A bougie is disclosed with a body, and a first depth indicator and a second depth indicator on the body. The body has a first end, a second end, and at least one surface extending between the first and second ends. The first depth indicator is spaced a first distance from the first end and indicates a first predetermined depth range such that the first end is positioned a first predetermined insertion range past the mouth of the patient when the body is positioned into the mouth of the patient. The second depth indicator is spaced a second distance from the second end and indicates a second predetermined depth range such that the second end is positioned a second predetermined insertion range past the mouth when the body is positioned into the mouth of the patient.

A medical device includes a handle portion downwardly extending from an examination portion. The handle portion has opposing upper and lower open ends and a through cavity extending therebetween. An illumination assembly mounted within the open upper end of cavity includes a housing, at least one battery disposed within the housing, and an LED disposed at the distal end of an arm extending from the housing. The housing is mounted through the open upper end of the through cavity. According to at least one version, the at least one battery can be removed without removing the housing from the handle portion. The extending arm is supported by the examination portion and configured to provide illumination to a medical target. The medical device can include a vaginal speculum, sigmoidoscope, laryngoscope, anoscope, or other hand-held medical device.

Provided herein is a handle of a multi-camera endoscope, the handle includes a user interface activating unit which includes one or more external activating/control buttons, and an internal activating element, the handle optionally includes a converter configured to receive one or more parallel signals and transform the one or more parallel signals to one or more corresponding serial signals, wherein the parallel signals are output by one or more cameras of the endoscope. Further provided are endoscopes and medical imaging system which include the handle, as well as methods of use thereof.

Systems and methods are disclosed providing a flexible articulable device for accessing deep within tight and arbitrarily shaped channels of a body. The flexible or articulable device may employ two, independent locomotion strategies. These strategies can be combined or independently used. However, both strategies use a segmented approach that employs one or multiple embedded actuation units along the body of the device. The multiple embedded actuation units may be individually controlled, are generally connected serially, and generally uses one of the locomotion strategies. One strategy relates to propulsion while the other strategy relates to shape control.

An endoscope that integrates the functions of an optical tower into a portable device, while eliminating the use of cords or cables that carry light, video signals or images, and power to the endoscope that may conflict with the movement of a surgeon and the members of the surgical team, or other operators in non-medical related applications is provided. The endoscope incorporates a camera, an image processor, a light source, a transmitter, a communication interface, a control interface, and one or more of a power source in a single portable unit or enclosure. The camera is in electrical communication with the image processor and supplies images and video to the image processor obtained via an elongated endoscope tube. The light source illuminates a viewing field of the endoscope via the elongated tube.

Embodiments of the present invention may be used to perform measurement of surfaces, such as external and internal surfaces of the human body, in full-field and in 3-D. Embodiments of the present invention may include an electromagnetic radiation source, which may be configured to project electromagnetic radiation onto a surface. The electromagnetic radiation source may be configured to project the electromagnetic radiation in a pattern corresponding to a spatial signal modulation algorithm. The electromagnetic radiation source may also be configured to project the electromagnetic radiation at a frequency suitable for transmission through the media in which the radiation is projected. An image sensor may be configured to capture image data representing the projected pattern. An image-processing module may be configured to receive the captured image data from the image sensor and to calculate a full-field, 3-D representation of the surface using the captured image data and the spatial signal modulation algorithm. A display device may be configured to display the full-field, 3-D representation of the surface.

A system for imaging and examination of a cervix, comprising a control module connectable with a changeable head configured to image the cervix and collect a tissue biopsy, the head selected from a group consisting of a digital colposcope module, a transvaginal optical probe module and an endo-cervical endoscope module. The system may additionally comprise light source(s) to illuminate cervix tissue; sensing device(s) to generate signal(s) from light and/or to acquire image(s) of a portion of a cervix; and processor(s) in communication with the sensing device(s). The system is configured to: (i) analyze the signal(s); (ii) detect the size of the cervix; (iii) determine parameters defining properties of the cervix; (iv) determine and distinguish normal tissue from abnormal tissue within the cervix; (v) determine the location of area(s) of abnormal tissue in the cervix; and (vi) generate a panoramic view of the cervix.

An optical fiber scanning probe includes a rotor and at least one optical fiber. The rotor includes a torque rope rotatable about its central axis. The optical fiber is disposed on the rotor and eccentric relative to the torque rope. A central axis of the optical fiber is substantially parallel to the central axis of the torque rope. When the torque rope rotates about its central axis, the rotor brings a free end of the optical fiber to scan along an arc path.

A pellet for testing intestinal and anorectal function. In one embodiment of a system of the present disclosure, the system comprises a pellet comprising a balloon or bag, and a fill tube configured to be removably coupled to the pellet, the fill tube configured to permit selective filling of the balloon or bag

Method for leveraging battery residue energy and a capsule endoscope using the method are disclosed. The capsule endoscope is capable of performing one or more functions at a first throughput or a first peak current when the battery has sufficient energy. According to this method, whether the battery energy is sufficient is determined. Upon determining the battery energy being insufficient, at least one function of the one or more functions is performed at a second throughput lower than the first throughput, or at least one function of the one or more functions is switched to another function requiring a second peak current lower than the first peak current.