US 20060276778 A1
An array of light beams is swept along a main scan direction and dithered in a sub-scan direction to generate a treatment pattern of spots. The array is elongated along the sub-scan direction and the dithering has a travel that is significantly less than the length of the array in the sub-scan direction.
1. A light treatment apparatus for generating a pattern of spots over a treatment area of skin tissue, comprising:
an optical module that generates an array of light beams configured to beneficially coagulate skin tissue, wherein the array is elongated along a sub-scan direction that is transverse to a main scan direction;
a sub-scan module coupled to the optical module that dithers the array of light beams in the sub-scan direction; wherein, for a sweep of the array along the main scan direction, a travel of the array in the sub-scan direction is not more than the length of the array in the sub-scan direction;
a handpiece configured to manually scan the array of light beams along the main scan direction across the treatment area of skin tissue; and
a controller that adjusts a location and/or an exposure of the light beams to generate a pattern of treatment energy.
2. The apparatus of
a plurality of light sources; and
optics coupled to the light sources for generating the array of light beams from the plurality of light sources.
3. The apparatus of
an optical input port for receiving one or more input light beams from an external source; and
optics coupled to the optical input port for generating the array of light beams from the received input light beams.
4. The apparatus of
5. The apparatus of
6. The apparatus of
a light deflecting module configured to deflect one or more of the light beams.
7. The apparatus of
8. The apparatus of
9. The apparatus of
10. The apparatus of
11. The apparatus of
12. The apparatus of
13. The apparatus of
14. The apparatus of
a main scan sensor for sensing the sweeping of the array of light beams along the main scan direction, wherein the controller is coupled to the sub-scan module and the main scan sensor and controls dithering of the array in response to sweeping of the array.
15. A method for generating a pattern of spots over a treatment area, comprising:
generating an array of light beams, wherein the array is elongated along a sub-scan direction;
directing a handpiece toward a region of dermal tissue; and
manually sweeping the handpiece across the region of skin tissue to scan the array of light beams along a main scan direction that is transverse to the sub-scan direction; and
for a sweep of the array along the main scan direction, automatically dithering the array in the sub-scan direction, wherein a travel of the array in the sub-scan direction is not more than a length of the array in the sub-scan direction and the sweeping along the main scan direction and the dithering in the sub-scan direction generate a pattern of treatment zones at the region of dermal tissue to cause a therapeutic change in the skin tissue.
16. The method of
generating all of the light beams simultaneously.
17. The method of
generating the light beams sequentially in time.
18. The method of
19. The method of
adjusting an exposure of the light beams in the array.
20. The method of
sensing sweeping of the array along the main scan direction; and
controlling dithering of the array in response to the sensed sweeping of the array along the main scan direction.
21. A light treatment apparatus for generating a pattern of spots over a treatment area of skin tissue, comprising:
optical means for generating an array of light beams configured to beneficially coagulate skin tissue, wherein the array is elongated along a sub-scan direction that is transverse to a main scan direction;
sub-scan means coupled to the optical means that dithers the array of light beams in the sub-scan direction; wherein, for a sweep of the array along the main scan direction, a travel of the array in the sub-scan direction is not more than the length of the array in the sub-scan direction;
handpiece means configured to manually scan the array of light beams along the main scan direction across the treatment area of skin tissue; and
controller means that adjusts a location and/or an exposure of the light beams to generate a pattern of treatment energy.
This application is a continuation of U.S. patent application Ser. No. 10/751,041, “Multi-Spot Laser Surgical Apparatus and Method,” filed Dec. 31, 2003. The subject matter of the foregoing is incorporated herein by reference in its entirety.
1. Field of the Invention
This invention relates generally to an array of light beams used to generate a pattern of spots, for example as can be employed in laser surgery and laser dermatology.
