An instrument for endoscopic applications, including a tubular member having a handling end portion having a flexible portion and actuating devices located at the other end portion, and longitudinal elements for transferring the movement of the actuating devices to the handling end portion resulting in a change of orientation thereof, whereby the handling end portion includes at least two independent flexible portions, whereby the actuating end portion has a corresponding number of actuating devices, and whereby each actuating device is connected by its own set of longitudinal elements to a part of the handling end portion for effecting a change of orientation of one of the flexible portions.

A guidewire with a cross section of at least a part of its length, comprising a filling material (PLM), a lumen (LM) arranged inside the filling material (PLM) for accommodating an optical fiber (OF) with optical shape sensing properties. One or more stiffening elements (RD) are arranged inside the first material (PLM), wherein the stiffening element(s) (RD) is formed by a material having a higher axial stiffness than the filling material. A braiding structure (BR) encircles all of: the filling material (PLM), the lumen (LM), and the stiffening element(s) (RD). Such guidewire can be designed with a circular symmetric bending behavior, and is thus suitable as an interventional medical device, e.g. for endovascular procedures, and still it can provide optical shape sensing properties.

A method for determining the force applied to a tip of a medical instrument includes receiving inputs from a medical instrument having at least one elongated actuation element used to manipulate a position of the instrument while in a patient's body. The method also includes applying the inputs to a lumped model of the instrument and determining a force on a tip of the instrument based on both the inputs and the lumped model.

An endoscope apparatus includes alight source, a bendable insertion section to be inserted into an observation target, a light guide path which is provided in the insertion section and which guides light emitted from the light source, an illumination light emitter which is provided at the distal end of the insertion section and which emits at least some of the light guided by the light guide path to the observation target as illumination light, a curvature sensor which detects a bending shape of at least part of the insertion section, and an illumination light controller which controls an optical characteristic of the illumination light on the basis of the bending shape of the insertion section detected by the curvature sensor.

An endoscopic system includes: an endoscope acquiring an image of an inside of a subject; and a processing device performing image processing on the acquired image. The endoscope includes: an imaging unit outputting the image of the inside of the subject as an electrical signal; and an optical transmission unit converting the electrical signal into an optical signal and transmitting the optical signal to the processing device via an optical fiber. The processing device includes: an optical reception unit receiving the optical signal transmitted from the optical transmission unit and converts the received optical signal into an electrical signal; a curvature-detecting unit detecting a curvature of the optical fiber, and a control unit controlling at least one of characteristics of the electrical signal output from the imaging unit and characteristics of the electrical signal output from the optical transmission unit based on the detection result of the curvature-detecting unit.

Example embodiments of the present invention relate to systems methods and computer program products for bend estimation. The system comprises a first and second light absorbers disposed at a substantially same position along an axis of a light guide and enabled to absorb first and second respective amounts of a plurality of wavelengths of a light transmitted along the light guide, a light detector enabled to detect respective intensities of the plurality of wavelengths of the light not absorbed by the first and second light absorbers, and a processor enabled to calculate a bend state of the light guide according to the detected intensities of the plurality of wavelengths of the light.

The present invention relates, generally, to controlling a steerable instrument having an elongate body. More particularly, the present invention relates to a system and method for sensing the shape of a steerable instrument and controlling the steerable instrument in response to a control signal from a user input device and a shape signal corresponding to the sensed shape of at least a portion of the steerable instrument. The present invention also relates to a system for sensing the shape of a flexible instrument with an optical shape sensor.

Devices and methods for treating rhinitis are provided. An integrated therapy and imaging device is provided for single handheld use. The device may have a hollow elongated cannula, a therapeutic element coupled to a distal portion of the cannula, an imaging assembly coupled to the cannula to provide visualization of the therapeutic element, and an articulating region operably coupled to the imaging assembly to articulate the imaging assembly. The imaging assembly may be articulated so as to translate vertically, laterally, axially, and/or rotationally.

An instrument system that includes an image capture device, an elongate body, an optical fiber and a controller is provided. The elongate body is operatively coupled to the image capture device. The optical fiber is operatively coupled to the elongate body and has a strain sensor provided on the optical fiber. The controller is operatively coupled to the optical fiber and adapted to receive a signal from the strain sensor and to determine a position or orientation of the image capture device based on the signal.

The present disclosure provides for a surgical device. The surgical device includes a jaw assembly and a camera assembly coupled to the jaw assembly. The camera assembly includes a camera housing defining an interior space having at least one opening on a side thereof, first and second support arms pivotally coupled within the camera housing and deployable therefrom, and a camera body coupled to the first and second support arms and moveable between a first position, in which the camera body is positioned within the interior space of the camera housing, and a second position, in which the camera body extends from the at least one opening of the camera assembly.