuclei of rods and cones
5..Inner nuclear layer,it mainly consists of cells bodies of bipolar bodies of
bipolar cells also contains cell bodies
 6.Inner plexiform layer consists of connection between the axons of bipolar cells and
dendrite of the ganglion cells and processes of amacrine cells
This layer disappears at fovea and in rest of retina consists of bipolar ,horizontal,
amacrine , the soma of the muller’s cells and capillaries of the central retinal
vessels
7.Ganglion cell layer ,mainly contains the cell bodies of ganglion cells(the second
order neurons of visual pathway)..There are 2 types of ganglion cells are present in
the macula region and the dendrite of each such as cell synapses with the axon of
single bipolar cells.The midget ganglion are present in.macular region and the
dendrite of each such a synapses with the axons of single bipolar cells
 8.Nerve fibre layer consists of axons of the ganglion which pass
through the lamina cribosa to form optic nerve
9.Interal limiting membrane ,it is the innermost layer and separates the
retina from vitreous..It is formed by the union of terminal expansions
of the Mullet fibres and to essentially basement
INTERNAL LIMITING MEMBRANE

It consist of PAS positive true basement membrane that forms the
interface between retina and vitreous
Consist of collagen fibrils , proteoglycans of the vitreous , the basement
membrane and the plasma membrane of the Muller cells and possibly
other glial cells off the retina
STRUCTURE OF FOVEAL CENTRALLS

There are no rods , cones are tightly packed and the other layer of the
retina are very thin.Central part (foveola) largely consists of cones
covered by a thin internal limiting membrane
All other retinal layer are absent in this region.In the foveal region
surrounding of foveola ;the cone axons are arranged obliquely (henle
layer) to reach the margin of the fovea
FUNCTIONS DIVISIONS OF RETINA

-divided into temporal retina and nasall by a line drawn vertically through the
centre of fovea
Nerve fibres arising from the temporal retina pass through the optic nerve and
optic tract of the same side to terminate in the geniculate body while the nerve
fibres originating from the nasal retina after passing through the optic nerve
cross in the optic chiasma and travel through optic tract to terminate in the
contralateral geniculate
 BLOOD SUPPLY
-outer four layers of the retina pigment epithelium,layer of rods and
cones,external limiting membrane and outer nuclear layer to get their
nutrition from the choroidal vessels
-Inner six layers get their supply from the central retinal artery ,which is
a branch of opthalmic artery
 Central retinary artery energy from the centre physiological cup of the optic
disk and divides into 4 branches namelythe superior nasal, superior temporal,,
inferior nasal and inferior temporal.These are end arteries.
Retinal veins ,these follow the pattern of retinal arteries.The central retinal
veins drain into cavernous sinus directly or through the superior opthalmic vein
BIOCHEMISTRY OF THE RETINA

The retina’s biochemistry involves light detection, signal transduction,
energy metabolism, and protection from oxidative damage. The
following sections outline the key biochemical processes:
-Phototransduction is the process by which photoreceptor cells (rods
and cones) convert light into an electrical signal.
PHOTO TRANSDUCTION

Rhodopsin and Cone Opsins:

Photoreceptors contain visual pigments: rhodopsin (in rods) and cone opsins (in cones).

Rhodopsin consists of opsin (a transmembrane protein) and 11-cis-retinal (a chromophore
derived from vitamin A).

1. Light Activation:

Light converts 11-cis-retinal to all-trans-retinal, causing a conformational change in rhodopsin.

2. Signal Amplification:

Activated rhodopsin stimulates transducin, a G-protein.
 Activated rhodopsin stimulates transducin, a G-protein.
3. cGMP Reduction:
Transducin activates phosphodiesterase (PDE), which hydrolyzes cyclic GMP
(cGMP).
cGMP levels decrease, leading to closure of cGMP-gated sodium channels.
4. Membrane Hyperpolarization:
Closure of sodium channels hyperpolarizes the photoreceptor, reducing
neurotransmitter release and initiating a neural signal.
VISUAL PATHWAY

The visual cycle regenerates 11-cis-retinal for continuous
photoreceptor function.

1. Release of All-Trans-Retinal:
After phototransduction, all-trans-retinal is reduced to all-trans-retinol.
2. Transport to the RPE:
All-trans-retinol is transported to the retinal pigment epithelium (RPE).
 3. Isomerization:
RPE enzymes, particularly RPE65, convert all-trans-retinol back to 11-
cis-retinol, then to 11-cis-retinal.
4. Recycling to Photoreceptors:
11-cis-retinal is transported back to photoreceptors to recombine with
opsins.
ENERGY METABOLISM

Energy Metabolism
The retina has one of the highest energy demands of any tissue.
Glycolysis and Oxidative Phosphorylation:
Despite sufficient oxygen supply, the retina relies heavily on aerobic
glycolysis (Warburg effect).
Mitochondria in the inner retina also perform oxidative phosphorylation
for ATP production.
GLUCOSE SUPPLY

Glucose Supply:
Glucose is transported into the retina by GLUT1 transporters in the
blood-retina barrier.
The pentose phosphate pathway (PPP) is active, providing NADPH for
antioxidant defense.
NEUROTRANSMITTERS

4. Neurotransmitters in the Retina
Neurotransmitters mediate signal transmission between retinal
neurons.
Glutamate:
Released by photoreceptors and bipolar cells.
Acts as the primary excitatory neurotransmitter.
Inhibitory Neurotransmitters:
GABA and glycine are released by horizontal and amacrine cells,
modulating signal flow.