Patent Application
20080275435
(1) Field of the Invention
The present invention pertains to a microsurgical laser probe used primarily in ophthalmic surgery. The probe has a handle and a tubular tip that projects from the handle, and three optic fibers that extend through the handle and the tip.
One of the optic fibers is a laser optic fiber. The laser optic fiber is specifically adapted to be connected to a source of laser light at one end of the laser optic fiber, to conduct the laser light through the fiber, and to transmit the laser light from the opposite end of the laser optic fiber at the distal end of the instrument tip.
The other two optic fibers are illumination light optic fibers. Each illumination light optic fiber is specifically adapted to be connected to a illumination light source at one end of the illumination optic fiber, to conduct the illumination light through the illumination fiber, and to transmit the illumination light from the distal end of the instrument tip. By providing two illumination light optic fibers in the instrument, the amount of illumination directed to the surgical site being accessed by the laser optic fiber is effectively doubled.
(2) Description of the Related Art
In ophthalmic surgery, various different types of instruments are available for use by the surgeon to transmit laser energy to a surgical site in the interior of the eye. The typical microsurgical laser probe comprises a handle with a small cylindrical metal tip that projects from a distal end of the handle. A laser optic fiber, having a proximal end with a connector for coupling to a source of laser light, passes through the handle and the tip of the probe. The distal end of the laser optic fiber is positioned adjacent the distal end of the instrument tip. Connecting the laser light connector to a source of laser light and activating the source of laser light enables the surgeon to direct the laser light from the instrument tip to a surgical site.
Illumination probes are also often used in ophthalmic surgery. The illumination probe has a similar construction to the laser probe, except that the optic fiber extending through the illumination probe is specifically designed for transmission of illumination light, where the optic fiber that extends through the laser probe is specifically designed for the transmission of laser light. In the typical ophthalmic surgery procedure, an incision must be made in the eye to accommodate the tip of the laser probe, and a second incision must be made through the eye to accommodate the tip of the illumination probe. Furthermore, the illumination probe must be manipulated by the surgeon in order to direct the illuminating light to the desired surgical site while the surgeon simultaneously manipulates the laser probe to direct the laser light to the desired surgical site. The requirement that both of the surgical instruments be simultaneously manipulated to direct both illumination light and laser light to the surgical site adds complexity to an already complex surgical procedure.
The present invention provides a laser probe designed primarily for ophthalmic surgery that overcomes the disadvantages associated with prior art laser probes by providing both a laser light transmitting optic fiber and an illumination light transmitting optic fiber in the same probe. Furthermore, the illumination function of the laser probe of the invention is multiplied by providing two illumination light transmitting optic fibers in the same instrument with the laser light transmitting optic fiber.
The instrument of the invention has a narrow, elongate handle that is designed to fit comfortably into the surgeon's hand. An elongate tubular tip of surgical steel projects from the handle.
A laser light transmitting optic fiber extends through both the handle and the tip. The proximal end of the laser light optic fiber is adapted for connection to a laser light source. The opposite distal end of the laser light fiber is positioned adjacent the instrument tip for transmitting laser light from the instrument to a surgical site.
A novel feature of the invention is provided by a pair of illumination light transmitting optic fibers that extend through the handle and the tip. Each illumination optic fiber has a proximal end that is adapted for connection to a separate source of illumination light. The opposite distal ends of the pair of illumination optic fibers are positioned adjacent the distal end of the tip. The illumination light transmitted from both illumination fiber distal ends provides a multiplied area of illumination at the surgical site being accessed by the laser light. In the preferred embodiment of the invention, to reduce the size of the instrument for use of the instrument in microscopic surgery, the laser light optic fiber and the pair of illumination light optic fibers are the only optic fibers that extend through the handle and the tip. Also in the preferred embodiment, the proximal ends of the two illumination light optic fibers are adapted for connection to two separate sources of illumination light. This effectively doubles the amount of illumination transmitted to the surgical site than was previously available using prior art ophthalmic surgery instruments.
Features of the invention are set forth in the following detailed description of the preferred embodiment of the invention and in the following drawing figures wherein:
The surgical instrument of the invention is primarily intended to provide illumination light and laser light in laser eye surgery. However, the instrument may be used in other types of surgery. In addition, instead of laser light, the instrument could be provided with a surgical device that provides aspiration to a surgical site, or the instrument could be provided with a bipolar cautery device, or some other type of surgical device. The instrument is designed as a disposable instrument, but alternatively, the instrument could be a reusable instrument that is sterilized after each use.
