Corneal Endothelium-Lecture 2.pptx

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Corneal Endothelium

Roy Joseph PhD MBA
School of Optometry and Vision Sciences

August 26th 2024
Schematic representation of the eye
Corneal epithelium
50 m,10% of total Five layers of cornea

Bowman’s
layer, 8-4 m

Stroma,
500 m,
90% of
total

Descemet’s
membrane,
10 m

Endothelium, 5 m
 Lamellae
Str
o ma

Descemet’s
membrane

Endothelium

Hexagonal
shape Endothelial
mosaic
Examples of Primary Endotheliopathies
Corneal guttata
Fuchs endothelial corneal dystrophy
Posterior polymorphous endothelial
dystrophy
Congenital hereditary endothelial dystrophy
Iridocorneal endothelial syndrome
Senile endothelial degeneration
 Endothelial Cell Function

Transport of nutrients from Maintenance of
aqueous into cornea cornea
deturgescence
Oxygen Glucose amino acids (maintains
(mainly from and vitamins corneal
tear film) Nutritional transparency)
transport
Paracellular Endothelium is leaky Factors for correct
route Na+/K+-ATPase hydration:
Apical surface retards
Tight zonular junctions
bulk flow from aqueous
Endothelial tight
to stroma
junctions
Pump-leak hypothesis
Na+/K+-ATPas (In epithelium
and endothelium)
 Corneal Endothelium
Pump-leak
hypothesis
Primary suggests that an Endothelium also
function: (1) To equilibrium is secrete an
maintain needed in the anteriorly located
corneal amount of passive basement
transparency fluid flow into the membrane called
by regulating cornea and energy Descemet’s
corneal expended pumping membrane and a
hydration and out excess fluid for posteriorly located
(2) nutrition maintenance of glycocalyx layer.
supply through corneal
a leaky barrier transparency and
and a relative dehydration
metabolic of corneal stroma.
pump function.
 Pump leak hypothesis
Two major
functions of the
endothelium are:
1. The ability to
permit transport of (Collagen, GAG and
nutrients from proteoglycans)
aqueous humor Na+,K+
into cornea. ATPase
Nutrients

2. Maintenance of
cornea in the Leaky
relative state of tight
Aqueous Water
junctions
deturgescence
needed to ensure
corneal
transparency.
 IS =
intercellular
space (20 nm)

65-year-old patient with healthy corneas Poerior corneal stroma, Descemet's
Tight
membrane, and corneal endothelium
Junctions from a 65-year-old patient
PS = posterior stroma. BDM = banded
Nucleus
portion of Descemet's membrane.
NBDM = non-banded portion of
Descemet's membrane. E = endothelial
cells
Figure 4.22 (A) Scanning electron micrograph (×1000) of the posterior surface of the corneal
endothelium from a 65-year-old patient with healthy corneas. Note how the hexagonal endothelial cells
form a uniform monolayer with small 20 nm intercellular spaces between adjacent endothelial cells. E
= endothelial cells. IS = intercellular space. (B) Transmission electron micrograph (×4750) of the
posterior corneal stroma, Descemet's membrane, and corneal endothelium from a 65-year-old patient
with healthy corneas. PS = posterior stroma. BDM = banded portion of Descemet's membrane. NBDM =
non-banded portion of Descemet's membrane. E = endothelial cells. IS = intercellular space. (C)
Immunofluorescent laser confocal microscopic photomicrograph (×2000) of human corneal endothelial
macula occludens tight junctional complexes stained with immunolabeled monoclonal antibodies to
junctional adhesion molecule-A (green). Nuclei are counterstained with TO-PRO (blue).
(Courtesy of Kenneth J. Mandell, MD, PhD.)
Specular Microscopy
 What specular microscopy reveals about
the patient's endothelium
Evaluate the corneal endothelium and be able to differentiate
between normal endothelial structure vs. abnormal
endothelial structure.
Identify the symptoms of moderate to advanced endothelial
disease, such as blurred vision, fluctuating vision, or
permanent visual impairment.
Explain the importance of endothelial cell density, and the
reasons why it may change.
Recognize the characteristics of different corneal
endotheliopathies using specular microscopy, including
corneal guttata, Fuch’s endothelial dystrophy, age-related
endotheliopathy, contact lens-induced endotheliopathy, and
others.
 6X increase

Entire posterior corneal
surface without gaps

Normal permeability of the human endothelial
cell monolayer to carboxyfluorescein.

