Teaching and Research Faculty

Department of Ophthalmology physicians and faculty members are the ophthalmic tertiary care providers for the Central New York region. They include some of the most respected names in ophthalmology, and bring a wealth of experience to their work. Their expertise ranges from comprehensive ophthalmology to sub-specialties that include retina and vitreous, neuro-ophthalmology, glaucoma, pediatric ophthalmology and strabismus, oculoplastics, cornea and external disease, ocular pathology, low-vision, and contact lenses. They perform some of the most advanced and ambitious treatments today, and several travel throughout the world sharing their expertise with physicians and patients in other countries and cultures.

Faculty members are intimately involved in the education of new generations of physicians. They direct and supervise weekly general and sub-speciality clinics and take an active role in all departmental meetings, including Grand Rounds, Eye Pathology and Fluorescein Angiography Conferences, a Monday Morning Ophthalmic Review Lecture Series, Monthly Seminar, and Visiting Professor Days.

The Department sponsors some of the best attended postgraduate conferences in the Northeast, usually attracting 150 ophthalmologists from throughout the region. Training is aimed at postgraduate physicians, ophthalmic technicians, and office personnel alike. A large general course given once a year and mini courses given throughout the year cover such topics a phacoemulsifcation, YAG laser therapy, visual rehabilitation, and orbital dissection.




Vision research by CVR faculty is wide ranging and covers the following active and exciting areas:

  • Ocular Tissue Diseases
  • Gene Therapy and Inherited Retinal Diseases
  • Cell and Molecular Biology of the Retina
  • Visual Processing in the Retina and Brain

Ocular Tissue Diseases

Basic and clinical studies of glaucoma, lens-dislocating disorders, and related diseases of ocular connective tissues utilize methods of ocular pathology, electron microscopy and immunochemistry. Defective expression of structural glycoproteins is helping to identify basic mechanisms in these disorders.

Major research questions:

Do open-angle glaucomas and pseudoexfoliation have shared molecular mechanisms? Is the elastic tissue of the trabecular meshwork really elastic? Do variations in synthesis of fibrillin and its associated glycoproteins underlie different functions of the elastic microfibril system? What is the role of the capsule in zonular fiber adhesion to lens capsule? Is there abnormal expression of other matrix proteins besides fibrillin in lens-dislocating diseases? Could many of the major corneal dystrophies be manifestations of a single mutated protein?

Faculty:

Gene Therapy and Inherited Retinal Diseases

Basic and clinical studies of inherited retinal diseases of which the various forms of retinitis pigmentosa are the most prevalent. Focus will be on uncovering the molecular mechanisms underlying these blinding diseases and developing gene therapies to alleviate them. Research will use molecular biological techniques and rely heavily on the large patient file of the Department of Ophthalmology

Major research questions:

Can gene therapies counteract specific forms of inherited retinal diseases? How do mutations in rhodopsin affect its activation and inactivation? How do mutations in photoreceptor proteins impair retinal function and lead to cell death? Can we degrade the codes (mRNAs) for mutant retinal proteins? What is the molecular origin of "dark noise" in the visual system? Will transgenic Xenopus provide a faster, cleaner method of studying rhodopsin mutations? Can antisense or ribozyme approaches lower rhodopsin expression levels? Having isolated a rod promoter for transgenic Xenopus, can we do the same for a cone promoter? (probably yes)

Faculty:

Cell and Molecular Biology of the Retina

Investigations of the cellular and molecular mechanisms that lead from the light activation of visual pigments to the generation of optic nerve signals. Areas of research include the evolution, structure and activation of rod and cone visual pigments; properties of transducin; cellular mechanisms of the circadian, hormonal and efferent modulation of the retina.

Major research questions:

How is the structure of the eye's light sensitive pigment related to their function? What genes express the molecules involved in the eye's sensitivity to light? How do biological clocks control our visual sensitivity? How do biological clocks regulate gene expression in the retina? What molecular mechanisms underlie the daily rhythms of the visual system?

Faculty:

Visual Processing in the Retina and Brain

Investigations of the mechanisms that encode and integrate visual information in the retina and central visual pathways. Emphasis will be on understanding the neural mechanisms that underlie visual perception and behavior.

Major research questions:

What information does the eye send to the brain when an animal sees? How do neurons in the brain control visual attention? How does the visual system efficiently encode natural scenes? Does our vision change with time of day? Do changes in our metabolism change how we see? How do efferent pathways in the visual system influence vision? What neural mechanisms underlie letter identification? Does glucose or time of day change the activity of the visual parts of our brain?

Faculty:


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Last Modified: April 20, 2007.