Posterior chamber

Question 1

What is the volume of the posterior chamber?

Answer 1

0.06ml

Question 2

What are the boundaries of the posterior chamber?

Answer 2

Anterior: heavily pigmented posterior iris
Peripherally: ciliary body
Posteriorly: lens and zonules

Question 3

Why is the sulcus between the iris and ciliary body significant?

Answer 3

Useful for putting lens in cataract surgery if there are issues putting it in the capsule

Question 4

What are the two sections of the ciliary body?

Answer 4

Anterior, Pars plicata: contains ciliary processes, 2mm, 60-80 ciliary processes
Posterior, Pars plana: avascular, good for injections, 4mm length

Question 5

Describe the shape of the lens

Answer 5

Biconvex transparent structure
Thin outer capsule
Medium dense cortex
Firm inner hard nucleus

Question 6

What is the ciliary body?

Answer 6

A ring of tissue in the anterior segment of the eye

Forms middle part of uveal tract

Question 7

What is the uveal tract?

Answer 7

Vascular, pigmented, middle layer of the eye
Formed by choroid, ciliary body and iris
Brings most of the nutrients to the eye and absorbs light

Question 8

What is the shape of the ciliary body?

Answer 8

In 3D is a ring

In cross section, triangle at iris root and apex at ora serrata

Question 9

How big is the ciliary body?

Answer 9

6mm in length

Runs from 1.5mm posterior to corneal limbus to 7.5-8mm posterior to this temporally and 6.5-7mm nasally

Question 10

What is the ciliary body continuous with?

Answer 10

Iris anteriorly
Choroid posteriorly (scalloped to fit into tooth like edge of ora serrata)

Question 11

What are the relations of the ciliary body?

Answer 11

External: 1.5mm posterior to corneal limbus

Internal: anteriorly: anteriorchamber, iridocorneal angle and scleral spur
Medial: posterior chamber and zonular ligaments
Zonules attach to surface of pars plicata
Equator of the lens is 0.5mm from ciliary processes
Posterior: vitreous

Question 12

What are the histological layers of the ciliary body?

Answer 12

Ciliary epithelium
ciliary stroma
Ciliary muscles
Supraciliaris

Question 13

What are the two layers of the ciliary epithelium?

Answer 13

Non pigmented layer

Pigmented layer

Question 14

Describe the non pigmented layer of the ciliary epithelium

Answer 14

Continuous with pigmented posterior epithelium of iris
Anterior continuation of neural retina
Continues anteriorly to line anterior chamber
Basement membrane faces posterior chamber
Junctions between cells represent primary blood aqueous barrier in ciliary body (from zonular occuldens and adherens)
Extensive foldings-interdigitate neighbouring cells
Well developed golgi apparatus, many mitochondria and extensive endoplasmic reticulum

Question 15

Describe the pigmented layer of the ciliary epithelium

Answer 15

Anterior continuation of retinal pigment epithelium
Continuous with anterior epithelium of the iris
Basement membrane faces ciliary stroma
Packed with melanosomes
Small golgi apparatus, many mitochondria
Basal lamina infolded suggesting ion transport

Question 16

How are the non pigmented and pigmented layers of the ciliary epithelium similar?

Answer 16

Both layers make aqueous
2 layers may be coordinated
Both cubical cells

Question 17

Describe the ciliary stroma

Answer 17

Loose connective tissue
Rich in blood vessels and melanocytes
Contains ciliary muscle
Core of ciliary process

Question 18

What type of muscle is the ciliary muscle? What are the 3 main groups?

Answer 18

Smooth muscle
Longitudinal: major, most external, closest to sclera, inserts into scleral spur
Oblique/radial: runs from first to 3rd layer, radiate out from scleral spur
Circular: most internal, like a sphincter, close to peripheral edge of the lens

Question 19

What is supraciliaris?

Answer 19

Pigemented collagen, containing fibroblasts and melanocytes

Question 20

What is the blood supply to the ciliary body?

