This document provides information on the anatomy of the peripheral retina and various lesions that can predispose the retina to detachment. It describes the pars plana, ora serrata, vitreous base, vitreous adhesions, and traction. Peripheral lesions discussed include lattice degeneration, snail track degeneration, retinoschisis, choroidal atrophy, white without pressure, and posterior vitreous detachment. Factors preventing retinal detachment and the progression to detachment when these factors are compromised are also summarized.
Ischemic condition affecting the eye.
The ischemia can occur secondary to systemically problem [or] particulary the eye.
Many retinal vascular disorders {like CRAO,CRVO,Diabetic retinopathy,Hypertensive Retinopathy} shows ischemic signs.
Ischemic condition affecting the eye.
The ischemia can occur secondary to systemically problem [or] particulary the eye.
Many retinal vascular disorders {like CRAO,CRVO,Diabetic retinopathy,Hypertensive Retinopathy} shows ischemic signs.
- Video recording of this lecture in English language: https://youtu.be/lK81BzxMqdo
- Video recording of this lecture in Arabic language: https://youtu.be/Ve4P0COk9OI
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micro teaching on communication m.sc nursing.pdfAnurag Sharma
Microteaching is a unique model of practice teaching. It is a viable instrument for the. desired change in the teaching behavior or the behavior potential which, in specified types of real. classroom situations, tends to facilitate the achievement of specified types of objectives.
The Gram stain is a fundamental technique in microbiology used to classify bacteria based on their cell wall structure. It provides a quick and simple method to distinguish between Gram-positive and Gram-negative bacteria, which have different susceptibilities to antibiotics
Title: Sense of Smell
Presenter: Dr. Faiza, Assistant Professor of Physiology
Qualifications:
MBBS (Best Graduate, AIMC Lahore)
FCPS Physiology
ICMT, CHPE, DHPE (STMU)
MPH (GC University, Faisalabad)
MBA (Virtual University of Pakistan)
Learning Objectives:
Describe the primary categories of smells and the concept of odor blindness.
Explain the structure and location of the olfactory membrane and mucosa, including the types and roles of cells involved in olfaction.
Describe the pathway and mechanisms of olfactory signal transmission from the olfactory receptors to the brain.
Illustrate the biochemical cascade triggered by odorant binding to olfactory receptors, including the role of G-proteins and second messengers in generating an action potential.
Identify different types of olfactory disorders such as anosmia, hyposmia, hyperosmia, and dysosmia, including their potential causes.
Key Topics:
Olfactory Genes:
3% of the human genome accounts for olfactory genes.
400 genes for odorant receptors.
Olfactory Membrane:
Located in the superior part of the nasal cavity.
Medially: Folds downward along the superior septum.
Laterally: Folds over the superior turbinate and upper surface of the middle turbinate.
Total surface area: 5-10 square centimeters.
Olfactory Mucosa:
Olfactory Cells: Bipolar nerve cells derived from the CNS (100 million), with 4-25 olfactory cilia per cell.
Sustentacular Cells: Produce mucus and maintain ionic and molecular environment.
Basal Cells: Replace worn-out olfactory cells with an average lifespan of 1-2 months.
Bowman’s Gland: Secretes mucus.
Stimulation of Olfactory Cells:
Odorant dissolves in mucus and attaches to receptors on olfactory cilia.
Involves a cascade effect through G-proteins and second messengers, leading to depolarization and action potential generation in the olfactory nerve.
Quality of a Good Odorant:
Small (3-20 Carbon atoms), volatile, water-soluble, and lipid-soluble.
Facilitated by odorant-binding proteins in mucus.
Membrane Potential and Action Potential:
Resting membrane potential: -55mV.
Action potential frequency in the olfactory nerve increases with odorant strength.
Adaptation Towards the Sense of Smell:
Rapid adaptation within the first second, with further slow adaptation.
Psychological adaptation greater than receptor adaptation, involving feedback inhibition from the central nervous system.
Primary Sensations of Smell:
Camphoraceous, Musky, Floral, Pepperminty, Ethereal, Pungent, Putrid.
Odor Detection Threshold:
Examples: Hydrogen sulfide (0.0005 ppm), Methyl-mercaptan (0.002 ppm).
Some toxic substances are odorless at lethal concentrations.
Characteristics of Smell:
Odor blindness for single substances due to lack of appropriate receptor protein.
