Source: http://www.google.com/patents/US4597380?dq=6819670
Timestamp: 2017-11-20 11:56:14
Document Index: 659793302

Matched Legal Cases: ['art 2', 'art 2', 'art 2', 'art 2', 'art 102', 'art 104', 'art 102', 'art 104', 'art 102', 'art 2', 'art 102', 'art 102']

Patent US4597380 - Endoscopic attachment to a surgical laser - Google Patents
An endoscopic attachment to a surgical laser comprises a hollow endoscopic tube adapted to be coupled at its rear end to the surgical laser, a coupling device including a pivotable reflector in the path of the laser beam transmitted through the endoscopic tube for reflecting same to the working area...http://www.google.com/patents/US4597380?utm_source=gb-gplus-sharePatent US4597380 - Endoscopic attachment to a surgical laser
Publication number US4597380 A
Application number US 06/613,338
Filing date May 23, 1984
Publication number 06613338, 613338, US 4597380 A, US 4597380A, US-A-4597380, US4597380 A, US4597380A
Inventors Joshua Raif, Eliezer Zair
Original Assignee Laser Industries Ltd.
Patent Citations (14), Referenced by (68), Classifications (16), Legal Events (5)
Endoscopic attachment to a surgical laser
US 4597380 A
An endoscopic attachment to a surgical laser comprises a hollow endoscopic tube adapted to be coupled at its rear end to the surgical laser, a coupling device including a pivotable reflector in the path of the laser beam transmitted through the endoscopic tube for reflecting same to the working area at the front end of the tube, and a manipulatable joystick connected to the reflector for manipulating the laser beam to direct it through the endoscopic tube and to selected positions in the working area at the front end of the tube. The attachment is to be used with a surgical laser producing a working laser beam and a separate, visible, aiming laser beam, the latter being partially reflected by the reflector and partially transmitted through the reflector to permit viewing the working area. The reflector further includes a light-absorbing member located to absorb the visible light transmitted through the reflector from the aiming laser beam, but not to interfere with observing the working area through the eyepiece.
1. An endoscopic attachment to a surgical laser, comprising:
a hollow endoscopic tube coupleable at one end, constituting its rear end, to the surgical laser such as to enable the laser to transmit a laser beam through the endoscopic tube and to exit therefrom onto a working area at the opposite end, constituting the front end of the endoscopic tube;
said hollow endoscopic tube including a fitting at its rear end for a light source to illuminate the working area at the front end of the tube;
and a coupling device for coupling the surgical laser to said rear end of the endoscopic tube; said coupling device including;
a pivotable reflector in the path of said laser beam for reflecting same through the endoscopic tube to said working area at the front end thereof; and
a manipulatable joystick connected to said reflector for manipulating the laser beam to direct it through the endoscopic tube and to selected positions in said working area at the front end of the endoscopic tube;
said surgical laser producing both a working laser beam and a separate, visible, aiming laser beam; said endoscopic attachment further including an eyepiece enabling viewing the visible aiming laser beam;
said eyepiece being located coaxially with said hollow endoscopic tube at said rear thereof;
said coupling device directing both of said laser beams along an axis perpendicular to the axis of the endoscopic tube to be reflected by said pivotable reflector along said latter axis to said working area;
said pivotable reflector being highly reflective with respect to said working laser beam, and partially reflective and partially transmissive with respect to visible light to permit said aiming laser beam to be viewed through said eyepiece, said reflector further including a light absorber member connected therewith to said joystick so as to be moved with the reflector by the manipulation of said joystick;
said light absorbing member being located out of the optical path through said eyepiece to the working area, but in position to absorb the visible light of said aiming laser beam transmitted through said reflector.
2. The endoscopic attachment according to claim 1, wherein said endoscopic tube includes a further fitting having an axis at an angle to the axis of the endoscopic tube to enable a tool to be inserted therethrough and to be manipulated at the working area.
3. The endoscopic attachment according to claim 2, wherein said coupling device includes a telescope having an eyepiece disposed along the longitudinal axis of said endoscopic tube rearwardly of the reflector, said reflector being highly reflective with respect to the laser beam, and paritally reflective and partially transmissive with respect to visible light.
