A medical cart is provided that allows confirmation that individual medicines have been managed at appropriate temperatures. The medical cart includes: shelves on which medicines can be placed; and a control part which communicates with an RF tag provided for each of the medicines and equipped with a temperature sensor, at appropriate time intervals via an antenna part provided in the vicinity of each of the shelves, and the control part has a memory part which stores ID information of the RF tag and temperature information sensed by a temperature sensor of the RF tag.

Disclosed is a portable rehabilitation apparatus and method for use of the apparatus by a user or patient. The apparatus is adapted for transitioning between a collapsed state to facilitate the mobility of the rehabilitation robot (e.g., using wheels) and an open state for operation of the rehabilitation robot by the user. The apparatus includes the rehabilitation robot that is contained within a compartment defined by a housing which is made up of moveable portions. The apparatus also includes a mast assembly adapted to form a gap between the moveable housing portions in order to provide the user with access to the rehabilitation robot. The mast assembly is further adapted to collapse, thereby eliminating the gap and closing off the compartment when the rehabilitation robot is not in use.

A method of dispensing medication including: filling a medication container with one or more medication dose, using one or more actuator of a medication dispenser device, according to a prescription for a specific patient, where the prescription is stored in a patient record for the specific patient; verifying delivery of the medication container to a vicinity of the specific patient and/or an environment of the specific patient, where the verifying includes generating a delivery verification signal; verifying use of the one or more medication dose, where the verifying includes generating a use verification signal; and where one or both of the use verification signal and the delivery verification signal are generated using and/or interacting with the medication container.

A cart for medical equipment includes a base having one or more wheels, a column supported by the base, and a platform supported on the column and opposite the base. The platform is configured to mount a piece of medical equipment to the cart. The cart also includes an adapter plate securable to the piece of medical equipment and configured to releasably couple to the platform. The adapter plate includes a locking assembly having one or more handles that upon actuation releases the adapter plate from the platform.

Described herein are systems and methods related to image management. A system may include an instrument that includes an elongate body and an imaging device. The elongate body can be configured to be inserted into a luminal network. The imaging device may be positioned at a distal tip of the elongate body. The system may receive from the imaging device one or more images captured when the elongate body is within the luminal network. For each of the images, the system may determine one or more metrics that are indicative of a reliability of an image for localization of the distal tip of the elongate body within the luminal network. The system may determine a reliability threshold value for each of the one or more metrics. The system can utilize the one or more images based on whether the one or more metrics meet corresponding reliability threshold values.

Systems and methods for adjusting remote center distances in medical procedures are provided. In one aspect, a robotic medical system includes a first robotic arm including a first instrument driver, wherein the first instrument driver is configured to manipulate a first tool that passes through a first cannula, and a second robotic arm including a second instrument driver, wherein the second instrument driver is configured to manipulate a second tool that passes through a second cannula. The first tool is configured to rotate about a first remote center of motion and the second tool is configured to rotate about a second remote center of motion. A first remote center distance between the first robotic arm and the first remote center of motion is different from a second remote center distance between the second robotic arm and the second remote center of motion.

Provided are systems and methods for location sensor-based branch prediction. In one aspect, the method includes determining a first orientation of an instrument based on first location data generated by a set of one or more location sensors for the instrument and determining a second orientation of the instrument at a second time based on second location data. A distal end of the instrument is located within a first segment of a model at the first time and the second time and the first segment branches into two or more child segments. The method also includes determining data indicative of a difference between the first orientation and the second orientation and determining a prediction that the instrument will advance into a first one of the child segments based on the data indicative of the difference.

A cart for dispensing, storing, and tracking medical instruments is provided. The cart has a housing, a first motor, a second motor, one or more trays, and a processor. The trays hold one or more medical instruments, and have a door and door opening assembly. The processor is in communication with the motors for rotating the housing and opening the doors. The processor has a storage medium for storing the cart's instrument dispensing history. The processor also has a user interface for capturing user input.

Examples of a module for housing unrelated electronic and electromechanical equipment for use during surgery. The module can include a lower section and a tower-like upper section. The lower section can house unrelated electronic and electromechanical equipment. The tower-like upper section can be located on top of the lower section. A water-resistant cowling can enclose at least a portion of the lower section and the tower-like upper section. A cartridge containing one or more ultraviolet-C producing lights can be protectively housed within the tower-like upper section. The cartridge containing one or more ultraviolet-C producing lights can be configured to emerge upward from a top of the tower-like upper section to substantially seat itself on the top of the tower-like upper section when activated allowing the ultraviolet-C light to disinfect the patient and staff-contacting upper surfaces of the equipment in the operating room.

Modular automated dispensing systems for dispensing secured medications in a medical environment are provided. The system includes a compact enclosure configured to be disposed in a medical treatment area without taking up valuable floor space. The system includes lockable drawers having one or more compartments for storing and dispensing medications or medical supplies. The system is unlocked by use of an access control interface internally or externally connected directly to the system, or networked to the system through a medical center network.