METHODS FOR LASER TREATMENT OF SOFT TISSUE Steve Murray, Scott Davenport, and Tony Coleman
CROSS-REFERENCE TO PRIOR APPLICATIONS This application derives priority benefit from U.S. Patent Application Number 09/737,721 entitled, "Methods for Laser Treatment of Soft Tissue," filed on December 15, 2000 and Provisional U.S. Patent also entitled, "Methods for Laser Treatment of Soft Tissue," filed October 24, 2001, which are both incorporated herein by reference.
BACKGROUND 1. Field of the Invention The present invention relates generally to laser treatment of soft tissue, and more particularly to laser treatment of the prostate.
2. Description of the Prior Art Human tissue can be categorized as either soft or hard. Hard tissues include bone, teeth, and urinary calculi, for example, and are characterized by low water content, little or no vascularization, and high vaporization temperatures. Removing hard tissue using
laser light requires extremely high peak powers that either vaporize the tissue or create a shock wave that fractures the tissue. In contrast, soft tissue is generally characterized as being malleable, usually has a high water content, and can be vaporized at a much lower temperature. There are a variety of medical conditions that require the surgical removal of soft tissue. Soft tissues include, for example, organs and tissues of the urinary tract, such as the urethra, prostate, bladder, uterus, and kidney. Organs and tissues of the reproductive system, gastrointestinal tract, such as the gal bladder, are other examples of soft tissue. Benign Prostatic Hyperplasia (BPH) is a condition wherein continued growth of the prostate restricts the passage of urine through the lower portion of the bladder and the urethra. BPH is often treated by surgically removing excess soft tissue (i.e., prostate tissue) from the transitional zone of the prostate that is pressing on the urethra, which usually relieves the bladder outlet obstruction and incomplete emptying of the bladder caused by the BPH. Recently, the most commonly employed procedure for removal of excess prostate tissue has been Transurethral
Resection of the Prostate, also known as TURP. In the TURP procedure, the surgeon utilizes a standard electrical cutting loop to shave off small pieces of the targeted tissue from the interior of the prostate. At the end of the operation, pieces of excised prostate tissue are flushed out of the bladder using an irrigant . While effective, the TURP procedure is known to cause numerous side effects, including incontinence, impotence, retrograde ejaculation, prolonged bleeding and TUR syndrome. Recently, alternative procedures have been developed which reduce or avoid the side effects associated with TURP. One class of procedures involves "cooking" prostate tissue by heating it to a temperature above 45 degrees Celsius. Typically this is accomplished using electrically resistive elements such as: radio frequency (RF) , microwave, or long-wavelength lasers. An example of a procedure of this nature is discussed in U.S. Pat. No. 6,064,914 by Trachtenberg ( "Thermotherapy Method"). Because these procedures leave the thermally-treated tissue in place, post-procedure edema, dysuria, and retention rates are relatively high. Further, use of thermal procedures requires the patient to be catheterized for several days following the procedure, and may cause
extensive and unpredictable scarring of the intra-prostatic urethra. Another class of procedures involves vaporizing or ablating the hyperplastic or cancerous tissue using laser light. These procedures generally avoid the high infection rates and scarring problems of thermally-based procedures. However, laser ablation of prostate tissue has, to date, required the use of an expensive laser capable of generating high-power laser light. The high cost of purchasing or leasing such a laser results in a concomitant increase in the cost of the procedure. Finally, the ablation process typically occurs slowly, resulting in a lengthy procedure time. The Ho:YAG laser and its fiberoptic delivery system is an example of a laser that is commonly used for ablating prostate tissue. In this application, the Ho:YAG laser generates light pulses with a wavelength of 2100 nm. The light pulses as that this wavelength are absorbed strongly by water in the prostate tissue and in the saline irrigant positioned between the distal end of the fiberoptic and the tissue. The absorption coefficient of water is so high at the 2100 nm wavelength that 50% of the light is absorbed within about 0.2 mm. Consequently even a thin layer of
