Abstract: A wound dressing and a method of making the wound dressing is described herein. The wound dressing is formed of an absorbent substrate formed of one or more layers and a low-adherence layer disposed on the substrate. The low-adherence layer can be disposed within at least a portion of the substrate. The low-adherence layer is formed of a mixture of at least one highly fluorinated polymer and at least one acidic polymer. The at least one highly fluorinated polymer has a fluorine content greater than the fluorine content of the at least one acidic polymer.

Abstract: A wound dressing and a method of making the wound dressing is described herein. The wound dressing is formed of an absorbent substrate formed of one or more layers and a low-adherence layer disposed on the substrate. The low-adherence layer can be disposed within at least a portion of the substrate. The low-adherence layer is formed of a mixture of at least one highly fluorinated polymer and at least one acidic polymer. The at least one highly fluorinated polymer has a fluorine content greater than the fluorine content of the at least one acidic polymer.

Abstract: A method of monitoring a condition within a patient's body includes locating a scanned beam imaging unit at an imaging location for a period of time to observe and characterize a portion of the patient's anatomy over at least a portion of the period of time. The scanned beam imaging unit is located at the imaging location using a locating instrument. The locating instrument is removed from the patient's body with the scanned beam imaging unit remaining at the imaging location. With the scanned beam imaging unit at the imaging location, a beam of light is scanned across the portion of the anatomy and light is received from the portion of the anatomy. A video image of the portion of the anatomy is produced from imaging data generated using detected light received from the portion of the anatomy.

Abstract: A wound dressing and a method of making the wound dressing is described herein. The wound dressing is formed of an absorbent substrate formed of one or more layers and a low-adherence layer disposed on the substrate. The low-adherence layer can be disposed within at least a portion of the substrate. The low-adherence layer is formed of a mixture of at least one highly fluorinated polymer and at least one acidic polymer. The at least one highly fluorinated polymer has a fluorine content greater than the fluorine content of the at least one acidic polymer.

Abstract: A wound dressing and a method of making the wound dressing is described herein. The wound dressing is formed of an absorbent substrate formed of one or more layers and a low-adherence layer disposed on the substrate. The low-adherence layer can be disposed within at least a portion of the substrate. The low-adherence layer is formed of a mixture of at least one highly fluorinated polymer and at least one acidic polymer. The at least one highly fluorinated polymer has a fluorine content greater than the fluorine content of the at least one acidic polymer.

Abstract: A method for viewing a portion of a patient's anatomy that comprises placing a scanner assembly including an oscillating reflector in the anatomy, securing the scanner assembly to an anatomical structure, scanning the anatomy with the scanner assembly secured to the anatomical structure, collecting radiation returned from the scanned anatomy, and generating a displayable image of the anatomy.

Abstract: A method for repairing or modifying an area of a patient's anatomy that comprises directing at least a portion of a scanning beam assembly to an area of a patient's anatomy, applying a radiation-responsive agent to portion of the anatomy, and exposing the radiation-responsive agent to radiation directed onto the agent by the reflector to cause the agent to therapeutically interact with the site. The scanning beam assembly including a radiation source capable of emitting radiation, a reflector that receives the radiation from the radiation source to direct the radiation onto the anatomy, wherein the reflector oscillates in at least two directions to create a scan of the anatomy, a detector to detect radiation returned from the anatomy, and a controller to convert the detected radiation into a displayable anatomy image.

Abstract: A scanned beam imaging system including a housing suitable for insertion into a body and a radiation source configured to direct a beam of radiation into or through the housing and onto an area within the body. The scanned beam imaging system further includes an adjustable element inside the housing and positioned to reflect the beam of radiation or to receive the beam of radiation therethrough, wherein the adjustable element is physically adjustable to vary a property of the beam of radiation that is reflected thereby or received therethrough. The scanned beam imaging system further includes a collector configured to receive radiation returned from the area within the body.

Abstract: A method for repairing or modifying an area of a patient's anatomy that comprises directing at least a portion of a scanning beam assembly to an area of a patient's anatomy, applying a radiation-responsive agent to portion of the anatomy, and exposing the radiation-responsive agent to radiation directed onto the agent by the reflector to cause the agent to therapeutically interact with the site. The scanning beam assembly including a radiation source capable of emitting radiation, a reflector that receives the radiation from the radiation source to direct the radiation onto the anatomy, wherein the reflector oscillates in at least two directions to create a scan of the anatomy, a detector to detect radiation returned from the anatomy, and a controller to convert the detected radiation into a displayable anatomy image.

Abstract: A medical device includes a radiation source assembly having at least two radiation sources, where one or more of the radiation sources is adapted to generate an imaging beam for use in visualization of a scene and one or more of the radiation sources is adapted to generate a therapeutic beam for treatment of a medical condition. An optical fiber for directing radiation energy from the radiation source assembly toward a distal end of the medical device in the form of a beam. A reflector that receives the beam from the optical fiber, the reflector configured to direct the beam onto a field-of-view. A receiving system including a detector arranged and configured to receive radiation from the field-of-view to generate a viewable image. The imaging beam and the therapeutic beam are directed to follow a common path from the at least two radiation sources to the reflector.

Abstract: A method of monitoring a condition within a patient's body includes locating a scanned beam imaging unit at an imaging location for a period of time to observe and characterize a portion of the patient's anatomy over at least a portion of the period of time. The scanned beam imaging unit is located at the imaging location using a locating instrument. The locating instrument is removed from the patient's body with the scanned beam imaging unit remaining at the imaging location. With the scanned beam imaging unit at the imaging location, a beam of light is scanned across the portion of the anatomy and light is received from the portion of the anatomy. A video image of the portion of the anatomy is produced from imaging data generated using detected light received from the portion of the anatomy.

Abstract: A method for viewing a portion of a patient's anatomy that comprises placing a scanner assembly including an oscillating reflector in the anatomy, securing the scanner assembly to an anatomical structure, scanning the anatomy with the scanner assembly secured to the anatomical structure, collecting radiation returned from the scanned anatomy, and generating a displayable image of the anatomy.