Origami robots, and associated systems, methods of treatment, and methods of manufacture are provided. A system includes an origami robot encapsulated for ingestion by a patient, such as in a biocompatible material that is dissolvable or meltable within the gastrointestinal tract. A method of treatment includes delivering an origami robot in a folded position into a gastrointestinal tract of a patient, causing the origami robot to unfold within the gastrointestinal tract, and directing the origami robot to a site requiring treatment in the gastrointestinal tract.

A wireless magnetic ultrasonic cavitation in-vivo therapeutic robotic device, including a micro-robot and an in-vitro control device; the in-vitro control device has an outer housing in which provided with electromagnetic coils and wireless power emitting coils; the micro-robot has a capsule shaped housing in which a super magnetic module is provided; a micro ultrasonic vibrator and a micro wireless power receiving coil electronically connected with each other are provided inside the housing; the wireless power emitting coils emit electromagnetic field to the micro wireless power receiving coil, which receives and then transforms the electromagnetic field to electrical current to supply power to the micro ultrasonic vibrator. The robotic device creates ultrasonic cavitation effect in the blood, causing rapid vibration of blood cells, which enhances cell regeneration power, burn blood lipids, clear blood clots and ensures good condition of blood vessels.

The present invention relates to a micro robot driving apparatus which can increase the intensity of magnetic field generation in a driving area of a micro robot by attaching a magnetic shield unit to an electromagnetic drive coil unit for driving the micro robot, or locally focus a magnetic field through the combination of two electromagnets, and a system using the same. According to the present invention, there is an effect that driving the micro robot injected into the body may be controlled by increasing a magnetic field generation intensity in the region of interest or focusing the magnetic field.

A surgical assembly may comprise an actuator system including a plurality of wedge-shaped actuator assemblies arranged radially around a longitudinal axis. The surgical assembly may also comprise a first instrument assembly including a first elongate instrument shaft and a first wedge-shaped transmission mechanism coupled at a proximal end of the first elongate instrument shaft. The first wedge-shaped transmission mechanism is configured to engage a first wedge-shaped actuator assembly of the plurality of wedge-shaped actuator assemblies. The first wedge-shaped actuator assembly is movable linearly, relative to the other of the plurality of wedge-shaped actuator assemblies of the plurality of wedge-shaped actuator assemblies, along a path parallel to the longitudinal axis to linearly translate the first instrument assembly.

A micro-robot operating system using an ultrasonic transducer according to an embodiment of the present invention may comprise: a micro-robot moving in an inspection object; and a micro-robot operating device for controlling the location of the micro-robot. A micro-robot operating device using an ultrasonic transducer may comprise: an ultrasonic transducer unit including a plurality of ultrasonic transducers; and a control unit for controlling the plurality of ultrasonic transducers, wherein the plurality of ultrasonic transducers are arranged to form a curved surface toward a particular location in a space.

A method of manufacturing a jointed device of a medical instrument includes providing a machining fixture on a wire electrical discharge machine having an electrical discharge wire. The fixture includes member holes each adapted to accommodate at least one workpiece, the workpiece being adapted to form a portion of the jointed device of the medical instrument. At least two workpieces each include a first workpiece and a second workpiece, accommodated within at least two member holes of the member holes. The fixture is associated with the wire electrical discharge machine so that the electrical discharge wire can cut at most one workpiece at a time. The machining fixture is rotated around a fixture rotation axis at a predetermined angle, which is chosen to provide that the electrical discharge wire can cut only one workpiece at a time. The workpieces are cut by the electrical discharge wire.

The invention relates to a tube (100) with a hollow cylindrical elastic base structure (102) for insertion into a blood vessel (200) of a vascular system (202). The tube (100) comprises an outer anisotropic surface structure (104) comprising a geometrical anisotropy between a direction circumferential to the tube and a direction longitudinal to the tube (100). The anisotropic surface structure (104) is configured for establishing an anisotropic friction between the anisotropic surface structure (104) and an inner surface of the blood vessel (200). The anisotropic friction results in a surface propulsion of the tube (100), when the tube (100) is rotated around a central longitudinal body axis (106) of the tube (100). The tube (100) further comprises a magnetic material (108) distributed circumferentially around the tube (100) and configured for establishing within an external magnetic field a rotation of the tube (100) around the central longitudinal body axis (106) of the tube (100).

A surgical system comprises a manipulator arm and a surgical instrument. The surgical instrument includes: a transmission mechanism including a plurality of interface members; and an elongate body extending from the transmission mechanism. The surgical system further includes an instrument mounting structure mounted to the manipulator arm. The transmission mechanism of the surgical instrument is removably couplable to the instrument mounting structure. The instrument mounting structure includes a plurality of actuator members and a passage defined within the instrument mounting structure. When the surgical instrument is coupled to the instrument mounting structure: the plurality of interface members mate with the plurality of actuator members; and the elongate body of the surgical instrument extends between at least some of the plurality of actuator members and through the passage.

A method of constructing a system comprising one or more surgical arms, comprising: providing: a plurality of modular units, each modular unit comprising at least one surgical arm attached to at least one motor unit configured for actuating movement of the surgical arm; coupling one or more modular units to each other in an attachment configuration; displaying on a user interface one or both of an indication of the attachment configuration and a selection of an attachment configuration.

Techniques for retracting an instrument into an entry guide include receiving a retraction command for the instrument, the retraction command commanding movement of the instrument into the entry guide; causing, in response to the retraction command and using an instrument manipulator, movement of a rotational joint of the instrument that is external to the entry guide toward a distal end of the entry guide; actuating, after the rotational joint reaches a minimum distance from the distal end of the entry guide, the rotational joint to orient a link of the instrument so that the link can be retracted into the entry guide, the link being adjacent to and distal to the rotational joint; and causing, after the link is oriented so that the link can be retracted into the entry guide and using the instrument manipulator, further movement of the rotational joint toward the distal end of the entry guide.