An apparatus includes a cart having a vertical adjustment element configured to adjust a distance between the platform and a ground supporting the cart, the cart defining a surface for supporting an arm of the patient. The apparatus includes a manipulation device including a plurality of motors each configured to operably couple to a different one of a needle, a catheter, and a guidewire to selectively advance one or more of the needle, the catheter, and the guidewire, and a robotic arm having a first end mounted to the cart and a second end coupled to the manipulation device, the robotic arm having a plurality of segments joined together via a plurality of joints such that the robotic arm can be moved to position the needle, the catheter, and the guidewire for insertion into a target vessel in the arm.

Various implementations include an automated endotracheal intubation device, including: a flexible tube sized to be advanced within a patient's airway; a base system; and a deployment arm having a proximal end coupled to the base system and a distal end spaced apart from the proximal end, the deployment arm including: at least one arm segment coupled to and extending from the base system, the at least one arm segment defining a channel within which the flexible tube is disposed; and an end effector coupled to the distal end of the deployment arm, the end effector including one or more twisted and coiled polymer (TCP) tendons configured to controllably expand and contract upon application of heat.

A retractor mounting assembly including an end-effector having a body extending between first and second faces. The first face is configured for attachment to an interface plate on the robotic arm of a surgical robot. The second face defines an arm mount. An arm extending between first and second ends with the first end configured for attachment to the end-effector arm mount and the second end providing a retractor mount configured for supportive attachment of a retractor.

A robotic interventional device control system includes a first hub assembly coupled to a first interventional device and including a first proximal end and a first distal end; and a second hub assembly coupled to a second interventional device and positioned distal to the first hub assembly. The second hub assembly includes a second proximal end and a second distal end. The system includes a sensor system configured to detect a first position of the first hub assembly and a second position of the second hub assembly; and one or more hardware processors configured to generate a user interface. The user interface includes a drive table window including a first representation of the first hub assembly and a second representation of the second hub assembly.

An apparatus for vascular access is described herein. The apparatus can comprise a manipulating device configured to releasably couple a cartridge including a needle, a catheter, and a guidewire that are coaxially disposed with respect to each other, and a robotic arm coupled to the manipulating device. The manipulation device or cartridge can include a plurality of actuation mechanisms configured to selectively advance the needle, the catheter, and the guidewire when the manipulating device is coupled to the cartridge. The robotic arm can include a plurality of joints that are configured to rotate about a plurality of axes to position the cartridge relative to the arm of the patient such that the needle, the catheter, and the guidewire can be inserted into a target vessel of the patient.

A method for providing a corrected dataset includes receiving a preoperative dataset having an image and/or a model of an examination region in an examination subject. Intraoperatively, a first part of a medical object is arranged in the examination region and a second part of the medical object is arranged outside the examination subject. Positioning information relating to a spatial positioning of the second part of the medical object is received. An entry angle of the medical object into the examination subject is determined using the positioning information. An intraoperative dataset having an image of the examination region is received. A conversion instruction is determined based on the entry angle of the medical object to minimize a deviation between the preoperative and the intraoperative dataset, and the corrected dataset is generated by applying the conversion instruction to the preoperative dataset. The corrected dataset is provided.

Systems and methods for introducing and driving flexible members in a patient's body are described herein. In one embodiment, a robotic method includes positioning a flexible elongated member that has a preformed configuration, wherein at least a part of the flexible elongated member has a first member disposed around it, and wherein the first member includes a first wire for bending the first member or for maintaining the first member in a bent configuration, releasing at least some tension in the first wire to relax the first member, and advancing the first member distally relative to the flexible elongated member while the first member is in a relaxed configuration.

A hub assembly for a robotically driven interventional device can include an interventional device hub having an interventional device and at least one magnet. The hub assembly can be configured to be positioned on a sterile side of a sterile field barrier and magnetically couple to a hub adapter on a non-sterile side of the sterile field barrier so that hub assembly moves axially in response to axial movement of the hub adapter and the at least one magnet of the hub assembly rotates in response to rotation of at least one magnet of the hub adapter.

An object sizing system sizes an object positioned within an anatomical feature. The object sizing system navigates an elongate body to a location within an anatomical feature and proximate to the object. An imaging sensor coupled to the elongate body captures images of the object. The object sizing system captures the object with a basket. The object sizing system captures an image of the object with the imaging sensor. The object sizing system detects a basket marker in the captured image. The object sizing system determines a distance from the object to the imaging sensor based on the detected basket marker. The object sizing system determines an estimated size of the object based at least in part on the distance.

A robotic system includes a medical instrument comprising an elongate shaft dimensioned to be disposed at least partially within an access sheath and control circuitry configured to cause the elongate shaft to be retracted at least partially within the access sheath, determine a position of a distal end of the elongate shaft relative to the access sheath, and modify a speed of retraction of the elongate shaft based on the determined position of the distal end of the elongate shaft relative to the access sheath.