irrigant positioned between the distal end on the fiberoptic and the tissue will absorb a large fraction of the laser light causing inefficient tissue removal. Because water is such a large constituent of both prostate tissue and blood, there is essentially no selective absorption by blood. The combination of superficial unselective light penetration of 2100 nm light in tissue leads to poor hemostasis (i.e. poor coagulation of the blood) . Nd:YAG lasers operating at 1064 nm have also been used for ablating prostate tissue. Although 1064 nm light is hemostatic at high power levels its low absorption in blood and prostate tissue leads to inefficient ablation and a large residual layer of thermally denatured tissue several millimeters thick. The Nd:YAG laser has a residual thermal damage zone that is typically 8-10 mm from the surface of the tissue. After surgery the thermally denatured tissue swells and leads to transient urinary retention, which in turn can cause long catheterization times, painful urination, and high infection rates. Frequency doubled or frequency converted Nd:YAG lasers operating at 532 nm in a Quasi continuous mode at power levels up to 60 watts have been used to efficiently and
hemostatically ablate prostate tissue. These lasers are pumped by CW krypton arc lamps and produce a constant train of Q-switched pulses at 25 kHz. The high Q-Switch frequency makes the tissue effects indistinguishable from CW lasers of the same average power. The 532 nm light emitted from these lasers is selectively absorbed by blood leading to good hemostasis. When ablative power densities are used, a superficial layer of denatured prostate tissue less than approximately 1 or 2 mm is left behind. This thin layer of denatured tissue is thin enough that the immediate post surgical swelling associated with other treatment modalities is greatly reduced. This reduced swelling leads to short catheterization times and less dysuria. At high powers, 532 nm lasers induce a superficial char layer that strongly absorbs the laser light and greatly improves the ablation efficiency. The problem with the existing 532 nm lasers used to date is that they are large, expensive, inefficient, and have a highly multi-mode output beam that makes them inefficient for ablating prostate tissue. High power densities are required for rapid and efficient vaporization of prostate tissue. In lasers, when the pump source has an emission spectrum that is different
from that of the lasing element (i.e., having a Stoke shift) the difference in energy, due to the difference in emission spectrums, is converted to heat energy, which induces thermal lensing in the lasing element. The difficulty of achieving higher average output power densities is that when high input powers are supplied to the laser element from an excitation source such as an arc lamp a large amount of heat is generated in the lasing element. This heat induces various deleterious effects in the lasing element. In particular, the temperature difference between the coolant and the relatively hot lasing element generates a thermally induced gradient index lens. This thermally induced lens decreases the beam quality of the laser and causes the laser to operate with more transverse optical modes than it would otherwise. See Walter Koechner, Solid- State Laser Engineering, Published by Springer-Verlag Berlin Hiedelberg, New York 1992, Pages 189-192, which is incorporated herein by reference, for a discussion of modes . The M2 parameter is a well established convention for defining the beam quality of a laser and is discussed in pages 480-482 of Orazio Svelto and David C. Hanna,
Principles of Lasers, Plenum Press, New York, 1998, which is incorporated herein by reference. The beam quality measures the degree to which the intensity distribution is Gaussian. The quantity M2 is sometimes called inverse beam quality rather than beam quality. As described herein, the quantity M2 is referred to as beam quality. Af2 is defined as
M ≡ { °P± = 4π(σxσf)NG I
where π refers to the number pie (i.e., 3.141...), σ is used to represent the spot size, the subscripts x and f represent spatial and frequency domains along the x-axis, respectively, and the subscripts G and NG signify Gaussian and non-Gaussian, respectively. The x-axis is defined as being transverse to the direction of propagation of the beam, such that the beam quality in any direction transverse to the beam (i.e., x- axis) is essentially the same. Therefore, the subscript x is dropped from the M2 elsewhere in the specification. The beam widths, or σs , are determined based upon the standard deviation of the position where the squared deviation of each position is weighted by the intensity at that point.
The beam width in the frequency domain, σt, is the beam width of the beam after being Fourier transformed. The formula usually used for calculating the angular divergence, θ, of a beam of light of wavelength, λ, is strictly only valid for a beam having a Gaussian intensity distribution. The concept of beam quality facilitates the derivation of the angular divergence for a beam with a non- Gaussian intensity distribution, according to
Θ = M πσ.
