A system is provided for healing a wound. The system includes a flexible body, a therapeutic agent delivery mechanism, a suction mechanism, and a power source. The flexible body includes a cover film having oppositely disposed first and second surfaces that define a compartment. The compartment includes a first porous material, a second porous material, and at least one electrode disposed therein. The second porous material is disposed between the first porous material and the at least one electrode. The therapeutic agent delivery mechanism and the suction mechanism are fluidly connected to the compartment. The power source is in electrical communication with the at least one electrode.

Presented herein are techniques for clinical-based automated control of the delivery of treatment substances to at least one inner ear of a recipient of an implantable medical device. More specifically, in-vivo biomarkers are analyzed to determine a biological state/status of one or more physiological elements of the inner ear. Subsequent delivery of one or more treatment substances to the inner ear of the recipient are controlled based on the determined biological state of the one or more physiological elements of the inner ear.

The present invention provides rapid-acting insulin and insulin analog formulations. The invention further provides delivery devices, particularly infusion sets, which allow for the rapid absorption of insulin and insulin analogs, as well as other active agents. Methods of using the insulin and insulin analog formulations as well as the insulin delivery devices for treating subjects with diabetes mellitus are also provided.

The subject invention pertains to a novel design and fabrication method for a transdermal drug delivery (TDD) device with one or both of ultrasonic and electrical stimulations to enhance drug penetrating through skin surface and a skin impedance sensor to enable closed-loop control providing stable drug release through the skin. The invention also provides a layered layout of the device and a corresponding fabrication protocol for realizing monolithic integration of the stimulation and sensing components and robust contact of the TDD device with skin. A flexible and layered architecture is provided to improve manufacturability, effectiveness, compactness, and usability of the provided TDD in clinical applications.

A system is provided for healing a wound. The system includes a flexible body, a therapeutic agent delivery mechanism, a suction mechanism, and a power source. The flexible body includes a cover film having oppositely disposed first and second surfaces that define a compartment. The compartment includes a first porous material, a second porous material, and at least one electrode disposed therein. The second porous material is disposed between the first porous material and the at least one electrode. The therapeutic agent delivery mechanism and the suction mechanism are fluidly connected to the compartment. The power source is in electrical communication with the at least one electrode.

A drug-delivery device includes a body configured for attachment to a handle of an ablation device, a shaft portion defining a passageway therein, and a delivery lumen to provide for drug delivery to tissue. The body includes a proximal portion, a distal portion, and a contoured portion disposed therebetween. The contoured portion is configured for engagement with a contoured portion of the handle of the ablation device. The shaft portion includes a proximal end and a distal end. The proximal end of the shaft engages with an opening defined in the distal end of the body. The passageway of the shaft portion is configured to receive the delivery lumen slideably moveably therein. The delivery lumen includes a proximal portion and a distal portion. The drug-delivery device also includes a knob member coupled to the proximal portion of the delivery lumen.

A system is provided for healing a wound. The system includes a flexible body, a therapeutic agent delivery mechanism, a suction mechanism, and a power source. The flexible body includes a cover film having oppositely disposed first and second surfaces that define a compartment. The compartment includes a first porous material, a second porous material, and at least one electrode disposed therein. The second porous material is disposed between the first porous material and the at least one electrode. The therapeutic agent delivery mechanism and the suction mechanism are fluidly connected to the compartment. The power source is in electrical communication with the at least one electrode.

Described herein are drug and other active agent transdermal delivery systems and devices to deliver active agents to skin or mucosa of a subject, and methods of delivering such active agents. In particular, systems, methods, and devices are described that control the concentration and timing of active agent delivery. Such systems or devices may include a transdermal membrane and a temperature control element for heating and/or cooling a portion of the transdermal delivery system to provide pulsatile active agent delivery through the transdermal membrane.

Described herein are drug and other active agent transdermal delivery systems and devices to deliver active agents to skin or mucosa of a subject, and methods of delivering such active agents. In particular, systems, methods, and devices are described that control the concentration and timing of active agent delivery. Such systems or devices may include a transdermal membrane and a temperature control element for heating and/or cooling a portion of the transdermal delivery system to provide pulsatile active agent delivery through the transdermal membrane.