The instrument has an elongate, narrow handle or hand piece 12 that has opposite proximal 14 and distal 16 ends. The handle 12 is dimensioned to a size similar to that of a pencil to fit comfortably in a surgeon's hand and to be easily manually manipulated by the surgeon's hand. A hollow interior bore 18 extends through the center of the handle 12 from the handle proximal end 14 to the handle distal end 16.
An elongate, tubular tip 32 projects from the handle distal end 16. The tip is preferably constructed of surgical steel, and has the general construction of a hypodermic needle. The tubular tip 32 has an interior bore that extends through the tip from a proximal end 36 of the tip to a distal end 38 of the tip. The tip proximal end 36 is received in the handle interior bore 18 at the handle distal end 16 and is secured stationary in place by adhesives 40 or other equivalent means. In alternative embodiments of the instrument, the tip 32 can be curved along a portion of its length.
A laser optic fiber 42 is one example of a surgical device that can be used in the instrument of the invention. The laser optic fiber 42 is specifically designed to conduct and transmit laser light. As stated earlier, other types of surgical devices could be used, and the instrument should not be viewed as only usable with a laser optic fiber. For example, in place of the laser optic fiber, the instrument could comprise an aspiration tube, or a bipolar cautery device, or some other type of surgical device. The laser optic fiber 42 has an elongate, continuous length with opposite proximal 44 and distal 46 ends. The optic fiber extends through the handle 12 and through the tip 32 to the fiber distal end 46. A laser connector 48 is provided at the laser optic fiber proximal end 44. The laser connector 48 is adapted for connecting the laser optic fiber 42 to a separate laser light source 50 that is represented schematically in
A first illumination optic fiber 52 having a continuous length with opposite proximal 54 and distal 56 ends extends through the handle 12 and through the tip 32. The illumination optic fiber 52 is specifically designed to conduct and transmit illuminating light. The illumination optic fiber proximal end 54 is adapted to be connected to a first illumination light source 58 that is represented schematically in
A second illumination optic fiber 62, entirely separate from the first illumination optic fiber 52, also extends through the handle 12 and through the tip 32. The second illumination optic fiber 62 has a length with opposite proximal 64 and distal 66 ends. The second illumination optic fiber proximal end 64 is adapted to be connected to an entirely separate, second illumination light source 68, represented schematically in
In other embodiments of the surgical probe, the positions of the optic fiber distal ends can be varied. For example, the laser optic fiber distal end 46 and the illumination optic fiber distal ends 56, 66 could all be positioned adjacent or flush with each other. These distal ends of the optic fibers could also be positioned adjacent or flush with the tip distal end 38, or could all be extended outwardly from the tip distal end. Furthermore, the optic fiber distal ends 46, 56, 66 could be positioned at staggered positions relative to each other. The distal ends of the optic fibers 46, 56, 66 could each have different configurations from the flat end surfaces shown in the drawings. For example, the distal end surfaces could have a cone shape, a bevel shape, a bullet shape, or any of various other shapes.
In use of the surgical instrument, the laser optic fiber proximal end 44 is connected to a source of laser light 50 and the first and second illumination optic fiber proximal ends 54, 64 are connected to separate sources of illumination light 58, 68. In alternate embodiments, for example where the surgical device is an aspiration tube, the proximal end of the aspiration tube would be connected to a source of aspiration. Where the surgical instrument is a bipolar cautery device, the proximal end of the cautery device would be connected with a power source for the device. Also, a single source of illumination light with two separate optic fiber connections could be used.
The tip 32 is then inserted through a cannula positioned in an incision in the eye, or is inserted directly through the incision. The tip is positioned in the eye with the tip distal end 38 positioned relative to the surgical site to provide the desired area of illumination from the illumination light transmitted from the first and second illumination optic fiber distal ends 56, 66.
With the desired area of the surgical site illuminated, the laser optic fiber distal end 46 is positioned at a desired position relative to the surgical site to begin the surgical procedure.
Thus, as discussed above, the surgical instrument of the present invention provides a source of laser light for performing surgery and a source of illumination where the illumination provided to the area of the surgical site is multiplied.
Although a specific embodiment of the invention has been described herein, it should be understood that other modifications and variations may be made to the invention without departing from the intended scope of protection provided by the following claims.
This patent application claims the benefit of provisional patent application No. 60/677,696, filed May 4, 2005.
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/US2006/016783 | 5/4/2006 | WO | 00 | 11/2/2007 |
| Number | Date | Country | |
|---|---|---|---|
| 60677696 | May 2005 | US |