2. Description of the Related Art
In laser surgical applications, for example in laser dermatology, an optical system generates a light beam(s) of a desired size and energy and this light beam is used to treat a selected region of the patient's body (i.e., the treatment area). For example, in many dermatology applications, a hand piece is used to guide the laser beam to the treatment area. The hand piece is typically attached to one end of an articulated arm, which transmits the laser beam to the hand piece and also supports a wide range of motion for the hand piece.
A physician typically treats the treatment area by sweeping the laser hand piece back and forth over the treatment area. In many cases, the physician is guided by an aiming line, which may be generated by the hand piece. The sweeping may be either manual or automated. Automated sweeping can be achieved by mounting the laser or other light source on a movable carriage. Whatever the mechanism, as the laser beam is swept over the treatment area, the physician typically pulses the laser beam on and off, either manually or via automatic means, thereby regulating the exposure of the treatment area and creating a pattern of treatment spots over the treatment area.
Many laser technologies for dermatology use a single high power beam that is scanned across the treatment area to create a pattern of exposed areas or spots. In many cases, the spots overlap sufficiently that the entire treatment area is exposed. The treatment rates achievable by scanning a single beam in this manner can be sufficiently fast when a high power laser (typically >10 W) is used with a large diameter beam (typically 2-6 mm).
However, new treatments can use smaller spot sizes and more spots. For example, see co-pending U.S. patent applications Ser. No. 10/367,582, “Method and Apparatus for Treating Skin Using Patterns of Optical Energy,” filed on Feb. 14, 2003; and Ser. No. 60/486,304, “Method and Apparatus for Fractional Phototherapy of Skin,” filed Jul. 11, 2003; both of which are incorporated herein by reference. Traditional laser systems are not well suited for these applications because the laser beams generated by traditional systems typically are too large and too energetic. Traditional systems also are typically based on more expensive types of lasers and do not take advantage of lower power, cheaper semiconductor lasers. In addition, the single laser beam generated by traditional systems would have to be individually positioned to generate each of the spots in the overall pattern and, since there typically are a large number of spots in the pattern, the required scan time becomes unacceptably long.
Hence, there is a need for devices and methods that can generate a pattern of spots on a treatment area, preferably in an efficient manner.
The present invention overcomes the limitations of the prior art by providing a laser treatment apparatus in which an array of light beams is used to generate a treatment pattern of spots. In one approach, the array is swept along a main scan direction and dithered in a sub-scan direction to generate the pattern of spots. The array is elongated along the sub-scan direction and the dithering has a travel that is significantly less than the length of the array in the sub-scan direction.
The optical module that generates the array of light beams can take many different forms. For example, it can be based on a fiber coupled laser source diode, a laser source followed by beam splitting optics, a fiber laser source followed by a beam splitter, multiple light sources each of which generates one of the light beams in the array, or an external light source(s) for example coupled by an optical fiber. The light beams in the array can also be generated simultaneously, sequentially (e.g., by scanning a single light beam to multiple locations), or a combination of the two. The sub-scan module that dithers the array of light beams can also take many different forms. A movable carriage that can be translated in the sub-scan direction and a light deflecting module are two examples.
In one embodiment, multiple laser diodes are coupled into optical fibers. The terminating ends of the optical fibers are aligned into a 1×N array and imaged onto the treatment area to generate the spots. The total length of the array is approximately 1 cm. The array is dithered to form an irregular pattern of spots (e.g., see
Other aspects of the invention include methods and systems corresponding to the apparatus described above, and applications for the above. One example application is medical treatments that use smaller spot sizes (for example, spots with diameters of 0. 1 mm) and more spots (for example, spot densities of 2000 spots/cm2) than conventional laser treatments. For example, see co-pending U.S. patent applications Ser. No. 10/367,582, “Method and Apparatus for Treating Skin Using Patterns of Optical Energy,” filed on Feb. 14, 2003; and Ser. No. 60/486,304, “Method and Apparatus for Fractional Phototherapy of Skin,” filed Jul. 11, 2003.
