Abstract: The present technology relates to systems, device, and methods for delivering an AIOL into a patients eye. In some embodiments, a tip assembly for delivering an AIOL into a includes an injector tip configured to receive the AIOL. The injector tip can include a distal portion configured to be inserted at least partially into the patients eye. The tip assembly can also include a plunger assembly positionable at least partially within the injector tip. The plunger assembly can include a plunger tip configured to engage the AIOL and an outer member coupled to the plunger tip and positioned at least partially around the plunger tip. When the plunger assembly is actuated, the plunger tip can be configured to move distally relative to the outer member to displace the AIOL out of the injector tip and into the patients eye.

Abstract: An accommodating intraocular lens (AIOL) for implantation within a capsular bag of a patient's eye comprises first and second components coupled together to define an inner fluid chamber and an outer fluid chamber. The inner region of the AIOL provides optical power with one or more of the shaped fluid within the inner fluid chamber or the shape of the first or second components. A surface treatment or coating may be applied to one or more surfaces of the first and second components. The surface treatment is expected to decrease the roughness of the machined surfaces of the boundary surfaces of the first and second components, and thereby reduce the mass of water coalescing at such boundary surfaces. The disclosed surface treatments are also expected to increase the hydrophobicity (i.e., decrease the surface energy) of the corresponding surface(s), thereby decreasing the “wettability” of these surfaces.

Abstract: An accommodating intraocular lens (AIOL) for implantation within a capsular bag of a patient's eye comprises first and second components coupled together to define an inner fluid chamber and an outer fluid chamber. The inner region of the AIOL provides optical power with one or more of the shaped fluid within the inner fluid chamber or the shape of the first or second components. A surface treatment or coating may be applied to one or more surfaces of the first and second components. The surface treatment is expected to decrease the roughness of the machined surfaces of the boundary surfaces of the first and second components, and thereby reduce the mass of water coalescing at such boundary surfaces. The disclosed surface treatments are also expected to increase the hydrophobicity (i.e., decrease the surface energy) of the corresponding surface(s), thereby decreasing the “wettability” of these surfaces.

Abstract: A neuromodulation system including a catheter has a balloon along its distal end. An ultrasound transducer positioned within an interior of the balloon can be selectively activated to emit acoustic energy radially outwardly, targeting nerve tissue and other portions of the subject anatomy. Targeted nerve tissue can be heated by the application of ultrasonic energy to neuromodulate the tissue. The system may be delivered over a guidewire. A catheter enhances fluid delivery to a distal end of the catheter while reducing an overall diameter of the catheter. The catheter comprises a guidewire lumen that is eccentric relative to a center axis of the catheter.

Abstract: A neuromodulation system including a catheter has a balloon along its distal end. An ultrasound transducer positioned within an interior of the balloon can be selectively activated to emit acoustic energy radially outwardly, targeting nerve tissue and other portions of the subject anatomy. Targeted nerve tissue can be heated by the application of ultrasonic energy to neuromodulate the tissue. The system may be delivered over a guidewire. A catheter enhances fluid delivery to a distal end of the catheter while reducing an overall diameter of the catheter. The catheter comprises a guidewire lumen that is eccentric relative to a center axis of the catheter.

Abstract: A neuromodulation system including a catheter having a balloon along its distal end is disclosed in several embodiments. An ultrasound transducer positioned within an interior of the balloon can be selectively activated to emit acoustic energy radially outwardly in order to target nerve tissue and other portions of the subject anatomy. In some embodiments, the system is configured to be delivered over a guidewire.

Abstract: A neuromodulation system including a catheter has a balloon along its distal end. An ultrasound transducer positioned within an interior of the balloon can be selectively activated to emit acoustic energy radially outwardly, targeting nerve tissue and other portions of the subject anatomy. Targeted nerve tissue can be heated by the application of ultrasonic energy to neuromodulate the tissue. The system may be delivered over a guidewire. A catheter enhances fluid delivery to a distal end of the catheter while reducing an overall diameter of the catheter. The catheter comprises a guidewire lumen that is eccentric relative to a center axis of the catheter.

Abstract: A neuromodulation system including a catheter having a balloon along its distal end is disclosed in several embodiments. An ultrasound transducer positioned within an interior of the balloon can be selectively activated to emit acoustic energy radially outwardly in order to target nerve tissue and other portions of the subject anatomy. In some embodiments, the system is configured to be delivered over a guidewire.