The present disclosure relates to a sterilization packaging method for a body-attachable biometric monitoring device. Provided is a sterilization packaging method for a body-attachable biometric monitoring device, the method in which a sterilization packaging process can be performed in a convenient and simple manner, further contamination which can occur during a sterilization process is prevented, damages due to moisture and the like after the packaging is complete are also prevented and thus complete sterilization packaging can be performed, in order to separately perform a sterilization packaging step in two steps, primary packaging is performed for a sterilizable state and then sterilization is performed, secondary packaging is performed to maintain airtightness for a primary packaged article which has been sterilized and thus penetration by an external contaminant and the like during the sterilization and packaging processes is prevented to prevent damages to a biometric monitoring device, a separate adsorbent is positioned outside the primary packaged article and then the secondary packaging is performed and thus functional degradation of the adsorbent during the sterilization process is prevented to enable inner packaging of the adsorbent in an excellent functional state, and a moisture removal function can be performed stably to enable a complete sterilization packaging.

A packaging, in particular sterile packaging, for a medical product, includes a receiving space for the medical product. A portion of the packaging facing the receiving space is made at least in part, preferably entirely, of a resorbable material.

A staple cartridge comprising a cartridge body, a longitudinal slot defined in the cartridge body, and a deck surface positioned on a first side of the longitudinal slot is disclosed. The deck surface comprises a plurality of staple cavity openings. The staple cartridge further comprises staples removable stored in the staple cavity openings, a honeycomb extension extending above the deck surface, and a plurality of through holes defined in the honeycomb extension. Each through hole is aligned with a corresponding staple cavity opening. Each through hole is larger than the corresponding staple cavity opening. The through holes are configured to prevent the flow of tissue when the staples are ejected from the staple cavity openings during a staple firing stroke.

A packaging system providing for sterile enclosure of devices including medical devices and systems such as delivery systems is described. The packaging system is comprised of a primary chamber and includes at least one vent or opening covered by a barrier.

An implantation device for prompt subcutaneous implantation of a sensor to measure a physiological signal of an analyte in a biofluid of a living body is disclosed. The implantation device includes a housing, an implantation module, a detachable module and a bottom cover. The housing has a bottom opening. The implantation module includes an implanting device and a needle extracting device. The detachable module includes the sensor detachably engaged with the implantation module; and a base configured to mount the sensor thereon. The bottom cover is detachably coupled to the bottom opening so that the housing and the bottom cover together form an accommodating space. The implantation module and the detachable module are accommodated in the accommodating space. The bottom cover has an operating portion configured to bear a force, and a supporting portion is formed on the opposite end of the operating portion.

An air-tight desiccating container for storing therein a sensor to be implanted into a subcutaneous portion of a living body is disclosed. The air-tight desiccating container includes a housing, an implanting module, a detachable module mounted on the housing, a bottom cover and a desiccating element. The housing includes an accommodating space and a bottom opening having a first joint portion. The implanting module is mounted in the housing and includes a needle implanting device and a needle extracting device. The detachable module includes the sensor having a chemical reagent for measuring a physiological signal from the living body having a skin surface and a lower mount base configured to assemble the sensor thereon. The bottom cover is detachably coupled to the bottom opening, and has a second joint portion.

A method for assembling a physiological signal monitoring apparatus on a body surface of a living body is provided, wherein the physiological signal monitoring apparatus is used to measure a physiological signal and includes a sensor module and a transmitter. The method comprises steps of: (a) detaching the bottom cover from the housing to expose the sticker from the bottom opening; (b) while holding the housing, causing the adhesive pad to be attached to the body surface; (c) applying a pressing force on the housing to cause the sensor module to be detached from the implantation module and the signal sensing end to be implanted under the body surface; (d) removing the implanting device while leaving the sensor module on the body surface; and (e) placing the transmitter on the base so that the signal output end is electrically connected to the port.

A sterile packaging assembly configured to receive a surgical instrument is disclosed. The sterile packaging assembly comprises a vacuum-molded tray and a particulate trap. The vacuum-molded tray comprises an instrument cavity configured to receive the surgical instrument, and a trap cavity. The particulate trap is positioned in the trap cavity. The particulate trap comprises a housing including a funnel shaped side terminating in an opening. The opening is in communication with a chamber defined in the particulate trap.

A surgical instrument comprising an instrument housing and a power unit releasably attachable to the instrument housing is disclosed. The instrument housing comprises a battery dock including a first electrical contact. The power unit comprises rechargeable battery cells, a first housing, and a second housing. The battery cells are positioned in the first housing. The first housing is enclosed within the second housing to create a sterile barrier around the first housing. The second housing comprises a second electrical contact and retention means for securing the power unit to the instrument housing. The second electrical contact is configured to electrically couple the battery cells of the first housing to the first electrical contact of the battery dock when the power unit is attached to the instrument housing.

A staple cartridge comprising a cartridge body comprising a longitudinal slot, a deck surface, and a plurality of staple cavities defined in the cartridge body is disclosed. The cartridge body further comprises a plurality of projections extending from the deck surface. A surface of each projection is flush with one of a proximal end wall and a distal end wall of each staple cavity. The staple cartridge further comprises staples removably stored in the staple cavities.