A system comprises a housing, a light source, a light guide configured to guide a light from the light source. The light guide includes a plurality of detection target configured to provide optical effect on the light in accordance with a bend state of the light guide. A light detector is configured to detect the light emitted from the light guide and provide information of the detected light. A communication unit is configured to transmit wirelessly the information of the detected light. The communication unit is disposed in the housing.

The invention relates to an interventional apparatus comprising an interventional device with a handle (6). The handle comprises a) a first guide (20, 51) guiding an optical fiber, which is also guided within the interventional device, from a first proximal opening (14) of the handle to a distal portion (21) of the handle, wherein the first guide only has radii of curvature being larger than 10 mm, and b) a second guide (22) for guiding an elongated interventional instrument from a second proximal opening (13) of the handle to the distal portion of the handle. Since the first guide is relatively straight, the optical fiber is substantially not bent or only slightly bent and the likelihood that the interventional instrument and the optical fiber press against each other can be significantly reduced. This allows for an improved accuracy of determining the position of the interventional device by optical shape sensing.

An apparatus comprises an instrument including an elongated shaft. The apparatus also comprises a first shape sensor including an elongated optical fiber extending within the elongated shaft at a first radial distance from the neutral axis. The apparatus also comprises a twist resistant feature configured to reduce twisting of the elongated optical fiber relative to the elongated shaft while permitting axial translation of the elongated optical fiber within the elongated shaft.

A future shape estimation apparatus includes an insertion section, a shape sensor and an insertion section future shape estimation circuit. The insertion section has flexibility and is to be inserted into an observation target object. The shape sensor detects a bending state of the insertion section and outputs a detection signal. The insertion section future shape estimation circuit estimates a future shape of the insertion section after a predetermined lapse of time based on information acquired from the detection signal output from the shape sensor, and outputs the future shape as future estimation shape information.

An apparatus includes an instrument that comprises an elongated, flexible body including an inner surface and an outer surface, wherein the inner surface is shaped to define a lumen extending through at least a portion of the elongated, flexible body. The instrument further comprises a plurality of portions extending along a length of the elongated, flexible body. The apparatus further comprises a radiopaque material incorporated into a first portion of the plurality of portions and a second portion of the plurality of portions, wherein the radiopaque material is incorporated into the first portion such that the first portion has a first radiopacity, and the radiopaque material is incorporated into the second portion such that the second portion has a second radiopacity, wherein the first radiopacity is different from the second radiopacity.

A method for determining a shape of a lumen in an anatomical structure comprises reading information from a plurality of strain sensors disposed substantially along a length of a flexible medical device when the flexible medical device is positioned in the lumen. When the flexible medical device is positioned in the lumen, the flexible medical device conforms to the shape of the lumen. The method further comprises computationally determining, by a processing system, the shape of the lumen based on the information from the plurality of strain sensors.

A supporting apparatus for supporting insertion of a flexible insertion member into a subject and removal of the insertion member includes a position acquisition unit, an interrelation calculation unit and a determination unit. The position acquisition unit acquires information on displacements at at least two attention points located at positions that are different in the longitudinal direction of the insertion member. The interrelation calculation unit calculates a degree of interrelation of the displacements acquired at the at least two attention points. The determination unit determines a state of the insertion member or a state of a predetermined target portion of the subject, based on the degree of interrelation.

A supporting apparatus for supporting insertion of a flexible insertion member into a subject and removal of the insertion member includes an attention point acquisition unit, a first displacement acquisition unit and a determination unit. The attention point acquisition unit specifies at least one first attention point specified by a shape of the insertion member. The first displacement acquisition unit acquires a first displacement of the first attention point. The determination unit determines how a state of the insertion member or the subject is at a position corresponding to the first attention point, based on displacement information including information on the first displacement.

A supporting apparatus for supporting insertion of a flexible insertion member into a subject and removal of the insertion member includes a self-following property evaluation unit and a determination unit. The self-following property evaluation unit evaluates self-following property or lateral movement during insertion of the insertion member. The determination unit which determines a state of the insertion member or the subject, based on the self-following property or the lateral movement.

An endoscope insertion shape observation probe that is elongatedly formed along a longitudinal axis direction and is insertable into a channel provided in an endoscope insertion section or is incorporated in the endoscope insertion section includes an electronic component, a housing section having a recessed shape that houses the electronic component, a pair of electric connection sections provided in the housing section, a pair of electric connection terminal sections provided in the electronic component and engaged with and electrically connected to the electric connection sections, the electric connection terminal sections mechanically holding the electronic component in the housing section, a groove section formed in the housing section, and two attaching-direction defining terminal sections provided in the electronic component, the attaching-direction defining terminal sections engaging into the groove section and defining a direction around a longitudinal axis in which the electronic component is attached to the housing section.