[0001] This invention relates to medical lasers, and more particularly to a surgical laser
device dermatological surgery.
[0002] A variety of lasers have been used in modern dermatology for correction of inborn
and acquired skin defects and diseases. One of the reasons for wide proliferation
of the lasers in this field is that their properties support the medical postulate
- "do not harm" a patient.
[0003] Drug therapy has been the most commonly used method of treatment in dermatology mainly
because it is readily available, simple and less painful. However, drug intolerance,
side effects, common allergic reactions as well as low efficiency in treatment of
a substantial number of disorders often make this treatment less desirable.
[0004] A need for more efficient cure of dermatological defects and diseases made surgical
involvement quite popular in this area of medicine. As to the surgical methods of
treatment of skin disorders, doctors are often compelled to resort to such procedures
as: dissection followed by transplantation, use of ultrasound and cryotherapy, application
of magnetic fields of ionizing radiation, electroco-agulation, utilizing of plasma
currents, etc. These surgical methods are used in spite of a great number of drawbacks
and harmful side effects which include: destructive nature of the treatment, protractive
healing process, high risk of hypopigmentation, possibility of atrophy, destruction
of a skin texture, formation of scars, damage to an adjacent skin area including healthy
regions. These problems are often alleviated when a surgeon uses local methods of
treatment having short and fixed duration of action at a specified depth of a skin
integument. This is one of the reasons why lasers have become recently the instrument
of choice for many dermatologists.
[0005] Currently, lasers having different wavelength of laser irradiation are used in dermatology.
Examples of such lasers are: excimer, ruby, argon laser; alexandrite and garnet laser;
tunable semiconductor laser; etc. These devices generate laser beams having the wavelength
in the visible range of the spectrum (0.4-0.7 µm) as well as in the invisible, the
UV range (0.18-0.40 µm). For instance, infrared lasers include a set of CO
2 lasers (with the wavelength of 10.6 µm), variations of neodymium lasers (with the
wavelength of 1.06 µm), etc. These lasers are produced by Candela Laser Corporation
and are described by " Lasers in Medicine" Tashkent, 1989.
[0006] In spite of the fact that these lasers maintain a short duration of action and provide
certain localization in the plane of the action, they do no not guarantee control
of the treatment, especially as to the depth of penetration in the skin integument.
Thus, use of these lasers does not eliminate such negative consequences as formation
of hypotrophic scars and penetration of a laser beam into the area of healthy skin.
[0007] It is a matter of general knowledge that a layer of water practically does not allow
optical irradiation at certain wavelength to pass therethrough. This region of the
spectrum is typically known as the "window of non-transparency" and includes the following
wavelength ranges: 1.25-1.40; 1.7-2.1; 2.5-3.1 and 5.5-7.5 microns. At these ranges
optical irradiation is strongly absorbed by water and by living tissue which also
consists of up to 90 percent of water. Such absorption leads to a rapid heating of
water and vaporization of the treated living tissue. At these wavelengths a laser
beam acquires an important quality, that is that laser irradiation can not penetrate
deeply in to living tissue substantially consisting of water. As a result, a scattered
laser beam propagates in living tissue only within the range which does not exceed
the depth of 15-20 microns and does not destroy adjacent tissue. Such a mode of operation
of a laser can be implemented only at specific levels of power density and energy,
predetermined rate and duration of the pulse and only when a temporary stability of
all these characteristics is achieved during a surgical procedure.
[0008] One of such known devices is the aluminum-yttrium-erbium garnet laser having the
wavelength of 2.94 µm of laser irradiation. Initial reports about stomatological application
of this laser appeared in 1989. However, its properties such as energy pulse of 1-2
J; the wavelength of 2.94 µm and the pulse rate of 1 Hz enabled doctors to use this
laser as surgical device in the field of dermatology. The first reports of such use
became known in Germany and Slovenia in 1991.
[0009] A schematic diagram of FIG.1 illustrates that such a device consists of a power unit,
a cooling unit, a laser cavity and an articulated mirror light-guide unit. In view
of the multiple reflections of the laser beam in the articulated mirror light-guide
, the efficiency of the device is quite low and does not exceed 60 percents at the
wavelength of 2.94 µm. This makes it necessary to sustain energy input of the laser
irradiation at the level 2.5-3.0 J and the operating power of the power unit at 300
W. Naturally, a laser of such high power has to have a very efficient cooling system.
Therefore, a special water cooling system was provided in this prior art device. In
view of that, the weight of the device was 70 kgs with overall dimensions of 0.5 m
3. Thus, large weight and dimensions as well as instability of the laser beam characteristics
greatly limited employment of this prior art laser in dermatology.
[0010] The water cooling system was necessary in the high powered prior art device to keep
the temperature of the active element within 20±10°C range. When this temperature
range was exceeded the thermolens effect developed in the active element which resulted
in considerable laser beam scattering and in the loss of energy in the focal plane
of a treated tissue.
[0011] One way of resolving these problems is through the formation of a more efficient
laser system which lacks the articulated mirror light guide and requires substantially
less power. This makes it possible the replacement of the water cooling system by
its air cooling counterpart. Such changes ultimately led to a substantial reduction
of the weight and overall dimensions of the laser assembly.
[0012] Thus, there has been a considerable need for an efficient hand held laser surgical
device usable in the field of dermatology which is capable of providing and controlling
a predetermined depth of skin penetration and does not damage healthy regions of tissue
adjacent the operation site.
[0013] This object is attained by a laser device in accordance with the technical teachings
of the accompanying claims.
[0014] As claimed, a laser device for conducting dermatological surgery comprises a housing
having interior and exterior regions.
[0015] A laser cavity is provided within said interior region of the housing, said laser
cavity containing at least a part of an operating laser element generating an operating
beam.
[0016] An exciting arrangement for exciting of said laser element is provided.
[0017] A cooling arrangement forming a stream of gaseous coolant being directed along said
laser cavity and said laser element is situated within said stream of gaseous coolant.
Said housing forms a part of a handpiece adapted for convenient positioning in a hand
of an operator and at least a portion of said cooling arrangement is situated within
an interior portion of said handpiece.