Behavioral and emotional influences of smell.
Transmission of Olfactory Signals:
From olfactory cells to glomeruli in the olfactory bulb, involving lateral inhibition.
Primitive, less old, and new olfactory systems with different path
Adv. biopharm. APPLICATION OF PHARMACOKINETICS : TARGETED DRUG DELIVERY SYSTEMSAkankshaAshtankar
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ADVANCED BIOPHARMACEUTICS & PHARMACOKINETICS : UNIT 5
APPLICATION OF PHARMACOKINETICS : TARGETED DRUG DELIVERY SYSTEMS By - AKANKSHA ASHTANKAR
Flu Vaccine Alert in Bangalore Karnatakaaddon Scans
As flu season approaches, health officials in Bangalore, Karnataka, are urging residents to get their flu vaccinations. The seasonal flu, while common, can lead to severe health complications, particularly for vulnerable populations such as young children, the elderly, and those with underlying health conditions.
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This year, the flu season is expected to coincide with a potential increase in other respiratory illnesses. The Karnataka Health Department has launched an awareness campaign highlighting the significance of flu vaccinations. They have set up multiple vaccination centers across Bangalore, making it convenient for residents to receive their shots.
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Local Advanced Lung Cancer: Artificial Intelligence, Synergetics, Complex Sys...Oleg Kshivets
Overall life span (LS) was 1671.7±1721.6 days and cumulative 5YS reached 62.4%, 10 years – 50.4%, 20 years – 44.6%. 94 LCP lived more than 5 years without cancer (LS=2958.6±1723.6 days), 22 – more than 10 years (LS=5571±1841.8 days). 67 LCP died because of LC (LS=471.9±344 days). AT significantly improved 5YS (68% vs. 53.7%) (P=0.028 by log-rank test). Cox modeling displayed that 5YS of LCP significantly depended on: N0-N12, T3-4, blood cell circuit, cell ratio factors (ratio between cancer cells-CC and blood cells subpopulations), LC cell dynamics, recalcification time, heparin tolerance, prothrombin index, protein, AT, procedure type (P=0.000-0.031). Neural networks, genetic algorithm selection and bootstrap simulation revealed relationships between 5YS and N0-12 (rank=1), thrombocytes/CC (rank=2), segmented neutrophils/CC (3), eosinophils/CC (4), erythrocytes/CC (5), healthy cells/CC (6), lymphocytes/CC (7), stick neutrophils/CC (8), leucocytes/CC (9), monocytes/CC (10). Correct prediction of 5YS was 100% by neural networks computing (error=0.000; area under ROC curve=1.0).
NVBDCP.pptx Nation vector borne disease control programSapna Thakur
NVBDCP was launched in 2003-2004 . Vector-Borne Disease: Disease that results from an infection transmitted to humans and other animals by blood-feeding arthropods, such as mosquitoes, ticks, and fleas. Examples of vector-borne diseases include Dengue fever, West Nile Virus, Lyme disease, and malaria.
Ozempic: Preoperative Management of Patients on GLP-1 Receptor Agonists Saeid Safari
Preoperative Management of Patients on GLP-1 Receptor Agonists like Ozempic and Semiglutide
ASA GUIDELINE
NYSORA Guideline
2 Case Reports of Gastric Ultrasound
2. ANATOMY OF THE PERIPHERAL RETINA
1.Pars Plana
The ciliary body starts 1mm from the limbus and extends posteriorly for about
6mm.
The first 2mm = pars plicata and the remaining 4mm = flattened pars plana.
In order not to endanger the lens or retina, the optimal location for a pars plana
surgical incision is 4 mm from the limbus in phakic eyes
and
3.5 mm from the limbus in pseudophakic eyes.
3.
4. 2. Ora Serrata
Forms the junction between the retina and ciliary body and is
characterized by the following :
1.Dentate processes
are teeth-like extensions of retina onto the pars plana; more
marked nasally than temporally.
2. Oral bays
are the scalloped edges of the pars plana epithelium in between
the dentate processes.
5. 3. A meridional fold
a small radial fold of thickened retinal tissue in line with a
dentate process, usually located in the superonasal quadrant .
A fold may occasionally exhibit a small retinal hole at its apex
4. An enclosed oral bay
a small island of pars plana surrounded by retina as a result of
meeting of two adjacent dentate processes.
