TITLE: METHOD AND APPARATUS FOR TREATING SKIN DISORDERS USING A NEAR BLACK BODY FLASHLAMP SOURCE
FIELD OF THE INNENTION The present invention is related to therapeutic applications for light energy, and in particular, to controlled, high-power flashlamps for delivery of near black body electromagnetic radiation. ///
RELATED INVENTIONS This Application is a Continuation-In-Part (CIP) of related pending U.S. Patent
Application Serial No. filed December 31, 2002 entitled Method and Apparatus for
Treating Skin Disorders Using a Near Black Body Flashlamp Source, which is incorporated herein by reference in its entirety, and claims any and all benefits to which it is entitled therefrom. ///
BACKGROUND OF THE INNENTION Approximately 3% of the United States population have been diagnosed with inflammatory skin disease such as psoriasis. There are two main treatment modalities. One is treatment with drugs and the other is treatment with light, typically UNA or UNB.
The problems with the drug treatments are the potential side effects. Steroids can cause thinning of the skin, bruising and stretch marks. Systemic drugs can cause high blood pressure, birth defects and damage kidneys.
The light based treatment is effective without the side effects but requires 15 to 30 treatments to be effective. These are typically done in a "tanning booth" device, which exposes healthy skin as well as affected skin to the treatment. Thus the dosage is limited to one to two MED's (minimal erythemal dose) to avoid sunburning and blistering of healthy skin. This requires the patient to return every few days, for a total of 15 to 30 treatments to reach a cumulative therapeutic dose.
A device is needed that will provide the benefits of the light treatments in a more efficient, manner. The proposed device will provide large amounts of energy directly to the affected site in a short amount of time. As affected skin tolerates doses at one sitting of three or more times the MED of healthy skin, this reduces the number of treatment sessions required to reach the therapeutic dose. This method also eliminates the need to expose healthy skin to the treatment.
Prior art systems using flashlamps have not been capable of significant light output in the UN or IR regions. The reason for this is in the design of the flashlamp and the power supply that drives the lamp. Conventional flashlamp systems are capable of producing therapeutic output primarily in the visible region (500 nm to 650 nm) and in the near IR ( 650 - 850 nm). In contrast, the present invention allows and uses therapeutic outputs in the UN as well as the mid IR ( 850 nm - 1300 nm).
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SUMMARY OF THE PRESENT INNENTION The present invention includes devices for the effective treatment of skin disorders such as psoriasis. The device will be capable of delivering single pulses or bursts containing several pulses. Each of these pulses may reach energies from between about 1 to about 50 J/pulse. This device will operate as a near black body radiator.
The device may have an energy output per pulse of between about 0.2 -10 J in the range of between about 320 nm to 400nm (UNA) and an energy output of between about 0.1-2 J in the range of between about 290nm-320nm (UNB).
In a preferred embodiment, there will be a delivery system consisting of a flashlamp, a reflector to direct the energy onto the treatment site and filters to control the output spectrum.
In another preferred embodiment, both the filters and flashlamp are water-cooled. Cooling the filters with flowing water allows higher energies to be delivered through the filters without damaging them.
In another embodiment, the flashlamp and filters will be cooled by flowing air.
The burst energy is adjustable by adding or dropping the number of pulses in the burst
(typically one to six). The total output energy is adjustable from between about 1 J to about 180 Joules.
By operating the flashlamp plasma, or discharge, at a very high temperature, it is possible to achieve near black body operation. This means that it is possible to operate the device so that the energy produced is enhanced in the desired portion of the spectrum.
It will be understood by those skilled in the art that the peak energy developed by other devices is centered in the visible portion of the spectrum. This means that when filters are employed to allow operation in UNA or UNB, they are actually filtering out most of the output energy. The present invention centers the peak energy at about 330nm. This allows more energy to be delivered in the desired wavelength range reducing the required number treatment sessions .
In another embodiment the present invention will provide a cooling spray to the treatment site to protect the skin and provide an analgesic effect. This spray can be carbon dioxide gas, cryogen, air/water or other cooling agents.
