Clinical management of many chronic ophthalmological disorders requires direct delivery of drugs into the vitreous. There is an important need to investigate novel needle-less alternatives to deliver drugs to the vitreous. The purpose of this study is to assess the effects of a needle-less system using ultrasound to enhance vitreal delivery of small molecules through the sclera in an ex vivo model and to evaluate whether changes in permeability are mainly due to the heat generated by sonication. An eye cup containing 1 mL of sodium fluorescein 0.1% was placed on top of the sclera of cadaveric rabbit eyes. Treated eyes were sonicated for 10 minutes, and left in contact with the fluorescein solution for an additional 50 minutes. Control eyes received the same exposure to fluorescein solution (60 minutes) in the eye cup without ultrasound treatment. Vitreous humor was collected and analyzed using a fluorescence spectrophotometer to calculate the concentration of fluorescein that diffused into the vitreous humor. An additional set of eyes was treated using a heating probe to evaluate whether changes in permeability were mainly due to heat. Vitreous samples from ultrasound-treated eyes showed a 44.6% higher concentration of fluorescein compared to control eyes. The concentration of fluorescein in the vitreous of heat-treated eyes did not show a significant difference when compared to control eyes. Thus, phonophoresis is a promising needle-less method for vitreal drug delivery, and local heating conducted to the surface of the sclera should be mitigated because it does not enhance the efficacy of the method.
Keywords: Ultrasonic; drug delivery systems; intravitreal; sclera; vitreous.