*It should not be mistaken for a retinal hole because it is
located anterior to the ora serrata.
5 Granular tissue
multiple white opacities within the vitreous base can
sometimes be mistaken for small peripheral opercula
6.
7. DESCRIPTION LENGTH
Width of ora serrata 2.1 mm temporally
0.7-0.8 mm nasally
Location from limbus 6mm nasally
7mm temporally
From equator 6-8 mm
From optic disc 25 mm
8. At the ora, fusion of the sensory retina with the RPE and choroid
limits forward extension of SRF.
However, there being no equivalent adhesion between the choroid
and sclera, choroidal detachments may progress anteriorly to
involve the ciliary body (CILIOCHOROIDAL DETACHMENT).
**IMP** Choroidal detachments do not extend to posterior pole
bcoz they are limited by the VORTEX VEINS entering their
scleral channels.
9.
10. VITREOUS BASE
3–4 mm wide zone straddling the ora serrata.
The cortical vitreous is strongly attached at the vitreous base,
so that following acute PVD, the posterior
hyaloid face remains attached to the posterior border of the
vitreous base.
Pre-existing retinal holes within the vitreous base do not lead
to RD.
Severe blunt trauma avulsion of the vitreous
base with tearing of the NPE of the pars plana along its
anterior border and of the retina along its posterior border.
11.
12. VITREOUS ADHESIONS
1 Normal.
The peripheral cortical vitreous is
loosely attached to ILM of the
sensory retina. Stronger adhesions :
• Vitreous base, strongest.
• Around the ONH fairly strong.
• Around the fovea, fairly weak,
except in eyes with VMT and
macular hole formation.
• Along peripheral blood vessels,
usually weak.
2 Abnormal adhesions at the
following :
• Posterior border of islands of
lattice degeneration.
• Retinal pigment clumps.
• Peripheral paravascular
condensations.
• Vitreous base anomalies eg. tongue
like extensions & posterior islands.
• ‘WWP’ and ‘WWOP’.
13. VITREORETINAL TRACTION
Is a force exerted on the retina by structures originating in
the vitreous, and may be dynamic or static.
1 Dynamic traction
is induced by eye movements
and
exerts a centripetal force towards the
vitreous cavity.
It plays an important role in the
pathogenesis of retinal tears and
Rhegmatogenous RD.
14. 2 Static traction
is independent of ocular
movements.
It plays a key role in the
pathogenesis of tractional RD and
proliferative vitreoretinopathy
16. LATTICE DEGENERATION
1. Prevalence - 8% of the population.
Develops early in life, with a peak incidence in the 2nd and 3rd decades.
More commonly in moderate myopes
and is the most important degeneration directly related to RD.
Bilateral
Temporal and superiorly
Lattice is present in about 40% of eyes with RD.
2. Pathology - There is discontinuity of the ILM with variable atrophy of
the underlying NSR.
The vitreous overlying an area of lattice is synchytic but the vitreous
attachments around the margins are exaggerated.
17.
18. 3.Signs-
Spindle-shaped areas of retinal thinning, commonly located
between the equator and the posterior border of the vitreous
base.
Arborizing network of white lines within the islands. **
Some lattice lesions may be associated with
‘snowflakes’ (remnants of degenerate Müller
cells.)
Associated hyperplasia of the RPE is common.
Small holes within lattice lesions are common and usually
innocuous.
19. 4.Complications –
No complications are encountered in most patients.
Tears may occasionally develop in eyes with acute PVD.
Atrophic holes may rarely lead to RD, particularly in young
myopes. The fellow eye often has a ‘mirror-image’ distribution
of holes.
20.
21. SNAILTRACK DEGENERATION
Characterized by sharply
demarcated bands of tightly
packed ‘snowflakes’which give
the peripheral retina a white frost-
like appearance.
The islands are usually longer
than in lattice degeneration and
may be associated with overlying
vitreous liquefaction.
o However, marked vitreous traction at the posterior border of the
lesions is seldom present so that tractional U-tears rarely occur,
although round holes within the snailtracks may be present.
22. RETINOSCHISIS
Symptoms.
Common in HYPERMETROPES.
SPLIT IN RETINAL LAYERS.
Cystoid degeneration.