Answer 20

Ophthalmic artery
2 long posterior ciliary arteries pierce sclera near optic nerve, go anteriorly between sclera and choroid at peripheral edge of the iris, forms major arterial circle (with 7 anterior ciliary arteries)
Venous drainage: via vortex veins (mainly) and anterior ciliary veins
Capillaries near ciliary epithelium are fenestrated

Question 21

What is the parasympathetic nerve supply to the ciliary body?

Answer 21

Parasympathetic: supplies ciliary muscle
Preganglionic neurons in Edinger-Westphal nulear, axons travel via occulomotor nerve to synapse in ciliary ganglion
Post ganglionic parasympathetic fibres pass forward in the short ciliary nerves (6-10)

Question 22

What is the sympathetic nerve supply to the ciliary body?

Answer 22

Vasomotor supply to blood vessels
Preganglionic neurones synapse in superior cervical ganglion, postganglionic travel via nasociliary nerve/ long ciliary nerves
Some pass the ciliary ganglion and pass forward in short ciliary nerves (2-3)

Question 23

What is the sensory supply to the ciliary body?

Answer 23

Function unknown

From nasociliary nerve via long and short ciliary nerves

Question 24

What are the functions of the ciliary body?

Answer 24

Aqueous production: actively produced in ciliary epithelium

Accomodation: contraction of ciliary muscle causes ciliary rings to decrease in diameter, ciliary body moves forward, tension decreases on zonules, lens becomes more convex-> increased power-> accomodation

Production and maintenance of zonular ligaments (by non pigmented epithelium)

Question 25

Which two embryological tissues form the ciliary body?

Answer 25

Neuroectoderm: forms 2 layers of epithelium covering the ciliary body

Mesenchyme: on edge of optic cup differentiates into connective tissue of ciliary body, SM of ciliary body and suspensory ligaments

Question 26

When does the ciliary body reach its adult dimensions?

Answer 26

7 years old
Linear relation between ciliary body and axial length of the eye
Pars plana and sclerotomy site will vary with age

Question 27

Why do the iris, ciliary body and anterior choroid get inflamed together?

Answer 27

Share a common blood supply

Called uveitis

Question 28

When can the position of the ciliary body lead to glaucoma?

Answer 28

Plateau iris

Question 29

What are the two key risks of trauma to the anterior chamber in relation to the ciliary body?

Answer 29

Angle recession: split between layers of ciliary muscle

Cylodialysis: split between sclera and ciliary body

Question 30

Which embryological tissue does the lens develop from?

Answer 30

Ectoderm thickens into lens placode, then invaginates into lens pit
Cells in posterior end of lens pit lengthen to form primary fibre cells

Question 31

How does the embryological lens differentiate into primary fibres and epithelium?

Answer 31

The primary fibre cells elongate and a space forms between them and the overlying lens epithelium

Question 32

Why does the lens grow throughout life?

Answer 32

Only the epithelium of the lens divides (just above the equator)
Epithelial cells which shift below the equator differentiate into secondary fibre cells which pile up throughout your life

Question 33

How are the fibres within the lens arranged?

Answer 33

Very regularly

Question 34

What shape do the apical fibres meeting at the anterior pole of the embryological lens make?

Answer 34

Y shaped sutures

Start out with Y shaped sutures then become more complex as lens grow

Question 35

How does lens develop polarity and growth patterns?

Answer 35

Relationship of lens to optic cup
Vitreous promotes fibre differentation
Aqueous promotes proliferation of epithelial phenotype
Confirmed by lens inversion experiment 1963

Question 36

Describe the 1963 lens inversion experiment

Answer 36

They took a chicken lens and inverted it so the epithelial cells face the retina and the original epithelial cells differentiates into a new mass of fibre cells

Question 37

Which hormone present in the vitreous induces fibre differentiation?

Answer 37

FGF

Question 38

Describe the epithelial cells in the lens capsule?