[0018] According to the invention the laser device further comprises a focusing lens arranged
in the operating beam and adapted to be moved in a direction substantially perpendicular
to the operating beam. The focusing lens is adapted to be rotated about the axis of
the operating laser beam, whereby the axis of the focusing lens is shifted by a predetermined
distance from the axis of the operating laser beam, so as to produce a complex image
pattern of the operating beam can be replaced in dependency upon the type of operation.
[0019] Another aspect of the invention provides a device in which at least a portion of
the operating laser assembly is positioned within the housing and the cooling unit
is a fan producing an air flow extending longitudinally within the interior portion
of the handpiece.
[0020] Still another aspect of the invention provides the device in which the exciting arrangement
is positioned outside the handpiece and is connected to the operating laser assembly
by a plurality of optical fibers.
[0021] Still further aspect of the invention provides a device with the operating laser
element consisting of working and auxiliary portions. The working portion is situated
in the handpiece, whereas the auxiliary portion and the exciting arrangement are situated
outside the handpiece. The main and auxiliary portions of the operating laser element
are connected through a light guide consisting of a plurality of optical fibers.
[0022] Yet another aspect of the invention provides the device in which the wavelength of
the operating beam emitted by the operating laser element is selected from the group
consisting of 1.25-1.40, 1.7-2.1; 2.5-3.1 and 5.5-7.5 microns. The laser medium of
the operating laser element is selected from the group consisting essentially Y
3AL
3O
12: Nd; Gd
3Ga
5O
12 : Cr, Ce, Nd; MgF
2 : Co; BaYb
2 F
8 : Er ; LiYF
4 : Er : Tm, Ho; Y
3Sc
2Al
3O
12: Cr, Er; (Y, Er)
3Al
5O
12 ; HF (chemical) and CO (gaseous).
[0023] The device can be used in a method of surgical vaporization of a living tissue. The
method comprises the steps of generating an operating laser beam having a predetermined
wavelength corresponding to a peak absorption wavelength of water and detecting a
condition of operating living tissue by receiving and reviewing a radiation signal
reflected from the tissue and producing a control signal. A further step of the method
is controlling and adjusting characteristics of the operating beam based on the control
signal, so that the depth of the vaporization of the living tissue does not exceed
15-20 microns.
[0024] Other advantages and features of the invention are described with reference to exemplary
embodiments, which are intended to explain and not to limit the invention, and are
illustrated in the drawings in which:
FIG.1 shows a prior art laser device;
FIG.2 shows one embodiment of a laser surgical device of the invention;
FIG. 3 shows another embodiment of the laser surgical device;
FIG. 4 shows a portion of a further embodiment of the laser surgical device;
FIG. 5 shows a simplified embodiment of a laser surgical device not within the claimed
invention;
FIG. 6 shows another simplified embodiment of a laser surgical device not within the
claimed invention;
FIG. 7 illustrates alternative positions of a lens of focusing arrangement not within
the claimed invention;
FIG. 8 shows a laser surgical device having substantially cylindrical focusing lens
not within the claimed invention;
FIG. 9 shows a laser surgical device with the focusing lens movable about shifted
axis not within the claimed invention;
FIG. 10 shows application of an accessory lens to the laser surgical device;
FIGS. 11 and 12 illustrate different patterns of laser beam images;
FIGS. 13 and 14 illustrate further patterns of laser beam images;
FIG. 15 illustrates conditions of beam scanning at a preset program; and
FIG. 16 illustrates conditions of beam scanning when the laser beam is in the slot
form.
[0025] Although specific embodiments of the invention will now be 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. 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.
[0026] It was indicated hereinabove that the optical irradiation in the wavelength region
corresponding to the "window of non-transparency" is very efficiently absorbed by
water and living tissue. The operating beam of the laser surgical device of the present
invention efficiently performs within such entire wavelength region. As a result of
application of the laser beam to the targeted area of a patient, a local vaporization
of the top skin layer occurs at the maximum depth of 10-20 microns. The diameter of
the irradiated spot on the skin is about 10 mm and the density is in the range of
5-50 J/cm
2.
[0027] Referring now to the drawings, in which there is shown in FIG. 2 an apparatus 10
for performing of a laser surgery. The apparatus 10 consists of the following main
units: a compact surgical laser instrument or a handpiece 12, a power supply unit
14 producing high-voltage potential pulses with tunable parameters, a suction unit
or suction apparatus 16 for suction of disintegrated skin products resulted from application
of an operating laser beam to a targeted area and a control unit 18. The handpiece
formed with a housing 20 is adopted to be conveniently held in the hands of an operator.
It is best illustrated in FIG.2 that a laser cavity 22 is provided within the interior
area of the housing 20. An operating laser assembly 24 is situated within the laser
cavity and consists of an active laser element or rod 26, an exciting arrangement
28 and an optical resonator 30. The exciting arrangement which is adopted for exciting
of the operating laser element can be any conventional exciting device such as, for
example, a flash lamp or a diode laser.
[0028] The optical resonator 30 includes a mirror 32 having high reflective capabilities
and positioned rearwardly of the laser element and a semi-reflective operating mirror
34 situated forwardly of the laser element so as to face a variable focusing lens
36. The mirrors of the optical resonator are disposed in the coaxial manner to a longitudinal
axis A-A of the laser rod 26 and operating laser beam. The focusing lens 36 which
is at least partially positioned within the housing 20 is typically operated by a
micromotor on command from the control unit 18. A desired position of the focusing
lens 36 can be also arranged manually by a medical personnel before or during a surgery.
The optical resonator 30 is adopted to align and amplify the laser beam, whereas the
focusing lens 36 directs it to the targeted area. In order to facilitate efficient
delivery of the light energy from the exciting arrangement 28 to the operating laser
element 26, the interior of the laser cavity can be covered by a material of high
reflectivity.
