Human bodily fluids and secretions contain molecules known as biomarkers that contain a wealth of information about the body’s health and the presence of disease. Among secretions such as tears, sweat and saliva, tears are considered the best source of biomarkers, with concentrations similar to those found in blood. Tears are also sterile, readily available and less susceptible to the damaging effects of temperature change, evaporation and secretion rate.
Useful and measurable biomarkers found in tears include sodium ions, which are useful indicators of dry-eye disease, and glucose molecules, an early diagnostic tool for diabetes. Also, measuring the pH of tears can be used to check for cell viability, drug effectiveness and for signs of disease.
Therefore, the ability to collect tears in an effective way and to measure their pH and levels of biomarkers in real-time is highly desirable. One approach that is actively being explored is the idea of contact lens biosensors. Such contact lenses could be designed to include tiny channels on their surfaces for guiding the flow of tears into tiny reservoirs for collection and monitoring.
Pliable and transparent materials, known as hydrogels, are currently being used commercially to make contact lenses; they are easy to work with and cost effective. However, to date, they have not been shown to be ideal materials with which to fashion channels and reservoirs, as they are sensitive to the fabrication techniques needed. In previous efforts, hydrogels have been vulnerable to deformities caused by the solvents or the temperature and vacuum conditions required by some fabrication methods. Other methods have produced hydrogel channels with rough surfaces or non-uniform dimensions.
A collaborative team, which includes a group from the Terasaki Institute for Biomedical Innovation, has developed a fabrication method to meet all the challenges in making a hydrogel contact lens for biomarker sensing. The team began by optimizing the components of the hydrogel to obtain elastic characteristics which would allow it to be engineered into various shapes with a smooth surface profile. They next fashioned microchannels in the hydrogel with the use of a 3D printed mold. The final step in the fabrication process was to enclose the hydrogel channels by bonding an additional layer of hydrogel onto the microchannel surface.
Once the successful prototype was completed, it was extensively tested for its performance in channeling and collecting fluids. Flow rates of artificial tears in the channels were measured at different levels of hydration, with zero flow measured at complete dehydration and full spontaneous flow observed at full hydration.
A noteworthy observation during these tests was that when the hydrogel was mildly dehydrated, liquid flow in the channels would stop, but when additional rhythmic pressure was applied, the flow would resume. This was an important demonstration of support for the hypothesis that eye blinking would also provide the necessary pressure and additional hydration needed to allow for tear flow in the contact lens, and therefore, in the eye.
The team next prototyped sensors to collect, test for and measure pH levels of artificial tears flowing through the microchannels. Sodium levels were also tested, and the results showed an acceptable and predicted range of sodium detection for diagnostic purposes.
Additional goals would be to fine-tune factors such as humidity, hydrogel hydration and applied pressure in order to enhance all the flow rates and dynamics of the biosensing contact lens. There are also plans to experiment with smaller channels in thinner hydrogel films before a final contact lens is devised.
News Source: Terasaki Institute for Biomedical Innovation