Answer 38

Mitotic figures present
Cobblestone pattern
Below lens equator cells begin elongating and pack very regularly

Question 39

Describe the fibre cells of the lens

Answer 39

Very aligned tram line arrangement
In transverse section: individual fibres hexagonal (2 large 4 short faces) and interlocked
From corners of fibre cells membrane protrusions interlock
NO ECM

Question 40

How do the fibre cells of the lens pack in with no ECM and how does this reduce light scatter?

Answer 40

The membrane protrusions out of each short face link

Plus the hexagonal shape allows them to stack together, reducing intercellular space and reducing light scatter.

Question 41

Which plasma membrane complexes are contained in the long face of the fibre cells of the lens?

Answer 41

Periplakin, periaxin, ezrin, desmoyokin

Question 42

Which plasma membrane complexes are contained in the short face of the fibre cells of the lens?

Answer 42

N- cadherin and cedherin-11

Question 43

What are the main cytoskeleton components of lens fibres?

Answer 43

Microtubules (tubulin)- which run along entire length of fibre
Microfiliaments (actin)- accumaltes at the corners but also runs entire length of the fibre
Intermediate filaments (filensin/phakinin)- run entire length of fibre

Question 44

How do fibres change as they move further towards the lens nucleus?

Answer 44

They initially have nuclei and organelles but these are lost towards the centre as they interfere with transparency

Question 45

What is the embryological origin of the lens nucleus fibres?

Answer 45

Primary fibres which appear during embryological development

Question 46

Which two factors enable the lens to remain transparent?

Answer 46

Lens fibre cells must have regular packing and remain very organised

Lens proteins are 90% crystallins which do not form aggregates. Aggregation is associated with cataract

Question 47

What are the three types of crystallin (lens protein)

Answer 47

Alpha- first crystallin to be detected. Produced by epithelial cells and fibre cells

Beta-only in fibre cells. Appears second.

Gamma- only in fibre cells. Last crystallin to be detected

Question 48

How does the iris develop?

Answer 48

Optic cup rim does not form neuroretina or retinal pigment epithelium
Becomes epithelial layers of iris and ciliary body
Migrating mesenchymal neural crest cells become associated with the 2 epithelial layers of the rip of the optic cup. Becomes stroma of iris and ciliary body.

Question 49

How does aqueous flow from the pars plicata of the ciliary body into the anterior chamber?

Answer 49

Travels between iris and the lens

Question 50

What are the components of the iris in crossection?

Answer 50

Anterior border layer/ stroma: nil epithelium (direct communication between aqueous and iris stroma)

Iris sphincter/ sphincter papillae

Iris dilator/anterior epithelium

Posterior pigment epithelium

Question 51

What are the two layers of the iris epithelium?

Answer 51

Anterior epithelium and dilator muscle

Posterior pigmented epithelium

Question 52

How does the iris change the size of the pupil?

Answer 52

When sphincter/constrictor contracts-> pupil constricts

Contraction of dilator muscle-> pupil dilates

Question 53

How big is the iris?

Answer 53

12mm diameter

Question 54

What are the 3 functions of the iris?

Answer 54

Control of retinal illumination
Reduce optical aberrations
Increase depth of field and focus

Question 55

What are the two different segments of the anterior surface of the iris?

Answer 55

Pupillary zone
Split by collarette
Ciliary zone (contains contraction furrows)

Question 56

What is the pupillary rough?

Answer 56

At the pupillary margin, the posterior pigmented epithelium of the iris sits, forming a dark ring. If this extends too anterior-> ectropion uveae

Question 57

How do radial streaks of the iris change with pupillary dilation?

Answer 57

Wavy when dilated

Straight when constricted

Question 58

What are the radial streaks made of?

Answer 58

Trabeculae of connective tissue which overlay oval holes called Fuch’s crypts

Question 59

Describe the arterial blood supply to the iris

Answer 59

2 circumferential circles
Peripherally located major arterial circle: formed by anastomosis of 2 long posterior ciliary arteries and 7 anterior ciliary arteries. Located in stroma of ciliary body.