BRIEF DESCRIPTION OF THE DRAWINGS The invention is illustrated below and represented schematically in the following drawings:
FIGS. 1A-1C show the spectra of a xenon-filled flashlamp pulsed at various current densities reaching into the blackbody regime at which the apparatus of the present invention operates.
FIG. 2 shows three blackbody spectral distribution curves in the range of operation of the present invention, with the prefered wavelengths for the phototherapy treatment of psoriasis shaded. This is used in a discussion of selecting an optimum lamp operating point in a dermatological application.
FIG. 3 A illustrates the thoretical plot of transmittance of light through a typical 700- 900 nm filter such as used in the apparatus and method of the present invention.
FIG. 3B illustrates the thoretical plot of transmittance of light through a typical LP for R% 250 nm, T% 300-320 nm such as used in the apparatus and method of the present invention.
FIG. 4A is a representative isometric view of a preferred embodiment of the handpiece of the present invention for treating skin disorders according to the method of the present invention.
FIG. 4B is a representative view of the treatment window in the front end of the handpiece shown in FIG. 4A.
FIG. 5 A is a representative isometric view of another preferred embodiment of the handpiece of the present invention for treating* skin disorders according to the method of the present invention.
FIG. 5B is a representative view of the treatment window in the front end of the handpiece shown in FIG. 5A.
FIG. 6A is a representative isometric view of yet another preferred embodiment of the handpiece of the present invention for treating skin disorders according to the method of the present invention.
FIG. 6B is a representative view of the flashlamp portion of the handpiece shown in FIG. 6A.
FIG. 7A is a representative side view of a preferred embodiment of a non-contact treatment apparatus of the present invention for treating skin disorders according to the method of the present invention.
FIG. 7B is a representative side view of the treatment apparatus shown in FIG. 7A.
FIG. 8 A is a representative side section view of a preferred embodiment of a blackbody flashlamp with filter within a water filled flow tube of the present invention for treating skin disorders according to the method of the present invention.
FIG. 8B is a representative end section view of the flashlamp with filter within a water filled flow tube shown in FIG. 8 A.
FIG. 9 is a representative schematic view of a preferred embodiment of a blackbody treatment apparatus with cooling system and remote resource and/or controller communication system of the present invention for treating skin disorders according to the method of the present invention.
FIG. 10A is a representative electronic circuit diagram of a preferred embodiment of a blackbody treatment apparatus of the present invention for treating skin disorders according to the method of the present invention.
FIG. 10B is another representative electronic circuit diagram of a preferred embodiment of a blackbody treatment apparatus of the present invention for treating skin disorders according to the method of the present invention.
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DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT The description that follows is presented to enable one skilled in the art to make and use the present invention, and is provided in the context of a particular application and its requirements. Various modifications to the disclosed embodiments will be apparent to those skilled in the art, and the general principals discussed below may be applied to other embodiments and applications without departing from the scope and spirit of the invention. Therefore, the invention is not intended to be limited to the embodiments disclosed, but the invention is to be given the largest possible scope which is consistent with the principals and features described herein.
It will be understood that in the event parts of different embodiments have similar functions or uses, they may have been given similar or identical reference numerals and descriptions. It will be understood that such duplication of reference numerals is intended solely for efficiency and ease of understanding the present invention, and are not to be construed as limiting in any way, or as implying that the various embodiments themselves are identical.
DESCRIPTION OF NEAR BLACK BODY OPERATION
The present invention is assigned to the same assignee as the Bender patents (US No.6,117,335 and No. 6,200,466) disclosing a flashlamp system operating in the near black body regime to generate UN light for the purpose of decontaminating water. The relevant discussion of the physics of flashlamps contained therein is incorporated here by reference.
1) Flashlamp Spectra. A continuum mode of radiation is created by strongly ionizing the gas within the flashlamp. This continuum radiation approaches a high-emissivity blackbody radiation profile with increasing flashlamp power density. Illustrated in Figure 1 are spectra for a xenon-filled flashlamp at three different levels of power density (see ILC Technology, Inc., Technical Bulletin o. 2, Fig. NUT). Power density is defined as:
P0 = (EJtpA) (watt/cm2) (1)
where: E0 = lamp discharge energy (joules); tp = pulse duration FWHM (seconds); and As = lamp bore surface area (cm2).
