Abstract: An intraocular device for implantation in an eye of a patient is provided. The intraocular device includes an inlet tube, an outlet tube, and a microfluidic chamber. The microfluidic chamber includes a chamber inlet coupled to the inlet tube, a chamber outlet coupled to the outlet tube, and one or more fluidic barriers. Each fluidic barrier is configured such that, as a fluid is injected into the microfluidic chamber, a front of the fluid coincides with the fluidic barrier before any of the fluid passes beyond the fluidic barrier. Associated methods are also disclosed herein.

Abstract: A MEMS check valve chip is described. The chip comprises a first side and an opposing second side, an outlet port extending from the first side to the second side, and a flexible outlet membrane anchored to the first side to overlie the outlet port. The flexible outlet membrane includes an outlet aperture and a sealing portion, and the sealing portion is movable between a closed position inhibiting fluid flow through the outlet aperture and an open position wherein the sealing portion displaces into the outlet port to permit fluid flow through the outlet aperture.

Abstract: A microfluidic valve for implantation in an eye of a patient is disclosed. The valve may include a chamber formed between a substrate and a flexible membrane. The valve may also include a boss disposed in the chamber and having a top edge in selective contact with the flexible membrane. The top edge includes a relief portion and a non-relief portion, with the relief portion being structurally arranged so that a pressure required to separate the membrane from the relief portion is less than a pressure required to separate the membrane from the non-relief portion. The valve also may include an inlet extending through the boss and the substrate through which fluid enters the chamber and an outlet configured to allow fluid to exit the chamber. Methods for priming a microfluidic valve are also disclosed.

Abstract: A microfluidic valve for implantation in an eye of a patient is disclosed. The valve may include a chamber formed between a substrate and a flexible membrane. The valve may also include a boss disposed in the chamber and having a top edge in selective contact with the flexible membrane. The top edge includes a relief portion and a non-relief portion, with the relief portion being structurally arranged so that a pressure required to separate the membrane from the relief portion is less than a pressure required to separate the membrane from the non-relief portion. The valve also may include an inlet extending through the boss and the substrate through which fluid enters the chamber and an outlet configured to allow fluid to exit the chamber. Methods for priming a microfluidic valve are also disclosed.

Abstract: An intraocular pressure monitoring and sensing device for implantation in an eye of a patient may include a substrate having a pressure sensor disposed on a top surface thereof and a pressure sensor cap disposed on the substrate over the pressure sensor. The pressure sensor cap may include a wall structure extending from the top surface of the substrate, the wall structure laterally surrounding the pressure sensor. The pressure sensor cap may further include a cap top situated above the pressure sensor, the cap top and wall structure together forming an interior chamber, and a chamber inlet providing fluid access to the interior chamber. At least one of the cap top and the wall structure includes a semi-permeable surface to aid in priming.

Abstract: Described herein is an IOP control device for implantation in an eye of a patient, comprising a drainage tube, a pressure-driven flow system, and a flow rate measurement system. The drainage tube includes a drainage lumen in fluid communication with an anterior chamber of the eye. The flow system is in fluid communication with the drainage lumen, and is configured to control the flow of fluid through the drainage tube. The flow rate measurement system is disposed distal to the flow system, and comprises a flow tube including a known hydraulic resistance to flow, a proximal pressure sensor disposed at the proximal end of the flow tube, and a distal pressure sensor disposed at the distal end of the flow tube. The flow tube includes a proximal end, a distal end, and a lumen extending therebetween that is configured to be in fluid communication with the drainage lumen.

Abstract: An intraocular device for implantation in an eye of a patient is provided. The intraocular device includes an inlet tube, an outlet tube, and a microfluidic chamber. The microfluidic chamber includes a chamber inlet coupled to the inlet tube, a chamber outlet coupled to the outlet tube, and one or more fluidic barriers. Each fluidic barrier is configured such that, as a fluid is injected into the microfluidic chamber, a front of the fluid coincides with the fluidic barrier before any of the fluid passes beyond the fluidic barrier. Associated methods are also disclosed herein.

Abstract: A MEMS check valve chip is described. The chip comprises a first side and an opposing second side, an outlet port extending from the first side to the second side, and a flexible outlet membrane anchored to the first side to overlie the outlet port. The flexible outlet membrane includes an outlet aperture and a sealing portion, and the sealing portion is movable between a closed position inhibiting fluid flow through the outlet aperture and an open position wherein the sealing portion displaces into the outlet port to permit fluid flow through the outlet aperture.

Abstract: An implantable device for mechanically stimulating the trabecular meshwork is disclosed. The device is implanted in the eye adjacent the trabecular meshwork. The device imparts mechanical stimulating in the form of vibrations or movement to the trabecular meshwork. The imparted mechanical stimulation causes the trabecular meshwork to move in a manner that produces a pumping action to remove aqueous from the anterior chamber of the eye.

Abstract: An implantable fluidic valve actuated by osmotic pressure gradient and methods of operating it are provided. The valve includes: an input fluid channel; an output fluid channel in fluid communication with the input fluid channel at an aperture; and a semi-permeable membrane forming a portion of a sealed chamber. The semi-permeable membrane may have an outer surface forming a wall of the input fluid channel, and an inner surface forming a wall of the sealed chamber, the membrane being configured to allow diffusion of a solvent into and out of the sealed chamber; and a first electrode and a second electrode disposed within the sealed chamber configured to receive a voltage. A pump including the above elements and a check valve is provided. An ocular implant including an inlet tube sized to receive aqueous humor and an intra-ocular pressure control system having a fluidic valve as above is also provided.