EYE & EAR

1. EYE & EAR This resource is licensed under the Creative Commons Attribution Non-Commercial & No Derivative Works License

2. Objectives Recognise and describe a section of neural retina, identifying areas of histogenesis with lamination/stratification and the adjacent choroid and scleral layers. Recognise and describe a section of cornea, distinguishing areas of limbus-like character, as well as Descemet’s and Bowman’s membranes. Be able to describe and recognise various stages in the development of optic vesicles, the differentiation of the optic cup, lens and adjacent structures, including : developing ciliary body and anterior and posterior chambers of the eye. Distinguish between otic vesicles at various stages of their development and their spatial relationship with portions of the pharynx and developing cochlea in histological section.

3. SLIDE 200 Retina dog Examine this section at low magnification and identify : Cornea. 5. Non- neural retina. 9. Anterior chamber. Iris. 6. Neural retina. 10. Posterior chamber. Ciliary apparatus. 7. Choroid. 11. Cavity of vitreous humor. Corneal limbus. 8. Sclera. 1.0 mm

4. SLIDE 200 Retina dog 2 Examine this section at low magnification and identify : Cornea. 5. Non- neural retina. 9. Anterior chamber. Iris. 6. Neural retina. 10. Posterior chamber. Ciliary apparatus. 7. Choroid. 11. Cavity of vitreous humor. Corneal limbus. 8. Sclera. 11 6 3 10 5 9 1 4 7 8 1.0 mm

5. SLIDE 200 Retina dog 2 Examine this section at low magnification and identify : Cornea. 5. Non- neural retina. 9. Anterior chamber. Iris. 6. Neural retina. 10. Posterior chamber. Ciliary apparatus. 7. Choroid. 11. Cavity of vitreous humor. Corneal limbus. 8. Sclera. 11 6 3 10 5 9 1 4 7 8 1.0 mm

6. SLIDE 200 Cornea dog Identify : Cornea. 4. Anterior chamber. Iris. 5. Posterior chamber. Corneal limbus. External eye – Dog ▪ Left eye. Note pigmented epidermis of eyelids. ▪ Identify : Medial canthus Lateral canthus 3rd eyelid Cornea Iris Pupil 250 µm

7. SLIDE 200 Cornea dog posterior chamber iris Identify : Cornea. 4. Anterior chamber. Iris. 5. Posterior chamber. Corneal limbus. corneal limbus anterior chamber cornea 250 µm

8. SLIDE 200 Cornea dog Examine the cornea at higher magnification. The function of the cornea is ……. 100 µm

9. SLIDE 200 Cornea dog Examine the cornea at higher magnification. The function of the cornea is ……. The cornea has an important role in image formation, it forms a primary refractive element in the eye. anterior posterior 100 µm

10. Five layers can be identified in the cornea : 1. anterior epithelium 2. anterior sub-epithelial membrane (lamina) 3. stroma 4. posterior limiting membrane (Descemet’s) 5. posterior epithelium (corneal endothelium) SLIDE 200 Cornea dog 100 µm

11. Five layers can be identified in the cornea : 1. anterior epithelium 2. anterior sub-epithelial membrane (lamina) 3. stroma 4. posterior limiting membrane (Descemet’s) 5. posterior epithelium (corneal endothelium) SLIDE 200 Cornea dog anterior epithelium posterior epithelium stroma posterior limiting lamina Descemet’s anterior lamina 100 µm

12. SLIDE 200 Cornea dog Identify : Anterior epithelium and anterior sub-epithelial basement membrane. What type of epithelium covers this surface? 25 µm

13. Identify : Anterior epithelium and anterior sub-epithelial basement membrane. What type of epithelium covers this surface? Non-keratinised stratified squamous epithelium. SLIDE 200 Cornea dog anterior epithelium Identify : Anterior epithelium and anterior sub-epithelial basement membrane. What type of epithelium covers this surface? stroma sub-epithelial basement membrane 25 µm