Li Fig. 1C, at the lowest power density of about 4 kW/cm2, it is evident that the
emission contains sharp peaks ( line spectra) superposed on a low continuous background. Line spectra are the result of the electrons in the discharge current colliding with atoms or ions, causing within them internal transitions between bound energy levels. In relaxing from these excited states, the atoms or ions emit light energy at discrete wavelengths (bound-bound transitions), or line spectra. As the power density is increased in Fig. IB to 14 kW/cm2, the proportion of continuous background increases. The continous spectrum is generated by the deceleration of electrons in collisions with ions (Bremstrahlung) and by collisions that ionize (bound-free transitions), both of which occur more frequently at higher power densities. At the highest power density of about 70 kW/cm2 in Fig. 1A, the envelope of the continuum spectra approachs the reference curve, which is superposed to show the spectral distribution of an ideal black body radiator at 9500°K absolute temperature. The peak of the continuous spectrum also lies in the UN (at a wavelength less than 400 nm) and the continuous spectrum fully dominates the line spectra. These are the charactersitics of the "near black-body" state, where the photons, and charged and neutral particles of the discharge plasma near thermal equilibrium. The approach is gradual with increasing power density; there is no abrupt demarcation point.
However, conventional rules of thumb for operation of a flashlamp as a near black-body radiator are that the power density exceeds 25 kW/cm2, or that the plasma temperature reaches 9500 °K.
2) Flashlamp Lifetime
The flashlamp must be optimized to deliver the maximum amount of useful energy with good conversion efficiency while still maintainging a useful long lifetime. Driving the lamp harder, while producing more UN, shortens the lamp life considerably. This tradeoff must be balanced by careful consideration of pulse duration and energy input.
To maintain reasonable lamp life, the input energy to the flashlamp must be kept below 18% of the theoretical single-shot explosion energy limit. Various models are used to predict lamp life. For a lamp that is driven hard, the expected failure mode is the limit imposed by envelope material tensile stress, seal strength, and wall abalation and cracking. Then the following formulas show how the explosion energy is related to the lamp geometry, envelope material, input energy, and pulse duration (see ILC Tech. Bulletin 2).
From the dimensions and envelope material of the flashlamp, an explosion-energy constant (K_ is obtained: K. =f(d)ld (2) where: f(d) = silica power function based on material transparency, thermal conductivity, wall
thickness, and bore diameter, W sec1/2 cm"2, 1 = discharge length of the flashlamp, cm, d = bore diameter of the flashlamp, cm. The single-shot explosion energy Ex then is: Ex = K. (tp/2)ιa . (3)
The lamp lifetime LT, in number of shots, is approximated by:
LT = [EJEJ * (4) where the flashlamp input energy E0 is in Joules, and the constant b depends on bore diameter and wall thickness. For the small bore lamps of 6 mm diameter or less (appropriate for mounting in a handheld device for dermatologic treatments) the constants to be used in Eq. (4) are K_ = 24600, and J = 8.5. To be conservative in the case of a lamp used in a commercial product, the number of shots predicted by Eq. (4) is frequrently reduced by some safety factor such as 10"3.
3) Advantages of a Near Blackbody Source in the Treatment of Skin Disorders
An ideal black-body emitter of a given temperature emits more energy than any real source with the same surface temperature. A flashlamp driven to near-blackbody operation thus approaches theoretical limits, and is a high power emitter providing light energy over broad spectrum. This makes possible treatments with a single source for a wide range of skin disorders. In the phototherapy treatment of skin disease, various wavelength bands are used:
Skin Condition Wavelengths of Treatment psoriasis 297-320 nm vitiligo 297-320 nm acne 405-420 nm hair removal 640-1200 nm reduction of vascularization 640- 1200 nm roseacea 640-1200 nm
The continuous nature of near blackbody radiation allows any of these wavelengths to be made available by spectral filtering in the delivery system, to pass the desired wavelengths, and reject the unwanted bands. Additionally, the peak wavelength of the blackbody spectral distribution can be tuned (by the control of the ratio E0/tp As as in Fig. 1) to weight the spectrum of the lamp for more output in the desired bands to make the lamp more efficient for a given application. Finally, the established nature of the life limits in this mode of operation permits a rational tradeoff to be made between lamp emittance (also called radiant exitance), spectral distribution, and lifetime.