These and other objects, features and advantages can be more readily understood from the following detailed description with reference to the accompanying drawings, wherein:
While this approach has many advantages compared to individually positioning a single laser beam to generate each of the spots in the pattern, one disadvantage of this approach is the travel 190 of the array 150 in the raster scan direction 120 can be long in certain applications. If the raster scan is accomplished by mechanically translating the light source, then the long travel increases the mechanical wear and tear and reduces the life of the system. The long travel can also make the hand piece bulky and reduce the speed or resolution of the overall scan. The raster scan pattern also leaves a tapered gap 170 at the start and end of the overall pattern. This type of raster scan also creates a regular pattern of spots. Artifacts of the regular pattern can be visible even when the individual spots are not, and this can be cosmetically undesirable.
One advantage of irregular patterns is that, compared to regular patterns, they are less likely to result in visible artifacts. In addition, an irregular pattern increases the distance between adjacent spot arrays. For example, the spots in arrays 331 and 332 are further separated than the spots in arrays 231 and 232. This increases the time between the generation of spots that are close to each other (e.g., arrays 331 and 333), thus allowing more cooling between exposures. Irregular patterns can also result in more uniform two-dimensional coverage. In
As another example, the array of light beams can take different shapes. The examples in
As used in this application, the term spot is meant to refer to a treatment location within a treatment area, for example a region on the patient's skin in a dermatological application, to which a light beam is directed in order to treat that location. The exposure of the light beam on the location typically can be varied in duration and/or intensity and the resulting exposure creates the spot within the treatment area. After a spot is created, the light beam typically is moved to a different location to create another spot. In this way, successive movement of the light beams over many locations results in treatment of the treatment area. The end result is a two-dimensional pattern of spots or, in some cases, a three-dimensional pattern depending on how deep the optical energy penetrates.
The apparatus operates as follows. The optical module 410 generates the array of light beams that is used to form the pattern of spots. The sub-scan module 420 is coupled to the optical module 410 and dithers the array of light beams in the sub-scan direction, as described above. The main scan module 430 is also coupled to the optical module 410 and sweeps the array of light beams along the main scan direction. If the apparatus does not do the sweeping (e.g., if the physician manually sweeps the array), then there is no need for a main scan module 430. The main scan sensor 440, if present, senses motion of the array of light beams along the main scan direction and this information can be used different purposes, as described below. The input/output 450 is conventional. Examples include a touch screen, keypad, liquid crystal display, electrical connector, wireless connection, etc.
Referring to each of the components in more detail, the optical module 410, which generates the array of light beams, can be implemented in a number of different ways. If the optical module 410 includes an optical source 415, then the array of light beams can be generated from the output of the optical source 415. Alternately, the optical module 410 may not have its own optical source 415. Rather, the optical module 410 could include an optical input port (e.g., an optical fiber) that receives an input light beam(s) from an external source. Optics within the optical module 410 then generate the outgoing array of light beams from the input light beam(s).
In addition, the light beams in the array can be generated simultaneously. For example, a single light beam can be optically split into multiple beams, all of which are simultaneously on or off. Examples of optical splitters include fiber optic splitters, integrated waveguide splitters, gratings, diffractive elements, multi-faceted optical components (i.e., with different regions, each of which is illuminated and directs a portion of the light beam to a different location) and free space beamsplitters.
Alternately, the light beams can be generated sequentially in time. For example, a light deflecting module can deflect a light beam to the first position in the array, then to the second position, then to the third, etc. Examples of light deflectors include scan mirrors (i.e., galvanometers), acousto-optic devices, and rotating optical elements (e.g., with facets that are sequentially illuminated as each facet rotates through the optical beam). The two approaches can also be combined. For example, three light beams may be sequentially deflected to each of four different positions to create an array with twelve light beams.
