A laparoscopic surgery support system can include a plurality of ports configured to receive a trocar therethrough and a plurality of arms connecting the plurality of ports together and configured to allow fixation of a relative position of the plurality of ports. For example, the plurality of ports can include three or more ports.

A motorized arm for a robotic medical system can include a shoulder coupled to a column of a table by a translational joint that allows translation of the shoulder along the column, a first link rotationally coupled to the column, a second link rotational coupled to the first link, and an arm support coupled to a distal end of the second link. The arm support can be configured to support one or more robotic arms usable during a robotic medical procedures. The motorized arm can include actuators for driving rotation of the links and arbors that can be engaged to increase the torsional stiffness of the motorized arm. The motorized arm can move the arm support between a stowed position below the table to a deployed position.

Disturbance compensation in computer-assisted devices include a first articulated arm configured to support an imaging device a second articulated arm configured to support an end effector, and a control unit coupled to the first articulated arm and the second articulated arm. The control unit is configured to set a first reference frame, where the first reference frame is based on a first position of the imaging device at a first time. The control unit is further configured to detect a first disturbance to the first articulated arm moving the imaging device away from the first position, receive a command to move the end effector, and transform the command to move the end effector from a command in the first reference frame to a command in a reference frame for the end effector.

Apparatuses and methods described herein relate to arm carts for transporting and securing a robotic arm to a surgical table. In some embodiments, an arm cart may include an arm support having two joints that can be manipulated to move an arm into a position in which a coupler of the arm is engageable with a coupling site of a surgical table. In some embodiments, an arm cart may include an arm support that is rotatable and translatable to permit movement of an attachment area for receiving and attaching a coupling site of a surgical table to a coupler attached to an arm. In some embodiments, an arm cart may include an arm support that releasably couples to a middle segment of the arm positioned at least two segments away from an end of the arm having a coupler for coupling to a coupling site of a surgical table.

A joint locking mechanism of a passive robotic arm includes: an output assembly, including a joint output shaft, and a friction disk fixed to the joint output shaft; a braking assembly, including a threaded shaft arranged coaxially with the joint output shaft, a threaded sleeve threaded to the threaded shaft, a rotary disk connected fixedly to the threaded shaft, an end cap rotatable relative to the rotary disk, and a scroll spring generating a rotational force on the threaded shaft. The scroll spring has one end connected fixedly to the end cap and the other end connected to the rotary disk or the threaded shaft. The threaded sleeve is abutted tightly against the friction disk.

A joint locking mechanism of a passive robotic arm includes: an output assembly, including a joint output shaft, and a friction disk fixed to the joint output shaft; a braking assembly, including a threaded shaft arranged coaxially with the joint output shaft, a threaded sleeve threaded to the threaded shaft, a rotary disk connected fixedly to the threaded shaft, an end cap rotatable relative to the rotary disk, and a scroll spring generating a rotational force on the threaded shaft. The scroll spring has one end connected fixedly to the end cap and the other end connected to the rotary disk or the threaded shaft. The threaded sleeve is abutted tightly against the friction disk.

A reusable flexible arm stabilizes tissues during surgical procedures. The stabilizer arm switches between a flexible state for conforming to a desired curvature and a rigid state for maintain a desired positioning. A suspension length provided by the stabilizer arm is also adjustable. The arm has an articulating portion with successive articulating links each having a central passage. A length adjustable portion has successive length-adjustable links each having a central passage. A tension cable extends through the central passages between a proximal one of the length-adjustable links and a distal one of the articulating links. A base member captures the length-adjustable links at a position corresponding to a desired extension length of the arm. A control mechanism is movable between a retracted position and an extended position to selectably separate the captured length-adjustable links, thereby adjusting a tension in the tension cable and a rigidity of the stabilizer arm.

The present application relates to a computer-implemented medical method of determining a compensation for gravity-related displacements of a medical carrier structure having at least one adjustable and selectively fixable joint which respectively connects two sections of the carrier structure. The present application further relates to a corresponding computer program and medical system.

A holding device for medical purposes holds an attached device. The holding device has a proximal end for attaching the holding device to a base and a distal end for receiving the attached device. The holding device also has a first arm segment and a second arm segment. The first arm segment is connected to a first joint and the second arm segment is connected to a second joint. Each joint is releasable or lockable. The holding device further has an operator control device for releasing and/or locking the first or second joint for placing the holding device in a desired pose. The holding device also has a controller for controlling the holding device and at least one receiver for electromagnetic radiation connected to the controller for transmitting signals to the controller based on received electromagnetic signals of a surgical navigation system.

In an embodiment, a system attaches a patient reference array of a computer-assisted surgery system to a patient. The system includes a fixation post having a shaft having proximal and distal ends that are offset from. A threaded fastener is coupled to the shaft at the distal end that rotates relative to the shaft so as to engage internal threads of a pedicle screw, thereby causing the distal end of the shaft to translate in the anchor seat and urge the pedicle screw to transition from an unlocked configuration to a locked configuration. The attachment assembly has an arm that supports the patient reference array, and a coupler supported by the arm. The coupler has a fixation body that defines a recess that receives at least a portion of the fixation post, and an actuator that secures the attachment assembly to the fixation post.