A flexible endoscope insertion method includes: rotating a hollow organ by changing the body position to semilateral position or lateral position for observing the lateral wall of the lumen; turning the tip of the flexible endoscope to the lateral wall of the lumen by rotating the endoscope in the counter direction of the lumen; and retracting the organ with the endoscope itself by rotating the endoscope in the counter direction of the lumen. In other embodiments, the method includes: rotating a body cavity by changing the body position to the appropriate position for observing the lateral side of the organ; turning the tip of the flexible endoscope to the lateral side of the organ by rotating the endoscope in the direction of the lateral side of the organ; and retracting the organ with the endoscope itself by rotating the endoscope in the direction of the lateral side of the organ.

A flexible endoscope insertion method includes: rotating a hollow organ by changing the body position to semilateral position or lateral position for observing the lateral wall of the lumen; turning the tip of the flexible endoscope to the lateral wall of the lumen by rotating the endoscope in the counter direction of the lumen; and retracting the organ with the endoscope itself by rotating the endoscope in the counter direction of the lumen. In other embodiments, the method includes: rotating a body cavity by changing the body position to the appropriate position for observing the lateral side of the organ; turning the tip of the flexible endoscope to the lateral side of the organ by rotating the endoscope in the direction of the lateral side of the organ; and retracting the organ with the endoscope itself by rotating the endoscope in the direction of the lateral side of the organ.

An examination system having separate enabled interchangeable operating modes includes at least one medical device having a housing retaining an optical system. The examination system further includes an adapter that is configured for aligning a plurality of disparate smart devices with the optical system of the medical device when the adapter is attached to the medical device, thereby enabling multiple operating modes without modification to the device. In at least one version, common engagement features are provided on a plurality of medical devices to permit the adapter and an attached smart device to be used therewith interchangeably.

An examination system having separate enabled interchangeable operating modes includes at least one medical device having a housing retaining an optical system. The examination system further includes an adapter that is configured for aligning a plurality of disparate smart devices with the optical system of the medical device when the adapter is attached to the medical device, thereby enabling multiple operating modes without modification to the device. In at least one version, common engagement features are provided on a plurality of medical devices to permit the adapter and an attached smart device to be used therewith interchangeably.

A system and a method for a medical diagnostic device are described herein. The medical diagnostic device can include an outer sleeve having a hollow interior and open distal and proximal ends, the outer sleeve being defined by a substantially tubular configuration including a proximal section having a substantially conical shape. A core is configured to be inserted axially within the outer sleeve. The core includes an axial inner cavity. The core is further defined by a proximal section having a conical shape substantially conforming to the proximal section of the outer sleeve. The core retains a diagnostic assembly, that can include at least one of a sample collecting assembly and an imaging assembly, that can be integrally or interchangeably attached and wherein the device can be utilized for self-patient or single patient use.

A system and a method for a medical diagnostic device are described herein. The medical diagnostic device can include an outer sleeve having a hollow interior and open distal and proximal ends, the outer sleeve being defined by a substantially tubular configuration including a proximal section having a substantially conical shape. A core is configured to be inserted axially within the outer sleeve. The core includes an axial inner cavity. The core is further defined by a proximal section having a conical shape substantially conforming to the proximal section of the outer sleeve. The core retains a diagnostic assembly, that can include at least one of a sample collecting assembly and an imaging assembly, that can be integrally or interchangeably attached and wherein the device can be utilized for self-patient or single patient use.

A laminated laser window having an inner layer transparent to light having wavelengths between 3.5 micrometers and 12 micrometers and having as an outer surface a nanometric-thick outer layer of SiO2. The window allows the passage of light within this wavelength range, for example from a CO2 laser. In The SiO2 outer layer maintains biocompatibility when used in laser devices for insertion into externally accessible bodily cavities.

A laminated laser window having an inner layer transparent to light having wavelengths between 3.5 micrometers and 12 micrometers and having as an outer surface a nanometric-thick outer layer of SiO2. The window allows the passage of light within this wavelength range, for example from a CO2 laser. In The SiO2 outer layer maintains biocompatibility when used in laser devices for insertion into externally accessible bodily cavities.

A speculum comprising a lower member including a handle having a proximal end and a distal end, and a lower blade extending from the proximal end of the handle, an upper blade configured to be movable with respect to the lower member, and an illumination assembly including at least one light source, at least one power source housed in the handle and an ejection mechanism for removal of the at least one power source from the handle, wherein the at least one power source is housed in the handle at a position closer to the proximal end of the handle than to the distal end, and wherein the ejection mechanism is configured to remove the at least one power source via an opening formed in the distal end of the handle.

A speculum comprising a lower member including a handle having a proximal end and a distal end, and a lower blade extending from the proximal end of the handle, an upper blade configured to be movable with respect to the lower member, and an illumination assembly including at least one light source, at least one power source housed in the handle and an ejection mechanism for removal of the at least one power source from the handle, wherein the at least one power source is housed in the handle at a position closer to the proximal end of the handle than to the distal end, and wherein the ejection mechanism is configured to remove the at least one power source via an opening formed in the distal end of the handle.