Smart Contact Lens with High Sensitivity and Biocompatibility for Continuous Non-Invasive Intraocular Pressure Monitoring

Abstract

Intelligent intraocular pressure (IOP) sensors capable of continuous monitoring play a crucial role in the treatment of glaucoma. However, early diagnosis and treatment continue to face significant challenges due to the unique physiological environment of the eye. The primary scientific challenge lies in developing a method for continuous, high-sensitivity IOP monitoring that does not damage corneal tissue. To address this issue, a novel smart contact lens was developed, integrating hydrogel-based micronano architectures with diffraction-grating-embedded films. This device leverages 3D printing technology to achieve conformal adhesion to the ocular surface, enabling real-time IOP monitoring through optical-to-digital signal transduction. Additionally, ex vivo porcine eyeballs were used for in vitro testing and evaluation to quantitatively demonstrate the performance of the smart sensor. The results indicate that the smart contact lens developed in this study exhibits excellent biocompatibility and a high sensitivity of 2.5% mmHg^-1 within the range of 0-50 mmHg, enabling precise IOP monitoring. These lenses hold significant potential for clinical IOP monitoring and demonstrate substantial promise for the next generation of ocular disease prevention.

Keywords: 3D printing; biocompatibility; intraocular pressure monitoring; smart contact lens; stress collection.