Photopsia and floaters are absent. ( because there is no
vitreoretinal traction. )
Occasionally symptoms occur as a result of either VH or the
development of progressive RD.
23. Typical RS /DEGENERATIVE
More common
Low lying
Split in OPL
Less complications
Located Ant to
equator
Less common
Absent
Reticular
/JUVENILE RS
Less common
BULLOUS
Split in NFL
more
Can be Posterior to
equator
Microaneursyms &
small telengeictasias
Outer layer holes
24. Signs :
Early retinoschisis - extreme inferotemporal periphery of both
fundi.
** appearing as an exaggeration of microcystoid degeneration with a
smooth immobile elevation of the retina.
**The surface of the inner layer may show snowflakes as well as
sheathing or ‘silver-wiring’ of blood vessels and the schisis
cavity may be bridged by rows of torn grey-white tissue.
Breaks may be +nt in one or both layers.
The elevation is convex, smooth, thin and relatively immobile,
unlike the opaque and corrugated appearance of a rhegmatogenous
RD.
25.
26.
27. RETINOSCHISIS RD
TYPICAL PT AGE Middle to elderly Middle age
Refractive association Hyperopia Myopia
Symptoms Almost always absent Acute : present
Chronic : absent
Scotoma Absolute Relative
VH or pigment Absent Present
Location Inferotemporal> ST Acute : usually superior
Chronic:usually inferior
Texture Smooth Ac: corrugated
Ch: smooth
Muller footplates Common Absent
Mobility Relatively immobile Ac: very often mobile
Ch: relatively immobile
Movement with scleral depression Moves as a single unit Height decreases
28. RETINOSCHISIS RD
Color with scleral
depression
WWP may be seen in
outer layer
NOT
Breaks May be present Present
RPE Normal Ac: normal
Ch: atrophy & demarcation lines
OCT Splitting of retinal layers SRF
Effect of LASER
application through
retinal break
Through inner layer
break: Uptake
Through full thickness break :
no uptake
29. DIFFUSE CHORIORETINAL ATROPHY
Characterized by choroidal
depigmentation and thinning
of the overlying retina in the
equatorial area of highly myopic
eyes.
Retinal holes developing in the atrophic retina may lead to RD.
Because of lack of contrast between the depigmented choroid
and sensory retina, small holes may be very difficult to
visualize without the help of slit-lamp biomicroscopy.
30. WHITE WITH PRESSURE
Retinal areas in which a translucent
white-grey appearance can be induced
by scleral indentation.
Each area has a fixed configuration
that does not change when
indentation is moved to an
adjacent area.
Along posterior border of lattice deg,
snail-track deg and the outer layers
of acquired retinoschisis..
Can be seen in normal eyes === abnormally strong attachment of
vitreous gel.
31. WHITE WITHOUT PRESSURE
Present without scleral
indentation.
Area with fairly strong
adhesion of condensed
vitreous.
Can be mistakes for flat retinal
hole.
Retinal breaks, GRTs can
develop along the posterior
border of WWOP.
Prohylactic therapy thus
considered in WWOP in
fellow eye of a patient with
spontaneous GRT in other eye.
32. POSTERIOR VITREOUS DETACHMENT
Separation of the cortical vitreous from the ILM of the NSR posterior to the
vitreous base.
Classification :
1 Onset
Acute : most common Develops suddenly and usually becomes
complete soon after onset.
Chronic : gradually weeks or months to become complete.
2 Extent
Complete PVD entire vitreous cortex detaches up to the posterior
margin of the vitreous base.
Incomplete PVD residual vitreoretinal attachments remain
posterior to the vitreous base.
33. Symptoms :
1. Photopsia -- inc in dim light, common in temporal periphery.
2.Myodesopsia (floaters) : spots/ cobwebs/ flies.
3. Blurred vision : d/t vitreous haemorrhage or d/t PHM or floaters in
visual axis.
34. Weiss ring :-
Detached former attachment of the margin of optic disc.
Can be seen by patient as a circle or other solitary lesion.
35. Signs :
Detached PHM seen on S/L as CRUMPLED TRANSLUCENT
membrane in mid vitreous cavity which is optically clear.
Haemorrhage---rbcs in ant vitreous.