For example, a TEM00 laser beam has a high beam quality with an M2 of 1, whereas by comparison, high power surgical lasers operate with M2 values greater than 100. The inventors have recognized that high power lasers typically have an M2 > 144. By definition larger number of traverse modes means that the value of M2 is larger, and, consequently, with larger values of M2, it is more difficult to focus the light into small, low numerical aperture fibers. Thus, larger values of M2 reduces the ability to project high power density light onto tissue. As a result, the vaporization efficiency of CW arc lamp pumped 532 nm lasers on prostate tissue is significantly reduced.
SUMMARY According to an embodiment of the invention, soft tissue is treated with laser light from a laser that does not have a lot of modes. In particular, for example, the number of traverse standing electro-magnetic waves is kept to a minimum. The number of modes needs to be kept small enough so that the beam density is high enough to efficiently ablate the soft tissue with a low power beam. The invention may include treating soft tissue with a low Stoke shift pump radiation laser, i.e. a laser having a pump radiation source that does not produce enough heat in the lasing element to create a significant amount of thermal lensing in the lasing element, such as in a solid state laser. According to one embodiment of the invention, a method for treating BPH comprises the steps of providing a solid- state laser having a laser element positioned to receive pump radiation from an excitation source; in some cases modulating the source to cause the laser to emit pulsed laser light; and delivering the laser light to targeted tissue. Various solid-state lasers may be used for this purpose, including (without limitation) , a Q-switched arc
lamp-pumped or a flashlamp-pumped laser using a frequency doubling crystal such as potassium-titanyl-phoεphate (KTP) . The pulse duration of the laser light is preferably in the approximate range of 0.1 to 500 milliseconds or preferably about 1 to 100 milliseconds .The wavelength of the laser light is preferably in the ranges of approximately: between 200 and 1000 nanometers or 300 to 700 nanometers; 480 to 550 nanometers; 500 to 550 nanometers; 1100 to 1800 nanometers; 1300 to 1400 or 1440 nanometers; or 1,320 nanometers or 1500 nanometers. Moreover, the wavelength of the laser light is preferably approximately 532 nanometers. Any of these exemplary ranges of wavelengths can be used with any embodiment of the invention. The laser light is preferably delivered to the targeted prostate tissue through an optical fiber terminating at a distal end in a side-firing probe. However the side-firing probe is not essential to practice the present invention. Optionally, the approximate repetition rates of 1 to 500 Hz, 10 to 100 HZ, or 10 to 120 Hz, for example, can be used with any embodiment of the invention. Operation of the solid-state laser in a "macropulsed" mode is more efficient in inducing rapid tissue ablation than a CW laser of the same average power. This is in part
because the macropulsing is more efficient in inducing "char" formation, a mild carbonization in which the tissue typically darkens slightly but does not necessarily turn completely black. Although char formation is not essential to efficient rapid ablation it is helpful because the darkened tissue is better at absorbing light. The macropulsed laser is also more efficient and has higher beam quality, with M2 values typically less than 144, for example, than a continuous wave laser with same average output power . According to a second embodiment of the invention, a method for treating soft tissue comprises the steps of providing a solid-state laser having a laser element positioned to receive pump radiation from a pump radiation source; modulating the pump radiation source to cause the laser element to emit laser light having a pulse duration of between approximately 0.1 milliseconds and 500 milliseconds or 1.0 to 100 milliseconds and an output power exceeding 20 watts; and delivering the laser light to targeted tissue. According to a third embodiment of the invention, a method for treating BPH comprises the steps of providing a solid-state laser having a laser element positioned to
receive pump radiation from a pump radiation source; Q- switching the laser to generate a quasi-continuous wave (CW) beam having an output power exceeding 60 watts; and, delivering the beam to targeted prostate tissue. According to a fourth embodiment of the invention, a method for treating BPH comprises the steps of providing a solid-state laser having a laser element positioned to receive pump radiation from a pump radiation source such as a laser diode; Q-switching the laser to generate a quasi- continuous wave (CW) beam having an output power exceeding 20 watts with an M2 less than 144; and delivering the beam to prostate tissue.
