| Literature DB >> 33776378 |
D Gongal1, S Thakur2, A Panse2, R Pawar3, C Q Yu4,5, C D Foster1.
Abstract
Corneal opacity is a leading cause of blindness, accounting for about 4% of global blindness. With corneal opacity, light is unable to pass through the cornea to form a clear image on the retina, resulting in blindness. To address this condition, an intraocular projection device has been designed. This device, while in use, would produce heat. According to international standard regulations, the temperature on the surface of the tissues should not increase more than 2°C due to medical devices. In order to establish the power budget of this intraocular electronic device, a steady state thermal finite element analysis was conducted on two different eye models. The device was placed at 9.98 mm from the retina, and was seen to run up to a maximum power of 82 mW for the first model and 91 mW for the second model. To reduce heating of tissues, the device was extended by 0.5 mm to create an air gap which acted as an insulator. The temperature in the nearest living tissue then dropped below the prescribed limit of 2°C at 100 mW.Entities:
Keywords: corneal blindness; corneal prosthesis; corneal transplantation; finite element analysis; thermal eye model
Year: 2020 PMID: 33776378 PMCID: PMC7993088 DOI: 10.1080/10407782.2020.1805230
Source DB: PubMed Journal: Numeri Heat Transf A Appl ISSN: 1040-7782 Impact factor: 2.928