Pigment granules in ant. vitreous in abscence
of inflammation, trauma, surgery on S/L -
k/a
SHAFER SIGN OR TOBACCO DUST
Presence of pigment granules in ant vitreous 95% sensitivity for
possibility of a retinal break
36. PHM as Crumpled translucent
membrane
Tobacco dust
Tobacco dust
39. Rhegmatogenous RD is usually associated with acute
PVD;
tractional RD is associated with chronic, incomplete PVD;
exudative RD is unrelated to the presence of PVD.
42. FACTORS PREVENTING RD
Metabolic pump of RPE.
Osmotic pressure of choroid.
Minor mechanical processes of the interphotoreceptor
matrix.
compromised
RETINAL DETACHMENT
45. A Condition in which the fluid from the vitreous cavity
passes through a retinal defect into the subretinal space
to cause seperation of neural retina from the underlying
RPE
Retinal break and vitreous liquefaction is must.**
Even though a retinal break is present, a RD will not
occur if the vitreous is not at least partially liquefied and
if the necessary traction is not present.
PVD V. .liquefaction Retinal tears at site of significant
VR adhesions
46. CONDITIONS THAT PREDISPOSE AN EYE TO RD
High myopia.------3 fold in RD
PP or Aphakia.
Blunt trauma and penetrating ocular trauma.
( 10-15%)
CMV retinits ass. AIDS.
YAG capsulotomy
47. FACTORS CAUSING RD
A. RETINAL BREAKS
B. VITREOUS LIQUEFACTION AND DETACHMENT
C. VR TRACTION
D. INTRAOCULAR FLUID CURRENTS ASSOCIATED WITH MOVEMENT OF
LIQUID VITREOUS AND SRF
49. RETINAL BREAKS
Full thickness defects in neurosensory retina.
Typical location- near vitreous base.
Holes/ tears/ dialysis.
M=F
R/F :
1. Myopia.
2. Lattice degeneration.
3. Ocular contusion and Penerating trauma.
Most common of retinal break after ocular contusion is :-
Retinal Dialysis
50. OCULAR MANIFESTATIONS:
1. RETINAL TEARS :
Full thickness breaks that occur secondary to vitreous traction.
(spontaneous posterior vitreous detachment).
horseshoe-shaped
Types
flap shaped
Most common site- vitreous base.
Symptoms: Floaters, Flashes.
In lattice deg, mc site of retinal tear is POSTERO-LATERAL
margin of lattice.
51. 2. ROUND HOLES WITH OPERCULA
Persistent traction on HST/ flap tear
Avulsion at base
Complete relief of VRT in that area
Small round defect in neural retina with an overlying opercula
52. 3.Round holes without opercula – ATROPHIC HOLES
Secondary to retinal thinning.
No role of vitreous traction.
Common in areas of lattice deg.
53. 4. TRAUMATIC retinal breaks :
HST Retinal dialysis Macular holes
MC site : INFEROTEMPORALLY &
SUPERONASALLLY
5. MACULAR BREAKS :
Secondary to tangential traction from precortical vitreous
54.
55. Pars plana cysts
Enclosed oral
bays
Meridional folds
Ora serrata pearls
Paving stone deg Chorioretinal scars
WWP
WWOP
D/D OF RETINAL BREAKS
56.
57. INDICATIONS FOR T/T OF RETINAL TEAR/ HOLE IN
ASYMPTOMATIC PATIENT
Type of lesion Phakic Highly myopic Fellow eye Aphakic or
Pseudophakic
Retinal
dialysis
Almost
always
Almost always Almost always Almost always
HST sometimes sometimes sometimes sometimes
Operculated tears no rarely rarely rarely
Atrophic holes rarely rarely rarely rarely
Lattice deg’n
w/ or w/o
holes
no no sometimes rarely
58.
59. Lincoff and Geiser reported 4 guidelines for locating RB causing
RRD *
Determined by
Location of causative break
Anatomic barriers (optic n.,ora serrata, existing chorioretinal
adhesions)
Effect gravity on SRF in upright position
Note : onlyfor freshRDwith1 RB
60. 1. A shallow inferior RD in which the SRF is slightly higher on
the temporal side points to a primary break located inferiorly on
that side.
61. 2. A primary break located at 6 o’clock will cause an inferior
RD with equal fluid levels.
62. 3. In a bullous inferior RD the primary break usually lies
above the horizontal meridian.
4. If the primary break is located in the upper nasal quadrant
the SRF will revolve around the optic disc and then rise on the
temporal side until it is level with the primary break.