4) Adjusting the Near-Blackbody Spectrum
The wavelength of the peak of the blackbody spectral distribution shifts with the surface temperature T of the emitter according to Wein's Displacement Law:
= 2898 ^ (5)
where ^eak is in micrometers, and T is the absolute temperature, in Kelvins. Figure 2 shows this peak wavelength shift for three different blackbody temperatures in the range of operation of the device of the present invention. The wavelength of the peak of the curve moves from 366 nm for the lowest curve at temperature of 7911 °K, to 333 nm for the middle curve at 8703 °K, and to 300 nm for the upper one at 9660 °K.
For the change from the lowest to the highest temperature of Fig. 2, the maximum emittance per unit wavelength interval (relative intensity) rises by a factor of 2.7, in accordance with Plank's Radiation Formula (see Bender's patent, US 6,117,335, Eq. (2)). When this formula is integrated over all emitting wavelengths, the Stefan-Boltzmann Law results, which states that the total power emitted over all wavelengths, per cm2 of blackbody surface area, increases with the fourth power of the surface's absolute temperture:
P = si4. (6)
The proportionality constant is called Stefan's constant and is equal to:
= 5.67 l0-12 W cm2 (°K)-4.
The power emitted from the flashlamp can be estimated as the input energy E0 times the average radiation efficiency (0.85) to get the total radiation, divided by the average time over which this energy is delivered (the pulse length tp). Balancing this power against the that from the Stefan-Boltzmann law gives the equivalent blackbody temperature of the lamp, TBB, the temperature of a perfect blackbody emitting .over the same area as the lamp at the same total power:
A, sT
BB 4 = (Total Power) = (0.85 )fE/ or
The temperature given by Εq. (7) is an upper bound for the plasma temperature of the lamp, since to the degree that a portion of the output spectrum may still exist as line spectra, there is
less power to be dissipated as blackbody radiation and a slightly lower plasma temperature may result.
Eq.(7) shows directly why the lamp spectrum moves towards the continuous blackbody spectrum as the lamp power density E/tpAs of Eq. (1) and Fig. (1) is increased, to balance the increasing power density, the average energy (temperature) of the particles in the plasma must increase to radiate more, and the theπnal interactions swamp the competiting means of radiating.
In general, to achieve a higher plasma temperature to increase the energy radiated into a desired bandwidth, or to increase the overall output energy, the application of shorter pulses of electrical input energy will be useful. Flashlamps are often driven with pulse forming networks (PFN's) where the input energy is determined by the charge on the capacitance C, and the time to deliver charge to the lamp is determined by the inductance L. Varying L conveniently adjusts the power density delivered and thus the lamp's blackbody radiation characteristics.
The tradeoff is that the lamp life decreases with explosion energy Ex, which by Eq.(3) is also a function of the pulse length tp. Substituting Eq.(3) into Eq.(4) shows that the expected lifetime LT of the lamp scales proportionally to:
Y,Υ = constωιt (tpY25, (8)
a rapid decrease as the pulse length decreases.
5) Optimizing TBP for Dermatological Applications
In the Bender patents there is presented the logic for optimizing the operating point of the flashlamp for his application of water decontamination through control of the pulse length. In dermatological applications, the situation is analogous.
For purposes of concreteness or to be more definite, consider the most demanding dermatological application, that of the phototherapy treatment to clear psorisis, which requires application of ultraviolet light in the range of 297-320 nm. Actually, the most effective ultraviolet band is 293 nm to 309 nm band (see J. A. Parrish et. al., Journal of Investigative Dermatology, v. 76 (1981) pp. 359-362, "Action Spectrum for the Phototherapy of Psoriasis").
These wavelengths are the points on the action spectrum where the effectiveness in clearing placque drops to 10% of that at the 300 nm peak of the spectrum. These limits are shown
shaded in Fig. 2. However, wavelengths shorter than 297 nm lie within what is believed to be the photocarcinogenesis action spectrum for humans (though it was measured on hairless mice; see C. A. Cole, et. al., Photochemistry and Photobiology, v. 43 (1986) pp. 275-284, "An Action Spectrum for UN Photocarcinogenesis"). Thus the repeated exposure to significant energy at wavelengths shorter than this will eventually cause skin cancer. Psoriasis sufferers generally accept this small risk, where the spectra overlap, to be cleared of the effects of their disease.
