An objective for a microscope includes a displaceable lens group for correcting a spherical aberration. The displaceable lens group is designed in so that an offset of same in the direction perpendicular to the optical axis leads to only a small coma.

An objective for a microscope includes a displaceable lens group for correcting a spherical aberration. The displaceable lens group is designed in so that an offset of same in the direction perpendicular to the optical axis leads to only a small coma.

A dental microscope includes a microscope unit, an adjustable support arm, and a display unit. The microscope unit includes a body part, at least one eyepiece that is disposed on the body part, and an objective lens disposed on a bottom end of the body part. The adjustable support arm has a first end connected to the microscope unit and a second end opposite to the first end. The adjustable support arm is adjustable in a segment-by-segment manner to move the second end relative to the first end. The display unit is connected to the second end of the adjustable support arm and is in signal communication with the microscope unit for displaying a captured image obtained by the microscope unit.

An observation device includes: a macro observation system; and a micro observation system. The macro observation system and the micro observation system are arranged so as to satisfy a first condition. The first condition is that a distance from a macro optical axis to a micro optical axis is equal to or less than a square root of a sum of squares of a first distance and a second distance. The first distance is a distance between the macro optical axis and a central axis of an outer diameter of the nosepiece. The second distance is a distance in a first direction between the central axis of the outer diameter and a side surface of the nosepiece. The first direction is a direction orthogonal to the macro optical axis and orthogonal to a line segment connecting the macro optical axis and the central axis of the outer diameter.

An observation device includes: a macro observation system; and a micro observation system. The macro observation system and the micro observation system are arranged so as to satisfy a first condition. The first condition is that a distance from a macro optical axis to a micro optical axis is equal to or less than a square root of a sum of squares of a first distance and a second distance. The first distance is a distance between the macro optical axis and a central axis of an outer diameter of the nosepiece. The second distance is a distance in a first direction between the central axis of the outer diameter and a side surface of the nosepiece. The first direction is a direction orthogonal to the macro optical axis and orthogonal to a line segment connecting the macro optical axis and the central axis of the outer diameter.

A method and microscopy system are useful for recording an image of a sample region. A laser beam is directed onto the sample region with interface(s). An objective lens facilitates images the laser beam on a focusing point which lies on the optical axis of the objective lens or an axis parallel thereto, and which lies in a focusing plane. The objective lens and the sample region are displaced with respect to one another in relative fashion along the optical axis of the objective lens to different relative displacement positions. Intensity values of the laser beam are captured for a respective relative displacement position. A respective highest intensity value for a respective displacement position, a curve of the highest intensity values, and a reference relative displacement position from at least one maximum of the curve, are determined. Image(s) of the sample region is/are captured at the reference relative displacement position.

A method and microscopy system are useful for recording an image of a sample region. A laser beam is directed onto the sample region with interface(s). An objective lens facilitates images the laser beam on a focusing point which lies on the optical axis of the objective lens or an axis parallel thereto, and which lies in a focusing plane. The objective lens and the sample region are displaced with respect to one another in relative fashion along the optical axis of the objective lens to different relative displacement positions. Intensity values of the laser beam are captured for a respective relative displacement position. A respective highest intensity value for a respective displacement position, a curve of the highest intensity values, and a reference relative displacement position from at least one maximum of the curve, are determined. Image(s) of the sample region is/are captured at the reference relative displacement position.

An optical probe assembly as a confocal endomicroscope includes an optical focusing stage that focuses an output beam onto a sample and a mirror scanning stage that is movable for scanning the output beam in both a lateral two dimensional plane and an axial direction, using a side-view configuration. The side-view configuration allows for output beam illumination and fluorescent imaging of the sample with greater imaging resolution and improved access to hard to reach tissue within a subject.

A phase-contrast microscope includes a light source section configured to emit light; a light guide including a plurality of optical fibers, the light guide transmitting the light emitted from the light source section through the plurality of optical fibers; and an object lens including a lens and an annular phase film, the annular phase film being on the side to which light passes through the lens, the object lens being configured to enlarge an image on a sample irradiated with the light transmitted by the light guide. The plurality of optical fibers include a plurality of emission faces arranged to form a ring, and the light guide is disposed in such a manner that the plurality of emission faces are in a conjugate position to the annular phase film.

A phase-contrast microscope includes a light source section configured to emit light; a light guide including a plurality of optical fibers, the light guide transmitting the light emitted from the light source section through the plurality of optical fibers; and an object lens including a lens and an annular phase film, the annular phase film being on the side to which light passes through the lens, the object lens being configured to enlarge an image on a sample irradiated with the light transmitted by the light guide. The plurality of optical fibers include a plurality of emission faces arranged to form a ring, and the light guide is disposed in such a manner that the plurality of emission faces are in a conjugate position to the annular phase film.