63. 5. A subtotal RD with a superior wedge of attached retina
points to a primary break located in the periphery nearest its
highest border.
6. When the SRF crosses the vertical midline above, the
primary break is near to 12 o’clock, the lower edge of the RD
corresponding to the side of the break .
64. B. VITREOUS LIQUEFACTION AND DETACHMENT
Ageing of human vitreous (SYNCHYSIS)
Liquefaction of vitreous gel with development of
optically emtpy lacunae in gel
Extensive liquefaction
Decrease in shock absorbing capacity and stability of gel
65. C. VR TRACTION
VR TRACTION
Gravitational
force
Rotational eye
movements
Fibrous tissue
contracture
Liquid
currents
Higher percentage
of SUPERIOR
retinal tears (80%)
Trauma/ retinal
vascular
proliferative
disorders
Continous flow of
liquid vitreous
through a retinal
break into subretinal
space is necessary to
maintain a RRD
66. OCULAR MANIFESTATIONS
SYMPTOMS
Sudden onset of tiny dark floating objects
Associated with Photopsia
**usually brief
**in the temporal visual field
SUBCLINICAL DETACHMENTS :
RD with small SRF (<2 DD) not acc by visual field loss
67.
68. SIGNS
1. RAPD
2. IOP is usually lower by about 5 mmHg compared with the
eye.
If the intraocular pressure is extremely low, an associated
choroidal detachment may be present.
3. Iritis is very common but usually mild.
4. ‘Tobacco dust’ consisting of pigment cells is seen in the
anterior vitreous.
It may normal be raised, characteristically in SCHWARTZ-MATSUO syndrome in
which RRD is associated with an apparent mild anterior uveitis , often due to a
DIALYSIS due to prior blunt trauma in a young man.
69. 5. Retinal breaks--- appear as discontinuities in the retinal
surface.
They are usually red because of the colour contrast between
the sensory retina and underlying choroid.
(However, in eyes with hypopigmented choroid (as in high myopia), the colour
contrast is decreased and small breaks may be overlooked unless careful slit-lamp
and indirect ophthalmoscopic examination is performed.)
6. Retinal signs depend on the
-- duration of RD and
-- the presence or absence of PVR.
73. PROLIFERATIVE VITREORETINOPATHY
Caused by epiretinal and subretinal membrane formation.
Most common cause of ultimate failure after surgical tt for
RRD.
Retinal break cells in vitreous cavity cells form
membranes on inner retinal surface or posterior vitreous
surface RRD.
Usually, Occurs following surgery for RRD or penetrating
injury.
However, it may also occur in eyes with RRD that have not
had previous vitreoretinal surgery.
74. RISK FACTORS FOR PVR
1. Giant retinal tear ( >3 clock hour).
2. Number and size of retinal break.
3. No.of previous operations.
4. Presence of choroidal effusions.
5. Use of cryotherapy.
6. Intraocular haemorrhage.
7.Aphakia.
8. Vitreous protein levels.
75. 1 Grade A (minimal) PVR : Characterized by diffuse vitreous haze and
tobacco dust. There may also be pigmented clumps on the inferior surface
of the retina.
2 Grade B (moderate) PVR : Characterized by wrinkling of the inner
retinal surface, tortuosity of blood vessels, retinal stiffness, decreased
mobility of vitreous gel and rolled edges of retinal breaks.
** The epiretinal membranes responsible for these findings cannot be
identified clinically.**
3 Grade C (marked) PVR Characterized by rigid full-thickness retinal
folds with heavy vitreous condensation and strands.
It can be either anterior (A) or posterior (P), the approximate dividing
line being the equator of the globe. The severity of proliferation in each
area is expressed by the number of clock hours of retina involved although
proliferations need not be contiguous.
4 B-scan ultrasonography in advanced disease shows gross reduction of
retinal mobility with retinal shortening and the characteristic triangular
sign. (FUNNEL LIKE)
76.
77.
78. T/T FOR PVR
1. No T/T if: retinal breaks absent unless macula is
involved.
localised TRD posterior to scleral buckle.
2. Macular pucker membrane peeling.
3. RRD location and severity of PVR
If surface membranes do not
prevent break closure……
SCLERAL BUCKLING
If surface membrane occur
in close association with
retinal break
Closed intraocular microsx with
membrane peeling
80. D/D FOR RRD
Traction RD.
