An integrated and standalone vibrating base assembly for cleaning contact lenses having two selective modes of operation, each mode operably configured to produce different preset vibrational rotations per minute, and comprising a base housing defining a housing cavity, with at least one vibration motor disposed within the housing cavity, electrically coupled to a power source, and operably configured to selectively induce a vibration therefrom with at least one switch coupled to the base housing; and a bottom surface and an upper surface spanning inwardly toward the housing cavity from an upper edge of the base housing to define a concave recess sized to receive two contact lens containers, the upper surface of a friction-inducing, deformable, and polymeric material configured to support two contact lens containers and operably coupled to the at least one vibration motor and to receive a vibration thereon upon activation of the at least one switch.

A contact lens for application to a human eyeball capable of emitting ultrasonic pressure waves from a plurality of piezoelectric transducers to mitigate the effects of airborne eye irritants and infectious microorganisms. The piezoelectric transducers converts mechanical energy applied upon the contact lens from the eyelid as the eyelid blinks and/or winks into electrical energy to be used for emitting ultrasonic pressure waves from the piezoelectric transducers. The ultrasonic pressure waves destroy airborne microorganisms near the contact lens. A photodiode onboard the contact lens indicates when the eyelid is not closed in order to limit or prevent emission of ultrasonic pressure waves from the piezoelectric transducers while the eyelid is closed. An antenna onboard the contact lens receives information from augmented reality glasses or other computing devices.

An integrated and standalone vibrating base assembly for cleaning contact lenses having two selective modes of operation, each mode operably configured to produce different preset vibrational rotations per minute, and comprising a base housing defining a housing cavity, with at least one vibration motor disposed within the housing cavity, electrically coupled to a power source, and operably configured to selectively induce a vibration therefrom with at least one switch coupled to the base housing; and a bottom surface and an upper surface spanning inwardly toward the housing cavity from an upper edge of the base housing to define a concave recess sized to receive two contact lens containers, the upper surface of a friction-inducing, deformable, and polymeric material configured to support two contact lens containers and operably coupled to the at least one vibration motor and to receive a vibration thereon upon activation of the at least one switch.

A contact lens for application to a human eyeball capable of emitting ultrasonic pressure waves from a plurality of piezoelectric transducers to mitigate the effects of airborne eye irritants and infectious microorganisms. The piezoelectric transducers converts mechanical energy applied upon the contact lens from the eyelid as the eyelid blinks and/or winks into electrical energy to be used for emitting ultrasonic pressure waves from the piezoelectric transducers. The ultrasonic pressure waves destroy airborne microorganisms near the contact lens. A photodiode onboard the contact lens indicates when the eyelid is not closed in order to limit or prevent emission of ultrasonic pressure waves from the piezoelectric transducers while the eyelid is closed. An antenna onboard the contact lens receives information from augmented reality glasses or other computing devices.