Figure 4.23 (A) The normal barrier function of corneal endothelium is due to
endothelial cells covering the entire posterior corneal surface without gaps and
the focal, discontinuous tight junctions in its apical intercellular space. (B)
shows the normal permeability of the human endothelial cell monolayer to
carboxyfluorescein (2.26 × 10−4 cm/min) compared to that without endothelium
(12.85 × 10−4 cm/min), which resulted in a six-fold increase in permeability.
(Modified from Watsky MA et al. Exp Eye Res 1989; 49:751–67.)
 Corneal Endothelium
Morphology and
Ultrastructure
Single cell layer (5 m) with Polymegathism:
apical surface facing anterior Uniformity of cell size
chamber and basal surface to
Pleomorphism: Decrease
the Descemet’s membrane
in hexagons
Hexagonal (70-80%of all the
Cell density:
cells)
-At birth: 4000 cells/mm2, ---
Leaky tight junctions at cell
At 8-9th decade: 1000-2000
apex
cells/mm2
Cell numbers: At birth: total
Minimum cells required for
cells: 400,000, Density: 3500-
transplant: 400-700
4000/mm2,Thickness 4-6 m
cells/mm2
and Cell width: 20 m
 Endothelial Morphometry
Determination: Measure the area of apical
membranes of a population of cells and calculate the
coefficient of variance (CV) of cell size. Normal CV is
about 0.25. An increase means variable cell size and
cells are in distress.

Polymegathism : A decrease in hexagons (size) with
concomitant increase in number of cells with more or
fewer than six sides.
Cell size (Polymegathism) can vary significantly with no change in cell
density
 Cell Density of Corneal Endothelium Decreases with Age

At birth: 4000 cells/mm2
At 8th or 9th decade: 1000-2000 cells/mm2
Minimum number of cells needed for endothelial function: 400-700 cells/mm2
 Effect of penetrating keratoplasty (full thickness
corneal grafting) on endothelial cell density
Cell density at graft: 1000 cells/mm2 Cell loss continues for 6 months and then
cornea stabilizes Remodeling of cornea continues for 2 years

Normal
endothelium

Graft endothelium
 Effect of cataract surgery Effect of contact lens wear on
on endothelial cells endothelial cells

Pleomorphism: 46 year-old non-contact lens
wearer

Percent cell loss

46 year-old wore hard
contact lenses for 27 years.
Polymegathism

Pleomorphism: Decrease in hexagons;
Polymegathism: Uniformity of cell size
 Corneal
diameter

Nuclei/100 m length
 Inset showing data
using a uniform
scale

Nclei/100 m length
 Age-related Cell loss from
human corneal endothelium Increase in
cell loss

Limbal

Paracentral

Central

(B) Graph illustrating the central, paracentral, and peripheral corneal ECDs
for healthy, normal subjects of different ages.
(From Edelhauser HF. Cornea 2000; 19:263–73; and Edelhauser HF. Invest
Ophthalmol Vis Sci 2006; 47:1755–67.)
 Pump-Leak Hypothesis
1. Leaky barrier function (Tight
junctions)
2. Metabolic pump function (Na,K-
ATPase)
Two major
functions of the
endothelium are:
1. The ability to
permit transport of
nutrients from Na+,K+
aqueous humor ATPase
Nutrients
into cornea.