4. The endoscopic attachment according to claim 1, wherein said endoscopic tube includes a telescope located in front of said reflector, said endoscopic tube including a channel for the laser beam and a separate channel for viewing the working area via said telescope.
5. The endoscopic attachment according to claim 1, wherein said light absorber member is a plate of absorbing glass located parallel to but spaced from said reflector on the side thereof opposite to said coupling device for the laser beams.
6. The endoscopic attachment according to claim 5, wherein said glass plate includes an anti-reflecting coating on the face thereof facing said reflector.
7. An endoscopic attachment to a surgical laser, comprising: a hollow endoscopic tube; a coupling device for coupling, to one end of the hollow endoscopic tube constituting its rear end, a surgical laser producing both a working laser beam and a separate, visible, aiming laser beam, such as to permit both laser beams to pass through the endoscopic tube onto a working area at the opposite end of the endoscopic tube, constituting its front end; said coupling device further including a pivotable reflector in the path of said laser beams for reflecting same through the endoscopic tube to said working area at the front end thereof; a manipulatable joystick connected to said reflector for manipulating both laser beams to direct them through the endoscopic tube to selected positions in said working area at the front end thereof; an eyepiece located at the rear end of said hollow endoscopic tube and coaxially thereof; said coupling device directing both said laser beams along an axis perpendicular to the axis of the endoscopic tube to be reflected by said pivotable reflector along said latter axis to said working area; said pivotable reflector being highly reflective with respect to said working laser beam, and partially reflective and partially transmissive with respect to visible light to permit said aiming laser beam to be viewed through said eyepiece; and a light-absorbing member connected with said reflector to said joystick so as to be moved therewith by the manipulation of said joystick; said light-absorber member being located out of the optical path of said eyepiece but in position to absorb the visible light of said aiming laser beam transmitted through said reflector.
8. The endoscopic attachment according to claim 7, wherein said light absorber member is a plate of absorbing glass located parallel to but spaced from said reflector on the side thereof opposite to said coupling device for the laser beams.
9. The endoscopic attachment according to claim 8, wherein said glass plate includes an anti-reflecting coating on the face thereof facing said reflector.
10. The endoscopic attachment according to claim 7, wherein said endoscopic tube includes a further fitting having an axis at an angle to the axis of the endoscopic tube to enable a tool to be inserted therethrough and to be manipulated at the working area.
11. Laser apparatus comprising a surgical laser producing both a working laser beam and a separate, visible, aiming laser beam; a hollow endoscopic tube coupled at one end, constituting its rear end, to said surgical laser such as to permit both laser beams to pass through the endoscopic tube onto a working area at the opposite end of the endoscopic tube, constituting its front end; a pivotable beam-splitter in the path of both of said laser beams for reflecting same through the endoscopic tube to said working area at the front end thereof; a manipulatable joystick connected to said beam-splitter for manipulating the laser beams to direct them through the endoscopic tube to selected positions in said working area at the front end thereof; an eyepiece located at the rear end of said hollow endoscopic tube and coaxially therewith; said surgical laser being disposed such that both its laser beams are directed along an axis perpendicular to the axis of the endoscopic tube and are reflected by said pivotable beam-splitter along said latter axis to said working area; said pivotable beam-splitter being highly reflective with respect to said working laser beam, and partially reflective and partially transmissive with respect to visible light to permit said aiming laser beam to be viewed through said eyepiece; and a light-absorbing member connected with said beam-splitter to said joystick so as to be moved therewith by the manipulation of said joystick; said light-absorber member being located out of the optical path of said eyepiece but in position to absorb the visible light of said aiming laser beam transmitted through said beam-splitter.
12. Laser apparatus according to claim 11, wherein said light-absorber member is a plate of absorbing glass located paralled to but spaced from said beam-splitter on the side thereof opposite to said surgical laser.
13. Laser apparatus according to claim 12, wherein said glass plate includes an acute-reflecting coating on the face thereof facing said beam-splitter.