[0029] A cooling arrangement 38 is provided within the housing 20 rearwardly of the laser
cavity 22. The cooling arrangement can be of any known type producing an axial stream
of gaseous coolant. In the preferred embodiment of the invention the cooling arrangement
is a fan 38 which generates an axially directed air stream B extending longitudinally
in the interior of the housing 20. In order to increase efficiency of the cooling
process the exterior of the laser cavity 22 is formed with a plurality of ribs 40
extending outwardly therefrom. Thus, upon activation of the fan, axially directed
air stream B is blown over the exterior of the laser cavity 22, including the ribs
40 reducing their temperature. The air stream B during its travel within the handpiece
is directed through openings in the housing (not shown) to the exterior parts of the
focusing lens 36, so as to prevent pollution or the lens by disintegrated skin products
resulted from the surgery. Upon reaching the operated area of the skin , the air stream
B also facilitates removal of the disintegrated tissue products from the site of the
surgery and reduces effect of an unpleasant odor on a medical personnel.
[0030] Longitudinal distribution of the elements of the invention within the housing 20
helps to reduce the dimensions and facilitates efficient delivery of the air coolant
and reduction of temperature of the laser cavity and throughout the interior area
of the handpiece. Furthermore, use of air cooling system results in better stability
of temperature and other characteristics of the laser cavity, especially during and
after multiple thermocycling.
[0031] The surgical apparatus 10 is energized through a source of standard electrical supply
42 or through a set of batteries 44. In order to eliminate any potential shock hazard
specially upon switching the power from the source of standard electrical supply to
the battery unit, a power interlock switch can be provided.
[0032] The power supply unit 14 generates electrical voltage pulses which are converted
by the exciting arrangement or the flash lamp 28 into light pulses. In the laser cavity
22, after being directed to the laser rod 26, such light pulses are converted into
laser pulses having shorter duration of emission compared to the voltage pulses. The
wavelength of the laser irradiation is determined by the type of the laser rod or
active element utilized by the surgical apparatus. In the preferred embodiment of
the invention Er:YAG (erbium) laser is used as the active element or laser rod 26
of the surgical apparatus. The laser rod made of this material emits the electromagnetic
energy corresponding to the wavelength of the " window of non-transparency" of water.
The wavelength of this laser is 2.94 µm and is very close to the maximum absorption
wavelength of water, which is about 3 µm. Thus, at this wavelength of the operating
laser beam a great portion of its energy is absorbed by the operated living tissue
which consists up to 90 percent of water.
[0033] The essential requirement for the materials used in the active element of the operating
laser is that the wavelength of their irradiation belongs to the " window of non-transparency"
region of the spectrum. Therefore, the laser medium of the active element of the invention
can be selected from, but is not limited to, the following group of materials which
forms a part of this category: Y
3AL
5O
12: Nd (wavelength 1.33 µm) ; Gd
3Ga
5O
12: Cr, Ce, Nd (wavelength 1.42 µm); MgF
2 : Co (wavelength 1.75 µm); BaYb
2F
8: Er (wavelength 2.0 µm); LiYF
4 : Er, Tm, Ho (wavelength 2.06 µm); Y
3Sc
2Al
3O
12: Cr, Er (wavelength 2.8 µm); (Y,Er)
3Al
5O
12 (wavelength 2.94 µm); HF- chemical (wavelength 2.6-3.0 µm) and CO-gaseous (wavelength
5.0-6.0 µm).
[0034] This wavelength of the operating laser beam belongs to the infrared region of the
spectrum and is invisible to the naked eyes of a surgical operator. In view of that,
an operator can not observe the emission of the operating laser beam from the forefront
of the handpiece. This might cause erroneous surgical steps raising serious questions
of security in the medical treatment. To eliminate this drawback, in the invention
a guide light unit 46 generating a continuous, visible guide light beam is provided.
Such guide light unit can be He:Ne laser, semiconductor laser, light-emitting diodes
or any other suitable source of visible radiation. In the embodiment of the invention
illustrated in FIG.2 such guide light unit 46 is a semiconductor laser providing a
very low power, continuous laser beam. Unlike the Er:YAG laser, the semiconductor
laser emits the beam in the visible region of the spectrum. The guide light beam is
adopted to indicate the focal point of the operating laser beam as a visible light
spot before the operating laser beam is applied. That is the operating beam is applied
to the same area as the guide light beam spot. Therefore, an operator can start the
operating laser after the guide light beam spot appears at the desired location. Thus,
the continuous guide light laser beam serves aiming function simplifying targeting
of the invisible pulse operating beam. In use, upon activation of the operating laser
as well as the guide lasers, the continuous and the pulse beams are delivered to the
targeted area. The operating laser can be easily focused at the targeted area based
on the image of the guide light laser there. The disintegrated skin products accumulated
at the site of the surgery are ultimately removed and disposed by the suction unit
16.
[0035] In the embodiments of FIGS. 2 and 3 the suction unit is designed as a device independent
from the handpiece and energized by the power supply unit 14 of the surgical device.
Nevertheless, forming the suction unit as a part of the handpiece is also contemplated.
[0036] In the alternative embodiment the cooling arrangement can be positioned outside the
handpiece. For instance, it can be associated with the power unit in such manner that
a stream of cooling air is delivered to the interior of the handpiece through a flexible
piping or similar arrangement.
[0037] In operation of the FIG. 2 embodiment, to excite the operating laser, high voltage
is developed in the power supply unit 14 and applied across the flash lamp 28. In
the laser cavity 22 the delivery of the light energy from the flash lamp is facilitated
by the highly reflective interior surface thereof. The energy from the flash lamp
28 is absorbed by the medium of the laser rod 26, so that the molecules in the laser
medium are transferred from the ground state to the excited state. As those molecules
return to their ground state, they emit photons of a particular wavelength. Part of
the light emanates from the laser rod. The light is returned to the rod by the mirrors
32 and 34. The returned photons react with molecules of the laser medium in the excited
state to cause those molecules to return to the ground state and themselves emit photons
of the particular frequency. Thus, the emitted photons are in phase with the photons
striking the molecules and directed in the same direction as the original photons.
In the operating laser the photons traveling between the mirrors 32 and 34 follow
a specific paths, so that the photons resonate in particular modes at common frequency
and phase. Eventually, the light between the mirrors 32 and 34 reaches such level
of intensity that its substantial amount passes through the semi-reflective mirror
34 and is directed by the focusing lens 36 to the targeted area of the skin of a patient
as an operating beam.
