FR2525098A1 - Optical head for eye observation and laser ophthalmological appts. - has concentric reflectors for coaxial marker and surgical beams - Google Patents

Abstract

The region of the eye to be treated by a coherent infrared beam from a Nd:YAG laser is observed by the visible light of a marker beam from a He-Ne laser, rotated by a beam splitter and rotator. The infrared surgical beam is enlarged by defocusing and converging lenses and reflected by two successive semitransparent mirrors through a focusing lens into the eye. The visible marker beam passes straight through the first mirror, enveloping the surgical beam and is reflected by the metallised outer zone of the second mirror in the same direction. Retroreflected light from the eye passes through the central zone, transparent to visible radiation, of the second mirror into e.g. a conventional binocular stereoscopic eyepiece.

Description

Optical head of an installation for the observation and treatment by laser radiation of the eye
The present invention relates to installations for the observation and treatment by laser radiation of the eye, and it relates more particularly to the optical head of such an installation.

 A number of eye conditions, such as different types of glaucoma or cataracts, or disorders resulting from the formation in the eye of membranes or filaments of various origins, can currently be treated with application in certain regions of the anterior or posterior chamber of the eye of high density laser radiation.

 For this purpose, ophthalmological treatment installations are used, generally complex, which combine a laser power generator. fixed, to produce the treatment laser beam, and a movable optical head capable of being approached by the patient's eye, and in particular making it possible to bring the treatment beam to the area to be treated.

 An installation of this type is described for example in the European patent application published under the number 0 030 210 in the name of the applicant. The power laser generator that it uses is an Nd-YAG laser that can deliver very short, very strong pulses in Q-Switch mode. The optical head of the installation, for its part, includes a device for lighting and observing the area of the eye to be treated and a generator of a marking laser beam.

The marking beam is produced for example by a laser
He-Ne and therefore consists of visible radiation. Its function is to precisely materialize the focal point of the processing beam, before the release of the pulse, as well as the envelope of this same beam. This last characteristic allows the operator of the installation to ensure that the treatment beam will not reach in passing a different zone from that which must be treated. The marking beam is obtained at the output of the generator by means of a rotating prism mechanism which divides the laser radiation produced into two elementary beams which will rotate around the treatment beam so as to materialize its envelope. fortuitous of one of these elementary beams with an obstacle is further improved by a modulator device alternately interrupting one or the other beam.

 Finally, the optical head of the aforementioned installation also includes a relatively complex set of optical elements such as prisms, mirrors, lenses making it possible to focus the various beams of lighting, marking and processing at the same point of the 'eye, through a contact lens applied to the cornea. In order to always guarantee perfect focusing of these beams at the same point, on which moreover the focusing of the observation device must be made, while allowing a displacement of this focal point in the axis of the beams, it has proven useful to provide a single focusing lens at the outlet of the optical head. However, the need to bring on this single focusing lens parallel beams of lighting and treatment, as well as the rotating marking beam , and also to provide means for bringing the image of the focal point into the observation device, has led to a complicated structure imposing numerous successive reflections on the different optical beams.

 This is why the present invention provides a simplified optical head which no longer necessarily includes an integrated lighting device. This head comprises a limited number of optical elements, which not only leads to a lower cost price and simpler assembly, but also to better optical efficiency. This latter improvement notably makes it possible to significantly lower the power of the processing radiation used, and it also results in greater brightness of the observation device. The advantage thus obtained of an increased luminosity more than compensates for the elimination of the integrated lighting device, which previously made it possible to focus the lighting beam on the place to be treated, avoiding parasitic reflections, but which notably complicated the construction The new optical head can thus be implemented without difficulty with any independent lighting system, of the slit lamp type, which is directed towards the patient's eye.

 According to an essential aspect of the invention, the optical head is provided, upstream of the focusing lens with a mirror which simultaneously ensures the reflection on this lens of the processing and marking beams, and the transmission of the observation beam .

 The marking and observation beams being made up of visible radiation, unlike the treatment beam, this mirror takes advantage of the location of the marking beam forming the envelope of the treatment beam. To this end, it comprises a central portion which ensures the passage of the observation beam and the reflection of the treatment beam, and an annular portion which is struck by the marking beam, and which is treated so as to also reflect it.

The invention will be clearly understood on reading the following description, made in conjunction with the accompanying drawings, among which:
- Figure 1 is a schematic view of the optical head according to
the invention; and
- Figure 2 is a view of the particular mirror used
in the optical head of figure 1.

 As best seen in FIG. 1, the optical head 1 comprises in particular observation means 2 on the optical axis 3 of which the focusing lens 4 is arranged. The observation means 2 can be constituted for example by a classic stereoscopic binocular set. The observation beam 5 which brings the image of the focal point F of the lens 4 to the observation means 2 passes directly through the central portion 6 of a first mirror 7 placed in front of the lens 4. This central part is formed by a surface with a maximum visible transmission coefficient.