14. Laser apparatus according to claim 12, wherein said eyepiece is a part of a telescope located behind said reflector.
15. Laser apparatus according to claim 12, wherein said endoscopic tube further includes a fiber-optical bundle extending therethrough and adapted to be coupled at its rear end to a source of visible light and to transmit same to its front end to illuminate the working area in the front end of the endoscopic tube.
16. Laser apparatus according to claim 12, wherein said endoscopic tube further includes a fitting having an axis at an angle to the axis of the endoscopic tube to enable a tool to be inserted therethrough and to be manipulated at the working area.
The present application is a continuation-in-part of application Ser. No. 06/431,204 filed Sept. 30, 1982, now abandoned.
The present invention relates to endoscopic attachments to a surgical laser.
Surgical lasers are now gaining increasing use for performing various types of surgical operations Among their many advantages are their ability to make very clean, fine cuts while minimizing damage to tissue outside the cutting line; and also their ability to readily coagulate the blood in capillaries, small veins and arteries, thereby minimizing loss of blood and keeping the wound area clean. One example of a surgical laser with respect to which the present invention is particularly useful is described in U.S. Pat. No. 3,913,582. Various types of attachments have also been devised to enhance the use of surgical lasers, some of these attachments being described in U.S. Pat. Nos. 3,865,113 and 3,865,114. Surgical lasers, however, have not yet been widely used with endoscopic attachments having long and small-diameter endoscopic tubes, because of the difficulty of directing the laser beams through such long and small-diameter tubes.
An object of the present invention is to provide an endoscopic attachment to a surgical laser to enable its use with long and small-diameter endoscopic tubes. Another object is to provide laser apparatus including such attachments.
According to a broad aspect of the present invention, there is provided an endoscopic attachment to a surgical laser, comprising a hollow endoscopic tube coupleable at its rear end to the surgical laser such as to enable the laser to transmit laser beams through the endoscopic tube and to exit therefrom onto a working area at the front end of the endoscopic tube; and a coupling device for coupling the surgical laser to the rear end of the endoscopic tube.
The coupling device includes a pivotable reflector in the path of the laser beam for reflecting it through the endoscopic tube to the working area at the front end of the tube, and a manipulatable joystick connected to the reflector for manipulating the laser beam to direct it through the endoscopic tube to selected positions in the working area at the front end of the tube.
The surgical laser produces two separate beams, namely, a working laser beam (e.g. CO2) and a visible, aiming laser beam (e.g., He-Ne). An eyepiece is located coaxially with the endoscopic tube for viewing the working area. Both of the laser beams are directed along an axis perpendicular to the axis of the endoscopic tube and eyepiece, and are reflected by a pivotable reflector along the latter axis to the working area. The reflector is actually a beam-splitter, being highly reflective with respect to the working laser beam, and partially reflective and partially transmissive with respect to visible light, to permit the aiming laser beam to be viewed through the eyepiece. The attachment further includes a light-absorber member connected to the beam-splitter reflector and to the joystick so as to be moved therewith by the manipulation of the joystick. The light-absorbing member is located out of the optical path through the eyepiece to the working area, but in position to absorb the visible light from the aiming laser beam transmitted through the beam-splitter reflector. Such a device is particularly useful as a laser bronchoscope.
In a second described embodiment, the endoscopic tube includes a telescope located in front of the laser beam reflector, the endoscopic tube including a channel for the laser beam and a separate channel for viewing the working area via the telescope. Such a device is particularly useful as a laparoscope.
The invention is herein described by way of example only, with reference to the accompanying drawings, wherein:
FIG. 1 illustrates one form of endoscopic attachment constructed in accordance with the invention, this form being particularly useful as a bronchoscope;
FIG. 1a is a sectional view along lines a--a of FIG. 1;
FIG. 2 illustrates a second form of endoscopic attachment constructed in accordance with the invention, this form being particularly useful as a laparoscope; and
FIG. 2a is a sectional view along lines a--a of FIG. 2.
