Abstract: The present invention is directed generally to a layered polymeric monofilament fiber drug delivery device, where each layer of the device can contain a different polymer, drug, additive, or any combination or mixture thereof. The layered nature of the current monofilament polymeric monofilament device provides the capability to modulate the release of one or more drugs and/or the mechanical properties of the fiber so that drug release and device failure can be separately tuned to provide for the tailored introduction of therapeutically effective drugs or agents to a target tissue. Moreover, the fiber may comprise more than one distinct segments along its length, each segment itself having different combinations and/or numbers of layers thereby providing even greater freedom in the design of the therapeutic delivery device. The invention is also directed to a method of manufacturing such a layered polymeric monofilament fiber drug delivery device, and methods of treatment using such devices.

Abstract: A paracorporeal respiratory assist lung is configured with an annular cylindrical hollow fiber membrane (fiber bundle) that is rotated at rapidly varying speeds. Fluid (for example, blood) is introduced to the center of the device and is passed radially through the fiber bundle. The bundle is rotated at rapidly changing velocities with a rotational actuator (for example, a motor or magnetic coupling). The rotation of the fiber bundle provides centrifugal kinetic energy to the fluid giving the device pumping capabilities and may create Taylor vortexes to increase mass transfer. Rotation of the fiber bundle increases the relative velocity between the fluid and the hollow fibers and increases the mass transfer. The porosity of the fiber bundle may be varied to enhance gas exchange with the blood. Alternatively, a rotating core may be used with a stationary fiber bundle.

Abstract: A paracorporeal respiratory assist lung is configured with an annular cylindrical hollow fiber membrane (fiber bundle) that is rotated at rapidly varying speeds. Fluid (for example, blood) is introduced to the center of the device and is passed radially through the fiber bundle. The bundle is rotated at rapidly changing velocities with a rotational actuator (for example, a motor or magnetic coupling). The rotation of the fiber bundle provides centrifugal kinetic energy to the fluid giving the device pumping capabilities and may create Taylor vortexes to increase mass transfer. Rotation of the fiber bundle increases the relative velocity between the fluid and the hollow fibers and increases the mass transfer. The porosity of the fiber bundle may be varied to enhance gas exchange with the blood. Alternatively, a rotating core may be used with a stationary fiber bundle.

Abstract: A paracorporeal respiratory assist lung is configured with an annular cylindrical hollow fiber membrane (fiber bundle) that is rotated at rapidly varying speeds. Fluid (for example, blood) is introduced to the center of the device and is passed radially through the fiber bundle. The bundle is rotated at rapidly changing velocities with a rotational actuator (for example, a motor or magnetic coupling). The rotation of the fiber bundle provides centrifugal kinetic energy to the fluid giving the device pumping capabilities and may create Taylor vortexes to increase mass transfer. Rotation of the fiber bundle increases the relative velocity between the fluid and the hollow fibers and increases the mass transfer. The porosity of the fiber bundle may be varied to enhance gas exchange with the blood. Alternatively, a rotating core may be used with a stationary fiber bundle.

Abstract: The present invention is directed generally to a layered polymeric monofilament fiber drug delivery device, where each layer of the device can contain a different polymer, drug, additive, or any combination or mixture thereof. The layered nature of the current monofilament polymeric monofilament device provides the capability to modulate the release of one or more drugs and/or the mechanical properties of the fiber so that drug release and device failure can be separately tuned to provide for the tailored introduction of therapeutically effective drugs or agents to a target tissue. Moreover, the fiber may comprise more than one distinct segments along its length, each segment itself having different combinations and/or numbers of layers thereby providing even greater freedom in the design of the therapeutic delivery device. The invention is also directed to a method of manufacturing such a layered polymeric monofilament fiber drug delivery device, and methods of treatment using such devices.