The invention is directed to a system and methods for treating neurovascular compression. Certain preferred embodiments of the invention generally comprise an apparatus having an elongated body portion including a proximal anchor element and distal anchor element. The apparatus also may include one or more marker elements to facilitate placement of the apparatus by the user. The apparatus may be configured to permit the user, after insertion and deployment of the apparatus in a blood vessel, to move the blood vessel so that the blood vessel is no longer in contact with and compressing a nerve or other parts of the nervous system.

A stent includes a main body having a plurality of rings that form a helix. Each of the plurality of rings includes a plurality of skewed v-shaped elements that each have a first leg and a second leg that is longer than the first leg. The stent further includes a first end ring and a second end ring positioned to an opposite side of the main body from the first end ring. Each of the plurality of rings of the main body is angled with respect to the first end ring and the second end ring. The stent further includes a first transitional region for connecting the first end ring to the main body, and a second transitional region for connecting the second end ring to the main body.

For personalizing a vessel stent, images associated with a subject generated by various imaging modalities are aggregated. The images are then processed for identifying Regions of Interest (ROIs) and various parameters associated with the ROIs. Further, a model and a composition of the vessel stent to be administered to the subject to alleviate the condition in the vessel are computed. Thereafter, the model is verified for compatibility using information derived from patient stratification parameters. Upon successful verification of the model, a format of the model is generated that can be used directly for fabricating the vessel stent using additive manufacturing processes known in the art.

Post deployment radial force recovery of biodegradable scaffolds are described where a high molecular weight polymer may be formed into a high molecular weight scaffold by solution casting into a tubular substrate such that the scaffold retains its mechanical properties through processing. The tubular substrate is laser cut and subsequently crimped onto a catheter for deployment into a body lumen. The polymeric scaffold may retain its mechanical properties and result in increased radial strength post-deployment in a saline environment, e.g., within a body lumen. This scaffold enhancement may be attributable at least in part to entanglement of high molecular weight polymer chains as one factor that effects radial force recovery and also to the design or geometry of the scaffold as another factor that effects radial force recovery after deployment.

An intra-annular mounting frame for an aortic valve having native aortic cusps is provided which includes a frame body with native leaflet reorienting curvatures and interconnecting points; the curvatures shaped to be received inside the valve below the native aortic cusps and to reorient the native aortic cusps within the aortic valve, where each of the curvatures extends concavely upward from a reference latitudinal plane tangential to each curvature's base.

A method for making a polymer with a porous layer from a solid piece of polymer is disclosed. In various embodiments, the method includes heating a surface of a solid piece of polymer to a processing temperature and holding the processing temperature while displacing a porogen layer through the surface of the polymer to create a matrix layer of the solid polymer body comprising the polymer and the porogen layer. In at least one embodiment, the method also includes removing at least a portion of the layer of porogen from the matrix layer to create a porous layer of the solid piece of polymer.

The present invention relates to methods of repairing an inguinal hernia defect including . . . a first portion forming a partial spherical cap surface shaped and dimensioned . . . a second portion extending from an inferior edge of the first portion . . . characterized in that the piece further includes: a third portion forming an arched part extending longitudinally in the inferior direction from a medial inferior corner of the first portion, the arched part extending radially substantially in the front direction, the third portion being intended to face the medial inferior area of the inguinal anatomy, and introducing the prosthesis into a patient.

A fiber-based surgical implant stabilized against fraying, includes a thermally crimped flat-knitted fabric of a biocompatible, optionally biodegradable, polymer material having a glass transition temperature or other thermally induced secondary conformational mobility threshold in the temperature range of from 20° C. to +170° C. Also disclosed is a corresponding fabric and methods of producing the implant and the fabric.

An implant suitable for being anchored with the aid of mechanical vibration in an opening provided in bone tissue. The implant is compressible in the direction of a compression axis under local enlargement of a distance between a peripheral implant surface and the compression axis. The implant includes a coupling-in face which serves for coupling a compressing force and the mechanical vibrations into the implant, which coupling-in face is not parallel to the compression axis. The implant also includes a thermoplastic material which, in areas of the local distance enlargement, forms at least a part of the peripheral surface of the implant.

A moldable rigid ankle brace is disclosed. The rigid stabilizing ankle brace includes a heat-moldable multi-layer housing having an opening for receiving a user's ankle, a footplate attached to the housing, and a closure mechanism. The multi-layer housing includes a middle layer, which is substantially stiff at a temperature below about 130° F. and moldable at temperatures between about 130° F. and 275° F. A method of stabilizing an ankle is also disclosed. The method may include providing a rigid stabilizing ankle brace, having a heat-moldable multi-layer housing having an opening for receiving a user's ankle, and a footplate removably attached to said housing, heating the ankle brace to between about 130° F. to about 275° F., and applying said heated ankle brace to the ankle of a patient in need thereof.