Medical systems, devices and methods for creation of autologous tissue valves within a mammalian body are disclosed. One example of a device for creating a valve flap from a vessel wall includes an elongate tubular structure having a proximal portion and a distal portion and a longitudinal axis; a first lumen having a first exit port located on the distal portion of the elongate tubular structure; a second lumen having a second exit port located on the distal portion of the elongate tubular structure; a recessed distal surface on the distal portion of the elongate tubular structure, wherein the recessed distal surface is located distally to the first exit port; and an open trough on the recessed distal surface extending longitudinally from the first exit port.

Components, systems and kits for capturing and removing tissue from mammalian bodies include a tissue container that may be introduced into a body cavity and within which a tissue specimen may be placed, cut and removed from the body cavity. Methods of using these components, systems and kits are also described.

A seal assembly including a septum seal, a lower seal support, an upper seal support and a return spring is disclosed. The septum seal includes an orifice and a plurality of apertures. The lower seal support includes an engagement surface configured to engage a portion of the septum seal. The upper seal support includes a plurality of fingers, wherein each of the plurality of fingers is configured to extend through a corresponding aperture of the septum seal. The return spring includes a collar portion and a plurality of spokes extending radially outward from the collar portion. At least a portion of the return spring may be sandwiched between the lower seal support and the upper seal support. The plurality of spokes is configured to bias the seal assembly toward a radial center of a housing.

Adjacent tissue layers can be accessed using a catheter device with a distal tip having a conductive portion including a first cutting feature and one or more projections extending from the first cutting feature towards an outer diameter of the distal tip. Electrical energy can be supplied to the conductive portion of the device to cut tissue. A stent can be delivered to form a fluid communication between the adjacent tissue layers.

A surgical instrument includes a shaft and a tissue fastener. The tissue fastener is releasably attached to the distal end portion of the shaft. The shaft is operable to rotatably drive the tissue fastener about a longitudinal axis of the shaft. The tissue fastener includes a base, first and second arms, and barbs. The first and second arms extend laterally and longitudinally from the base and are configured to be received within a first and second tissue portion, respectively. The first and second arms are configured to draw the first tissue portion against the second tissue portion. The barbs extend from the first and second arms and are configured to anchor the first and second arms within the first and second tissue portions. The shaft is configured to release the tissue fastener thereby securing the first tissue portion against the second tissue portion with the tissue fastener anchored therein.

Example embodiments relate to a system having a port assembly and instrument arm assembly. The port assembly includes an outer body, inner body, and internal channels. The outer body includes a first access port, first and second ends, and anchoring portions. The inner body may be positionable in the first access port. The internal channels may be formed around an exterior of the inner body when the inner body is positioned in the first access port. The instrument arm assembly may include one or more joint portions, arm segments, an end instrument, and an instrument arm anchor portion. One of the internal channels may be configurable to house at least a portion of the instrument arm anchor portion. The port assembly may be configurable to allow an insertion of the instrument arm assembly through the first access port of the outer body.

The surgical robotic access system provides access for robotic instruments and/or actuators including the introduction, operation and withdrawal of such robotic manipulators into a body cavity without permitting the escape of pressurized fluid or gas. The surgical robotic access system also provides a multi-faceted range of movement without touching or effecting pressure on the opening in the patient's body cavity.

A device and method is provided to gain access to interior body regions. The system includes a safety needle assembly, a stylet assembly, a blade assembly, an obturator assembly, and a dilator assembly. The safety needle assembly or stylet assembly accesses an interior body region, after which the blade assembly expands the pathway created by the safety needle assembly or stylet assembly. The obturator then further expands the pathway and delivers the dilator assembly to the desired location. The safety needle assembly, obturator assembly, and blade assembly are removed, leaving the dilator assembly in place for future procedures.

Embodiments relate to robotic arm assemblies. Embodiments include shoulder segment and upper arm segment having motor drive portion. Embodiments include shoulder coupling joint assembly connecting upper arm segment to shoulder segment. Shoulder coupling joint assembly includes distal shoulder joint subassembly connected to upper arm segment. Distal shoulder joint subassembly includes distal shoulder joint forming first axis. Distal shoulder joint subassembly includes shoulder planetary gear assembly having shoulder sun gear configured to rotate relative to first axis when motor drive portion is driven to rotate. Shoulder planetary gear assembly includes shoulder planetary gear carrier. When shoulder sun gear rotates, shoulder planetary gear carrier drives upper arm segment to rotate relative to first axis. Shoulder coupling joint assembly includes proximal shoulder joint subassembly connecting shoulder segment to distal shoulder joint subassembly. Proximal shoulder joint subassembly includes proximal shoulder joint forming second axis, which rotates distal shoulder joint subassembly relative to second axis.

A catheter device having a distal tube portion having a longitudinal axis and a tube wall comprising at least one side port; and a guide tip mounted on the distal tube portion, the guide tip defining: a unitary body having an outer wall, and a plurality of indentations in the outer wall, wherein the indentations are oriented substantially parallel to the longitudinal axis, and wherein each indentation extends from a distal-most end of the guide tip to a proximal region of the guide tip.