Reasonably and scientifically optimize the introduction of multiple stimuli to the periphery of the retina,
further improving the effectiveness of myopia management!
Multiple Stimulus Signals
Coexistence of multiple mechanisms to inhibit axial growth: At least two types of stimulus signals based on different principles adhere to the surface of the lens and act together on the periphery of the retina, creating a phenomenon of multiple signal competitions between peripheral and central retinal signals. At the same time, controlling the additional stimulus signals can better guide the direction of myopia development and achieve the effect of inhibiting axial growth. Moreover, with the support of multiple stimulation signals, it is more helpful to improve the duration of wearing glasses, avoid the development of drug resistance in a short period of time due to a single stimulation signal, and bring long-lasting and effective myopia control to myopic patients.
Dynamic Aberration Modulation
Patients with different degrees of myopia will have different farsightedness defocusing amounts, and even in the same myopic eye of myopic patients, the amount of farsightedness defocusing around the retina will vary with position. Therefore, in order to better solve the problem of differences in farsightedness defocusing amounts caused by different degrees of myopia and different retinal positions, our company proposes the "dynamic Aberration Modulation" technology. By adding special lens designs to the correction of refractive errors basic lens, we can solve the problem of differences in farsightedness defocusing amounts, better match eye data, reduce the negative impact of farsightedness defocusing on myopic patients, and achieve better myopia prevention and control effects.


Stimulus Quantitative Evaluation System
Based on the design principles of micro-structured lenses, a suitable method for evaluating myopia effects is selected. Through a large number of simulation experiments, the relationship between myopia prevention and control effects and micro-structured eyeglass lens stimulation signals is quantified within the acceptable visual quality range of the human eye. Therefore, a design scheme with better prevention and control effects is selected to more efficiently, accurately, and reasonably design micro-structured eyeglass lenses that match eye data, thereby achieving the effect of suppressing myopia progression. By establishing a stimulus quantitative evaluation system for micro-structured eyeglass lenses, it can provide design basis for eyeglass lens designers and potentially offer new and more functional myopia prevention and control products for optometrists.