With reference to FIG. 1, the bronchoscope illustrated comprises two main parts, namely, the endoscopic tube portion, generally designated 2, and a coupling device, generally designated 4, for coupling portion 2 to a surgical laser, schematically indicated by box 6.
Part 2 of the bronchoscope illustrated in FIG. 1 comprises an endoscopic tube 21 coupleable at its rear end (right end in FIG. 1) to the coupling device 4 such as to enable the laser 6 to transmit a laser beam through the endoscopic tube 21 and to exit therefrom to a working area at the front end (left end, FIG. 1) of the endoscopic tube. The front end of the endoscopic tube 21 is preferably cut at a bias, as shown at 22.
Part 2 also includes a number of fittings for use with the endoscopic tube 21 during surgical operations. Thus, part 2 includes, at the rear end of the endoscopic tube 21, a fitting 23 for a light source 24 adapted to illuminate the rear end of a fiber-optical bundle 25 (see FIG. 1a) extending through the endoscopic tube 21 to illuminate the working area at the front end of that tube: a fitting 26 whose axis is at an angle (e.g. 45°) to that of the endoscopic tube 21, to enable a tool to be inserted through the endoscopic tube and to be manipulated by the surgeon at the working area during the surgical operation; a fitting 27 for applying suction through a tubelet 28 (FIG. 1a) extending through the endoscopic tube to the working area at the front end of the tube; and a further fitting 29 for coupling the interior of the endoscopic tube to a source of pressurized fluid, such as pressurized air, for inflating the working area at the front end of the endoscopic tube.
The coupling device 41 for coupling the laser beam to the endoscopic tube 21, includes a tube 41 adapted to be coupled to the rear end of, and to extend coaxially with, the endoscopic tube 21 of part 2; a second tube 42 for coupling to the surgical laser 6, the longitudinal axis of tube 42 being perpendicular to that of tube 41 and the endoscopic tube 21; and a reflector 43 at the intersection point of the axes of tubes 41 and 42.
Reflector 43 is connected to a joystick 44 which is manipulatable by the surgeon to direct the laser beam through the tube 44. An optical device, in the form of a telescope including an optical tube 45 and an eyepiece 46 both coaxial to the longitudinal axis of the endoscopic tube 21, is attached to the rear end of tube 21 to permit receiving the working area at the front end of the tube.
The coupling device 4 further includes a two-position mechanical shutter 47 between fitting 42 for coupling to the laser 6, and the reflector 43. The mechanical shutter 47 is operated to selectively block the laser beam from, or to transmit it to, the reflector 43 and thereby to the working area at the front end of the endoscopic tube 21.
The surgical laser 6 produces two laser beams, namely, a working beam (e.g., CO2) and visible, sighting or aiming laser beam (e.g., He-Ne). Both beams are introduced via fitting 42 along an axis perpendicular to the axis of the endoscopic tube 21, and are reflected by reflector 43 along the latter axis to the working area at the front of the tube. Reflector 43 is a beam-splitter, being highly reflective with respect to the working laser beam, and partially reflective (about 50%) and partially transmissive with respect to visible light, i.e., the visible, aiming laser beam, so as to permit the aiming laser beam to be viewed through eyepiece 46.
The illustrated apparatus further includes a light-absorbing member 62 befween beam-splitter reflector 43 and the inner face 60 of the coupling device 4.
Absorber member 62 is in the form of a plate of absorbing glass which is located parallel to but spaced from the beam-splitter reflector 43 on the side thereof opposite to the coupling device 42 for the surgical laser 6, i.e. between reflector 43 and the inner face 60 of the coupling device. Plate 62 is connected by a coupling schematically indicated by broken lines 64, to the joystick 44 so as to be moved with reflector 43 during its manipulation by the joystick. In addition, the absorbing glass plate 62 is located sufficiently below reflector 43 so as to absorb the visible light passing through the reflector, but out of the optical path through the eyepiece to the working area so as not to interfere with the viewing of the working area.
