A computer-implemented method for collecting data within a facility is disclosed. The method includes receiving, by a computer system, perioperative data from a plurality of surgical devices located within the facility, the perioperative data associated with a plurality of surgical procedures performed in the facility; determining, by the computer system, procedural context data associated with the plurality of surgical procedures based at least in part on the perioperative data; aggregating, by the computer system, the perioperative data according to the procedural context data; and determining, by the computer system, trends associated with the surgical procedures performed in the facility according to the perioperative data and the procedural context data.

A processor acquires a confirmation radiographic image including a surgical tool. In a case in which a radiographic image is input, the processor detects a region of the surgical tool from the confirmation radiographic image using a discriminator that detects the region of the surgical tool included in the radiographic image.

A processor detects a surgical tool from a radiographic image acquired by irradiating a subject with radiation emitted from a radiation source and detecting the radiation transmitted through the subject with a radiation detector. The processor measures a size of the detected surgical tool on the radiographic image. The processor derives a position of the surgical tool in a height direction in the subject on the basis of an actual size of the surgical tool, the measured size, and a geometrical positional relationship between a position of the radiation source and a position of a detection surface of the radiation detector.

Medical procedure related objects (e.g., instruments, supplies) tagged with transponders (e.g., RFID transponders, dumb transponders) are accounted for in a medical or clinical environment via an accounting system using a number of antennas and interrogators/readers. A first set of antennas and RFID interrogator(s) interrogate portions of the environment for RFID tagged objects, for example proximate a start and an end of a procedure. A cannula of a trocar may include one or more trocar antennas positioned and oriented to integrate tapped objects that pass through a lumen of the cannula. Shielded packaging and/or shielded receptacles shield tagged objects, preventing interrogation except for those objects in unshielded portions of the environment. A data store may maintain information including a current status or count of each instrument or supply, for instance as checked in or checked out. A handheld antenna and/or second set of antennas interrogates a body of a patient for retained instruments or supplies tagged with dumb transponders.

An interrogation and detection system for detection of surgical implements within a patient's body, the system including One or more RFID tags affixed to a surgical implement within the patient's body. Each RFID tag being configured to transmit a return signal when energized, and a remote signal generator configured to generate an energizing signal for the one or more RFID tags. The signal generator operably coupled to the in-vivo introducible antenna via a communication cable. The system further includes an in-vivo introducible antenna configured to be inserted through a trocar-cannula assembly into a surgical site within the patient's body. Wherein the tubular channel defines a shape having a dimension “D1”, such that the dimension “D1” of the tubular channel is less than the dimension “D2” of the in-vivo introducible antenna.

Modulated light therapy devices for treatment of dermatological disorders of the scalp are provided. An exemplary device includes a flexible printed circuit board (FPCB) supporting at least one light emitting device having an emitter height. The FPCB includes multiple interconnected panels and bending regions defined in and between at least some of the interconnected panels as to allow the FPCB to be configured in a concave shape to cover at least a portion of a cranial vertex of the patient. At least one light-transmissive layer proximate to the FPCB is configured to transmit (e.g., incoherent) light emissions generated by at least one light emitting device. At least one standoff is configured to be arranged between the FPCB and the scalp of the patient, wherein the at least one standoff includes a standoff height that exceeds the emitter height.

A method for controlling an output of an energy module of a modular energy system. The energy module can comprise a plurality of amplifiers configured to generate a drive signal at a frequency range and a plurality of ports coupled to the plurality of amplifiers. The method includes determining to which port of the plurality of ports the surgical instrument is connected, selectively coupling an amplifier of the plurality of amplifiers to the port of the plurality of ports to which the surgical instrument is connected, and controlling the amplifier to deliver the drive signal for driving the energy modality to the surgical instrument through the port.

Aspects of the present disclosure relate to a system including an image capture device and a computing device configured to receive a test image from the image capture device corresponding to a first surgical instrument, determine an identity type of the first surgical instrument using the test image in a machine vision technique, determine whether the first surgical instrument is flagged, and perform at least one operation in response to whether the first surgical instrument is flagged.

Methods of operating a surgical instrument are disclosed herein.

An adapter assembly is provided and includes a housing for connection with a surgical device and for operative communication with at least one rotatable drive shaft of the surgical device; an outer tube having a proximal end supported by the housing and a distal end for connection with a selected end effector, wherein the distal end of the outer tube is in operative communication with each of the at least one force receiving drive member of the end effector; at least one drive transmitting/converting assembly for interconnecting a respective one of the at least one rotatable drive shaft of the surgical device and one of the at least one force receiving drive member of the end effector; and a circuit board supported in the housing and storing at least one of operating parameters and life cycle information which are unique to the adapter assembly.