[0038] FIG. 3 illustrates the embodiment of the invention in which the laser surgical device
is formed with two working cavities. An auxiliary cavity 17 is associated with the
power supply unit 14. This cavity contains the exciting arrangement such as a flash
lamp 28 and is connected through an activated fiber optic arrangement 19 to a main
laser cavity 15. Similar to the embodiment of the FIG. 2, the main laser cavity 15
contains the active element or laser rod 26 and the optical resonator 30 having two
mirrors 32 and 34. In operation, high voltage developed in the power supply unit 14
is applied to the exciting arrangement 28 of the auxiliary cavity 17 generating impulses
of light energy. These impulses are delivered to the active element 26 situated in
the main cavity 15 by means of the activated fiber optic arrangement 19.
[0039] In the embodiment of FIG. 3 the high voltage pulses energizing the flash lamp 28
are not transmitted directly to the handpiece. Instead, such high voltage pulses are
delivered to the auxiliary cavity 17 situated remotely from the handpiece and an operator.
This provides even higher degree of safety for the surgical device of the invention
since chances of electrical shock hazards to the medical personal are effectively
minimized.
[0040] Furthermore, since the exciting arrangement or the flash lamp 28 is positioned outside
of the main cavity, the weight of the handpiece is greatly reduced simplifying manipulations
of the device by a surgeon.
[0041] It is best illustrated in FIGS. 2 and 3 that during a surgery the condition of operated
tissue is monitored by a detecting arrangement or detector 48 adopted to detect irradiation
reflected from that tissue. One of the main functions of the detector 48 is to control
the effect of the operating laser beam on the skin of a patient in general and specifically
to control the depth of penetration of the operating laser beam and the depth of vaporization
of the epidermis. In every individual case a doctor sets specific characteristics
of the laser irradiation to produce the required effect. If a predetermined depth
of penetration of the operating laser beam and/or the thickness of the vaporized layer
of a skin are achieved, the detector 48 generates a signal directed to the control
unit 18 which in turn produces a correcting signal to the power unit or other units
of the surgical device. Similar signals can be also produced when the prearranged
levels of the energy density, power density or other characteristics of the operating
laser are attained. This is necessary to exclude possibility of deeper penetration
of the operating laser beam and/or damaging an adjacent healthy skin tissue. The intensity
of the reflected light radiation from the skin of a patient depends upon such factors
as: type and stage of a disease, color of a skin, general condition of a patient,
the depth of a treated skin layer, etc. For each individual patient, considering the
initial level of optical irradiation, such value of intensity characterizes a condition
of an area of the skin treated by the laser surgical device of the invention. The
detecting arrangement 48 can be made utilizing a wide variety of photosensitive elements,
photoresistors, photodiodes and similar devices. If a photosensitive element is used
to form the detector 48, the light reflected from the targeted area of the skin produces
a flow of electrons in the photosensitive element directed towards its cathode and
generates an electrical current or control signal for forwarding to the control unit
18. When photoresistors are utilized, the electrical resistance of the detector 48
varies depending upon the level of intensity of the light reflected from the operated
tissue and received by the detector 48. The signal to the control unit 18 is based
on such resistance.
[0042] FIG. 4 schematically illustrates a part of the laser assembly of another embodiment
of the invention in which only portions of the active element and optical resonator
are positioned in the main working cavity 21 situated in the handpiece. To accommodate
such arrangement an auxiliary cavity 23 is provided. The exciting arrangement 28 and
a first or auxiliary part 25 of the active element are situated within the auxiliary
laser cavity 23. A distal end 29 of the first part 25 of the active element faces
the mirror 32 having high reflectivity , whereas a proximal end thereof 31 is positioned
at an end 37 of the light guide 41. To facilitate efficient delivery of the light
energy from the exciting arrangement 28 to the first portion 25 of the active element
the interior of the auxiliary cavity can be formed from a material having high reflective
properties. A second or working part 27 of the active element and a semi-reflective
mirror 34 of the optical resonator are situated in the main working cavity 21. The
distal end 33 of the second part 27 of the active element and the proximal end 31
of the first part thereof are optically connected through a fiber light guide 41.
Both ends of the light guide situated in the vicinity of the active element can be
manufactured as parts of the optical resonator. In this respect, the end 37 of the
light guide positioned in the auxiliary cavity 23 can be formed as a mirror having
characteristics facilitating passage of the laser irradiation from the first part
25 towards the second part 33 of the active element. To facilitate the required operating
laser beam operation from the main cavity 21, the end 39 of the light guide situated
thereinside can be formed as a mirror enabling passage of irradiation only in the
direction of the second part 27 of the active element. As in the previously discussed
embodiment of FIG.3, an operator is provided with an instrument devoid of electrical
shock hazard and having considerably reduced weight. This is an important advantage
of the present invention especially during prolonged surgical operations.
[0043] A simplified embodiment of a laser surgical device not within the present invention
is best illustrated in FIGS. 5 and 6. It is shown in FIG.5 that a handpiece 112 which
resembles a housing of a hair drier contains an operating pulse laser 122, a cooling
fan 138 and a light guide arrangement 146. In order to provide an axial air flow directed
toward a patient, the fan 138 is positioned rearwardly of the operating laser. Two
light-emitting diodes 145 and 147 of the light guide arrangement 146 are installed
within the housing between the operatng laser and the focusing lens 136. The light-emitting
diodes are arranged in such a manner that the distance between the images of their
light guide beams 121 and 123 in the focal plane of the focusing lens 136 is substantially
equal to the diameter of the spot of the operating beam 127 of the operating Laser
122 in this plane. Therefore, the targeted area of the operating beam spot can be
identified by watching the visible images of the light guide beams. The dimensions
of this operating beam spot can be adjusted by changing the distance between such
visible images. The power supply unit 114 energizes not only the laser, fan and light
guide arrangement but also the suction unit 116 positioned outside the housing. For
the safety reasons all power feeding cables can be jacketed by earthen metal hoses.
The pulse rate and the pulse energy of the operating laser 122 are set manually by
generating a command from the control panel of the power supply unit 114. Similar
to previously described embodiments, the suction unit 116 provides removal of the
fragments of the disintegrated particles of skin developed during the surgery. The
focusing lens 136 can be made of a quarts glass.
