Medical imaging camera head devices and methods are provided using light captured by an endoscope system or other medical scope or borescope. Afocal light from the scope is manipulated and split. The resulting first and second beams are passed through focusing optics to a single sensor. To take better advantage of the available number image sensor pixels, the beam may pass through lens elements (or prisms) to generate an anamorphic aspect ratio prior to being split, increasing the resolution of the image in one dimension. The afocal anamorphic beam is then split, and both images are focused on the image sensor. The anamorphism is compensated for in image processing, permitting higher resolution in one dimension along the image sensor. The manipulation of the beams prior to being split (and in some cases after or while being split) can take several forms, each offering distinct advantages over existing systems.

An imaging device according to an embodiment of the present technology includes a first polarization section, a second polarization section, a rotation control section, and a generation section. The first polarization section irradiates a body tissue with polarization light of a first polarization direction. The second polarization section extracts a polarization component of a second polarization direction that intersects with the first polarization direction, from beams of reflection light that are the polarization light reflected by the body tissue. The rotation control section that rotates each of the first polarization direction and the second polarization direction while maintaining an intersection angle between the first polarization direction and the second polarization direction. The generation section that generates an image signal of the body tissue on the basis of the polarization component of the reflection light extracted by the second polarization section in accordance with rotation operation performed by the rotation control section.

An endoscopic device includes an optical guide head connfigured to be at least partially inserted into a body or a cavity in order to view or image an object or a site that is poorly accessible to the naked eye. The optical guide head of such an endoscopic device is formed from an optical rod with a refractive index gradient.

An endoscopic device includes an optical guide head connfigured to be at least partially inserted into a body or a cavity in order to view or image an object or a site that is poorly accessible to the naked eye. The optical guide head of such an endoscopic device is formed from an optical rod with a refractive index gradient.

The present disclosure provides a cancer-specific or tissue specific targeting theranostic capsule using hepatitis E viral nanoparticle (HEVNP) to enhance the accuracy of cancer diagnosis in endoscopic examinations, as well as treatment, for example hyperthermia treatment, after diagnosis. The present disclosure also provides a method of delivering a theranostic agent using the endoscopic apparatus, as well as a non-transitory computer readable medium storing a program that causes a computer to execute the method of the present invention.

An endoscope having an outer shaft member with a distal end forming a distal end of the endoscope and an optics member with a distal end. The optics member is located inside the outer shaft member. The optics member defines a viewing direction of the endoscope, the viewing direction being tilted relative to a longitudinal axis of the outer shaft member. The endoscope further has optical fibers comprising an optically transparent material and provided and conditioned for the transport of illumination light to the distal end of the endoscope. The endoscope further has a segment located between an outer surface region of the distal end of the optics member and an inner surface region of the distal end of the outer shaft member. The orientation of distal ends of the optical fibers is defined by the segment.

An endoscope having an outer shaft member with a distal end forming a distal end of the endoscope and an optics member with a distal end. The optics member is located inside the outer shaft member. The optics member defines a viewing direction of the endoscope, the viewing direction being tilted relative to a longitudinal axis of the outer shaft member. The endoscope further has optical fibers comprising an optically transparent material and provided and conditioned for the transport of illumination light to the distal end of the endoscope. The endoscope further has a segment located between an outer surface region of the distal end of the optics member and an inner surface region of the distal end of the outer shaft member. The orientation of distal ends of the optical fibers is defined by the segment.

A swing prism endoscope with adjustable viewing direction includes a shaft with a proximal end and a distal end and a window of a transparent material that seals an opening on the distal end of the shaft so that it is fluid-tight. In addition the swing prism endoscope includes a pivotable prism on the distal end of the shaft for adjustable diversion of light that falls through the window into the shaft of the swing prism endoscope onto an object lens, where the pivotable prism is made of diamond.

A living body observation system has a light source apparatus configured to generate white observation light and excitation light for exciting fluorescent medical agent, a camera unit configured to pick up an image of a subject, a switch capable of giving an instruction to switch an observation mode, and a processor. The processor generates a white observation image and a fluorescent image; judges whether or not a parameter acquired based on the fluorescent image meets a condition under which observation of fluorescence is possible, switches to a fluorescence observation mode if the condition under which observation of the fluorescence is possible is met, when an instruction is given in a normal observation mode, and switches to a predetermined observation mode different from the fluorescence observation mode if the condition under which observation of the fluorescence is possible is not met.

Medical imaging camera head attachment devices and methods are provided using light captured by an endoscope system or other medical scope or borescope. Various camera head attachments are provided with a camera head design and system allowing recognition of the attachments, and enabling processing algorithms associated with each. The camera head optics are designed to work with a variety of attachments. Several attachments optical designs are provided.