Thus both applications have a short wavelength limit, below which the lamp output is not useful. In Bender's case, this was the transparency limit of the lamp envelope, about 185 nm. In the case of psoriasis treatment, the lower limit is the turn-on of the carcinogenesis spectrum at 297 nm. Bender's logic is to adjust the pulse length, to shift the peak wavelength of the blackbody spectral distribution just to the long- wavelength side of the useful short wavelength limit. He showed that in generating light in the useful band for the water decontamination application (which extended from 185 nm up to 400 nm) that the efficiency did not depend strongly on TBB as long as the blackbody peak wavelength, and the useful short wavelength limit were close. Essentially, driving the lamp harder at this point, to move the spectrum down to shorter wavelengths, generated more light that fell in wavelength below the short wavelength limit, with a severe penalty in lamp lifetime. Bender's logic determines an optimum operating point— position the blackbody spectral peak just to the right of the short wavelength limit at the first acceptable value for lamp lifetime. For the psoriasis application, the same logic gives the middle curve of Fig. (2).
Actually, in the psoriasis application the optimum blackbody peak moves further to the right when it is considered that it is often an advantage to use a greater number of lower energy shots, to give adequate resolution in doseage control by counting the number of shots. The lamp life considerations favor this approach.
For example, five shots to complete a dose gives a 20% doseage control with ± 1 shot added or dropped. This is about what is desired. Consider then the alternatives of the two operating points represented by the two lower curves of Fig. 2. From the Stefan-Boltzmann law (Eq. (6)), the power densities for the two lower curves are in the ratio of 1:1.46. Holding the input energy to the lamp constant, reaching these two operating points would then require pulse lengths in the ratio of 1 : 1/1.46. By the scaling law Eq.(8), the shorter pulse length would reduce the lamp lifetime by a factor of 1/5.06 = 0.2 = [1/1.46]425. The useful energy per shot with the shorter pulse length is only 46% larger, or the total dose with the lower curve can be reached in 7 shots, if it were reached in 5 shots with the middle curve as operating point. Using 46% more shots, with 5 times as many shots available from the lamp, is a better tradeoff if the resultant
treatment times are acceptable to the doctor and patient.
FIGS. 1A-1C show the spectra of a xenon bore flashlamp pulsed at various power densities reaching into the near blackbody regime at which the apparatus of the present invention operates.
APPARATUS AND METHOD OF USE
FIG. 4A is a representative isometric view of a preferred embodiment of the handpiece 400 of the present invention for treating skin disorders according to the method of the present invention. FIG. 4B is a representative view of the treatment window 402 in the front end 404 of the handpiece 400 shown in FIG. 4A. The handpiece 400 compirses an elongated handle portion 406 as well.
FIG. 5 A is a representative isometric view of another preferred embodiment of the handpiece 500 of the present invention for treating skin disorders according to the method of the present invention. FIG. 5B is a representative view of the treatment window 402 in the front end 504 of the handpiece 500 shown in FIG. 5 A. In this preferred embodiment, the handpiece 500 compirses a curved or bent, pistol-shaped, handle portion 506 as well.
The treatment window 402 is only about 3 cm x 4 cm, or about 12 cm2, it will be understood that the shape of the treatment window 402 can be rectangular or square, round or other operative or ornamental shape.
FIG. 6A is a representative isometric view of yet another preferred embodiment of the handpiece 600 of the present invention for treating skin disorders according to the method of the present invention. FIG. 6B is a representative view of the flashlamp portion 602 of the handpiece 600 shown in FIG. 6A. It will be understood from the foregoing that the embodiments shown in FIGS. 4A-5B as well as others may be constructed with as follows.