[0044] The laser surgical device of FIG. 6 is similar to that of FIG. 5. However, in FIG.
6 the exciting arrangement 135 is positioned outside the handpiece 112 and the impulses
of light energy are delivered to the operating laser 122 by means of a light guide
137. In this respect, the instrument of FIG. 6 operates in a manner similar to the
embodiment of FIG. 3. The modified embodiment of FIG. 6 in which a portion of the
active laser element or rod is situated outside of the handpiece (see FIG. 4) is also
contemplated.
[0045] In the embodiments illustrated in FIGS. 5 and 6 the focusing lens 136 is moved manually
a predetermined distance. During such movement the position of images generated by
the light-emitting diodes 145 and 147, which determine the size of the operating laser
spot in the focal plane, is automatically changed.
[0046] If the motion of the lens 136 is provided in the direction substantially perpendicular
to the operating beam axis A-A, a series of laser beam images may be obtained in the
focal plane. For example, FIG. 11 illustrates this condition for the normal and FIG.
12 for cylindrical lenses.
[0047] Upon motion of the focusing lens in the direction perpendicular to the axis of the
beam it is possible to obtain a more complex image pattern, ie. circular (see FIG.
13), spiral patterns (see FIG. 14).
[0048] Depending upon the type of operation, replacement of the focusing lens is possible
in the present invention. Typically the most suitable lens is one having an optical
element smoothly traveling along the axis of the operating laser beam, so that the
optical element, can be fixed at a prearranged intermediate position. In this respect,
FIG. 7
corresponding to an embodiment not within the present invention, illustrates the focusing lens 137 having three such intermediate positions.
[0049] The size of the operating laser spot in the focusing region can be regulated by a
microdevice upon a signal from the control unit 18 (see FIG.2). This can be also accomplished
manually by an operator or according to a prearranged program. Thus, the size of the
operating laser spot of the operating laser beam can be adjusted in the focal plane
of the focusing lens up to the sizes at which irregularities of the laser spot are
still acceptable.
[0050] The focusing lens shown in FIG. 8
which corresponds to an embodiment not within the present invention, produces the operating beam in the form of an oblong strip. This is achieved by using
a semicylindrical lens 237.
[0051] The required changes in the form of this strip can be provided by rotating and guiding
the lens 237 in a predetermined fashion.
[0052] The embodiment of the focusing lens 236 illustrated in FIG.9
according to the claimed invention enables to produce a trace of movement of the focused operating laser beam in the
form of a ring. This is achieved by rotating the focusing lens 236 about its axis
B-B which is shifted a predetermined distance C from the axis A-A of the operating
laser beam.
[0053] As to the embodiment of FIG. 10, it illustrates a supplemental focusing lens for
the precise focusing of the operating laser beam on the targeted area. For this purpose
it is advisable initially to fixedly attach the laser assembly 222 with the lenses
236, 239 and the mirrors 245, 247 at the prearranged condition. The visible guide
light should be prealigned with the invisible operating laser beam. In this case it
desirable to keep stationary at least a part of the patients body which is the subject
of a surgery. A special device can be provided to accomplish this task.
[0054] The surgical device of the invention utilizes laser irradiation within the entire
spectrum of the wavelength corresponding to the "window of non-transparency" of water.
At the density of the laser irradiation of the operating beam spot 5-10 J/cm2 and
the diameter of the operating laser beam spot 3-10 mm, the depth of penetration of
the operating laser beam of the invention into the epidermis does not exceed 10-20
microns. This occurs upon application of impulses having a very short duration of
about 0.001 sec. After dehydration of the tissue, the spot of the operating laser
beam produces only local vaporization of the top layer of the skin of a patient. This
occurs without damaging in depth as well as superficially healthy regions of epidermis
surrounding the operated area. The treated area of the tissue can be increased by
moving the spot of the operating laser beam over the surface of the skin. The depth
of penetration of the operating laser beam into the living tissue can be manipulated
by changing the frequency of the electromagnetic impulses. Typically, during a session
having duration of 30-60 seconds about 50-100 impulses are provided.
[0055] The laser surgical device of the invention can be also utilized for disinfecting
lesions by scattered infrared laser emission. The density of this type of emission
does not produce damage to normal healthy skin. However, such emission eliminates
staphylococcal colonies in the skin area damaged by a disease.
[0056] The optical system of the laser surgical device also enables a user to perform surgical
operations which are followed by the laser photocoagulation and laser dissection including
ablation of cancerous tumors. The present invention also facilitates removal of a
benign tumor by vaporization of one layer of tissue at a time. This task can be accomplished
through application of several laser impulses having a predetermined spot area to
each part of the skin affected by the disease. The treatment is continued until "
blood dew" appears on the skin and is typically followed by a course of drug treatment
.
[0057] To carry out a therapy of the skin by infrared radiation to remedy, for example,
face wrinkles, the laser surgical device of the invention can be used in combination
with a scanning system of a preset scattered radiation. In order to utilize this treatment
it is expedient to secure conditions of the beam scanning according to a preset program
(the spot diameter of the operating beam can vary in a predetermined fashion, the
density of energy of the beam can be either variable or constant, see FIG.15). The
same condition can be provided if the laser beam is in a form of a slot (see FIG.
16).
[0058] The focused laser irradiation of the invention can be utilized for conducting of
local surgeries, such as, for a example, dissection and removal of a furuncle or a
pustule and consequent introduction of a medicine into the area of the incision.
[0059] The following examples are presented in order to provide more complete understanding
of the invention.
Example 1
[0060] An Er:YAG laser was employed as an active element of the laser surgical device having
a flash lamp as the exciting arrangement. The Er: YAG active element was interposed
between two substantially flat resonator mirrors. The lasing occurred at the wavelength
of 2.94 µm with the pulse duration 250± 50 microseconds, the pulse rate up to 1Hz
and the pulse energy up to 2 J.