Exudative RD.
Retinoschisis.
Elevated choroidal lesions.
Intravitreal optical illusions (vitreous h’age).
SYSTEMIC ASSOCIATIONS
Most important ocular disorder : STICKLER $
Most important systemic association : DM, AIDS
81. TREATMENT OF RD
AIM : to counter the factors and forces that causes RD and to re-
establish physiological conditions that normally maintain contact
between neural retina and RPE.
83. VITRECTOMY
INDICATIONS :
1. RD with PVR
2. Giant retinal Tears.
3.RD with posterior retinal breaks
.
4.RD with vitreous hemorrhage.
5. RD with intraocular foreign body.
6. TRD threatening to or involving the macula.
Less likely to be closed with
scleral buckle
Retinal breaks can not be
visualized
86. SCLERALBUCKLING SURGERY
INDICATIONS :
1. RRD (PVR less than C1)
2. Inferior retinal dialysis.
3. Retinal dialysis.
4.Pediatric RD
SEGMENTAL BUCKLING
Usually reserved for
** RRD < 1 clock hour
** Anterior breaks
87.
88. CONTRA-INDICATIONS :
1. Posterior breaks.
2. Opaque media.
3. Vaso-occlusive diseases.
4. PVR more than C2.
COMPLICATIONS :
1. Diplopia. (mc)
2.Perforation.
3. Rise in IOP.
4. Extrusion.
5. Infection.
6. AS ischemia.
89. 7. ERM
8. Recurrent RD.
9. Surgical failure : ‘FISH-MOUTHING’
Phenomenon of a tear, typically a large superior equatorial U-
tear in a bullous RD,
to open widely following scleral
buckling requiring further operative tt
90. PNEUMATIC RETINOPEXY
INDICATIONS :
1. A detachment caused by a single break, in superior 8 clock hours.
2. The break should not be more than 1clock hour.
3. Multiple breaks but in 1-2 clock hours of each other.
CONTRA-INDICATIONS :
1. Break > 1 clock hr.
2. Break inferior to 4 clock hr.
3. PVR grade C,D.
4. Cloudy ocular media.
5. Uncontrolled or severe glaucoma.
6. Can’t maintain Head position.
91. GAS EXPANSION NON-EXPANSIBLE
CONC
AVERAGE
DURATION
VOLUME
USED FOR PR
SF6 2 times 20 % 10-14 days 0.5 ml
C3F8 4 times 12% 30-45 days 0.35 ml
AIR Non expansile - 5-7 days 0.8 ml
SILICONE OILS :
-Lighter than water,
-Commonly used for : intraop retinal manipulation
prolonged postop intraocular tamponade.
-Particularly useful in PVR.
92.
93. DRAINAGE OF SUBRETINAL FLUID
In deep and long standing viscous SRF.
Complications : incarceration at drainage site ,
Retinal perforation,
Choroidal haemorrhage
95. LASER PHOTOCOAGULATION
Usually cannot seal RB if presence SRF may be used to
create barrier to prevent progression of RD
Esp. useful in
Chronic inferior RD
Systemic illness contraindicated to surgery
Laser
photocoagulation
Slit-lamp
biomicroscope with
contact lens
laser indirect
ophthalmoscope
(LIO)
96. Slit-lamp LIO
Indentation +
better magnified significant cataracts, PCO, mild VH more
easily treated with LIO
Safer in inexpertise
operator
Need more skill
Less need of corneal
care during laser
Less pain
not be readily
available
Any patient position
97. IMP**
Compared with diathermy and cryopexy
less breakdown of blood–ocular barrier.
thermal effect confined predominantly to retina and RPE
with little or no effect on choroid or sclera.
Induces adhesive effect between neurosensory retina &
RPE within 24hr.
98. CRYORETINOPEXY
RD with very shallow fluid can be cured by cryoretinopexy.
Test cryoprobe prior to use to make sure probe is freezing.
Freezing or whitening of RPE will noticed first,
Followed by delineation of edges of retinal tear
And whitening of retina
99. ** Excessive freezing or ice crystal formation should be avoided
Histologic response depends on whether
RPE alone or RPE and overlying detached retina together are
frozen
100. Disadvantage :
Dispersion of pigment epithelial cells, which can result in
subretinal pigmentary changes after reattachment.
