Electrochemically initiated bioadhesive compositions comprising biocompatible polymers containing derivatives of diazonium, arylsulfonium, or diaryliodonium in general, and to their use in tissue fixation, in particular.

This invention describes a wound dressing product for active continuous debridement of devitalized tissues in non-healing wounds including diabetic ulcers, pressure ulcers, burn injuries and other etiologies. The present invention pertains to the principle of continuous wound debridement which makes necrotic tissue more susceptible for removal and hence enhances progressive wound healing. The dressing contains an active ingredient, such as collagenase which serves to debride wounds in-situ. In the present invention purified Collagenase (90% pure) was deposited onto several wound dressing materials. A key feature of this invention is that the activity level of the Collagenase used was substantially preserved.

A medical product which contains a mechanophore, and the use of a mechanophore for producing a medical product.

A radiation-resistant resin additive that contains, as an effective ingredient, a bisphenol compound as indicated by General Formula (1) below, or General Formula (2) below, as well as a radiation-resistant medical polyamide resin composition comprising the foregoing bisphenol compound and an amide resin, and a radiation-resistant medical molded article fabricated using the foregoing radiation-resistant medical polyamide resin composition.

##STR00001##

(In the Formula, R.sup.1, R.sup.2, and R.sup.3 respectively may be the same or different and indicate a hydrogen atom or a saturated hydrocarbon group having not less than 1 carbon.)

##STR00002##

(In the Formula, R.sup.4, R.sup.5, and R.sup.6 respectively may be the same or different and indicate a hydrogen atom or a saturated hydrocarbon group having not less than 1 carbon.)

Systems, methods, and apparatuses for debriding a tissue site are described. The system includes a manifold and a cover adapted to form a sealed space over the tissue site for providing negative pressure. The system also includes a debridement tool positioned between the manifold and the tissue site. The debridement tool having a tissue-facing surface and a plurality of holes separated from each other by walls. The walls have transverse surfaces extending between the tissue-facing surface and an opposite surface that form cutting edges. The holes have a perforation shape factor that allows the holes to collapse from a relaxed position to a contracted position in response to the application and removal of negative pressure from the sealed space. The cutting edges debride the tissue site in response to movement between the relaxed position and the contracted position.

Devices and methods for the treatment of open and closed wound spinal cord injuries are disclosed. For example, described herein are devices and methods for mitigating secondary injury to, and promoting recovery of, spinal cord primary injuries. More particularly, certain embodiments of the present invention are directed to polymeric mini-tubes that may be used for the treatment of spinal cord injuries. In addition, other embodiments are directed to polymeric fill-in bandages that may be used for the treatment of spinal cord injuries. For example, an erodible, or biodegradable, form of biocompatible polymer of the present invention is fabricated for surgical implantation into the site of the spinal cord injury.

Systems, methods, and apparatuses for debriding a tissue site are described. The system includes a manifold and a cover adapted to form a sealed space over the tissue site for providing negative pressure. The system also includes a debridement tool positioned between the manifold and the tissue site. The debridement tool having a tissue-facing surface and a plurality of holes separated from each other by walls. The walls have transverse surfaces extending between the tissue-facing surface and an opposite surface that form cutting edges. The holes have a perforation shape factor that allows the holes to collapse from a relaxed position to a contracted position in response to the application and removal of negative pressure from the sealed space. The cutting edges debride the tissue site in response to movement between the relaxed position and the contracted position.

A method and device for local delivery of a water-insoluble therapeutic agent to the tissue of a normal or diseased body lumen is disclosed. An expandable structure of a medical disposable device, such as a balloon of a balloon catheter, is coated with a non-durable coating which comprises poly(HEMA) complexed with iodine and has a substantially water-insoluble therapeutic agent dispersed therein. The medical disposable device is inserted into a body lumen, and expanded to contact the non-durable coating against the body lumen and deliver the substantially water-insoluble therapeutic agent to the body lumen tissue.

Devices and methods for the treatment of open and closed wound spinal cord injuries are disclosed. For example, described herein are devices and methods for mitigating secondary injury to, and promoting recovery of, spinal cord primary injuries. More particularly, certain embodiments of the present invention are directed to polymeric mini-tubes that may be used for the treatment of spinal cord injuries. In addition, other embodiments are directed to polymeric fill-in bandages that may be used for the treatment of spinal cord injuries. For example, an erodible, or biodegradable, form of biocompatible polymer of the present invention is fabricated for surgical implantation into the site of the spinal cord injury.

A medical balloon includes at least one internal wall dividing the balloon into a plurality of separate chambers which may be separately inflatable and deflatable. The at least one internal wall is impregnated with heat conductive particles. The heat conductive particles enable heat produced during the balloon blowing process to pass through the polymer material of the balloon and specifically into the internal wall or walls, enabling these to soften and stretch during the process. This improves the integrity of the balloon and also balloon flexibility. The radiopaque particles embedded in the internal wall or walls of the balloon can also, in preferred embodiments, be of radiopaque material, providing the balloon with imaging visibility during deployment thereof in a patient.