BRIEF DESCRIPTION OF THE FIGURES FIG. 1 depicts a laser system for implementing the tissue ablation methods of the invention; FIG. 2 depicts a side-firing probe for use with the system of FIG. 1; FIG. 3 depicts an exemplary output waveform of the FIG. 1 laser when the laser is operated in a macropulsed mode; and FIG. 4 depicts an exemplary output waveform of the FIG. 1 laser when the laser is operated in a quasi-CW mode,
DETAILED DESCRIPTION OF EMBODIMENTS OF THE INVENTION FIG. 1 is a block diagram depicting an exemplary laser system 100 which may be employed for implementing the present invention. Laser system 100 includes a solid-state laser 102, which is used to generate laser light for delivery through optical fiber 106 to target tissue 104. As will be discussed in further detail herein below, laser 102 is capable of being operated in a "macropulsed" mode, wherein the laser light is emitted as macropulses having relatively long pulse durations . Laser 102 more specifically comprises a laser element assembly 110, pump source 112, and frequency doubling or frequency converting crystal 122. In the preferred embodiment, laser element 110 outputs 1064 nm light, which passes through a frequency doubling crystal 122 to create 532 nm light. According to one implementation, laser element assembly 110 may be a neodymium doped YAG (Nd:YAG) crystal, which emits light having a wavelength of 1064 nm (infrared light) when excited by pump source 112. Laser element 110 may alternatively be fabricated from any suitable material wherein transition and lanthanide metal ions, such as Yb3+, Nd3+, Ho3+, Pr3+, Er3+, and the like, are disposed within a crystalline host. Examples of a
crystalline host include YAG, Lithium Yttrium Fluoride, Sapphire, Alexandrite, Spinel, Yttrium Orthoaluminate, Potassium Gadolinium Tungstate, Yttrium Orthovandate, or Lanthanum Scandium Borate . Laser element 110 is positioned proximal to pump source 112 and may be arranged in parallel relation therewith, although other geometries and configurations may be employed. Pump source 112 may be any device or apparatus operable to excite laser element assembly 110. Non- limiting examples of devices that may be used as pump source 112, include: arc lamps, flashlamps, and laser diodes . A Q-switch 114 disposed within laser 102 may be operated in a repetitive mode to cause a train of micropulses to be generated by laser 102. Typically the micropulses are less than 1 microsecond in duration separated by about 40 microseconds, creating a quasi- continuous wave train. Q-switch 114 is preferably of the acousto-optic type, but may alternatively comprise a mechanical device such as a rotating prism or aperture, an electro-optical device, or a saturable absorber. Laser 102 is provided with a control system 116 for controlling and operating laser 102. Control system 116
will typically include a control processor which receives input from user controls. User control may include, but is not limited to, a beam on/off control, a beam power control, and a pulse duration control) and processes the input to accordingly generate output signals for adjusting characteristics of the output beam to match the user inputted values or conditions. With respect to pulse duration adjustment, control system 116 applies an output signal to a power supply (not shown) driving pump source 112 which modulates the energy supplied thereto, in turn controlling the pulse duration of the output beam. Control system 116 may be programmable and may store a program for operating the laser according to one or more methods or the invention. Although FIG. 1 shows an internal frequency doubled laser, it is only by way of example. The infrared light can be internally or externally frequency doubled using non-linear crystals such as KTP, Lithium Triborate (LBO) , or Beta Barium Borate (BBO) to produce 532 nm light. The frequency doubled, shorter wavelength light is better absorbed by the hemoglobin and char tissue, and promotes more efficient tissue ablation. Finally, the green light
leaves only a thin char layer with little pre and post- operative bleeding. In the preferred embodiment the resonant cavity control system is that described in U.S. Patent Number 5,151,909, incorporated herein by reference. In an embodiment the wavelength of the laser used for ablation has a high enough absorption in tissue such that the residual thermal damage zone is not significant (i.e., does not cause significant post operative swelling, dysuria or long catheterization) . For example, the thermal damage zone could be less than 3-4 mm and large enough to be hemostatic. In an embodiment the wavelength of light used is chosen so that the cooling fluid, such as water, does not absorb the light as strongly as the targeted tissue. Laser 102 further includes an output port couplable to optical fiber 106. Output port 118 directs the light generated by laser 102 into optical fiber 106 for delivery to tissue 104. Mirrors 124, 126, 128, and 130 direct light from the lasing element 110 to the frequency doubling crystal 122, in addition to forming the resonant cavity of the laser. Mirrors 124, 126, 128, and 130 are configured for focusing the light to form an image just in front of