[0061] The shape of the operating laser beam was adjusted by the focusing arrangement. Since
the Er: YAG laser beam belongs to the infrared region of the spectrum it was invisible
to the naked eye of the operator. The position and dimensions of the laser spot of
the operating laser beam on the skin of a patient were indicated with help of two
guide light beams generated by the guide semiconductor laser which emitted the beam
in the visible region of the spectrum. The maximum diameter of each guide light laser
beam was about 2.0 mm. The distance between projections of two guide light laser beams
on the skin of a patient corresponded to the spot diameter of the Er:YAG laser on
the same object. Thus, the position and diameter of the Er:YAG laser beam on the skin
of the patient was determined by the position of two guide light laser beams emitted
by the guide light semiconductor laser. The energy density of the Er:YAG laser was
adjustable within the range between 1.0-10 J/cm
2. Considering that during the treatment the level of the pumping energy was about
the same, the smaller the dimension of the Er:YAG laser beam, the higher its energy
density. Upon reaching minimal focusing dimensions of the spot of Er:YAG laser beam
on the skin of a patient a local vaporization of the tissue occurred at a depth of
up to 1.5 mm. Visible vaporization from the epidermis took place when the energy density
of the Er:YAG laser beam was about 50 J/cm
2.
[0062] Treatment of skin diseases of 48 patients was carried out by using surface vaporization
of the epidermis by Er:YAG laser with 50 J/cm
2 maximum energy density. Among them were 15 patients with pointed candylomas, 8 patients
with colloidal scars, 8 patients with warts on hands and feet, 10 patients with pointed
hyperkeratoses, 7 patients with tattoos. Depending on the type of the disease or skin
defect, the treatment was carried out by conducting 6-10 sessions, each consisting
of 3-20 pulses.
[0063] During these sessions the diameter of the spot of the Er:YAG laser beam was 3-5 mm.
The coagulation degree control was performed until appearance of the "blood dew" symptom.
As a result of such application of the laser beam to the skin of the patients there
had been no changes detected in the peripheral blood content and no remote relapses
of the disease revealed.
EXAMPLE 2
[0064] Unlike Example 1, there were two working cavities provided in the laser device of
Example 2. In the first cavity electrical pulses were transformed into light pulses.
Such light pumping pulses were received via the optical light guide in the second
cavity. There the light pulses were transformed into the laser beam. The first cavity
was situated at the power supply unit remotely from the patients and medical personnel.
The second cavity was located within the handpiece of the surgical device. In this
example another set of the working cavities was formed in such a manner that the first
cavity contained the exciting arrangement and a portion of the operating laser rod,
whereas the main part of the laser rod was situated in the second cavity. The cavities
were also interconnected by the optical fiber light guide. The laser pulses received
within the second cavity were of such pumping wavelength as to minimize losses in
the optical light guide. The laser pulses generated in the second cavity were transformed
into the laser irradiation beam operating of the required wavelength, for example,
2.94 µm.
1. A laser device (10) for conducting dermatological surgery comprising:
a housing (20) having interior and exterior regions;
a laser cavity (15, 21, 22) provided within said interior region of the housing, said
laser cavity containing at least a part of an operating laser element (26; 122) generating
an operating beam (127);
an exciting arrangement (28; 138) for exciting of said laser element (26; 122);
a cooling arrangement (38; 138) forming a stream of gaseous coolant being directed
along said laser cavity and said laser element (26; 122) is situated within said stream
of gaseous coolant; wherein said housing (20) forms a part of a handpiece (12; 112)
adapted for convenient positioning in a hand of an operator and at least a portion
of said cooling arrangement (38; 138) is situated within an interior portion of said
handpiece (12; 112);
characterized in that the laser device further comprises
a focusing lens (135, 236) arranged in the operating beam and adapted to be moved
in a direction substantially perpendicular to the operating beam, and
in that the focusing lens (236) is adapted to be rotated about the axis (A-A) of the operating
laser beam, whereby the axis (B-B) of the focusing lens is shifted by a predetermined
distance (C) from the axis (A-A) of the operating laser beam, so as to produce a complex
image pattern of the operating beam.
2. The device of Claim 1, further comprising a detecting arrangement for detecting a
condition of an operated living tissue by receiving and reviewing a signal reflected
from said operated living tissue and producing a control signal; and a control unit
for controlling and adjusting characteristics of said operating beam (127) in response to said control signal.
3. The device of Claim 1, further comprising a guide light unit generating a guide light
beam for targeting of said operating beam at said operated living tissue, so that
at least a portion of said guide light unit is situated within an interior portion
of the handpiece (12, 112); and a suction arrangement for removal of disintegrated tissue products produced during
the surgery from an area of said operated living tissue.
4. The device of Claim 1, wherein said cooling arrangement is a fan producing said stream
of gaseous coolant.
5. The device of Claim 3, wherein said laser cavity (15, 21, 22), said cooling arrangement, said focusing lens and said guide light unit are situated
within said interior portion of the housing in such a manner that relative to the
direction of said stream of gaseous coolant at least a part of said cooling arrangement
is positioned rearwardly of said laser cavity and said guide light unit situated forwardly
of said laser cavity facing said focusing lens.
6. The device of Claim 1, wherein said operating laser element (26, 122) consists of working and auxiliary parts, said working part is situated within said
handpiece, said auxiliary part is situated outside of said handpiece, said working
and auxiliary parts of the operating laser element are connected through a light guide
consisting of at least one fiber; and said exciting arrangement consists of working
and auxiliary parts, said working part is situated within said handpiece and said
auxiliary part of the exciting arrangement situated outside of said handpiece, said
working and auxiliary parts of the exciting arrangement are connected by a light guide
consisting of at least one fiber.
7. The device of Claim 2, wherein said detecting arrangement is selected from the group
consisting of photoelements, photoresistors and photodiodes.
8. The device Of Claim 1, wherein said operating laser element is Er : YAG laser rod
and said operating laser element generates an operating beam with wavelength selected
from the group consisting of the following ranges; 1.25-1.40 ; 1.7-2.1; 2.5-3.1 and
5.5-7.5 microns.
