A hand-held electromechanical surgical device is configured to selectively connect with a surgical accessory. The surgical device includes a power-pack, an outer shell housing, and a gasket. The power-pack is configured to selectively control a surgical accessory. The outer shell housing includes a distal half-section and a proximal half-section, the distal half-section and the proximal half-section together defining a cavity configured to selectively encase substantially the entire power-pack therein. The gasket is located between the distal half-section and the proximal half-section of the outer shell housing. The gasket is configured to create a seal between the distal half-section and the proximal half-section and to provide a sterile barrier between the power-pack and an outside environment outside the outer shell housing.

A method of operating a surgical assembly is disclosed. The method includes receiving a first input from a first RFID scanner indicative of a first information stored in a first RFID chip of a first modular component of the surgical assembly, receiving a second input from a second RFID scanner indicative of a second information stored in a second RFID chip of a second modular component of the surgical assembly, determining an operational parameter of a motor of the surgical assembly based on the first input and the second input, and causing the motor to effect a tissue treatment motion of the first modular component.

A surgical fastener applier including a housing containing a compartment, an elongated member extending distally from the housing, first and second jaws and a firing mechanism positioned within the housing. The firing mechanism is movable between a first position and a second position to effect firing of fasteners into the tissue clamped between the first and second jaws. A cover on the housing is openable to access the compartment. A power pack is removably loadable into the compartment, the power pack having a motor and an engagement member removably engageable with the firing mechanism within the compartment when the power pack is loaded into the compartment to effect movement of the firing mechanism from the first position to the second firing position.

A fluid retaining tray including a tray surface panel having a fluid retaining space. A first side panel extends outwardly from a first side edge of the tray surface panel and rotatable relative thereto between a storage position and an operative position. The first side panel has a first flap rotatably secured thereto. The flap has an engagement element selectively securable to the tray surface panel for securing the first side panel in an operative position. The first side panel has a distal end including a first recess adapted to retain a first tube end above the fluid retaining space.

A loading unit removably loadable into a surgical instrument positioned within a body of a patient having an elongated member, first and second jaws at a distal portion and a firing mechanism movable within the elongated member to effect firing of fasteners into the tissue clamped between the first and second jaws. The loading unit is insertable into a proximal opening of the instrument and through a lumen in the shaft of the instrument while the instrument is positioned in the body of the patient. The first and second jaws extend distally of the shaft of the instrument and the loading unit is actuable by the instrument. A surgical instrument to receive the loading unit and a method for reloading the instrument are also provided.

A storage case with a biomedical electrode pad for storing a biological signal processing circuit unit for processing an biological electrical signal which has been detected by the biomedical electrode pad, wherein a case body thereof has a storage area for the biological signal processing circuit unit, the storage area being provided in an openable and closable manner, and the biological signal processing circuit unit is detachable with respect to the storage area.

An enclosure for an electronic device, such as a wearable physiological monitor, may be formed of at least two different materials, e.g., a first part formed of a first material (e.g., a metal) and a second part formed of a second material (e.g., a plastic). The second part may include an opening to receive at least a portion of the first part therein, where the first part includes an anchor projecting from a surface thereof into the opening of the second part. To ensure that the enclosure is waterproof, a third part that can be chemically bonded to the second part may secure the first part by filling a volume between the anchor of the first part and an adjacent surface of the second part around the opening. In some aspects, the chemical bond between the second part and the third part creates an environmental seal around the opening.

A liner for an endoscope storage tray is provided. The liner has an interior comprising a flexibly deformable material substantially impermeable to fluids and an absorbent material disposed within or attached to at least a portion of the flexibly deformable material. The liner is configured to temporarily line at least an interior of the endoscope storage tray. Systems and methods are also provided.

A sheath for an oximetry device includes a top and a body where the top opens to provide an opening where the oximetry device can be placed into the body of the sheath. The top of the sheath can be closed onto the body and the closure of the top can be verified by circuits in the oximetry device. The circuits can monitor the position of a latch that is connected to the top of the sheath. The circuits can determine when the latch is unlatched and the top is open and not sealed closed to the body. And, the circuits can determine when the latch is latched and the top is closed and sealed to the body.

An enclosure for an electronic device, such as a wearable physiological monitor, may be formed of at least two different materials, e.g., a first part formed of a first material (e.g., a metal) and a second part formed of a second material (e.g., a plastic). The second part may include an opening to receive at least a portion of the first part therein, where the first part includes an anchor projecting from a surface thereof into the opening of the second part. To ensure that the enclosure is waterproof, a third part that can be chemically bonded to the second part may secure the first part by filling a volume between the anchor of the first part and an adjacent surface of the second part around the opening. In some aspects, the chemical bond between the second part and the third part creates an environmental seal around the opening.