the frequency doubling crystal 122 on the side closer to mirror 130, and to compensate for thermal lensing in the lasing element. Although mirrors 124, 126, 128, and 130 are illustrated as flat and parallel to the walls of the laser, typically the focusing is achieved by curving and/or angling the mirrors. Alternatively, transmissive optical elements could be used to focus the light and compensate for the thermal imaging. Mirrors 124, 128 and 130 reflect both the wavelength of light produced by the lasing element (e.g., 1064 nm) and the wavelength of the frequency doubled light (e.g., 532 nm) . Mirror 126 only reflects the light originating from the lasing element 110 (e.g.. 1064 nm) but is transparent to the frequency converted light (e.g., 532 nm) , forming an output window. While a bare fiber may be utilized for certain procedures, optical fiber 106 preferably terminates in a tip 140 having optical elements for shaping and/or orienting the beam emitted by optical fiber 106 so as to optimize the tissue ablation process. FIG. 2 depicts a side-firing probe tip 200, which may be used as tip 140 (FIG. 1) . The tip 140 is treated to deflect light sideways. Some examples of methods for deflecting the light sideways are to include a light
scattering material in the tip 140 and/or to place a ■ reflective element in the tip 140. The reflective element could be angled at 45°, for example, to deflect the light at 90° with respect to the axis of the fiber 106. Side-firing probe tip 200 includes an optically transparent sleeve 202 having a transparent window 204 (which may be constructed as a cutout in the wall of sleeve 202 through which the beam is emitted in a direction transverse to the optical axis of fiber 106) . An acceptable range of angles in which to deflect the light beam is between about 40 to 120 degrees with respect to the axis of the fiber. The preferred embodiments use an angle of either 70 or 100 degrees. The angle of 80° is preferred from the standpoint of the ease in manufacturing the tip 200 and the angle of 90° is preferred from the standpoint of the ease in aiming the side firing light. In a typical mode of operation, optical fiber 106 is held within an endoscope such as a cystoscope or similar instrument that allows the clinician to precisely position the distal end of the optical fiber adjacent to the targeted tissue. The endoscope also has channels for supplying and removing an irrigant solution to and from the tissue. In addition, light and image guides are also
included for illuminating and imaging the tissue so that the clinician may direct the laser light and enhances the progress and efficacy of the ablation procedure. FIG. 3 illustrates an exemplary output waveform applied to tissue 104 when laser 102 is operated in the macropulsed mode. Each macropulse 302 is defined by a train of Q-switched micropulses 304. While a relatively small number of micropulses 302 are depicted for purposes of clarity, an actual macropulse may comprise hundreds or thousands of component micropulses 304. In the preferred embodiment, there are between 2 and 12,200 micropulses per macropulse. An arc lamp, for example, when used as the pump source 112, is kept at a low power level between pulses that are preferably just enough to maintain the arc. These low pump powers are below the lasing threshold of the laser; as a consequence, there is no laser output between macropulses. As mentioned above, the pulse duration or width D (FIG. 3) of the output beam is governed by the modulation of pump source 112, and more specifically by the period during which the pump source 112 is maintained in an "on" or high-power condition. In other words, the longer the pump source 112 is maintained in an on condition, the
longer the pulse width. Typically, laser 102 will be capable of delivering pulses 302 having pulse durations D in the range of 1 to 20 milliseconds (2 to 490 micropulses) or 1 to 50 or 100 milliseconds (2 to 1,220 or 2,440 micropulses) and average output powers preferably exceeding 60 watts and preferably up to 100 watts, and possibly up to 200 or 300 watts. The ratio of D to the period of the macropulses defines the duty cycle, which is typically between 10 and 50%. In accordance with one embodiment of the invention, a laser system 100 of the foregoing description is employed to treat BPH by ablating targeted prostate tissue 104. The clinician may utilize an endoscope or similar instrument to guide the distal end and tip 140 of optical fiber 106 into alignment with the targeted prostate tissue 104. Laser system 100 is then operated in the macropulsed mode so that laser 102 generates laser light having the pulsed waveform depicted in FIG. 3 and delivers it through optical fiber 106 to tissue 104. It is known that irradiation of prostate tissue 104 may initially cause tissue heating resulting in the formation of a char layer. This char layer is highly optically absorptive in the wavelengths emitted by laser