 Furthermore, the optical head 1 also includes a defocus lens 8 adjustable in position and a converging lens 9 defining a treatment beam 10 from the coherent radiation 11 produced outside the head 1 by a generator 12 of the laser type Nd-YAG whose operating wavelength is around 1.06 zJ. The lenses 8 and 9 thus constitute a beam enlarger by the coherent beam 11. A second mirror 13 having a maximum reflection coefficient for this wavelength then sends the treatment beam 10 to the central portion of the first mirror 7, of which the surface has this same characteristic. The processing beam 10 is thus directed onto the focusing lens 10 coaxially with the observation beam 5.

 Finally, the optical head 1 also comprises a laser generator 14, for example of the He-Ne type, emitting in the visible a coherent radiation 15. A separation and rotation device 16 is associated with the generator 14 to form a beam of marking consisting of two elementary parts or rays 17 and 18 rotating around an axis 19 which coincides with that of the treatment beam 10 upstream of the first mirror 7. The spacing of the rays 17 and 18 is very slightly greater than the diameter of the beam treatment 10, so as to define the outer envelope of the latter. On leaving the device 16 for separation and rotation, the marking beam 17, 18 passes through the second mirror 13, which has a maximum transmission coefficient in the visible, and comes to strike the first mirror 7.An annular portion 20 of the latter, surrounding its central portion 6 is provided to reflect the marking beam 17, 18 towards the focusing lens 4. For this purpose, this annular portion 20 carries a coating reflecting in the visible, or at least for the length d wave of the marking beam, for example based on aluminum, whose internal diameter is greater than that of the observation beam 5 so as not to intercept it, and whose external diameter is greater than the spacing of the rays 17 and 18 of the marking beam.

 The observation means 2, the laser generators 12 and 14, the separation and rotation device 16, the focusing lens 4, as well as the operation of the insal # lati on as a whole have been exposed so very detailed in the aforementioned European patent application, and it is therefore unnecessary to repeat the description here.

 blanks in Figure 2, there is shown the first mirror 7 of the optical head, as well as the trace of the intersection of the observation beams 5, treatment 10, marking 17 and 18 with its central portion 6 and its outer portion ring finger 20.

 Although it has been described in relation to one of its particular embodiments, the present invention is in no way limited thereto, but is on the contrary liable to be the subject of numerous modifications and variants which will appear skilled in the art.

Claims (7)

 1. Optical head of an installation for the observation and treatment by laser radiation of the eye, comprising in particular observation means (2) of the area of the eye to be treated, means (8, 9) to define a beam (10) of treatment laser radiation and a beam (17, 18) of marking laser radiation, this marking laser radiation beam forming a visible envelope of the treatment beam and a focusing lens (4) of which the axis coincides with the optical axis (3) of the observation means and which ensures the focusing on the area of the eye to be treated of the treatment and marking beams, characterized in that it also comprises, in upstream of the focusing lens, a first mirror (7) simultaneously ensuring the reflection towards this lens (4) of the processing and marking beams and the transmission of an observation beam (5) to said observation means.  2. Optical head according to claim 1, characterized in that said first mirror (7) comprises a central portion (6) formed of a surface having a maximum reflection coefficient for the wavelength of the treatment beam, and a maximum transmission coefficient in the visible, this central portion being surrounded by an outer annular portion (20) having a maximum reflection coefficient for the wavelength of the marking beam.  3. Optical head according to claim 2, characterized in that the inside diameter of the annular portion of the first mirror is greater than the diameter of the observation beam (5), and in that its outside diameter is greater than the outside diameter of the beam marking (17, 18).  4. Optical head according to one of the preceding claims, characterized in that it further comprises a generator (14) of laser radiation (15), the axis of this radiation (15) coinciding with that (19) of the beams processing (10) and marking (17, 18) before their reflection on the first mirror (7), and a second mirror (13) adapted to ensure the transmission of the marking beam and the reflection, coaxially with this marking beam of the processing beam (10) generated outside the device and brought to the second mirror so as to ensure the superposition of these two beams.  5. Optical head according to claim 4, characterized in that it comprises a divergent lens (8) disposed on the axis of a coherent radiation 11, generated outside the device to form the treatment beam 10, at its entry into the optical head, and followed by a converging lens (9) disposed upstream of the second mirror (13), these two lenses (8 and 9) constituting for said coherent radiation 11 a beam enlarger.  6. Optical head according to claim 5, characterized in that the axial position of the diverging lens (8) is adjustable.  7. Optical head according to one of claims 4 to 6, characterized in that it comprises a device (16) for separation into two parts (17, 18) of the radiation (15) produced by the radiation generator (14) laser for marking, and for rotating these parts (17, 18) coaxially with the axis (19) of the treatment beam (10) before its reflection on the first mirror 7.