Dispersion of viable pigment epithelial cells capable of
causing PVR following cryopexy.
Induce choroidal congestion & hyperemia (transient)
May complicate drainage of SRF through treated areas.
Breakdown of BRB cause post-op CME and ERD
103. Main causes of tractional RD
penetrating posterior segment
trauma
proliferative
retinopathy such as
diabetic and ROP
104. PATHOGENESIS OF DIABETIC TRACTIONAL RD
Caused by progressive contraction of
fibrovascular membranes over large areas of vitreoretinal
adhesion.
PVD in diabetic eyes is gradual and frequently incomplete.
RD is Caused by leakage of plasma constituents into the
vitreous gel from a fibrovascular network adherent to the
posterior vitreous surface.
In the very rare event of a subsequent complete PVD, the new
blood vessels are avulsed and RD does not develop.
105. Static vitreoretinal traction of the following three types is
recognized --
A Tangential traction
Caused by the contraction of
epiretinal fibrovascular membranes
with puckering of the retina and
distortion of retinal blood vessels.
106. B Anteroposterior traction is
Caused by the contraction of
fibrovascular membranes
extending from the posterior retina,
usually in association with the
major arcades, to the vitreous base
anteriorly
107. C Bridging (trampoline) traction
is the result of contraction of fibrovascular membranes
which stretch from one part of the posterior retina to
another or between the vascular arcades,
tending to pull the two involved points together.
108.
109. DIAGNOSIS
Symptoms : Photopsia and floaters are usually absent
Signs :
Concave configuration
breaks are absent.
Retinal mobility is severely reduced
shifting fluid is absent.
The SRF is shallower than in a RRD and seldom extends to the ora serrata.
Highest elevation of the retina at sites of vitreoretinal traction.
If a tractional RD develops a break it assumes the characteristics of a RRD
and progresses more quickly (combined TRD-RRD).
110.
111.
112. TREATMENT
GOAL : To release antero-posterior and/or circumferential
traction.
Simple peeling------------------NOT POSSIBLE(vascularity and
friable retina)
Methods of removing fibrovascular membranes in Diabetic TRDs.
DELAMINATION SEGMENTATION
(Vertical cutting) (horizontal cutting)
114. PATHOGENESIS
Characterized by the accumulation of SRF in the absence of
retinal breaks or traction.
As long as the RPE is able to compensate by pumping the
leaking fluid into the choroidal circulation,
no fluid accumulates in the subretinal space
RD does not occur.
However, when the normal RPE pump is overwhelmed, or if
the RPE activity is decreased,
then fluid starts to accumulate in the subretinal space.
115. ETIOLOGY
1 .Choroidal tumours
such as melanomas, haemangiomas and metastases; it is therefore very
important to consider that exudative RD is caused by an intraocular tumour
until proved otherwise.
2 .Inflammation such as Harada disease and posterior scleritis.
3 .Bullous central serous chorioretinopathy : rare
4 .Iatrogenic causes - RD surgery & PRP.
5. Subretinal neovascularization which may leak and give rise to extensive
subretinal accumulation of fluid at the posterior pole.
6. Hypertensive choroidopathy, as may occur in toxaemia of pregnancy:rare.
7. Idiopathic such as the uveal effusion syndrome.
118. DIAGNOSIS
Symptoms:-
**Photopsia is absent because there is no vitreoretinal traction,
although
floaters may be present if there is associated
vitritis.
Signs:-
Convex configuration, just like a RRD,
BUT
its surface is smooth and not corrugated.
119. The detached retina is very mobile and exhibits the phenomenon of
‘shifting fluid’
in which SRF responds to the force of gravity and detaches the area
of retina under which it accumulates.
(For example, in the upright position the SRF collects under the
inferior retina, but on assuming the supine position for several
minutes, the inferior retina flattens and the SRF shifts posteriorly
detaching the superior retina.)
The cause of the RD, such as a choroidal tumour, may be apparent
when the fundus is examined, or the patient may have an associated
systemic disease responsible for the RD (e.g. Harada disease,
toxaemia of pregnancy).
‘Leopard spots’ consisting of scattered areas of subretinal pigment
clumping may be seen after the detachment has flattened.
120.
121.
122. Leopard sign pigmentation following resolution of
exudative RD