102, which thereby facilitates efficient absorption of the laser light and resultant ablation of tissue 104. However, the formation of the char layer is not essential for efficient ablation. Prior art techniques for treatment of BPH by laser ablation (such as the technique described by Kuntzman et al. in "High-Power (60-Watt) Potassium-Titanyl- Phosphate Laser Vaporization Prostatectomy in Living Canines and in Human and Canine Cadavers," Urology, Vol. 49, No.5 (1997)) utilized a quasi-CW laser to irradiate the prostate. Although such lasers do produce moderately high average powers, they have a large number of transverse modes and, as such, produce highly divergent light when focused into small optical fibers. This leads to less than optimal power densities when the laser light is directed at the tissue. As a consequence, these lasers are not particularly efficient at inducing formation of a char layer, and ablation rates are relatively slow, significantly lengthening procedure times. Further, since formation of the char layer takes place at relatively low rates, undesirable thermal damage to deeper tissue layers may occur. In contrast, it has been found that a macropulsed beam, such as that generated by laser 102, promotes rapid
formation of a char layer even at moderate output energy levels, thereby helping to accelerate ablation rates and reducing procedure time. The macropulsing can also increase efficiency because the threshold electrical power required for lasing while macropulsing (the operating threshold) is lower than the initial threshold voltage for lasing (the cold threshold) . Macropulsing is also more efficient for frequency conversion by means of second harmonic conversion to frequency doubled light increases as the square of the infrared light intensity. The higher peak powers of the macropulsed infrared light leads to higher second harmonic conversion efficiency. For example, at any given time, the input power and output power of a frequency-doubled laser using KTP are related according to Po=A(Pi)2' Where A is an experimentally determined positive constant less than Po . This equation relates the peak input power to the peak output power. However, the average input power and output power for a duty cycle of k percent are given by <Pi>=k(Pi) and <Po>=k(Po)= kA(Pi)2= A(<Pi>)2/k,
where the brackets "< >" indicate an average value of the enclosed quantity. Thus, decreasing the duty cycle from 100% to 50% (i.e. reducing k from 1 to 0.5) while simultaneously doubling the peak input power Pi results in no change to the average input power <Pi> and a doubling of the average output power <Po>. Pulse modulating or macropulsing using Q-switching, for example, enables reaching higher average output powers with less thermal lensing due to the lower input power. Additionally, it is possible that the frequency doubling crystal has nonlinearly increasing output power as a function of the input power. In other words the second derivative of the output power with respect to the input power may be positive, in which case the rate of increase of the output power increases with increasing input power. Specifically, in such a case the functional dependence of the instantaneous or peak output power, Po, on the instantaneous or peak input power, Pi, is such that d2(Po)/d(Pi)2 > 0. When this is true and Po is an increasing function of Pi, the higher peak input powers result in a more efficient laser because the ratio of the output to input power increases .
By way of a non-limiting example, prostate tissue 104 may be efficiently and rapidly ablated when laser 102 is operated at an output power of 100 watts, a pulse duration of 1-50 milliseconds, and a wavelength of 532 nanometers. In accordance with a second method embodiment of the invention, laser system 100 may be utilized to ablate other types of tissue 104. Treatment of tissue 104 is performed in a manner substantially identical to the technique for treating BPH disclosed above. The clinician may utilize an endoscope or similar instrument to guide the distal end and tip 140 of optical fiber 106 into alignment with the tissue 104. Laser system 100 is then operated in the macropulsed mode so that laser light having the pulsed waveform depicted in FIG. 3 is generated by laser 102 and delivered through optical fiber 106 to tissue 104. To achieve adequate results, laser system 100 is adjusted to emit a beam having a pulse duration between 0.1 and 500 milliseconds or preferably between 1 and 100 milliseconds, and an output power of at least 20 watts. Upon ablating the required volume of tissue 104, (which may be assessed via an imaging channel contained in the endoscope) , the output beam of laser 102 is turned off.
