Abstract: A selectively deployable balloon member for insertion into and illumination of a body cavity. The selectively deployable balloon member includes a flexible tubular body having a non-deployed configuration during insertion into the body cavity and a deployed configuration after insertion into the body cavity, the flexible tubular balloon member being inflated after the insertion into the body cavity so as to be in the deployed configuration and having a reflective portion configured to reflect illuminated light received from at at least one light source disposed on an interior of the flexible tubular body when in the deployed configuration, and a transparent portion located at a distal end thereof which enables illuminated light from the light source to pass therethrough.

Abstract: The multi-section deployable and articulating endoscope is designed with tubing and flat cables that are small enough that the endoscope becomes a thin stick that is minimally invasive and usable with other devices in a common port. The endoscope includes very thin flat cables that are used for electrical connectivity and threaded above and below an articulation and deployment hinge for opening the endoscope passively using an adjustable tension spring, or by pulling on a first cable and closing the endoscope by pulling on a second cable, When in a tubular configuration the endoscope may be inserted into the port and an insufflation membrane inside the port forms an air seal with the endoscope, which aids in insufflation and desufflation. The endoscope includes one or more tubes for creating an air jet stream above the camera to act as a shield for keeping the camera clean.

Abstract: A device for display of medical vision images and video may include a portable display screen and housing. The device may also include a mounting mechanism located on the back of the housing. The mounting mechanism may be configured to removably engage a complementary mounting mechanism on a structure for removably mounting the portable display screen and housing to the structure. The device may also include means for communicatively coupling the portable display screen to one or more optoelectronic vision and illumination modules for control and processing of information.

Abstract: The multi-section deployable and articulating endoscope is designed with tubing and flat cables that are small enough that the endoscope becomes a thin stick that is minimally invasive and usable with other devices in a common port. The endoscope includes very thin flat cables that are used for electrical connectivity and threaded above and below an articulation and deployment hinge for opening the endoscope passively using an adjustable tension spring, or by pulling on a first cable and closing the endoscope by pulling on a second cable, When in a tubular configuration the endoscope may be inserted into the port and an insufflation membrane inside the port forms an air seal with the endoscope, which aids in insufflation and desufflation. The endoscope includes one or more tubes for creating an air jet stream above the camera to act as a shield for keeping the camera clean.

Abstract: A device for illuminating a body cavity may include an elongate tube, at least one lens element, and at least one deployable element. The elongate tube may include an internal lumen extending between a distal opening at a distal end and a proximal opening at a proximal end opposite the distal end. The at least one lens element may extend substantially across a diameter of the internal lumen of the elongate tube. The at least one deployable element may include a light source. The at least one deployable element may be operably coupled to a region of the elongate tube proximate the distal end and may be configured to be moved between an insertion position and a deployed position.

Abstract: Improved optical devices and methods transmit optical images along elongate optical paths with relatively limited cross-sectional dimensions using an improved objective, relay, and ocular systems. At least one intermediate image is formed within an optical component. For example, a first intermediate image is formed within glass of the most proximal objective lens, with the first intermediate image extending axially along a curved image location within the glass. The last intermediate image may similarly be disposed within a distal lens of the ocular system. The ocular system allows independent adjustment of diopters, magnification, X-Y positioning, and rotation orientation of the captured image while introducing minimal aberrations.

Abstract: Various embodiments for providing removable and pluggable opto-electronic modules for illumination and imaging for endoscopy or borescopy are provided for use with portable display devices. Generally, various medical or industrial devices can include one or more solid state or other compact electro-optic illuminating elements located thereon. Additionally, such opto-electronic modules may include illuminating optics, imaging optics, and/or image capture devices. The illuminating elements may have different wavelengths and can be time-synchronized with an image sensor to illuminate an object for imaging or detecting purpose or other conditioning purpose. The removable opto-electronic modules may be plugged in on the exterior surface of a device, inside the device, deployably coupled to the distal end of the device, or otherwise disposed on the device.

Abstract: A device for display of medical vision images and video may include a portable display screen and housing. The device may also include a mounting mechanism located on the back of the housing. The mounting mechanism may be configured to removably engage a complementary mounting mechanism on a structure for removably mounting the portable display screen and housing to the structure. The device may also include means for communicatively coupling the portable display screen to one or more optoelectronic vision and illumination modules for control and processing of information.

Abstract: Various embodiments for providing removable, pluggable and disposable opto-electronic modules for illumination and microscopic imaging are provided, for use with portable display devices. Generally, various medical or industrial miniature microscopes can include one or more solid state or other compact electro-optic illuminating elements, electronic vision systems and means of scanning located thereon. Additionally, such opto-electronic modules may include illuminating optics, imaging optics, and/or image manipulation and processing elements. The illuminating elements may have different wavelengths and can be time-synchronized with an image sensor to illuminate an object for imaging or detecting purpose or other conditioning purpose. All control and power functions of such disposable microscope units can be made in the control unit that the disposable microscopes are plugged into.

Abstract: Various embodiments for providing removable, pluggable and disposable opto-electronic modules for illumination and imaging for endoscopy or borescopy are provided for use with portable display devices. Generally, various medical or industrial devices can include one or more solid state or other compact electro-optic illuminating elements located thereon. Additionally, such opto-electronic modules may include illuminating optics, imaging optics, and/or image capture devices. The illuminating elements may have different wavelengths and can be time-synchronized with an image sensor to illuminate an object for imaging or detecting purpose or other conditioning purpose. The removable opto-electronic modules may be plugged onto the exterior surface of another medical device, deployably coupled to the distal end of the device, or otherwise disposed on the device.

