A surgical navigation system is provided to create a plan to correct a deformed spinal alignment. A processor is configured to obtain a first set of image data associated with a deformed alignment in a spine of a patient from at least one imaging device. The processor is also configured to process the first set of image data to identify a set of deformed alignment parameters associated with the deformed alignment. The processor is further configured to identify a set of corrected alignment parameters. The processor is also configured to process the first set of image data, the set of deformed alignment parameters, and the set of corrected alignment parameters to generate a correction plan to surgically manipulate the deformed alignment to the preferred alignment. The processor is additionally configured to provide navigation through the correction plan to facilitate surgical manipulation of a patient spine to the preferred alignment. The processor is also configured to receive information relating to forces on a rod-link reducer or surgical implants from strain gauges to aid the correction plan.

In an embodiment, a method includes receiving, by a user device, a code start trigger, where the user device is dockable on a crash cart and in communication with a controller disposed in relation to the crash cart. The method also includes, responsive to the code start trigger, initiating a code workflow, creating an event log for the code workflow, and determining a patient rhythm. The method also includes monitoring for real-time code events. The monitored real-time code events include patient intervention and a new patient rhythm. The method also includes, responsive to a determination that a real-time code event has occurred, executing programmed action that includes updating the event log.

A trolley system configured to transport a patient within an MRI environment includes a patient support portion, a base portion configured for movement relative to a floor, a lift coupled to the patient support portion and the base portion, an electric motor coupled to the lift, and an electric blower coupled to the patient transfer device. The lift is configured to change the elevation of the patient support portion relative to the base portion. The motor is mounted such that the elevation of the motor is fixed relative to base portion. The trolley system is positionable adjacent an MRI apparatus within the MRI environment and the magnetic field of the MRI does not interfere with the operation of the motor or blower. The trolley system may further include a patient transfer device having an air bearing. The blower is configured to deliver air to the air bearing.

A camera tracking system for computer assisted navigation during surgery. The camera tracking system includes a processor operative to receive streams of video frames from tracking cameras which image a plurality of physical objects arranged as a reference array. For each of the physical objects imaged in a sequence of the video frames, that processor determines a set of coordinates for the physical object over the sequence of the video frames. For each of the physical objects, the processor generates an arithmetic combination of the set of coordinates for the physical object. The processor generates an array template identifying coordinates of the physical objects based on the arithmetic combinations of the sets of coordinates for the physical objects, and tracks pose of the physical objects of the reference array over time based on comparison of the array template to the reference array imaged in the streams of video frames.

The present disclosure relates to a method for determining a target spot path, which is applied to a determining system including a shooting device and a locating device that are separate from each other, and a calibration device connected to the shooting device, the method comprising: S1. obtaining a three-dimensional partial image for an affected part and a virtual path located in the three-dimensional partial image; S2. matching a simulated two-dimensional image obtained based on projection of the three-dimensional partial image with a two-dimensional projection image obtained based on the affected part; S3. determining a surgical guide path on the two-dimensional projection image that corresponds to the virtual path according to position information of the virtual path on the simulated two-dimensional image, when the simulated two-dimensional image and the two-dimensional projection image are matched; and/or S4.

Embodiments of the present disclosure provide a surgical robot system may include an end-effector element configured for controlled movement and positioning and tracking of surgical instruments and objects relative to an image of a patient's anatomical structure. In some embodiments the end-effector and instruments may be tracked by surgical robot system and displayed to a user. In some embodiments, tracking of a target anatomical structure and objects, both in a navigation space and an image space, may be provided by a dynamic reference base located at a position away from the target anatomical structure.

An imaging apparatus that is easily moved between locations protects an imaging element in motion and provides a first arm member and a proximate movable second arm member. A lighting-imaging element is movably positionable proximate an arm mechanism and also proximate a rear-side location of a wheeled platform relative to a traveling direction thereby preventing damage. The first and second arm are relatively surrounded with a sub-arm and lighting-imaging element, thereby preventing further unintended movement. Accordingly, an elongating (separation) of the first and second arm members are prevented.

A surgical robotic system includes an image processing device configured to receive an endoscopic video feed and generate a stereoscopic video feed with confidence shading overlays on display. The confidence shading is based on a level of confidence associated with uncertain regions within images making up the stereoscopic video feed.

A trigger point treatment system for treating a patient, includes a cart, including a display; a trigger point scanning device with a scanning probe, and a trigger point massage therapy device, including a pressure point tip, a pressure sensor component, and an actual pressure indicator. A method of trigger point treatment includes scanning for myofascial trigger points, including locating, mapping, and marking trigger points; measuring a pressure pain threshold; applying a massage treatment; and optionally applying an injection treatment.

A system may comprise a connection member configured to be connected to an anatomic orifice device. The anatomic orifice device may be configured for insertion into a patient. The system may also comprise a mounting bracket coupled to a robot-assisted medical system. The mounting bracket may also include a movable mounting component coupled to a fixed mounting component. The movable mounting component may have a first configuration for mounting to the connection member in a first engagement and a second configuration for mounting to the connection member in a second engagement. The connection member may be spaced apart from the fixed mounting component in the first engagement and may be in direct contact with the fixed mounting component in the second engagement.