The handpiece 600 has a handle portion 606 which contains various connectors and other systems. A treatment window 604 at the front end 608 comprises a quartz glass window 610. The flashlamp 602 may be a gas discharge device filled with xenon or krypton gas. It may be linear, helical or U shaped. The flashlamp 602 will be capable of operation in a near black body mode. Energy emitted by the flashlamp 602 will be concentrated. The flashlamp 602 will be cooled by water in one embodiment and by airflow in another. Filters 612 may be used to control the energy spectrum, for example BG1 filter glass for UNB operation. Other filters 612
may be used to operate in different portions of the spectrum.
The housing 620 of the handpiece 600 also has a cooling fluid inlet 622 and chamber area 624 for circulation of cooling fluid, this chamber is defined, in a preferred embodiment, by an aluminum or other reflective surface 626. Optionally, a solenoid or other control valve means 630 allows cooling fluid or other coolant to flow to a teatment site 632 from the distal tip 636 of a delivery tube 634 or other directional focusing means as, when and how desired.
In one preferred embodiment of the present inventiion, the looped flashlamp 602 may be dual and wired in series. This allows greater lifetime for the lamp 602 while maintaining a compact source area. The looped design of the flashlamp 602 allows a much more compact reflector 626 design and simplifies the task of holing up, sealing and configuring electrical connections and circulating cooling water around the lamp 602.
FIG. 7A is a representative side view of a preferred embodiment of a non-contact treatment apparatus 700 of the present invention for treating skin disorders according to the method of the present invention. FIG. 7B is a representative side view of the treatment apparatus 700 shown in FIG. 7A.
FIG. 8 A is a representative side section view of a preferred embodiment of a blackbody flashlamp 702 with filter 712 within a water filled flow tube 740 of the present invention for treating skin disorders according to the method of the present invention. FIG. 8B is a representative end section view of the flashlamp 702 with filter 712 within a water filled flow tube 740 shown in FIG. 8A.
The delivery system 700 consists of a housing 708 that encloses an elliptical reflector 726, a flashlamp 702, flow tube 740, filters 712 and cooling fluid chamber 724 for the flashlamp 702 and filters 712. Another embodiment (as shown in FIG. 9) includes cooling system for the treatment site 632.
The housing 708 may have a handle portion (not shown) to facilitate the directed delivery of therapeutic light to the treatment site 632. In another embodiment, the housing 708 may be attached to a mechanical articulating arm (not shown) so that the operator doesn't need to support the entire weight of the delivery system 700 unassisted. Attached to the housing 708 will be an umbilical 750 or other means for communicating containing high voltage wires and cooling tubes (not shown). In another embodiment, the housing 708 may accommodate a means
of cooling the treatment site 632 with CO2 gas, cryogen air/water or other cooling agents. The reservoir 730 or other container holding the cooling agent may be mounted directly onto the housing 708 or it may be remote. In the remote configuration, the cooling agent may be delivered via a tube in the umbilical 750 or by another means. The cooling agent container 730 may be disposable or refillable. Adelivery tube 734 or other directional providing means
The elliptical reflector 726 will be designed to focus the maximum amount of energy onto the treatment site 632. The reflective surface 728 may be polished aluminum, gold, silver or other formed of other reflective materials. The surface 728 may also and optionally be protected or unprotected.
The flowtube 740 will enclose the flashlamp 702 and and filters 712. Water or other temperature regulating material will flow through the flowtube 740 to cool both the flashlamp 702 and the filters 712 while allowing the treatment energy to exit through the flowtube 740. The flowtube 740 may be made of titanium doped quartz or other material that is transparent at the treatment wavelengths. In another embodiment, the flowtube 740 may be coated with a reflective coating, which will act as a filter to control the operation of the device within the chosen portion of the spectrum.
The filters 712 may be absorbing filter glass to filter out unwanted wavelengths of energy. They may be arranged around the flashlamp 702 in such a manner that no unfiltered energy can escape. They may be arranged in such a manner that they will be cooled by the flashlamp 702 coolant. In another embodiment, the filters 712 may be cooled be flowing air.
The filters 712 may be titanium doped quartz or another glasslike substance coated with a reflective coating to remove unwanted wavelengths. The flow tube 740 may be coated in a similar manner so that it is used as the filter 712.