The array of light beams can also be generated from multiple sources. Each source can be used to generate one of the light beams in the array. For example, an array of laser diodes can be imaged onto the treatment area to form the array of light beams. In fact, multiple sources can even be combined to form each of the light beams in the array. In one approach, different sources are coupled into the optical module 410 by fiber bundles, with at least three fibers of uniform size in a bundle. Each fiber bundle generates one of the light beams in the array.
The wavelengths of the light beams depend in part upon the application (e.g., the type of dermatological condition to be treated). Lasers having different wavelengths are used in surgical applications such as dermatology. Examples of laser light sources include diode lasers, diode-pumped solid state lasers, Er:YAG lasers, Nd:YAG lasers, argon-ion lasers, He—Ne lasers, carbon dioxide lasers, excimer lasers, erbium fiber lasers, and ruby lasers. These devices generate laser beams having the wavelength in the visible range of the spectrum (0.4-0.7 μm) as well as in infrared (0.7-11 μm) and UV (0.18-0.40 μm) ranges. It should be noted that terms such as “optical” and “light” are meant to include all of these wavelength regions and not just the visible range of the spectrum. Candela Laser Corp. of Wayland, Mass., Coherent, Inc. of Santa Clara, Calif. and other manufacturers market these types of lasers.
The optical source could include one particular type of laser light source capable of providing one wavelength or a wavelength range. Alternatively, the optical source could include two or more different types of laser light sources to provide a variety of different wavelengths or wavelength ranges. Light beams from different laser light sources can be directed to the treatment area either simultaneously or sequentially. For example, see co-pending U.S. patent application Ser. No. 10/017,287, “Multiple Laser Treatment,” filed on Dec. 12, 2001 and incorporated by reference herein.
For certain embodiments, the optical source is desirably a diode laser, such as an infrared diode laser. For other embodiments, the optical source is desirably a fiber laser, such as an erbium fiber laser manufactured by IPG Photonics of Oxford, Mass. However, while lasers are the preferred embodiment of the optical source described here, other optical sources such as a flashlamp can also be used.
Referring now to the sub-scan module 420, the optical module 410 generates the array of light beams and the sub-scan module 420 dithers the array in the sub-scan direction. These two modules are shown as separate in
The sub-scan module 420 can be implemented in a number of different ways. Conventional techniques for dithering a light beam or an array of light beams can be used. For example, the optical source generating the array or other components within the optical train can be physically moved, for example by mounting the components on a slide or a movable carriage. Alternately, the light beams can be dithered by optically deflecting the beams. Scan mirrors (i.e., galvanometers), acousto-optic devices, and rotating optical elements are some examples.
The optional main scan module 430 sweeps the array of light beams along the main scan direction. The underlying function (steering light beams) is similar to that of the sub-scan module 420, although the total travel and desired speed may be significantly different. Thus, the same conventional approaches are also candidates for the main scan module, although the actual implementation may be significantly different due to the travel and speed considerations. For example, both sweeping and dithering may be implemented by physical translation. But the main scan module 430 may sweep across several inches or feet at a moderate speed; whereas the sub-scan module 420 dithers across a fraction of an inch at much higher speeds. Thus, the main scan module 430 may be implemented by a robotic arm that holds the hand piece of the apparatus; whereas the sub-scan module 420 may be implemented by a small carriage mounted on rails, located internal to the hand piece.
The main scan sensor 440 senses the sweeping motion and can be implemented in different ways. For example, the main scan sensor 440 can measure relative position or velocity, similar to the mechanisms used in certain types of computer mouse. Alternately, it can measure absolute position, using triangulation from known beacons, or GPS or similar systems.
The information gathered by the main scan sensor 440 can be used for different purposes. The information can be used as feedback to control automated sweeping by the main scan module 430, or can also be used to control or coordinate the dithering by the sub-scan module 420. For example, if the physician sweeps at an uneven speed, then the dithering speed can be automatically adjusted to match the physician's sweep speed. For example, see co-pending U.S. patent application Ser. No. 10/745,761, “Method And Apparatus For Monitoring and Controlling Laser-Induced Tissue Treatment,” filed on Dec. 23, 2003 and incorporated by reference herein.
