Oculoplastic surgical simulation using goat sockets.

PURPOSE: To describe a reproducible and easily available goat socket model for training of various oculoplastic operations, and to evaluate trainees' perception of this training model in terms of their learning progress and satisfaction. METHODS: Goat sockets including orbital rim and eye with eyelids were harvested in form of a split-head model. Ophthalmology residents underwent individual surgical training using the goat socket model, supervised by an oculoplastic attending. Participants completed a questionnaire in form of a 5-point Likert Scale to evaluate their learning progress and satisfaction. OUTCOME MEASURES: Types of oculoplastic operations performed using the goat socket models, and participants' rating of their learning progress and satisfaction were reported. RESULTS: A wide range of oculoplastic operations including both eyelid and orbital operations could be simulated because of similarities of the goat eye model to the human eye anatomy. Fifteen ophthalmic trainees participated in surgical training using the goat eye model. All (100%) participants agreed that surgical simulation using the goat socket model increased their skills in surgical instrumentation and carrying out surgical steps, and their confidence in operating on patients. Most (87%) agreed the model resembled reasonably well compared to surgeries in human, and 93% would recommend training with the model to fellow resident ophthalmologists before operating on human patients. CONCLUSIONS: Oculoplastic surgical training using goat sockets is simple, readily available, and inexpensive. Trainee users showed promising feedback and positive learning progress using the goat socket model.

Indocyanine Green-Assisted Endoscopic Transorbital Excision of Lateral Orbital Apex Cavernous Hemangioma.

Orbital apex lesions posed operative difficulties to neurosurgeons and ophthalmologists due to limited surgical corridor and close vicinity to cranial nerves and arteries. Lateral orbital apex lesions were traditionally operated via the transcranial route by neurosurgeons. Recently, only a handful of reports have described the use of endoscope alone for excision of lateral orbital apex lesion. Our group, with both endoscopic skull base neurosurgeons and oculoplastic surgeons, has adopted the endoscopic transorbital approach for orbital apex lesions. We also used an indocyanine green (ICG) endoscope to aid identification and dissection of orbital apex cavernous hemangioma, which otherwise can be difficult to differentiate from surrounding intraconal recti muscles. Video 1 captured the first reported case of excision of lateral orbital apex cavernous hemangioma via endoscopic transorbital approach, using a zero-degree ICG endoscope. This was a 64-year-old Chinese woman who presented with right eye painless blurring of vision with visual acuity of 0.6 and right relative afferent pupillary defect. Fundoscopic examination showed absence of right optic disc swelling, and automated visual field testing confirmed a superior and infratemporal visual field defect in the right eye. On magnetic resonance imaging, there was a 1-cm oval mass that was hypointense on T1-weighted and hyperintense on T2-weighted images, with slow enhancement, suggestive of cavernous hemangioma. Optical coherence tomography of the retinal nerve fiber layer showed evidence of subtle right nerve fiber layer thinning. Right endoscopic transorbital excision of the tumor was performed with an ICG-assisted endoscope. Lateral skin crease incision was followed by crescent-shaped superolateral orbital rim removal. Superior and inferior orbital fissures were identified after stripping off the periorbita. The meningoorbital band was divided to release the orbital apex from the middle fossa dura. The greater wing of sphenoid bone was drilled with a 3-mm high-speed diamond burr under irrigation to create space for dissection. Injection of ICG resulted in delayed enhancement of the lesion at around 1 minute and 30 seconds, in contrast to rapid enhancement of surrounding recti muscles at around 30 seconds. Incision of periorbita was guided by ICG enhancement of lesion. The tumor was dissected from the lateral rectus and superior division of oculomotor nerve and was excised en bloc. The supraorbital rim was reconstructed with 2 miniplates. Pathology confirmed the diagnosis of cavernous hemangioma. Postoperatively, the patient had good recovery, with right eye visual acuity of 0.8 and resolution of the relative afferent pupillary defect.