A data processing method performed by a computer (2) for determining the structure of a medical implant (12; 18; 20; 22) which is to replace removed tissue in a patient's body, comprising the steps of:—acquiring a 3D dataset which represents remaining tissue (10; 17) which at least partly surrounded the removed tissue before the latter was removed;—determining the required contour of the implant (12; 18; 20; 22) from the 3D dataset;—simulating forces exerted by the remaining tissue (10; 17) on the contour of the implant (12; 18; 20;22); and—determining a structure dataset which represents the structure of the implant (12; 18; 20; 22) such that the implant (12; 18; 20; 22) has the required contour and can absorb the simulated forces.

A method for modifying the eating behavior of a patient equipped with a gastric restriction apparatus includes the steps of: a. providing an adjustable gastric band (AGB); b. providing a pressure sensor to measure pressure within the AGB; c. providing a processing unit containing instructions to collect a set of pressure measurement and to analyze the set pressure measurement; d. providing a data base comprising data concerning pressure exerted within the AGB by a bolus of liquid food, a bolus of semiliquid food, and a bolus of solid food; e. recording the sets of pressure measurements; f. recording the results; g. communicating the results; h. placing the AGB in position; i. measuring the pressure within the AGB; j. using the distinction of the current eating pattern to modify the eating behavior of the patient.

Disclosed herein is an article comprising a first screw and a second screw, the first screw being reversibly attached to the second screw such that a longitudinal axis of the first screw coincides with or is parallel to a longitudinal axis of the second screw; the first screw and the second screw each comprising a biodegradable composition, the biodegradable composition comprising a metal or metal alloy comprising magnesium, strontium, zinc, calcium or a combination comprising at least one of the foregoing. Methods of making and using the article are also disclosed herein.

Disclosed herein is an article comprising a first screw and a second screw, the first screw being reversibly attached to the second screw such that a longitudinal axis of the first screw coincides with or is parallel to a longitudinal axis of the second screw; the first screw and the second screw each comprising a biodegradable composition, the biodegradable composition comprising a metal or metal alloy comprising magnesium, strontium, zinc, calcium or a combination comprising at least one of the foregoing. Methods of making and using the article are also disclosed herein.

Provided are hybrid biomaterials comprising one or more layers of cross-linked poly(propylene fumarate) and/or cross-linked copolymer comprising a plurality of cross-linked propylene fumarate moieties. The layers may further comprise a plurality of microparticles, a plurality of micropores, or both a plurality of microparticles and a plurality of micropores encapsulated within the cross-linked poly(propylene fumarate) and/or cross-linked copolymer comprising a plurality of cross-linked propylene fumarate moieties. One of the layers is disposed on a compliant matrix dense tissue substrate (e.g., a pericardium tissue substrate). The hybrid biomaterials can be used, for example, in method of repairing tissue defects.

Provided are hybrid biomaterials comprising one or more layers of cross-linked poly(propylene fumarate) and/or cross-linked copolymer comprising a plurality of cross-linked propylene fumarate moieties. The layers may further comprise a plurality of microparticles, a plurality of micropores, or both a plurality of microparticles and a plurality of micropores encapsulated within the cross-linked poly(propylene fumarate) and/or cross-linked copolymer comprising a plurality of cross-linked propylene fumarate moieties. One of the layers is disposed on a compliant matrix dense tissue substrate (e.g., a pericardium tissue substrate). The hybrid biomaterials can be used, for example, in method of repairing tissue defects.

A two dimensional (2D) active plasmonic scaffold includes a polymer film and one or more nanoparticle layers disposed on the polymer film. The nanoparticles has functional groups attached thereon. A three dimensional (3D) structure fabricated using the 2D scaffold.

A two dimensional (2D) active plasmonic scaffold includes a polymer film and one or more nanoparticle layers disposed on the polymer film. The nanoparticles has functional groups attached thereon. A three dimensional (3D) structure fabricated using the 2D scaffold.

Methods, systems, and computer readable media for physiology parameter-invariant meal detection are disclosed. According to one system, the system includes at least one processor and a meal detection module implemented using the at least one processor. The meal detection module is configured to receive insulin intake information and blood glucose level information for a user, to detect a meal event using a physiology parameter-invariant meal detection algorithm, and after detecting the meal event, to perform at least one control action associated with insulin management.

A burr hole cover includes a cap or cap assembly and a retainer and is configured to be partially positioned within a burr hole formed in a patient. The retainer has a cap-receiving aperture; a plurality of grooves provided in the retainer and a plurality of cut-outs wherein each cut-out is provided at an end of each groove towards the outer perimeter of the retainer. A channel may be provided at an opposite end of each groove vertically-extending from the top to the bottom of the retainer to encourage a medical device segment to remain in a groove during installation of the burr hole cover. The burr hole cover may be used to secure segments of medical devices relative to a burr hole and to allow a range of lateral motion for the portion(s) of the medical device(s) extending proximally out of the corresponding groove.