Mechanical Superficial Keratectomy for Corneal Haze After Photorefractive Keratectomy With Mitomycin C and Extended Wear Contact Lens

Current paradigms in refractive surgery

Refractive surgeries have evolved from the archaic incisional corneal procedures to the use of sophisticated femtosecond lasers and new-generation phakic intraocular lenses (pIOL) for surgical correction of refractive errors. The armamentarium of modern-day refractive surgery includes corneal-based procedures such as photorefractive keratectomy, laser-assisted in situ keratomileusis and keratorefractive lenticule extraction, as well as lensbased pIOL implantation. The current procedures are associated with a high index of efficacy and predictability, with enhanced safety and a significant reduction in sight-threatening complications. Patient counselling and case selection is imperative to achieve optimal visual outcomes and patient satisfaction. This review article provides a comprehensive overview of current refractive surgery procedures, with an emphasis on decision-making. Evolving frontiers in refractive surgeries like customised corneal ablation and presbyopia correcting pIOL are also discussed.

Superficial Keratectomy: A Review of Literature

Superficial keratectomy (SK) is the manual dissection of the superficial corneal layers (epithelium, Bowman's layer, and sometimes superficial stroma). SK is done using a surgical blade or diamond burr. Some surgeons use intraoperative mitomycin C 0.02% or amniotic membrane transplantation to improve surgical outcomes. This literature review shows that SK remains an effective method for different indications, including tissue diagnosis, excision of corneal degenerations, dystrophies, scarring, recurrent corneal erosions, and retained corneal foreign body.

A Simple Inner-Stopper Guarded Trephine for Creation of Uniform Keratectomy Wounds in Rodents

Purpose

Creating controllable, reproducible keratectomy wounds in rodent corneas can be a challenge due to their small size, thickness, and the lack of usual tools available for human eyes such as a vacuum trephine. The purpose of this work is to provide a consistent, reproducible corneal stromal defect in rats using a simple, economical, and customized inner-stopper guarded trephine.

Methods

The inner-stopper guarded trephine is used to induce a circular wound in rat corneas. After trephination, the corneal flap can be removed by manual dissection using a blunt spatula. We used optical coherence topography (OCT) to measure the defect wound depth induced in ex vivo rat eyes.

Results

Despite a minor learning curve, this simple device enables depth control, reduces variability of manual keratectomy wound depth in rats, and decreases the risk for corneal perforation during keratectomy. Corneal defect creation was highly reproducible across different researchers and was independent of their surgical training.

Conclusion

This inner-stopper guarded trephine can be utilized and applied to pre-clinical testing of a wide range of corneal wound healing therapies, including but not limited to biotherapeutics, corneal prosthetics, and regenerative technologies.