It was found that this arrangement substantially improves the visibility of the working area via eyepiece 46, since it eliminated the glare produced by the light from the aiming laser beam passing through reflector 43 which impinged against the inner face 60 of the fitting and was reflected back to the beam-splitter reflector 43 and then to the eyepiece 46.
As one example, plate 62 may be of Schott Filter Glass RG 850 coated with an anti-reflection coating on the face thereof facing reflector 43.
The joystick 44 may be coupled to reflector 43 in any known manner, such as by a mechanical coupling as described in U.S. Pat. No. 4,228,341 or by an electrical coupling, so as to enable the surgeon to manipulate the reflector, and thereby to manipulate the laser beams, to selected positions in the working area at the front end of the endoscopic tube 21, while that working area is being viewed via the telescope eyepiece 46.
The laparoscope illustrated in FIGS. 2 also includes two main parts, namely, part 102 carrying the endoscopic tube 121, and part 104 constituting the coupling device for coupling the endoscopic tube 121 to the surgical laser, schematically indicated by box 106. The laparoscope of FIG. 2 also includes a telescope optical device to enable viewing the working area, but in this case, the telescope is carried by the endoscopic tube part 102, rather than by the coupling device part 104 as in the FIG. 1 embodiment
More particularly, part 102 also includes, as part 2 in FIG. 1, in addition to the endoscopic tube 121 and at its rear end: a fitting 123 for coupling a visible light source 124 to the rear end of a fiber-optical bundle 125 (FIG. 2a) extending through the endoscopic tube 121; a suction fitting 127 for applying suction via a tubelet 128 extending through the endoscopic tube 121; and a pressurized-fluid fitting 129 for applying a pressurized fluid, such as air, via the interior of the endoscopic tube 121 to the working area at its front end. It will be noted that the laparoscope illustrated in FIG. 2 does not include a tool insertion fitting, corresponding to fitting 26 in FIG. 1, but does include the telescopic optical device.
The telescopic optical device, generally designated 130 in FIG. 2, includes a first optical tube tube 131 located at the rear of the endoscopic tube 121 with its longitudinal axis perpendicular to that of the endoscopic tube. One end of optical tube 131 is coupled to part 102, and the opposite end of optical tube 131 is coupled to a second optical tube 132 whose axis extends parallel to the longitudinal axis of the endoscopic tube 121. The outer end of optical tube 132 is provided with an eyepiece 133 to permit the surgeon to view the working area at the front end of the endoscopic tube 121 via a separate channel 134 through the endoscopic tube 121.
The coupling device 104, for coupling the endoscopic tube 121 to the surgical laser 106, includes: a first coupling tube 141 for coupling to the endoscopic tube part 102 and coaxial with the endoscopic tube 121; a second coupling tube 142 for coupling to the laser 106 perpendicular to the axis of the endoscopic tube 121; and a reflector 143 at the point of intersection of the longitudinal axis of the endoscopic tube 121 with that of coupling tube 142. The coupling device 104 further includes a joystick 144, corresponding to joystick 44 in FIG. 1, for manipulating the reflector 143, to permit the surgeon to manipulate the laser beam passing through the endoscopic tube 121 to selected positions in the working area at the front end of the endoscopic tube and also to initially direct the beam through the tube.
It will be seen that the telescopic device 130 in the laparoscope of FIG. 2 does not use the manipulatable reflector 143 provided for manipulating the laser beam, but rather uses a separate channel 134 (FIG. 2a), to view the working area at the front end of the endoscopic tube. Accordingly, the reflector 143 need only be reflective with respect to the laser beam and need not be transmissive with respect to visible light, as in the FIG. 1 embodiment. Preferably, however, the laser beam in the FIG. 2 embodiment also includes a working CO2 beam and a sighting He-Ne beam as in FIG. 1.
