A tubular connector for use with a spiral tube used on an insertion section of an endoscope. The tubular connector including: an outer surface; an inner surface; and a plurality of cams circumferentially spaced on the inner surface to project radially inward from the inner surface, the plurality of cams extending in a longitudinal direction of the tubular connector; wherein each of the plurality of cams have one or more cam surfaces configured to engage a rotating member to rotate the spiral tube. The plurality of cams can alternatively be formed directly on an interior surface of the spiral tube.

A biomaterial collection device can include a wire that includes a functional member including a proximal end, a distal end, a first flat surface and a second flat surface opposing the first surface. The functional member can be configured to fit within a body lumen. The functional member can include binding elements configured to bind circulating biomolecules and cells. The functional member can include curved portions that form revolutions around the longitudinal axis of the device.

An endoluminal crawler used in endoscopic procedures includes a body and an actuation unit. The body includes a tubular portion. The actuation unit includes an actuator providing a rotational output and a traction belt. The traction belt includes a traction portion and an engaging portion. The traction portion protrudes out of a slot defined in the tubular portion and the engaging portion operatively engages the actuator.

An insertion device includes a thin and elongated insertion section, a rotating body which is rotated to advance or retreat the insertion section, a driving force supply source which supplies a driving force to the rotating body, a variable stiffness section provided for the insertion section and permitting stiffness of the insertion section to be varied, a stiffness detector which detects the stiffness of the insertion section varied by the variable stiffness section, and a controller which controls the driving force supply source in accordance with the stiffness of the insertion section detected by the stiffness detector.

An exemplary apparatus for obtaining data for at least one portion within at least one luminal or hollow sample can be provided. For example, the apparatus can include a first optical arrangement configured to transceive at least one electromagnetic radiation to and from the portion(s). The apparatus can also include a wavelength dispersive second arrangement, which can be configured to disperse the electromagnetic radiation(s). A housing can be provided with a shape of a pill, and enclosing the first and second arrangements.

Lumen-traveling biological interface devices and associated methods and systems are described. Lumen-traveling biological interface devices capable of traveling within a body lumen may include a propelling mechanism to produce movement of the lumen-traveling device within the lumen, electrodes or other electromagnetic transducers for detecting biological signals and electrodes, coils or other electromagnetic transducers for delivering electromagnetic stimuli to stimulus responsive tissues. Lumen-traveling biological interface devices may also include additional components such as sensors, an active portion, and/or control circuitry.

Systems and methods are provided for controlling lateral movement of a medical capsule system. A capsule housing is configured to be inserted into an anatomical structure of a patient. The multichannel tether is coupled to a rear of the capsule and includes at least one liquid exhaust channel conveying liquid to the capsule housing. The plurality of liquid exhaust ports are positioned around an outer circumference of the capsule housing and each configured to controllably expel liquid laterally from the capsule housing at varying rates to affect lateral movement of the capsule housing.

Biological navigation devices and methods are disclosed. The devices can be used as or to support colonoscopies or endoscopes. The devices can have longitudinally extensible cells that can be selectively inflated. The devices can have articulable links. The devices can be removably attached to elongated elements, such as colonoscopes or other endoscopes.

This invention relates to a robot to improve the inspection of a pipe or lumen. More particularly, this invention relates to a soft-pneumatic robot for endoscopy that is suitable for performing colonoscopy procedures. The robot of this invention comprises leading and tailing balloons configured for selective inflation to anchor a portion of the robot within the pipe or lumen and a soft-pneumatic actuator that is located between the leading balloon and the trailing balloon. The soft-pneumatic actuator is operable to extend or contract the robot in a longitudinal direction, in addition to positioning the leading balloon in a 360 degree circumference around the longitudinal direction by pneumatically controlling a fluid within a plurality of chambers within the soft-pneumatic actuator.

An insertion device includes a rotor rotating around a first revolution axis, and an assist tool attached to an insertion section with covering the rotor from an outer peripheral side. An assist tool rotates together with the rotor around a second revolution axis when press force is applied from a first protrusion of the rotor to a second protrusion of the assist tool by rotating of the rotor. The first revolution axis of the rotor and the second revolution axis of the assist tool move closer to each other when the rotor and the assist tool are rotating together.