A vibrating needle device of the invention includes a needle including a main body portion extending in a direction of a first axis and having a groove formed in an outer circumferential surface over an entire circumference in a circumferential direction around the first axis. A tip portion is provided at one end of the main body portion and tapered in a direction away from the main body portion in the direction of the first axis. A vibrating unit is configured to vibrate the needle along the direction of the first axis and a direction of a second axis that intersects with the direction of the first axis.

A method of operating a surgical system including an endoscope, a treatment tool, an overtube, and a sheathing tube. The method includes the following steps: removing the treatment tool from the sheathing tube inserted into a body cavity through a body wall in a state where the sheathing tube is covering an outer circumference of the overtube into which an insertion part of the endoscope and an insertion part of the treatment tool are inserted, while keeping a state where the sheathing tube is covering the outer circumference of the overtube; removing the endoscope from the overtube while keeping a state where the sheathing tube is covering the outer circumference of the overtube; and removing the sheathing tube from the body wall while keeping a state where the sheathing tube is covering the outer circumference of the overtube.

Devices for guiding an instrument into a body of a patient, at a targeted point of entry and along an insertion path at a targeted insertion angle, are described herein, such as a guide for an access needle in a PCNL procedure for accessing the kidney to remove kidney stones, the devices comprising a base component, a guide assembly, and optionally an insertion mechanism. The base component is aligned in use with the point of entry and the guide assembly cooperates with the base component to allow for the instrument to be aligned and fixed at any circumferential angle around an axis perpendicular to the point of entry and at any vertical angle ranging from 0 to 45 degrees away from the axis in a direction toward the body. The optional mechanism allows for mechanical insertion once the instrument is aligned and fixed. Devices and methods disclosed herein allow a medical professional to accurately and stably guide an instrument at a targeted point and angle and to a desired depth, while minimizing the exposure to radiation in the surgical field that is used to image the insertion path.

A body mountable robot may include a set of stages disposed in a parallel configuration. The body mountable robot may include a set of actuating joints, wherein an actuating joint, of the set of actuating joints, is configured to rotate with respect to a corresponding stage of the set of stages. The body mountable robot may include at least one actuator, wherein the at least one actuator is configured to actuate at least one actuating joint of the set of actuating joints. The body mountable robot may include a set of scissor mechanisms, wherein a scissor mechanism, of the set of scissor mechanisms, that is coupled to the actuating joint, is supported by the corresponding stage, and wherein the scissor mechanism is configured to translate with respect to the corresponding stage.

An instrument drive unit includes a hub, a motor pack, and an annular member disposed between the hub and the motor pack. The hub and motor pack each have a surface feature. The motor pack is rotatably coupled to the hub. The annular member defines an upper annular channel, and a lower annular channel. The annular member has a stop formed in each of the upper and lower annular channels. Upon the motor pack achieving a threshold amount of rotation relative to the hub, the surface feature of the motor pack abuts the stop of the lower annular channel to rotate the annular member. Upon the annular member achieving a threshold amount of rotation relative to the hub, the stop of the upper annular channel abuts the surface feature of the hub stopping further rotation of the motor pack.

Tissue localization devices and methods of localizing tissue using tissue localization devices are disclosed. The tissue localization device can comprise a handle comprising a delivery control, a delivery needle extending out from the handle, and a localization element within the delivery needle. The localization element can be deployed out of the delivery needle or retracted back into the delivery needle when the delivery control is translated in a first direction or a second direction, respectively. The localization element can be coupled to a flexible tracking wire.

An apparatus for controlling a needle guide includes a first lever, a second lever, a first cam and a second cam. The first cam is attached to and extends from the first lever to a housing under the needle guide. The second cam is attached to and extends from the second lever to the housing under the needle guide. At least one of the first cam and the second cam is configured to translate rotational movement from the first lever and the second lever to both linear and rotational movement of the needle guide via the housing.

A surgical robotic system has a tool drive coupled to a distal end of a robotic arm that has a plurality of actuators. The tool drive has a docking interface to receive a trocar. One or more sensors in the docking interface sense a magnetic field generated by the trocar. One or more processors are configured to determine a position and orientation of the trocar based on the sensed magnetic field, and then drive the actuators to orient the docking interface to the determined orientation of the trocar, or otherwise guide the robotic arm toward the determined position of the trocar. Other aspects are also described and claimed.

A uterine manipulator includes an elongated shaft assembly, a colpotomy cup supported on the elongated shaft assembly, and a tip assembly. The tip assembly extends distally from the colpotomy cup and has a piercing tip configured to pierce tissue.

A surgical port assembly for use with surgical instruments includes a body including an exterior surface and an interior space defined by an interior surface of the body. The surgical port assembly includes a control interface including a plurality of drive members coupled to the body and controllable to apply a force to a different portion of a shaft of an surgical instrument, when the shaft is disposed within the interior space, to move a distal portion of the surgical instrument to a desired position within a body cavity.