2. Maintenance of Leaky
cornea in the tight
Aqueous Water
junctions
relative state of
deturgescence
needed to ensure
corneal
transparency.
 Leaky Barrier (Tight Junctions) Function of
Endothelium
Macula occludens tight When endothelial cells
Barrier function is
junctions: Characterized by: are disrupted, the
dependent on:
1. Partial obliteration of corneal permeability
1. Sufficient
intercellular space and a increases 6X. When
number of cells.
partial retention of 10 central ECD decreases
2. Intact macula
nm wide intercellular below 2000 cells/mm2 the
occludens (tight
space. compensatory metabolic
junctions)
2. In healthy corneas: pump mechanism keeps
between The barrier prevents bulk the cornea at normal
endothelial cells
flow of fluid from dehydrated state until
resulting a low
aqueous humor to the central ECD of 500
electrical
corneal stroma, but cells/mm2
resistance to
allows moderate
aqueous humor
diffusion of small
flow.
nutrient, water and other
metabolites to cross into
stroma through 10 nm
wide intercellular space.
 Pump-Leak Hypothesis
Rate of leakage of water and solutes into corneal stroma
from aqueous

Balanced (via ion pumping by Na+,K+ATPase)

Rate of pumping of excess of water
from the stroma back to aqueous

Imbalance Corneal swelling

Na+,K+ATPase
Operates at constant Rate of leakage proportional to
rate pressure gradient across the
endothelium
(Self-adjusted homeostasis mechanism)
 When the leak rate
equals the
metabolic pump
rate, the corneal
stroma is 78
percent hydrated
and the corneal
thickness and
transparency is
maintained.

(C) The opposing forces of the leaky corneal endothelial barrier and the metabolic
pump sites are shown. When the leak rate equals the metabolic pump rate, the
corneal stroma is 78 percent hydrated and the corneal thickness and
transparency is maintained.
 Metabolic Pump Function
Transporters located at The Na+/K+ ATPase numbers are
basolateral membrane, quantified by using [+H]-oubain, which
and transport ions (Na+ binds at 1:1 ratio with pump.
and HCO3-) out of 3X106 pump sites/single endothelial
stroma to aqueous. cells. This corresponds to 4.4 trillion
sites /mm2 of an intact endothelial cells.

An osmotic gradient is
Factors that alter endothelial pump function:
created and water is
1. Pharmacological inhibition of Na+/K+ ATPase,
osmotically drawn from
2. Decreased temperature.
stroma into aqueous
3. Lack of HCO3-, carbonic anhydrase inhibitors.
humor
4. Chronic reduction of ECD from mechanical
injury or disease state
Osmotic gradient Compensatory mechanism
can be maintained At ECD between 2000 and 750
only if endothelial cells/mm2: Increase in the activity of At ECD
barrier is maintained. pump sites with more ATP production 750cells/mm2:
and/or increasing the total number Compensatory
and density of pump sites on lateral mechanism fails
membrane.
 Oubain
A crystalline glycoside derived from the
seeds of Strophanthius gratus and the
wood of Acocanthera oubaio.
It blocks Na+,K+-ATPase activity and
often used for pharmacological studies
because of its greater solubility in
water.
It is also used as an arrow poison in
Africa.
 Retardation of Bulk Flow of water from
aqueous through Endothelium

Resistance to bulk flow

Gap junctions
Tight junctions
(Secondary, act as selective
(primary) filters)

Normal: 25-40 nm
Corneal endothelium: 3 nm
10-20 nm
intercellular space Gap junctions act as
selective barrier
 Retardation of bulk flow via endothelium (continued)

Molecular
Junctions at Larger than tracer
apical membrane epithelial (Peroxidase,
junctions Mr=60,000 D)
Obliterate and integrity
extracellular space of epithelial
junctions is Leaks
greater around tight
junctions
Main function: Retards
bulk flow of water
Enters inter-
across endothelium Resistance
cellular spaces
Endothelial junctions: 73±6
Ohms/cm2
Epithelial junctions: 1.6-9.1
k/cm2 (>1246X greater)
 Nutritional transport occurs via paracellular route,
i.e. solutes move between cells rather than being
actively transported through them.

 This type of transport requires that endothelium be
leaky to substances within aqueous humor.
Eye bank media to preserve human
donor corneas
Changes in corneal thickness of rabbit corneas during
perfusion
Rapid swelling

Low pH

Glutathione, bicarbonate
Ringer’s (GBR) solution
(Resembles aqueous
humor)
Maintenance of corneal thickness requires an intact barrier and metabolic pump

Inhibits Na,K
ATPase

Inhibits carbonic
anhydrase