An optional or additional filter 712 may be placed between the flashlamp 702 and the treatment site 632 to filter out visible and infrared radiation. This filter 712 may be quartz or other material coated as a "hot mirror". In another embodiment, this coating may be applied to the flowtube 740. The filters 712 can be changed by snapping their holders on and off. An electrical connection 750 to the handpiece 700 may be used to allow the power supply console 752 to identify and calibrate the user display.
FIG. 3 A illustrates the theoretical plot of transmittance of light through a typical 700-
900 nm filter such as used in the apparatus and method of the present invention. FIG. 3B illustrates the thoretical plot of transmittance of light through a typical LP for R% 250 nm, T% 300-320 nm such as used in the apparatus and method of the present invention.
FIG. 9 is a representative schematic view of a preferred embodiment of a blackbody treatment apparatus 700 with cooling system 730 and remote resource and/or controller communication system 752 of the present invention for treating skin disorders according to the method of the present invention.
Cooling for the flashlamp 702 and filters 712 may be achieved by flowing water over them within the flowtube. The water will then be cooled by a water to air heat exchanger enclosed (not shown) with the power supply 752. In another embodiment, the flashlamp 702 and filters 712 will be cooled by airflow provided by a fan (not shown).
Cooling to the treatment site 632 may use CO2 gas, Cryogen, air/water or other cooling agents. These cooling agents may be delivered to the treatment site 632 by activating a solenoid 630 or other switch. The container 730 containing the cooling agent may be mounted on the delivery system 700. The container 730 may be disposable or refillable. In another embodiment, the container may also be remote (and therefore not shown) to the delivery system and delivered to the treatment site 632 via a tube 734 or other means. In the remote embodiment, the container (not shown) may be disposable or refillable.
Apertures at the tip 636 of the delivery tube 634 or 734 of varying sizes may be used to protect the healthy skin from exposure to the treatment energy while allowing the sufficient and adequate exposure to affected skin.
FIG. 10A is a representative electronic circuit diagram 1000 of a preferred embodiment of a blackbody treatment apparatus 1002 of the present invention for treating skin disorders according to the method of the present invention. FIG. 10B is another representative electronic circuit diagram 1000' of a preferred embodiment of a blackbody treatment apparatus 1002 of the present invention for treating°skin disorders according to the method of the present invention.
The circuit 1000 comprises a high voltage source power supply 1004 and a low voltage power supply (LNPS) 1005. A pulse forming network (PFΝ) 1010 regulates a water to air heat exchanger and a controller 1016. The PFΝ 1010 may be comprised of a single inductor 1012 and multiple storage capacitors 1014. With this configuration, bursts containing multiple pulses can
be produced by trigger or switch 1018. The burst width may be adjusted by varying the time between pulses and by adjusting the number of pulses per burst. The output energy can be adjusted by varying the high voltage.
The power supply 1020 may be microprocessor controlled 1016 and provide high voltage pulses to the flashlamp 702, cooling for the lamp 702 and filters 712 and control for treatment site 632 cooling. The power supply 1020 may contain safety monitoring and feedback devices (not shown). The temperature of the treatment site 632 may be monitored and data utilized therefrom in a selected control scheme or protocol. In a preferred embodiment of the system and method of the present invention 1000' as shown in FIG. 10B, the flashlamp 702 may be simmered 1250. In another, as shown in FIG. 10A, the circuit 1000 may be unsimmered.
Additional pulsed blackbody, deep-UV radiators and water purifications systems are described in U.S. Patents No. 6,117,335 and 6,200,466, both entitled DECONTAMINATION OF WATER BY PHOTOLYTIC OXIDATION/REDUCTION UTILIZING NEAR
BLACKBODY RADIATION, both of which are hereby expressly incorporated by reference in their entireties herein.
Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Although any methods and materials similar or equivalent to those described can be used in the practice or testing of the present invention, the preferred methods and materials are now described. All publications and patent documents referenced in this application are incorporated herein by reference.
While the principles of the invention have been made clear in illustrative embodiments, there will be immediately obvious to those skilled in the art many modifications of structure, arrangement, proportions, the elements, materials, and components used in the practice of the invention, and otherwise, which are particularly adapted to specific environments and operative requirements without departing from those principles. The appended claims are intended to cover and embrace any and all such modifications, with the limits only of the true purview, spirit and scope of the invention.
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