The controller 490 may be used to control the placement, intensity, duration and other characteristics of the light beams in order to generate the spots on the treatment area. The controller 490 can be implemented in many different forms: for example, electromechanical systems, dedicated electronic circuitry, ASIC, microprocessor, programmable DSPs, software, or combinations of the above. The controller 490 communicates with the different components 410-450, as applicable. In general, a controller may respond to preprogramming or operator activation (e.g., via the input/output 450).
Control parameters can be used to specify the location of each spot in the pattern; the dither amounts and/or dither sequence for the array of light beams in the sub-scan direction; when to line feed in the main scan direction (i.e., reset to the beginning of the next sweep); the intensity of the light beams to be generated; the duration of the illumination; and/or when to turn on or off a particular light beam in the array (individual beams can be turned on and off independently in some embodiments). Thus, the control parameters can be used to specify the amount of exposure commensurate with a treatment goal. The control parameters can be hard wired. Alternately, an operator may program the control parameters, for example via the input/output 450. In an embodiment, these control parameters are stored in the memory.
For purposes of non-ablative coagulation of a dermal layer of the treatment area, a laser light source can provide an optical beam having a wavelength of approximately 1.5 μm and an optical fluence incident on the outer surface of the skin between approximately 0.1 Joules/cm2 and 100,000 Joules/cm2, such as between approximately 1 Joules/cm2 and 1000 Joules/cm2. For certain applications, the pulse duration of an optical beam can be approximately equal to or less than a thermal diffusion time constant, which is approximately proportional to the square of the diameter of the focal spot within the treatment area. Pulse durations that are longer than the thermal diffusion time constant can be less efficient and cause the spot to undesirably grow or shrink by thermal diffusion. It should be noted that the light beams might accomplish the goal of completely treating the treatment area in one pass or in multiple passes.
Additional optics 520 between the collimating and focusing elements 517 and 562 dither the location of the multiple light beams on the surface of the skin. In this implementation, optical elements 520 are rotated by motors in the hand piece. Each optical element is divided into different facets, each of which dithers the light beams by different amounts. When the elements are rotated, the array of light beams is sequentially dithered to the different locations, thus generating the pattern of spots. For example, see co-pending U.S. patent application Ser. No. 10/750,790, “High Speed, High Efficiency Optical Pattern Generator using Rotating Optical Elements,” filed on even date herewith and incorporated by reference herein.
The user can adjust the distance between adjacent spots in the treatment pattern according to the desired treatment level. In addition, selected spots within the pattern can be turned off if a larger range of treatment levels is desired. A velocity sensor in the tip of the hand piece measures the speed of the hand piece as it moves across the treatment area. If the user changes the velocity of the hand piece across the skin, the controller 590 adjusts the rate at which the apparatus generates spots.
Although specific embodiments of the invention have been described with reference to the drawings, it should be understood that the embodiments shown are by way of examples only and merely illustrative of but few of many possible specific embodiments, which represent application of the principles of the invention. For example, there is no need for a mechanical device or a carriage to sweep the laser beam over a treatment area in the main scan direction. This can be accomplished using a manual method, such as a hand piece that a physician or other operator moves over a treatment area. As another example, the transverse sub-scan direction can make angles other than 90 degrees with respect to the main scan direction. For example, for spots placed on a hexagonal grid pattern, the transverse sub-scan direction may be at 60 degrees to the main scan direction. Another common angle that can be used is 75 degrees. Various changes and modifications obvious to one skilled in the art to which the invention pertains are deemed to be within the spirit, scope and contemplation of the invention as further defined in the appended claims. Furthermore, no element, component or method step is intended to be dedicated to the public regardless of whether the element, component or method step is explicitly recited in the claims.