US3796220 * Mar 24, 1972 Mar 12, 1974 H Bredemeier Stereo laser endoscope
US3865113 * Dec 4, 1972 Feb 11, 1975 Laser Ind Ltd Laser device particularly useful as surgical scalpel
US3865114 * Oct 11, 1973 Feb 11, 1975 Laser Ind Ltd Laser device particularly useful as a surgical instrument
US4141362 * May 23, 1977 Feb 27, 1979 Richard Wolf Gmbh Laser endoscope
US4211229 * Dec 1, 1977 Jul 8, 1980 Richard Wolf Medical Instruments Corp. Laser endoscope
US4228341 * Dec 12, 1978 Oct 14, 1980 Laser Industries Ltd. Mechanical control system particularly useful for directing a laser beam
US4261346 * Nov 23, 1979 Apr 14, 1981 Richard Wolf Medical Instruments Corporation Endoscopes
US4273110 * Jul 11, 1979 Jun 16, 1981 Jean Groux Ultraviolet endoscope
US4392485 * Apr 21, 1981 Jul 12, 1983 Richard Wolf Gmbh Endoscope
US4759360 * Oct 14, 1986 Jul 26, 1988 Kowa Company Ltd. Laser coagulation system
US4798452 * Oct 4, 1985 Jan 17, 1989 Erb Robert C Autoclavable laser beam manipulator
US4844062 * Oct 23, 1987 Jul 4, 1989 Spectranetics Corporation Rotating fiberoptic laser catheter assembly with eccentric lumen
US4887894 * Feb 6, 1989 Dec 19, 1989 Edward Weck Incorporated Beam deflector
US4998971 * Jun 19, 1990 Mar 12, 1991 Kabushiki Kaisha Toshiba Electronic endoscope apparatus capable of observing laser-illuminated biological body portion
US5026367 * Mar 18, 1988 Jun 25, 1991 Cardiovascular Laser Systems, Inc. Laser angioplasty catheter and a method for use thereof
US5074860 * Jun 9, 1989 Dec 24, 1991 Heraeus Lasersonics, Inc. Apparatus for directing 10.6 micron laser radiation to a tissue site
US5128509 * Sep 4, 1990 Jul 7, 1992 Reliant Laser Corp. Method and apparatus for transforming and steering laser beams
US5203781 * Dec 19, 1991 Apr 20, 1993 Meditron Devices, Inc. Lumbar arthroscopic laser sheath
US5219347 * Dec 24, 1991 Jun 15, 1993 Laser Engineering, Inc. Decoupled dual-beam control system
US5251612 * Nov 13, 1991 Oct 12, 1993 Laser Engineering, Inc. Self-aligning coupler for a laser endoscope
US5312397 * Sep 23, 1991 May 17, 1994 Ioan Cosmescu Lens exchanger for a surgical laser system and method therefor
US5339812 * Dec 14, 1992 Aug 23, 1994 Medical Instrumentation And Diagnostic Corporation Three-dimensional computer graphics simulation and computerized numerical optimization for dose delivery and treatment planning
US5342353 * May 6, 1992 Aug 30, 1994 Allen Paul M System for laser treatment of the female urethra and bladder
US5354314 * Aug 28, 1992 Oct 11, 1994 Medical Instrumentation And Diagnostics Corporation Three-dimensional beam localization apparatus and microscope for stereotactic diagnoses or surgery mounted on robotic type arm
US5398684 * Mar 31, 1992 Mar 21, 1995 Hardy; Tyrone L. Method and apparatus for video presentation from scanner imaging sources
US5425729 * Mar 16, 1992 Jun 20, 1995 Kowa Company Ltd. Laser coagulation system
US5437659 * Apr 6, 1993 Aug 1, 1995 Eli Lilly And Company Angioplasty catheter and method of use thereof
US5783798 * Dec 19, 1995 Jul 21, 1998 Laser Industries Ltd. Laser beam delivery method and system
US6240308 Mar 22, 1996 May 29, 2001 Tyrone L. Hardy Method and apparatus for archiving and displaying anatomico-physiological data in a normalized whole brain mapping and imaging system
