NL7906056A - FIBER OPTICAL ENDOSCOPE. - Google Patents

Description

(tr ar 49 242 / Bs / MV - - AMERICAN OPTICAL CORP., SOUTHBRIDGE, Mass.,

Far. States of America.

Fiber optic endoscope.

The invention relates to fiber optic endoscopes for both medical and other purposes.

In medical endoscopes, as well as their industrial counterparts, the space within the flexible probe 5 plays a major role due to the various functions to be accommodated within it, such as image transfer, object illumination, articulation, biopsy channel, etc. Each of these functions is essential to the operation of the instrument, and as more space is given to one of them, this means an exchange of the desired operation for other functions.

Accordingly, it is a primary object of the invention to reduce the space requirement for one function, to provide more space for the other, eg to reduce the space requirement for object illumination in favor of a larger diameter for the image-bearing beam, in order to to provide better image quality or improvement in articulation mechanisms and / or incorporation of larger or added medical channels for greater accessibility to the object.

This and other objects are achieved according to the invention in the construction of an endoscope by providing an unusually small illumination fiber bundle, eg a single fiber or two fibers, and amplifying the light of the transferred image at the front end. This concerns both image enlargement with a fiber optic cone and image enhancement.

Since the space area, which is usually made available for exposure fibers, is almost equal to the size of the image-carrying beam, such as eg.

7906056 9- * 2 - in U.S. Pat. Nos. 3,091,235, 3,902,880, and 3,913,568, the invention makes it possible to approximately double the area (section size) of the image-bearing beam with a corresponding increase in image-quality. . The single or small multiple fiber used to illuminate the article can be made of molten silica to allow ultraviolet light transmission for fluorescent studies in both medical and industrial applications.

10 Intensive arc lamps, lasers or ultraviolet sources can be used safely, as only little of the total energy can be transferred to the object (eg tissue) under investigation.

The invention will now be further elucidated with reference to the drawing. In the drawing: Fig. 1 shows a schematic side view, partly in cross-section, of a preferred embodiment of the invention, and Fig. 2 shows an enlarged cross-section of the endoscope of Fig. 1, taken along line II-II.

In the drawing, the endoscope 10 consists of a front-facing main body section 1.2 and a flexible probe 14, each of which is contained within, and preferably a rigid and a flexible support, i.e. sheaths 16, 16 and 18, shown schematically with dashed lines.

The carriers 16 'and 18 can be of any conventional shape. Examples are covered in U.S. Patents 3,091,235, 3,698,099, and 3,913,568.

In particular, sheath 18 may include means for suffering the rear end of probe 14, these means may include the arrangement disclosed in U.S. Pat. No. 3,913,568 or in U.S. Pat. Nos. 3,091,235 and 3,162,214.

Since the invention can be applied to any of the known forms of medical endoscopes as well as industrial endoscopes, details of these instruments will become. omitted.

As for the details of the invention; it aims to provide very small exposure fiber members 5 to allow the image carrier beam to be greatly enlarged and / or the medical channels to be increased in number or enlarged in size, the scheme of the invention schematically illustrated in the drawing , as follows: 10 By reducing the conventionally large number of exposure fibers to one or two fibers 20, as shown, a correspondingly larger free space 22 is provided within the sheath 18 of the probe 14. This space therefore becomes available for enlargement. of the operation of other functions of the endoscope, eg enlarging the image-conducting fiber bundle 24, enlarging a biopsy channel 26 or adding other channels, eg for medical catheters etc. If, for example, it is assumed that the illumination fibers 20 (Fig. 2) usually occupy approximately the cross section of the image connection beam 24, the space is saved within sheath 18 by incorporating only the two fibers 20 for the above purpose to be easily seen. While the schematic illustrations of Figures 1 and 25 show much unused space 22, it will be understood that it is precisely this space obtained by the reduction in number and / or size of the exposure fibers made available for the the aforementioned improvement of other functions of the endoscope.

The fibers 20 may be formed of glass or molten silicon dioxide, the latter allowing transmission of ultraviolet light for fluorescence research in either medical or industrial applications.

The illumination from source 28 can be in any desired form 35, including that produced by intensive arc lamps, lasers or high energy UV sources, which can be safely used in the invention since only one little total energy is transmitted backwards to tissues in eg medical applications.

Since there is a clear loss of object exposure by reducing the usual large number of exposure fibers to the above one or two fibers 20, it is recommended that this loss be compensated for by incorporating an image intensifier 30 at the front end of the endoscope 30. The image intensifier 30 shown is a close focusing fiber optic type, details of which can be found in U.S. Pat. Nos. 3,141,105, 3,321,658, and 3,436,142. With an object 32 exposed by the fibers 20 and imaged by the objective lenses 34 at the end 36 of the fiber bundle 24, the image can be transferred from the bundle 24 into the fiber optic cone 38 to be enlarged prior to amplification by the image intensifier 30, and are observed on end face 40 of the image intensifier 30 with the eyepiece lens 32. Further details of fiber optic cones can be found in U.S. Pat. Nos. 2,992,516, 2,992,587, and 3,187,627.

An exemplary specific configuration of the system shown in FIGS. 1 and 2, 25 may include a fiber optic cone (bundle 38) capable of enlarging an image conveyed by bundle 24 by a factor 4. The flexible beam 24 can have an effective diameter of about 3mm, so that the enlarged diameter is about 12mm, the image intensifier 30Q having an effective aperture of this latter diameter.

With the size of a single fiber for the flexible beam 24 of 15 microns (corresponding to a resolution of about 40 line pairs per mm), a magnification of four times the required resolution at 35 will reduce the image intensifier 30 to 10 line pareri per mm, which can easily be transferred in the usual way

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With the aforementioned starting image diameter of about 12 mm, an eyepiece magnification of about five times can meet normal observation requirements. However, it is clear that the amplified image output at the end face 40 can be directly coupled to a television camera or other means for display on a monitor (screen).

It will be apparent to those skilled in the art that numerous other modifications and modifications are possible to the invention as shown in the example described, in order to accommodate for special requirements. Such modifications and adaptations are also within the scope of the invention.

- conclusions - 790605e

Claims (7)

1. Endoscope with a front-facing main body and a flexible probe protruding from this main body and wherein in this probe are flexible image guiding and object exposure means, characterized in that the image guiding member consists of a large number of juxtaposed light-conducting fibers, which provide opposite image-receiving and image-emitting end faces of substantial diameter-10. that the exposure member consists of a significantly smaller number of optical fibers than is used for the image guide member, in order to minimize the space occupied by said exposure member in the probe, but yields a corresponding reduction in the exposure intensity of objects through the exposure member, and that in the main body is a front image intensifying member for receiving images of the image-emitting surface of the guiding member and displaying -sian- ^ p ^ p hpgiripn nm where. with an intensity increase which at least partially compensates for said reduction in illumination intensity of the object. 2. Endoscope according to claim 1, characterized in that the exposure member has a pair of optical fibers. 3. Endoscope according to claim 1, characterized in that the exposure member has a single fiber. 4. Endoscope according to claim 1, 2 or 3, characterized in that an image enlarger 7906056 is arranged between the image-endtering surface of the image guide member and the image intensifier member. Endoscope according to claim 1, 2, 3 or 4, characterized in that the reduction in illumination intensity of the object is fully compensated by the increase in image intensity. 6. Endoscope according to claim 1, 2, 3 or 4, characterized in that the reduction in object illumination intensity is overcompensated by the increase in image intensity. Endoscope according to any one of the preceding claims, characterized in that medical channels are accommodated in the probe. 7906056