9. The device of Claim 1, wherein a laser medium of said operating laser element is selected
from the group consisting of Y3Al5O12: Nd; Gd3Ga5O12 : Cr, Ce, Nd; MgF2 : Co; BaYb2F8 : Er ; LiYF4 : Er, Tm, Ho; Y3Sc2Al3O12: Cr, Er; (Y, Er)3Al5O12 ; HF (chemical) and CO (gaseous).
10. The device of Claim 3, wherein said guide light unit provides a continuous low power
beam and is selected from the group consisting of a filament lamp; He:Ne laser, a
semiconductor laser and light emitting diodes; whereby said exciting arrangement (28, 138) is selected from the group consisting of flash lamp and a diode laser.
1. Eine Laservorrichtung (10) zum Durchführen dermatologischer Operationen, mit folgendem:
einem Gehäuse (20), das einen inneren und einen äußeren Bereich aufweist;
einem Laserresonator (15, 21, 22), der innerhalb des inneren Bereichs des Gehäuses
angeordnet ist, wobei der Laserresonator zumindest einen Teil eines einen Operationsstrahl
(127) erzeugenden, Arbeitslaserelements (26; 122) enthält;
einer Anregungsanordnung (28; 138) zum Anregen des Laserelements (26; 122);
einer Kühlanordnung (38; 138), die einen entlang des Laserresonators gerichteten Strahl
eines gasförmigen Kühlmittels ausbildet, wobei das Laserelement (26; 122) innerhalb
des Strahls des gasförmigen Kühlmittels angeordnet ist, wobei das Gehäuse (20) einen
Teil des zum passenden Positionieren in einer Hand eines Bedieners ausgebildeten Handstücks
(12; 122) ausbildet, und wobei mindestens ein Teil der Kühlanordnung (38; 138) innerhalb
eines inneren Bereichs des Handstücks (12; 122) angeordnet ist;
dadurch gekennzeichnet, dass die Laservorrichtung ferner umfasst:
eine in dem Operationsstrahl angeordnete Fokussierlinse (136, 236), die dazu ausgebildet
ist, in einer Richtung im wesentlichen senkrecht zu dem Operationsstrahl bewegt zu
werden, und dadurch dass die Fokussierlinse (236) dazu ausgebildet ist, um die Achse (A-A) des Operationslaserstrahls
gedreht zu werden, wobei die Achse (B-B) der Fokussierlinse um einen vorbestimmten
Abstand (C) von der Achse (A-A) des Operationslaserstrahls verschoben ist, um ein
komplexes Abbildungsmuster des Operationsstrahls zu erzeugen.
2. Die Vorrichtung nach Anspruch 1, ferner umfassend eine Detektionsanordnung zum Detektieren
eines Zustands eines operierten lebenden Gewebes durch Empfangen und Überprüfen eines
von dem operierten lebenden Gewebe reflektierten Signals und zum Erzeugen eines Steuersignals;
und eine Steuereinheit zum Steuern und Einstellen der Eigenschaften des Operationsstrahls
(127) in Antwort auf das Steuersignal.
3. Die Vorrichtung nach Anspruch 1, ferner umfassend eine einen Führungslichtstrahl erzeugende
Führungslichteinheit zum genauen Zielen des Operationsstrahls auf das operierte lebende
Gewebe, so dass mindestens ein Teil der Führungslichteinheit innerhalb eines inneren
Bereichs des Handstücks (12; 112) angeordnet ist, und eine Absauganordnung zum Entfernen
von zersetzten Gewebeprodukten, die während der Operation im Bereich des operierten
lebenden Gewebes erzeugt werden.
4. Die Vorrichtung nach Anspruch 1, wobei die Kühlanordnung ein Gebläse, das einen Strahl
des gasförmigen Kühlmittels erzeugt, ist.
5. Die Vorrichtung nach Anspruch 3, wobei der Laserresonator (15, 21, 22), die Kühlanordnung,
die Fokussierlinse und die Führungslichteinheit innerhalb des inneren Bereichs des
Gehäuses in einer solchen Weise angeordnet sind, dass bezüglich der Richtung des Strahls
des gasförmigen Kühlmittels zumindest ein Teil der Kühlanordnung hinter dem Laserresonator
angeordnet ist und die Führungslichteinheit vor dem Laserresonator und der Fokussierlinse
gegenüberliegend angeordnet ist.
6. Die Vorrichtung nach Anspruch 1, wobei das Arbeitslaserelement (26, 122) aus einem
Arbeitsteil und einem Hilfsteil besteht, wobei das Arbeitsteil innerhalb des Handstücks
angeordnet ist, das Hilfsteil außerhalb des Handstücks angeordnet ist, das Arbeits-
und das Hilfsteil des Arbeitslaserelements mittels eines aus mindestens einer Faser
bestehenden Lichtleiters verbunden sind; und wobei die Anregungsanordnung aus einem
Arbeitsteil und einem Hilfsteil besteht, wobei das Arbeitsteil innerhalb des Handstücks
angeordnet ist und das Hilfsteil der Anregungsanordnung außerhalb des Handstücks angeordnet
ist, wobei das Arbeits- und das Hilfsteil der Anregungsanordnung mittels eines aus
mindestens einer Faser bestehenden Lichtleiters verbunden sind.
7. Die Vorrichtung nach Anspruch 2, wobei die Detektionsanordnung aus der Gruppe, die
Fotoelemente, Fotowiderstände und Fotodiode umfasst, ausgewählt ist.
8. Die Vorrichtung nach Anspruch 1, wobei das arbeitende Laserelement ein Er:YAG Laserstab
ist und das Arbeitslaserelement einen Operationsstrahl erzeugt mit Wellenlängen, die
aus der Gruppe, die aus den folgenden Bereichen besteht, ausgewählt sind: 1,25 - 1,40;
1,7 - 2,1; 2,5 - 3,1 und 5,5 bis 7,5 Mikrometer.
9. Die Vorrichtung nach Anspruch 1, wobei ein Lasermedium des arbeitenden Laserelements
aus der Gruppe, die folgendes umfasst, ausgewählt ist: Y3Al5O12:Nd; Gd3Ga5O12 : Cr, Ce, Nd; MgF2 : Co; BaYb2F8:Er; LiYF4:Er,Tm,Ho; Y3Sc2Al3O12 : Cr, Er; (Y, Er) 3Al5O12; HF (chemisch) und CO (gasförmig).