US6873867 Apr 5, 2001 Mar 29, 2005 Brainlab Ag Referencing or registering a patient or a patient body part in a medical navigation system by means of irradiation of light points
US7561317 Nov 3, 2006 Jul 14, 2009 Ethicon Endo-Surgery, Inc. Resonant Fourier scanning
US7577474 Feb 22, 2005 Aug 18, 2009 Brainlab Ag Referencing or registering a patient or a patient body part in a medical navigation system by means of irradiation of light points
US7589316 Jan 18, 2007 Sep 15, 2009 Ethicon Endo-Surgery, Inc. Scanning beam imaging with adjustable detector sensitivity or gain
US7740626 * Nov 17, 2004 Jun 22, 2010 Terumo Kabushiki Kaisha Laser induced liquid jet generating apparatus
US7951139 Jan 18, 2008 May 31, 2011 Inlight Corporation Laser surgical apparatus
US20050124985 * Nov 17, 2004 Jun 9, 2005 Terumo Kabushiki Kaisha Laser induced liquid jet generatng apparatus
US20050143645 * Feb 22, 2005 Jun 30, 2005 Stefan Vilsmeier Referencing or registering a patient or a patient body part in a medical navigation system by means of irradiation of light points
US20080255458 * Apr 13, 2007 Oct 16, 2008 Ethicon Endo-Surgery, Inc. System and method using fluorescence to examine within a patient's anatomy
US20090187176 * Jan 18, 2008 Jul 23, 2009 Inlight Corporation Laser Surgical Apparatus
EP0327410A1 * Jan 4, 1989 Aug 9, 1989 Karl Storz GmbH &amp; Co. Multifunctional operatory laparoscopy device permitting to execute different operatory actions with instruments introduction
EP0402101A2 * Jun 5, 1990 Dec 12, 1990 Heraeus Surgical, Inc. Apparatus for directing 10.6 micron laser radiation to a tissue site
EP0402101A3 * Jun 5, 1990 Jul 3, 1991 Heraeus Surgical, Inc. Apparatus for directing 10.6 micron laser radiation to a tissue site
EP0746225A1 * Nov 12, 1992 Dec 11, 1996 Plc Medical Systems, Inc. Self-aligning coupler for a laser endoscope
EP0746225A4 * Nov 12, 1992 Nov 17, 1995 Plc Medical Systems Inc Self-aligning coupler for a laser endoscope
EP1142536A1 * Apr 5, 2000 Oct 10, 2001 BrainLAB AG Patient referencing in a medical navigation system using projected light points
WO1989006519A2 * Jan 19, 1989 Jul 27, 1989 Refractive Laser Research & Development Program, L Method and apparatus for laser surgery
WO1989006519A3 * Jan 19, 1989 Nov 16, 1989 Refractive Laser Res & Dev Method and apparatus for laser surgery
WO1992017138A2 * Apr 3, 1992 Oct 15, 1992 Premier Laser Systems, Inc. Laser surgical probe
WO1992017138A3 * Apr 3, 1992 Nov 12, 1992 D Michael Colvard Laser surgical probe
WO1993011712A1 * Dec 18, 1992 Jun 24, 1993 Meditron Devices, Inc. Lumbar arthroscopic laser sheath
WO1993012727A1 * Dec 22, 1992 Jul 8, 1993 Laser Engineering, Inc. Decoupled dual-beam control system
U.S. Classification 600/108, 219/121.78, 600/164, 606/14, 219/121.76, 606/18, 600/138
International Classification A61B19/00, G02B26/08, A61B18/20
Cooperative Classification A61B2018/2025, A61B18/201, G02B26/0816, A61B2034/742
European Classification A61B18/20B, G02B26/08M
May 23, 1984 AS Assignment
Owner name: LASER INDUSTRIES LTD., KIRYA L TAASIOT ATIROT MEDA
Free format text: ASSIGNMENT OF ASSIGNORS INTEREST.;ASSIGNORS:RAIF, JOSHUA;ZAIR, ELIEZER;REEL/FRAME:004263/0757
Owner name: LASER INDUSTRIES LTD.,ISRAEL
Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNORS:RAIF, JOSHUA;ZAIR, ELIEZER;REEL/FRAME:004263/0757
Nov 24, 1989 FPAY Fee payment