Incomplete minor arterial circle: formed by radial arteries which come from the major arterial circle. Located at in the collarette.

Question 60

Describe the venous drainage of the iris

Answer 60

Follows arteries

Minor venous circle at collarette, drains into radial veins in centrifugal arrangement towards vortex veins

Question 61

What is significant about iris capillaries?

Answer 61

Form an integral part of blood aqueous barrier as have non fenestrated epithelium and tight junctions

Question 62

What is the nerve supply of the iris?

Answer 62

Sensory and autonomic
Long ciliary nerves derived from nasociliary branch of ophthalmic division of trigeminal nerve. Contains sensory fibres and sympathetic fibres from superior cervical ganglion which innervates dilator pupillae and iris vessels.

Parasympathetic supply from Edinger-Westphal nucleus, synapses at ciliary ganglion before travelling via short ciliary nerve to sphincter pupillae

Question 63

Where is the sphincter papillae of the iris?

Answer 63

Posterior iris stroma in the central pupillary zone

Anterior to posterior pigmented epithelium

Question 64

What are the 3 stages of iris sphincter development?

Answer 64

1. Initial anterior epithelial layer near pupillary margin
2. Division of epithelial cells into spindle shaped protoplasmic elements, forming a mass in pupillary margin
3. Differentiation of spindle shaped cells into myoblasts which form mature sphincter muscle

Question 65

What is the arterial supply to the iris sphincter?

Answer 65

Via the major and minor arterial circles

Question 66

What do the parasympathetic short ciliary nerves supply?

Answer 66

97% to ciliary body

3% anticholingeric to iris sphincter, causing contraction of the pupil

Question 67

What is Adie’s tonic pupil?

Answer 67

Pupil unresponsive to light, slow to contract in light and slow to dilate in the dark. Caused by disorder of parasympathetic innervation of iris sphincter muscle
Benign but must be distinguished from Argyl robertson. Can be confirmed by hypersensitivity to cholinergic agents (will constrict when 0.1% pilocarpine is put in the eye)

Question 68

What is the different between Argyl Robertson pupil and Adie’s tonic pupil?

Answer 68

Argyl Robertson: small pupil, no reaction to light but contracts with accomodation. Pupil WILL NOT constrict with cholinergic agent. Caused by neurosyphilitic lesion interrupting fibres from pretectal nucleus to parasympathetic nuclei

Adies: Sluggish pupil, no reaction to light will slowly contract with accomodation. Pupil will constrict with cholingeric agent.

Question 69

What is the most significant gene for eye morphogenesis?

Answer 69

Pax6

Question 70

Which hormones regulate the elongation of primary lens fibres in the embryonic lens?

Answer 70

BMP and FGF

Question 71

How do the Y sutures formed by secondary lens fibre development differ based on polarity and what controls this process?

Answer 71

IGF and FGF
Anteriorly : upright Y suture
Posteriorly: upside down Y suture

Question 72

What significant event occurs in week 9 gestation for the lens?

Answer 72

Distal hyoid artery forms tunical vasculosa lentis
AKA posterior vascular capsule. This anastomoses with choroidal veins to form capsulopupillary membrane
Nourishes lens until aqueous takes over. This network of vessels atrophies from 4 months onwards and has completely disappeared by birth

Question 73

What are the dimensions of the lens?

Answer 73

Unaccommodated
10MM Equatorially
4MM AP diameter

Question 74

What separates the lens from the vitreous humour posteriorly?

Answer 74

Hyaloid capsule called Wieger’s ligament and retrolental/Berger’s potential space

Question 75

What is significant about the lens epithelium?

Answer 75

Cuboidal
Contains Na/K+ ATPAse pumps which are involved in homeostasis of lens with aqueous humour
Also have pre-equatorial epithelial cells which are porgenitors for new lens fibres

Question 76

How does the thickness of the lens capsule vary?

Answer 76

Thickest near the equator and thinnest posteriorly

Question 77

What are the zonules?

