A system for managing female incontinence includes a body of biocompatible material configured to fit between the labia minora and the vestibule floor, the body having a surface configured to occlude the urethral meatus, an adhesive carried on at least a first portion of the surface and configured to provide a sealing engagement between the body and the urethral meatus, and a substance carried by at least one of the body and the adhesive and configured for controlling the odor of the general vaginal-urethral area of a female.

Methods, systems, apparatuses and devices for implantation in a soft-tissue biological environment that include a primary layer for containing a filler substance, an interface and a secondary layer, including embodiments where the secondary layer an ePTFE layer, the primary layer is a silicone layer, the interface is mechanical or adhesive and the filler substance can include particulates and lattices.

A woven retention device, lattice device and woven patch device that are configured to receive a fastener in a bone hole can be configured to impede biofilm formation. The devices can be made of woven filaments that outline apertures of varying sizes and shapes and can serve as an interface between a fastener and the bone material. The devices can be configured to allow for optimal bone growth while at the same time minimizing the likelihood that biofilm forms thereon. The devices can be made of materials that facilitate soft tissue fixation, and screw-activated expansion.

An artificial blood vessel is a tubular fabric including a fiber layer containing an ultrafine fiber(s) and an ultrafine fiber layer in the inside of the fiber layer, the ultrafine fiber layer being composed of an ultrafine fiber(s) having a fiber diameter(s) of not less than 10 nm and not more than 3 m, wherein a quaternary ammonium group-containing polymer having alkyl groups each of a carbon number 10 or less is covalently bound to the ultrafine fiber(s); heparin is ionically bound to the quaternary ammonium group-containing polymer; and the residual heparin activity after washing with physiological saline at 37 C. for 30 minutes is 20 mIU/cm2 or more.

Medical devices that include a tubular member with a plurality of braided filaments, each filament crossing another of the filaments at a respective crossing point forming sidewall and a plurality of pores in the sidewall that are sized to inhibit flow of blood through the sidewall into an aneurysm to a degree sufficient to lead to thrombosis and healing of the aneurysm when the tubular member is positioned in a blood vessel and adjacent to the aneurysm, the pores have an average pore size that is less than or equal to about 500 microns when the tubular member is in an expanded state, the filaments possessing antithrombogenic surfaces to increase antithrombogenicity of the medical device with pores substantially free of webs formed by antithrombogenic material, such that fewer than 5% of the crossing points have webs formed by antithrombogenic material thereby permitting the pores to be substantially free of webs.

The present invention relates to an implantable device, in particular for wall repair comprising a reinforcing textile implant having first and second surfaces, a bioadhesive coating to coat said first surface at least in part, said coating comprising at least one ionic, cross-linked bioadhesive polymer selected from among the following polymers: an acrylic acid polymer, methacrylic acid polymer, itaconic acid polymer, maleic acid polymer or maleic anhydride polymer having an adhesive function that can be activated in an aqueous medium.

An expandable intervertebral cage with living hinges manufactured using 3D printing. The intervertebral cage is configured to expand from an unexpanded to an expanded configuration. The intervertebral cage can include a deployment system, such as a variable volume pouch or deployment cable, to apply force to the intervertebral cage to deploy the intervertebral cage.

An artificial meniscus that is a supportive device for a knee joint, which is circular in shape, and less likely to be displaced is disclosed. The artificial meniscus includes a polycarbonate urethane and has a shell having flexibility and a core having a rigidity higher than that of the shell. A surface of the artificial meniscus is coated by MPC and micro dimples are formed on a surface of the artificial meniscus. The artificial meniscus is placed between the femur and tibia and is sewn to an articular capsule.

An intradiscal shield and an exterior shield configured to prevent re-herniation and to provide structural integrity to a spinal defect within or on a spinal disc. An insertion instrument to insert the intradiscal shield within the spinal defect and attach the intradiscal shield or exterior shield to the spinal disc. The insertion instrument having a distal tip for spraying a protein crosslinking reagent within the spinal defect. The exterior shield configured for attaching to the exterior wall of the spinal disc and blocking an exterior opening of the spinal defect.

The present invention aims at improving and upgrading the conventional devices based on the low temperature magnetron sputtering coating devices. Starting from the material systems, the invention provides a new material system and a manufacturing method thereof based on a high molecular weight polyethylene joint cup to solve the poor binding force problem between the film and the matrix, and the problems of easy oxidization and carbonization of high molecular weight polyethylene with low temperature magnetron sputtering technologies at the same time. On the above basis, the ultra-lubrication performance of graphite-like structure films and ultra-hardness of diamond-like structure films are utilized to construct a nano-scale multilayer structure DLC film alternatively coated with a graphite-like film and a diamond-like film. The present invention improves the wear resistance of high molecular weight polyethylene joint cups, and restricts low accuracy of joints due to creeping by constructing a new artificial hip joint cup of ultra-wear-resisting nano-scale multilayer structure DLC film with high hardness and self-lubricating capability.