10. Die Vorrichtung nach Anspruch 3, wobei die Führungslichteinheit einen kontinuierlichen
Niedrigenergiestrahl bereitstellt und aus der Gruppe, die aus folgendem besteht: eine
Glühfadenlampe; ein He:Ne Laser, ein Halbleiterlaser und lichtaussendende Dioden,
ausgewählt ist; und wobei die Anregungsanordung (28, 138) aus der Gruppe, die eine
Blitzlampe und einen Diodenlaser umfasst, ausgewählt ist.
1. Dispositif laser (10) pour effectuer de la chirurgie dermatologique comprenant :
un boîtier (20) comportant une région intérieure et une région extérieure ;
une cavité laser (15, 21, 22) prévue dans ladite région intérieure du boîtier, ladite
cavité laser contenant au moins une partie d'un élément laser opératoire (26 ; 122)
générant un faisceau opératoire (127) ;
un ensemble d'excitation (28 ; 138) pour exciter ledit élément laser (26 ; 122) ;
un ensemble de refroidissement (38 ; 138) formant un courant de fluide caloporteur
gazeux dirigé le long de ladite cavité laser et ledit élément laser (26 ; 122) est
situé dans ledit courant de fluide caloporteur gazeux ; dans lequel ledit boîtier
(20) forme une partie d'un embout à main (12 ; 112) adapté pour un positionnement
pratique dans la main d'un opérateur et au moins une partie dudit ensemble de refroidissement
(38 ; 138) est située dans une partie intérieure dudit embout à main (12 ; 112) ;
caractérisé en ce que le dispositif laser comprend en outre une lentille de mise au point (136, 236) placée
dans le faisceau opératoire et adaptée pour être déplacée dans une direction sensiblement
perpendiculaire au faisceau opératoire, et
en ce que la lentille de mise au point (236) est adaptée pour tourner autour de l'axe (A-A)
du faisceau laser opératoire, moyennant quoi l'axe (B-B) de la lentille de mise au
point est décalé d'une distance prédéterminée (C) par rapport à l'axe (A-A) du faisceau
laser opératoire, afin de produire un motif d'image complexe du faisceau opératoire.
2. Dispositif selon la revendication 1, comprenant en outre un ensemble de détection
pour détecter un état d'un tissu vivant opéré en recevant et en analysant un signal
réfléchi par ledit tissu vivant opéré et en produisant un signal de commande, et une
unité de commande pour régler et ajuster les caractéristiques dudit faisceau opératoire
(127) en réponse audit signal de commande.
3. Dispositif selon la revendication 1, comprenant en outre une unité de lumière de guidage
générant un faisceau lumineux de guidage pour diriger ledit faisceau opératoire sur
ledit tissu vivant opéré, de sorte qu'au moins une partie de ladite unité de lumière
de guidage se situe dans une partie intérieure de l'embout à main (12 ; 112), et un
ensemble d'aspiration pour retirer d'une région dudit tissu vivant opéré les produits
tissulaires désintégrés produits pendant la chirurgie.
4. Dispositif selon la revendication 1, dans lequel ledit ensemble de refroidissement
est un ventilateur produisant ledit courant de fluide caloporteur gazeux.
5. Dispositif selon la revendication 3, dans lequel ladite cavité laser (15, 21, 22),
ledit ensemble de refroidissement, ladite lentille de mise au point et ladite unité
de lumière de guidage sont situés dans ladite partie intérieure du boîtier de manière
telle que par rapport à la direction dudit courant de fluide caloporteur gazeux, au
moins une partie dudit ensemble de refroidissement est positionnée en arrière de ladite
cavité laser et ladite unité de lumière de guidage est située en avant de ladite cavité
laser, en face de ladite lentille de mise au point.
6. Dispositif selon la revendication 1, dans lequel ledit élément laser opératoire (26,
122) est constitué d'une partie de travail et d'une partie auxiliaire, ladite partie
de travail étant située à l'intérieur dudit embout à main, ladite partie auxiliaire
étant située à l'extérieur dudit embout à main, lesdites parties de travail et auxiliaire
de l'élément laser opératoire étant connectées par l'intermédiaire d'un guide de lumière
constitué d'au moins une fibre ; et ledit ensemble d'excitation est constitué d'une
partie de travail et d'une partie auxiliaire, ladite partie de travail étant située
à l'intérieur dudit embout à main et ladite partie auxiliaire étant située à l'extérieur
dudit embout à main, lesdites parties de travail et auxiliaire de l'ensemble d'excitation
étant connectées par l'intermédiaire d'un guide de lumière constitué d'au moins une
fibre.
7. Dispositif selon la revendication 2, dans lequel ledit ensemble de détection est choisi
dans le groupe comprenant les photo-éléments, les photorésistances et les photodiodes.
8. Dispositif selon la revendication 1, dans lequel ledit élément laser opératoire est
un barreau laser Er : YAG et ledit élément laser opératoire génère un faisceau opératoire
ayant une longueur d'onde choisie dans le groupe constitué des plages suivantes :
1,25 à 1,40 ; 1,7 à 2,1 ; 2,5 à 3,1 et 5,5 à 7,5 micromètres.
9. Dispositif selon la revendication 1, dans lequel un milieu laser dudit élément laser
opératoire est choisi dans le groupe constitué de Y3Al5O12 : Nd ; Gd3Ga5O12 : Cr, Ce, Nd ; MgF2 : Co ; BaYb2F8 : Er; LiYF4 : Er, Tm, Ho ; Y3Sc2Al3O12 : Cr, Er ; (Y,Er)3Al5O12 ; HF (chimique) et CO (gazeux).
10. Dispositif selon la revendication 3, dans lequel ladite unité de lumière de guidage
fournit un faisceau continu de faible puissance et est choisie dans le groupe constitué
d'une lampe à filament ; d'un laser He:Ne, d'un laser à semiconducteur et de diodes
électroluminescentes ; moyennant quoi ledit ensemble d'excitation (28 ; 138) est choisi
dans le groupe constitué d'une lampe éclair et d'un laser à diode.