Answer 77

Bundles of microfibrils
Originate from non pigmented epithelium of pars plana and insert onto equatorial region of lens capsule
Facilitates accommodation and suspends lens in position

Question 78

What is the neurovascular supply of the lens?

Answer 78

None
Supplied by aqueous humour
Dependent on Na/K ATPase

Question 79

What is the triad of acccomodation?

Answer 79

Convergence
Miosis
Accomodation

Question 80

What is Helmholz theory?

Answer 80

Unaccomodated eye: ciliary muscle relaxed, zonular fibres under tension which stretches the lens and makes it less convex, decreasing optic power

Accommodated eye- construction of ciliary muscle relaxes zonular fibres, makes lens more spherical and increases optic power

Question 81

How does the lens protect the retina from UV light?

Answer 81

Blocks UV 300-400nm long

Cornea blocks shorter wave lengths

Question 82

What are the main causes of presbyopia?

Answer 82

Increased thickness + reduced elasticity of lens capsule
Stiffening and reduced pliability of central lens
Increasing equatorial lens diameter moves lens closer to ciliary body (decreasing potential change in zonular tension)
Loss of smooth muscle cells in ciliary body

Question 83

How do the 3 main types of age related cataracts differ?

Answer 83

Cortical: disrupted homeostasis and damage of lens epithelial cells causes water accumulation between lens fibres

Nuclear: reduced a-crystallin causes protein aggregation and oxidation of nuclear lens fibres

Posterior subcapsular: abnormal posterior suture formation or differentiation of lens fibres

Question 84

Why does the lens stiffen with age?

Answer 84

During life, epithelial cells differentiate and become lens fibre cells
Mature cells have no organelles packed with proteins
Cells added onto preexisting lens
As new lens fibre cells are added, lens becomes stiffer (1000x over life)

Question 85

What causes age related nuclear cataract?

Answer 85

Oxidation and colouration of proteins in the lens centre
These proteins display highest degree of oxidation of any biological tissue
90% of protein sulfhydrl are lost in advanced ARN cataract. Susceptible to irreversible damage by oxidation

Question 86

How does methionine in the lens change with oxidation/ cataract development?

Answer 86

Methionine becomes methionine sulphoxide when oxides

Increased methionine sulphoxide as a catarct develops

Question 87

What causes lens oxidation?

Answer 87

GSH/glutathione (body’s main antioxidant) made in cortex (has to pass via gap junction to nucleus)
Found in higher concentration in cortex than nucleus in normal lens
In cataract: GSH zero in nucleus, normal in cortex
Barrier to diffusion develops in middle age so GSH cant flow from for cortex to nucleus

Question 88

What causes the barrier to diffusion between the cortex and nucleus of the lens?

Answer 88

Protein breakdown
Denatured proteins and clog pores
Instrinsically unstable proteins
a-crystallin acts to bind denatured proteins
However by age 40 a-crystallin is used up

Question 89

How does the sucrose gradient protocol prove that with increased age there is increased protein binding to membranes and blocking pores in the old lens?

Answer 89

Concentration of soluble and membrane proteins are lower in older eye, particularly in the inner and core segments. Extra couple of bands at the bottom correspond with denatured protein that is bound to the membranes, increasing from outer to core

Question 90

At what age does the lens start being full of denatured proteins blocking the entry of GSH into the lens core?

Answer 90

Between 40 and 50

Question 91

How does heat effect the sucrose gradient?

Answer 91

Increasing the temperature from 4 to 50 degrees changes and eye from young to old
(because temperature denatures proteins)

Question 92

What causes age related protein denaturation?

Answer 92

Heat
Deamindation (removal of amide functional group)
Racimisation (conversion from one enantiomer to another)
Truncation

Question 93

Why don’t we see violet or UV light?

Answer 93

Lens fliters this UV light
Made in lens by tryptophan (amino acid)
300-400 UV light band most important as this is believed to cause photooxidation of the retina

Question 94

What determines the colour of the iris?

Answer 94

Pigment in the melanocytes

Blue has less pigment in melanocytes compared to brown iris