14. Identify : Anterior epithelium and anterior sub-epithelial basement membrane. What type of epithelium covers this surface? Non-keratinised stratified squamous epithelium. Consider the cellularity and the extent of the extracellular matrix in these compartments and the cornea ‘proper’. SLIDE 200 Cornea dog anterior epithelium Identify : Anterior epithelium and anterior sub-epithelial basement membrane. What type of epithelium covers this surface? stroma sub-epithelial basement membrane 25 µm

15. SLIDE 200 Cornea dog Identify : Posterior epithelium (corneal endothelium) and posterior limiting membrane (Descemet’s membrane). What type of epithelium covers this surface? 25 µm

16. Identify : Posterior epithelium (corneal endothelium) and posterior limiting membrane (Descemet’s membrane). What type of epithelium covers this surface? Simple squamous epithelium. Note the lack of vasculature in the cornea. SLIDE 200 Cornea dog Descemet’s membrane Identify : Posterior epithelium (corneal endothelium) and posterior limiting membrane (Descemet’s membrane). What type of epithelium covers this surface? stroma posterior epithelium or corneal endothelium 25 µm

17. SLIDE 200 Cornea dog posterior chamber iris What is the corneal limbus? corneal limbus anterior chamber corneal stroma 250 µm

18. What is the corneal limbus? The corneo-scleral junction. Here the collagen fibres of the corneal stroma become irregular and blood vessels supplying nutrients to the cornea are seen. The anterior epithelium becomes the conjunctival epithelium. SLIDE 200 Cornea dog posterior chamber posterior chamber sclera iris iris What is the corneal limbus? corneal limbus corneal limbus anterior chamber anterior chamber conjunctival epithelium posterior epithelium corneal stroma corneal stroma anterior epithelium 250 µm

19. SLIDE 200 Iris dog posterior chamber iris The iris is the most anterior part of the vascular tunic (uvea) a continuation of the choroid layer. corneal limbus anterior chamber cornea 250 µm

20. SLIDE 200 Iris dog posterior chamber iris The iris is the most anterior part of the vascular tunic (uvea) a continuation of the choroid layer. corneal limbus anterior chamber cornea 250 µm

21. SLIDE 200 Iris dog Examine the iris at higher magnification. 50 µm

22. SLIDE 200 Iris dog posterior chamber pars iridica retinae myoepithelial cells The iris at higher magnification. connective tissue stroma BV BV : blood vessels BV M M : melanocytes anterior surface of iris sphincter muscle anterior chamber 50 µm

23. Through examination observe whether different areas of the retina exhibits neural (thicker) and non neural (thinner) organisation approaching the iris. SLIDE 200 Retina dog 100 µm

24. Through examination observe whether different areas of the retina exhibits neural (thicker) and non neural (thinner) organisation approaching the iris. SLIDE 200 Retina dog towards iris close to edge of neural retina non-neural retina edge of neural retina neural retina 100 µm

25. This non neural portion of the retina approaching the iris consists of two layers of non-light sensitive epithelium. This epithelium is continuous with that covering the ciliary body and iris. SLIDE 200 Retina dog 50 µm

26. This non neural portion of the retina approaching the iris consists of two layers of non-light sensitive epithelium. This epithelium is continuous with that covering the ciliary body and iris. SLIDE 200 Retina dog epithelium of non-neural retina choroid 50 µm

27. This area shows the sudden increase in thickness of the retina as it becomes the neural retina. The junction is called the ora ciliaris retinae. SLIDE 200 Retina dog 50 µm

28. This area shows the sudden increase in thickness of the retina as it becomes the neural retina. The junction is called the ora ciliaris retinae (arrowed). SLIDE 200 Retina dog retina choroid sclera space artefact 50 µm

29. A comparison of the neural retina close to the periphery (left) and at its full thickness (right). Larger blood vessels may be seen in the nerve ganglion cell layer towards the edge of the retina. The individual layers are more easily recognised (right). Note the much thicker layer of rods and cones. SLIDE 200 Retina dog 50 µm

