DD217711A1 - LASER DEVICE FOR SURGERY - Google Patents

Abstract

In addition to its use in surgery, the laser device can also be used in material processing. It is an Nd-YAG laser device with only one light source for sighting and treatment created and thereby a reduction of the target error can be achieved. In a laser device comprising a laser resonator with a first resonator mirror, polarizer, Nd-YAG crystal and second resonator mirror and an exciter assembly with excitation flash lamp and associated electronics, according to the invention, following the second resonator mirror, an SHG crystal and a compensation plate, which in the laser beam path can be pivoted, provided, wherein in SHG crystal with compensation plate located in the beam path, the discharge of the excitation flash lamp with a rapid sequence of low-energy pulses. figure

Description

-Laseiyöirichtungfür the Chis'uirgi.i ^ ";;" ·., ''''' ''.^ν 'Λ' '' '

, Field of application of the invention ''>. ,

The laser device according to the invention is preferably used for surgical purposes in medicine. In addition, however, a use in material processing is conceivable. ',,

Characteristic of the known technical solutions' - ^:

Known laser devices for surgery have as active laser medium an Nd-YAG crystal and emit radiation of wavelength i060.nm in cw or pw mode. The radiation is transferred in known manner to an optical device, e.g. on . : Surgical microscope, introduced and directed to the site of action. .

The emitted radiation of wavelength 1060 nm is not visible to the human eye and therefore can not be used to target the target site. For sighting therefore a second, visible light beam is necessary (DD-WP 132756), which must match exactly in its position and geometry with that of the Y AG laser beam. Known devices work with a second, smaller laser, preferably with a He-Ne laser, which is reflected via a coupling element in the optical target device in the beam path of the YAG laser radiation. This arrangement requires the technical overhead of a second laser with associated Einspiegelungsvorrichtungen that a particularly accurate; ; and require stable adjustment, otherwise target errors are the result.

Object of the invention

The aim of the invention is a laser device with reduced effort while reducing the target error possibilities and their consequences.

Explanation of the essence of the invention

The invention is based on the object to provide a Nd-YAG laser device for surgery, the only one light source

to treat and to target the destination. .

The object is achieved by a laser device consisting of a laser resonator and a excitation subassembly, wherein a first resonator mirror, a polarizer, a Nd-Yag crystal and a second resorator mirror are successively arranged along an optical axis and form the resonator and the excitation subassembly comprises an excitation flash lamp with associated laser electrical control consists, according to the invention in that along the optical axis in the propagation direction of the laser beam to the second resonator mirror following an SHG crystal and ej ne compensation plate are provided that the SHG crystal and the compensation plate can be pivoted into the laser beam path and that in the beam path SHG crystal with compensation plate discharge of the excitation flash lamp with a rapid sequence of low-energy pulses is carried out. It is advantageous if between the Nd-YAG crystal and the second resonator mirror a switchable in the beam path Q-switching device is provided.

To increase the conversion efficiency, it is advantageous if, between the second resonator mirror and the SHG crystal, a lens which can be pivoted into the laser beam path for focusing the infrared radiation into the SHG crystal

is provided. ',> ^:

It is also possible that the lens, the SHG crystal and the compensation plate are disposed within the laser cavity

are. ·. '.., .. ··

When the Shg crystal and the compensation plate are swiveled into the laser beam path, the birefringent crystal with non-linear optical properties (eg lithium iodate) in conjunction with the discharge of the excitation flash lamp causes the invisible laser radiation of wavelength 1060 nm to be visible by means of a rapid sequence of low-energy pulses Light of wavelength 530 nm converted. This light, as visible to the human eye, can be used to target the target site. The compensation plate is connected to compensate for the displacement of the extraordinary beam as a result of the necessary internal phase-matching the SHG crystal The compensation plate can be mirrored to eliminate interfering primary radiation for the wavelength 1060 nm.

For treatment of the SHG crystal and the compensation plate is swung out of the laser beam path, the discharge of the excitation flash lamp is carried out in a known manner by means of individual high-energy pulses, so that a laser radiation

high power with a wavelength of 1060 nm is available. , · '

Embodiment.

The invention will be explained in more detail with reference to an embodiment shown in the drawing. The laser device consists of a laser resonator in which a first resonator mirror 1> a polarizer 2, an Nd-YAG crystal 3, a Q-switching device 4 and a second resonator mirror 10 are arranged along the optical axis 8. In the propagation direction of the laser beam, following the resonator, a lens 5, an SHG crystal 6 and a Korhpensationsplatte 7 are present. Furthermore, there is a exciter assembly with an excitation flash lamp 14, which is connected via a switch 13 to a small capacitor bank 11, which is coupled to a pulse generator 15, or to a large capacitor bank 12. The Q-switching device 4, the lens 5, the SHG crystal 6 and the compensation plate 7 can be swung out of the laser beam path. '

To target the target location, the switch 13 is in the position that the excitation flash lamp 14 is connected to the small capacitor bank 11. Simultaneously with this switch position, the Q-switching device 4 is swung out of the beam path and the lens 5, the SHG crystal 6 and the compensation plate 7 pivoted into the beam path. The excitation flash lamp 14 is discharged by means of pulse generator 15 and small capacitor bank 11 by a series of small low-energy pulses. The SHG crystal 6 thus causes a frequency doubling, so that light of the wavelength 530 nm is formed, which serves as a quasi-continuous sighting light by the excitation type of the laser. The compensation plate 7 causes a return of the green light on the optical axis 8, the infrared light passes through the SHG crystal 6,

The offset of the green light beam is shown at 9 in the figure. The lens 5 focuses the infrared light into the SHG crystal 6.

When introducing the lens 5 and the SHG crystal 6, the SHG efficiency can be increased so that, with appropriate stimulation, the green light for therapy, eg. B. for Qphthajmokgagulation, can be used.

: · ".>." -2- 251577

For treatment, the switch 13 connects the excitation flash lamp 14 with the large capacitor bank 12. Lens 5, SHG crystal 6 and compensation plate 7 are thereby swung out of the beam path, quality switching device 4 is pivoted into the beam path. The discharge of the excitation flash lamp 14 is carried out in a known manner by means of individual high-energy pulses, so that the high-energy laser pulses are produced for treatment. The invention allows the use of a radiation source for treating and targeting the target location by the different excitation modes of the laser with simultaneous pivoting in and out of optical components in or out of the laser beam path.

Claims (4)

. '. '-.''^; ...:. -3- 251577.5 Invention claims '' , A surgical laser device comprising a Laserr.eson.ato / and a exciter assembly, wherein along a
optical axis successively a first resonator, a polarizer, a NdTYAG crystal and a second
ReSonatorspiegeLangeordnet are and the exciter assembly of a Anreurigsblitzlampe with associated electrical
Control consists, characterized in that along the optical axis in the propagation direction of the laser beam to the second resonator mirror following an SHG crystal and a compensation plate are provided, that the SHG crystal and the compensation plate can be pivoted into the laser beam path and that befindlichem in the beam path
SHG crystal with compensation plate, the discharge of the excitation flash lamp with a rapid sequence of low-energy pulses takes place. 2. Laservprününg according to item 1, characterized in that between the Nd-VAG crystal and the second
Resonator mirror an engageable in the beam path Q-switching device is provided. 3. Laser device according to item 1 and 2, characterized in that between the second resonator mirror and the
SHG crystals, a lens pivotable into the laser beam path is provided for focusing the infrared radiation into the SHG crystal. 4. Laser device according to item 1 to 3, characterized in that the lens, the SHG crystal and the compensation plate .. are arranged within the laser cavity. For this 1 page drawing