In a third method embodiment of the invention, treatment of BPH is effected by operating laser 102 in a quasi-CW mode at an output power greater than 60 watts. The increased denaturization of the tissue is dramatic with increases in power, suggesting a threshold effect. As depicted in FIG. 4, laser 102 generates a continuous train of Q-switched micropulses 400 when operated in quasi-CW mode. The laser light is then delivered via optical fiber 106 to targeted tissue 104. Operation in a quasi-CW mode at powers above 60 watts facilitates formation of char and consequent rapid ablation rates, whereas operation in a quasi-CW mode at powers below 60 watts forms char layer more slowly and causes more thermal damage to underling tissue. A fourth embodiment of this invention is to produce a high power, high beam quality laser that can project high power density laser light onto tissue. To do this the number of transverse optical modes supported by the resonator needs to be kept as low as possible. Small M2 and high average powers can be achieved by reducing the degree of thermal lensing in the laser element. Using laser diodes as the excitation source is one effective way of greatly reducing both the size of the
lasing element and the thermal gradient responsible for creating the thermal lens. The reason for this is that while 2-10% of the light produced from a flashlamp or arc lamp is converted into useful laser light 30-60% of the light emitted from laser diodes can be converted laser light. Because the energy that is not converted to laser light is converted into heat, laser diodes deposit significantly less heat in the lasing element and, as a consequence, create a less powerful thermal lens. In this manner laser diodes can be used to pump crystalline laser elements or fiber lasers to produce high beam quality lasers. Slab and waveguide lasers that can be pumped by laser diodes, arc lamps, or flashlamps are another method of creating low M2, lasers . This is because the thermal gradient produced in slab lasers is linear across the thin dimension of the slab and not radially dependent as in a typical cylindrical lasing element. The linear thermal gradient does not produce a thermal lens resulting in low AT2 values . For example, as a result of the low M2 some embodiments of this invention are capable of producing laser light that upon exiting a flat end of a fiber having a diameter of 600 μm has a divergence of 15.3° or lower; 15° or lower; 10° or
lower; or 5° or lower, and the power density can be 13,400 watts per centimeter or greater. The advantages of using high average power laser light with this invention to ablate soft tissue include the ability to deliver laser light endoscopically through a small flexible fiber optic element, rapid tissue ablation and excellent hemostasis. When high power laser light is used in this invention the tissue may be irrigated and delivery devices with water or other fluid may be used during the laser exposure. Some organs and tissues that are suitable for laser ablation using the present methods include those that have lumens that are externally accessible by a body orifice and can be irrigated. In the urinary tract tissue such as the urethra, prostate, bladder, uterus, and kidney are particularly well suited for treatment using the present methods. Most of the female reproductive system is well suited for high average power laser treatment according to the present invention including the removal of myomas, leimyomas or uterine fibroids. Similarly, most of the gastrointestinal tract can be easily accessed and treated. Soft tissue that cannot be reached from a body orifice can be reached percutaineously by making a small incision through which
surgical instruments can be inserted. Laparoscopic access through the navel is one way of removing gal bladders and myomas that are outside of the uterus . An advantage of using a laser with a low M2 is the power density is higher as a result of the smaller spot size than were Λf2 high. In an embodiment the power density is kept above 1000 watts per square centimeter, above 4,000 watts per square centimeter, above 5,000 watts per square centimeter, or above 22,000 watts per square centimeter. Any of the powers, power ranges, wavelengths, wavelength ranges, pulse durations, pulse duration ranges, frequencies, frequency ranges, M2 ranges, and power density ranges listed in this specification can be used in any of the embodiments of the invention. Any place where the specification mentions frequency doubling other frequency conversions can also be used. While the invention has been particularly shown and described with reference to preferred embodiments thereof, it will be understood by those skilled in the art, that various changes in form and details may be made therein without departing from the spirit and scope of the invention, as defined by the appended claims.