Abstract: Various embodiments for providing removable, pluggable and disposable opto-electronic modules for illumination and imaging for endoscopy or borescopy are provided for use with portable display devices. Generally, various rigid, flexible or expandable single use medical or industrial devices with an access channel, can include one or more solid state or other compact electro-optic illuminating elements located thereon. Additionally, such opto-electronic modules may include illuminating optics, imaging optics, and/or image capture devices, and airtight means for suction and delivery within the device. The illuminating elements may have different wavelengths and can be time-synchronized with an image sensor to illuminate an object for 2D and 3D imaging, or for certain diagnostic purposes.

Abstract: Various embodiments for providing removable and pluggable opto-electronic modules for illumination and imaging for endoscopy or borescopy are provided. Generally, various medical or industrial devices can include one or more solid state or other compact electro-optic illuminating elements located thereon. Additionally, such opto-electronic modules may include illuminating optics, imaging optics, image capture devices, and heat dissipation mechanisms. The illumination elements may have different wavelengths and can be time synchronized with an image sensor to illuminate an object for imaging or detecting purpose or otherwise conditioning purpose. The optoelectronic modules may include means for optical and/or wireless communication. The removable opto-electronic modules may be plugged in on the exterior surface of a device, inside the device, deployably coupled to the distal end of the device, or otherwise disposed on the device.

Abstract: Various embodiments for providing solid state illumination for endoscopy or borescopy are provided. Generally, various medical or industrial devices can include one or more solid state or other compact electro-optic illuminating devices located thereon. The solid state or compact electro-optic illuminating device can include, but is not limited to, a light emitting diode (LED), laser diode (LD), or other Infrared (TR) or Ultraviolet (UV) source. Solid state sources of various wavelengths may be used to illuminate an object for imaging or detecting purpose or otherwise conditioning purpose. The solid state illuminating device may be placed on the exterior surface of the device, inside the device, deployably coupled to the distal end of the device, or otherwise disposed on the device.

Abstract: Various embodiments for providing solid state illumination in conjunction with wavelength multiplexing imaging schemes for mono and stereo endoscopy or borescopy are provided. In one embodiment, the current disclosure provides a device configured for insertion into a body cavity. The device can include a tubular portion having a proximal end and a distal end. The distal end of the tubular portion can be configured to be at least partially inserted into the body cavity. The device can also include a solid state electro-optic element located on the tubular portion. Furthermore, the device can include a power source electrically coupled to the solid state electro-optic element.

Abstract: Various embodiments for providing solid state illumination for endoscopy or borescopy are provided. Generally, various medical or industrial devices can include one or more solid state or other compact electro-optic illuminating devices located thereon. The solid state or compact electro-optic illuminating device can include, but is not limited to, a light emitting diode (LED), laser diode (LD), or other Infrared (IR) or Ultraviolet (UV) source. Solid state sources of various wavelengths may be used to illuminate an object for imaging or detecting purpose or otherwise conditioning purpose. The solid state illuminating device may be placed on the exterior surface of the device, inside the device, deployably coupled to the distal end of the device, or otherwise disposed on the device.

Abstract: Collection optics are used with one or more light emitting diodes to produce, e.g., collimated light. The collection optics are produced in multiple pieces including a small reflective ring that surrounds the one or more light emitting diodes. The reflective ring may be positioned relative to the LEDs, using a mesa upon which the LEDs are mounted, as a lateral positioning guide. A separate upper reflector uses the reflective ring as a lateral positioning guide during assembly. The reflective ring and the upper reflector include reflective sidewalls that are approximately continuous when the reflective ring and upper reflector are assembled.

Abstract: Improved optical devices and methods transmit optical images along elongate optical paths with relatively limited cross-sectional dimensions using an improved objective, relay, and ocular systems. At least one intermediate image is formed within an optical component. For example, a first intermediate image is formed within glass of the most proximal objective lens, with the first intermediate image extending axially along a curved image location within the glass. The last intermediate image may similarly be disposed within a distal lens of the ocular system. The ocular system allows independent adjustment of diopters, magnification, X-Y positioning, and rotation orientation of the captured image while introducing minimal aberrations.

Abstract: Improved optical devices and methods transmit optical images along elongate optical paths with relatively limited cross-sectional dimensions using an improved objective, relay, and ocular systems. In a first aspect, at least one intermediate image formed within an optical component, rather than being formed in a gap between optical components. In a preferred embodiment, a first intermediate image is formed within glass of the most proximal objective lens, with the first intermediate image extending axially along a curved image location within the glass. The last intermediate image may similarly be disposed within a distal lens of the ocular system. By making use of a first and/or last intermediate image disposed in this manner within a lens, endoscopes can exhibit a significantly larger Numerical Aperture than known endoscopes having similar cross-sectional dimensions.

Abstract: A means for optically coupling a semiconductor laser to an optical fiber is disclosed. In one embodiment, a volume phase holographic element is disposed on a light-emitting surface of a semiconductor laser. The volume phase holographic element acts as an aberration-corrector for a lens that is disposed between the semiconductor laser and the optical fiber. In this way, an inexpensive lens that is not aberration free can be used. In some embodiments, the volume phase holographic element converts a Gaussian light beam emitted by the semiconductor laser into an annular beam that is more suitable for long distance transmission in multimode fibers.

Abstract: Various embodiments for providing removable, pluggable and disposable opto-electronic modules for illumination and imaging for endoscopy or borescopy are provided for use with portable display devices. Generally, various rigid, flexible or expandable single use medical or industrial devices with an access channel, can include one or more solid state or other compact electro-optic illuminating elements located thereon. Additionally, such opto-electronic modules may include illuminating optics, imaging optics, and/or image capture devices, and airtight means for suction and delivery within the device. The illuminating elements may have different wavelengths and can be time-synchronized with an image sensor to illuminate an object for 2D and 3D imaging, or for certain diagnostic purposes.