30. A comparison of the neural retina close to the periphery (left) and at its full thickness (right). Larger blood vessels may be seen in the nerve ganglion cell layer towards the edge of the retina. The individual layers are more easily recognised (right). Note the much thicker layer of rods and cones. SLIDE 200 Retina dog BV : blood vessel BV layer of rods & cones choroid sclera 50 µm

31. Examine the neural retina in more detail Observe a full depth portion of this area and identify the different zones. SLIDE 200 Retina dog • Inner limiting membrane. • Nerve fibre layer. • Ganglion cell layer. • Inner plexiform layer. • Inner nuclear layer. • Outer plexiform layer. • Outer nuclear layer. • Outer limiting membrane. • Layer of rods and cones. • Pigmented epithelium. • Choroid layer. • Scleral layer. 50 µm

32. Examine the neural retina in more detail Observe a full depth portion of this area and identify the different zones. SLIDE 200 Retina dog 1 2 3 4 • Inner limiting membrane. • Nerve fibre layer. • Ganglion cell layer. • Inner plexiform layer. • Inner nuclear layer. • Outer plexiform layer. • Outer nuclear layer. • Outer limiting membrane. • Layer of rods and cones. • Pigmented epithelium. • Choroid layer. • Scleral layer. 5 6 7 8 9 10 11 12 50 µm

33. SLIDE 11 Developing head coronal section at level of diencephalon and developing eyes. Identify at low magnification : Oral cavity. Tongue. Developing eyes. Developing nasal cavity. Mandible. Other bones of skull. Developing enamel organs. Developing brain. Eye-lids. 1.0 mm

34. SLIDE 11 Developing head coronal section at level of diencephalon and developing eyes. 8 6 6 9 4 3 Identify at low magnification : Oral cavity. Tongue. Developing eyes. Developing nasal cavity. Mandible. Other bones of skull. Developing enamel organs. Developing brain. Eye-lids. 3 9 1 7 7 2 5 5 1.0 mm

35. SLIDE 11 Developing headcoronal section at level of diencephalon and developing eyes. Identify : 1. Lens. 2. Cornea. 3. Iris. 4. Developing retinal layers. 5. Ciliary body. 6. Eye-lid. 7. Anterior chamber. 8. Vitreous humor. 9. Optic nerve, (may not be visible in all sections). Identify the main regions of the eye. Care should be taken to distinguish between eye chambers and ‘space artefacts’. 250 µm

36. SLIDE 11 Developing headcoronal section at level of diencephalon and developing eyes. Identify : 1. Lens. 2. Cornea. 3. Iris. 4. Developing retinal layers. 5. Ciliary body. 6. Eye-lid. 7. Anterior chamber. 8. Vitreous humor. 9. Optic nerve, (may not be visible in all sections). 6 A 3* 2 Identify the main regions of the eye. Care should be taken to distinguish between eye chambers and ‘space artefacts’. 1 8 7 9 5* 4 A 6 A : space artefacts * Unclear due to distortion of tissue during fixation. 250 µm

37. SLIDE 11 Developing headcoronal section at level of diencephalon and developing eyes. At a higher magnification identify: Equator of developing lens. 4. Developing retina. Lens anterior surface epithelium. 5. Cornea. Optic nerve (may not be visible on all sections). 100 µm

38. SLIDE 11 Developing headcoronal section at level of diencephalon and developing eyes. E : equator of lens developing retina A At a higher magnification identify: Equator of developing lens. 4. Developing retina. Lens anterior surface epithelium. 5. Cornea. Optic nerve (may not be visible on all sections). anterior epithelium of lens E optic nerve cornea A : space artefacts A 100 µm

39. SLIDE 11 Developing headcoronal section at level of diencephalon and developing eyes. How is the diameter of the lens controlled? 100 µm

40. SLIDE 11 Developing headcoronal section at level of diencephalon and developing eyes. cornea lens capsule cuboidal lens epithelium How is the diameter of the lens controlled? By the contraction and relaxation of the ciliary muscle. proliferating cells at equator of lens distortion due to fixation; developing iris and ciliary body displaced developing retina artefact 100 µm

41. SLIDE 11 Developing headcoronal section at level of diencephalon and developing eyes. The surrounding lens capsule is composed of basal lamina and collagen fibres. The cuboidal epithelial cells on the anterior surface have their bases facing the lens capsule and their apices facing the lens fibres. At the equator of the lens the cells elongate and differentiate into lens fibres forming the body of the lens. These run in an anterior-posterior direction. The fully differentiated fibres are hexagonal in cross section and have lost their nucleus and most cell organelles. At high magnification identify: note the spatial differentiation of the lens fibre cells. 50 µm

42. Demonstration slides with green labelsThis set of slides is available during classes from the front bench in the teaching lab (or by request).These slides are serial sections through the the head region of developing embryos.They show stages in the early development of the eye and the ear.In the set can be found :1. Very early stage in development of the eye.2. Slightly later stage of eye development.3. Very early stage in development of ear.4. Slightly later stage in ear development.Remember; if you look at the slides, you will need to search for the section which shows best either the eye or ear. Try also to recognise some of the other developing structures sectioned.

43. SLIDE (green label) Early stage of developing eye In the early embryo, the eyes are first seen as diverticulae developing laterally from the diencephalon. In this section only the optic diverticulum on the right side can be seen. These specimens are often cut at an oblique angle, so the eye on one side will appear before its partner. At this stage of development, the prominent flexure of the head region can result in the section going through both hind-brain and fore- brain (and sometimes the spinal cord). 250 µm

44. SLIDE (green label) Early stage of developing eye spinal cord diencephalon diocoel* In the early embryo, the eyes are first seen as diverticulae developing laterally from the diencephalon. In this section only the optic diverticulum on the right side can be seen. These specimens are often cut at an oblique angle, so the eye on one side will appear before its partner. At this stage of development, the prominent flexure of the head region can result in the section going through both hind-brain and fore- brain (and sometimes the spinal cord). developing optic vesicle pharyngeal pouch * diocoel ═ lumen of diencephalon 250 µm

45. SLIDE (green label) Early stage of developing eye A few sections along on the same slide and both developing optic vesicles can be seen. 250 µm

46. SLIDE (green label) Early stage of developing eye diencephalon optic vesicle optic vesicle A few sections along on the same slide and both developing optic vesicles can be seen. blood vessels 250 µm

47. SLIDE (green label) Early stage of developing eye Two adjacent sections from another of the slides showing the early stages in the development of the eye. The optic vesicles are well developed and due to the flexure in the head an area of mid-hind brain can be seen. Note the embryonic membranes. 100 µm

48. SLIDE (green label) Early stage of developing eye branches of vitelline vein wall of diencephalon optic vesicles amniotic cavity amnion Two adjacent sections from another of the slides showing the early stages in the development of the eye. The optic vesicles are well developed and due to the flexure in the head an area of mid-hind brain can be seen. Note the embryonic membranes. 100 µm

49. SLIDE (green label) Later stage of developing eye The diverticulae (seen in the previous slide), invaginate to form the optic cup. Producing the retina, ciliary layers and iris. The lens is formed from modified epithelial cells; the surface ectoderm overlying the optic cup. The apparent discontinuity between the diencephalon and the retinal layer of the optic cup is because of the shape of the cup and the plane of the section. 250 µm

50. SLIDE (green label) Later stage of developing eye amniotic cavity diencephalon retina diocoel The diverticulae (seen in the previous slide), invaginate to form the optic cup. Producing the retina, ciliary layers and iris. The lens is formed from modified epithelial cells; the surface ectoderm overlying the optic cup. lens optic cup anterior cardinal vein choroid layer The apparent discontinuity between the diencephalon and the retinal layer of the optic cup is because of the shape of the cup and the plane of the section. myelencephalon (with thin roof) 250 µm