WO2015125394A1 - 噴流生成装置、および、噴流生成装置の噴流生成方法 - Google Patents
噴流生成装置、および、噴流生成装置の噴流生成方法 Download PDFInfo
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- WO2015125394A1 WO2015125394A1 PCT/JP2014/083358 JP2014083358W WO2015125394A1 WO 2015125394 A1 WO2015125394 A1 WO 2015125394A1 JP 2014083358 W JP2014083358 W JP 2014083358W WO 2015125394 A1 WO2015125394 A1 WO 2015125394A1
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- jet
- liquid
- liquid chamber
- laser beam
- laser light
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B17/00—Surgical instruments, devices or methods, e.g. tourniquets
- A61B17/32—Surgical cutting instruments
- A61B17/3203—Fluid jet cutting instruments
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B1/00—Instruments for performing medical examinations of the interior of cavities or tubes of the body by visual or photographical inspection, e.g. endoscopes; Illuminating arrangements therefor
- A61B1/00064—Constructional details of the endoscope body
- A61B1/00071—Insertion part of the endoscope body
- A61B1/0008—Insertion part of the endoscope body characterised by distal tip features
- A61B1/00087—Tools
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B1/00—Instruments for performing medical examinations of the interior of cavities or tubes of the body by visual or photographical inspection, e.g. endoscopes; Illuminating arrangements therefor
- A61B1/012—Instruments for performing medical examinations of the interior of cavities or tubes of the body by visual or photographical inspection, e.g. endoscopes; Illuminating arrangements therefor characterised by internal passages or accessories therefor
- A61B1/015—Control of fluid supply or evacuation
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B17/00—Surgical instruments, devices or methods, e.g. tourniquets
- A61B17/28—Surgical forceps
- A61B17/29—Forceps for use in minimally invasive surgery
- A61B17/295—Forceps for use in minimally invasive surgery combined with cutting implements
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B05—SPRAYING OR ATOMISING IN GENERAL; APPLYING FLUENT MATERIALS TO SURFACES, IN GENERAL
- B05B—SPRAYING APPARATUS; ATOMISING APPARATUS; NOZZLES
- B05B12/00—Arrangements for controlling delivery; Arrangements for controlling the spray area
- B05B12/02—Arrangements for controlling delivery; Arrangements for controlling the spray area for controlling time, or sequence, of delivery
- B05B12/06—Arrangements for controlling delivery; Arrangements for controlling the spray area for controlling time, or sequence, of delivery for effecting pulsating flow
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B05—SPRAYING OR ATOMISING IN GENERAL; APPLYING FLUENT MATERIALS TO SURFACES, IN GENERAL
- B05B—SPRAYING APPARATUS; ATOMISING APPARATUS; NOZZLES
- B05B7/00—Spraying apparatus for discharge of liquids or other fluent materials from two or more sources, e.g. of liquid and air, of powder and gas
- B05B7/16—Spraying apparatus for discharge of liquids or other fluent materials from two or more sources, e.g. of liquid and air, of powder and gas incorporating means for heating or cooling the material to be sprayed
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B05—SPRAYING OR ATOMISING IN GENERAL; APPLYING FLUENT MATERIALS TO SURFACES, IN GENERAL
- B05B—SPRAYING APPARATUS; ATOMISING APPARATUS; NOZZLES
- B05B7/00—Spraying apparatus for discharge of liquids or other fluent materials from two or more sources, e.g. of liquid and air, of powder and gas
- B05B7/24—Spraying apparatus for discharge of liquids or other fluent materials from two or more sources, e.g. of liquid and air, of powder and gas with means, e.g. a container, for supplying liquid or other fluent material to a discharge device
- B05B7/2402—Apparatus to be carried on or by a person, e.g. by hand; Apparatus comprising containers fixed to the discharge device
- B05B7/2405—Apparatus to be carried on or by a person, e.g. by hand; Apparatus comprising containers fixed to the discharge device using an atomising fluid as carrying fluid for feeding, e.g. by suction or pressure, a carried liquid from the container to the nozzle
- B05B7/2408—Apparatus to be carried on or by a person, e.g. by hand; Apparatus comprising containers fixed to the discharge device using an atomising fluid as carrying fluid for feeding, e.g. by suction or pressure, a carried liquid from the container to the nozzle characterised by the container or its attachment means to the spray apparatus
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B05—SPRAYING OR ATOMISING IN GENERAL; APPLYING FLUENT MATERIALS TO SURFACES, IN GENERAL
- B05B—SPRAYING APPARATUS; ATOMISING APPARATUS; NOZZLES
- B05B9/00—Spraying apparatus for discharge of liquids or other fluent material, without essentially mixing with gas or vapour
- B05B9/002—Spraying apparatus for discharge of liquids or other fluent material, without essentially mixing with gas or vapour incorporating means for heating or cooling, e.g. the material to be sprayed
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B2217/00—General characteristics of surgical instruments
- A61B2217/002—Auxiliary appliance
- A61B2217/005—Auxiliary appliance with suction drainage system
Definitions
- the present invention relates to a jet generating device and a jet generating method of the jet generating device.
- a jet knife that uses incision and crushing of biological tissue using a liquid jet has been put into practical use.
- a jet knife using a high-pressure pump is also known.
- This jet scalpel is a surgical device that obtains a continuous jet flow by jetting liquid pressurized by a high-pressure pump from a jet nozzle, irradiates a living tissue with the jet flow, and obtains an incision / fracture effect by its kinetic energy.
- the jet knife does not use thermal energy like the laser knife and the high frequency knife, an effect can be obtained at a low temperature (such as room temperature).
- a low temperature such as room temperature.
- the action part is a solid metal like an ultrasonic scalpel
- the jet knife where the action part is a liquid after the liquid collides with the living body, the liquid itself deforms and applies pressure to the living body, There is a feature that acts on a low-elasticity part of a living tissue, and the action on a living tissue having a different elasticity is differentiated. This feature differentiates the incision and crushing effect by uniform jet irradiation in a stunning living tissue, and it is possible to preserve a specific part.
- Jet scalpels that use high-pressure pumps can only adjust the output of the high-pressure pump to roughly adjust the output of the jet flow, and remove thrombus etc. by utilizing minute differences in the elastic properties of living tissue Not suitable for surgery.
- a living body is irradiated with a continuous jet, when the jet intrudes into the vascular system, the pressure wave propagates through the vasculature at the speed of sound and damages a portion that is vulnerable to pressure. Since the vascular network is formed in the living body, the propagation range of the pressure wave is wide, and there is a possibility of causing pressure damage to a distal site.
- An optical fiber is inserted into the tube, and a laser beam emitted from the laser oscillator through the optical fiber is used to rapidly heat a liquid such as water filled in the tube to generate a liquid jet flow.
- a surgical instrument pulse jet knife that crushes and removes thrombus and the like by force is known.
- the laser-induced liquid jet generating device described in Patent Document 1 has a jet generating tube portion that accommodates a laser irradiation portion formed at the tip of an optical fiber and generates a jet flow.
- This laser-induced liquid jet generating device has a Y connector and a connecting member that connects the Y connector to a laser oscillator, and the connecting member includes a sleeve member that is screwed with a connecting protrusion protruding from the laser oscillator, The laser oscillator and the Y connector are detachably connected.
- An optical fiber is inserted into a predetermined port of the Y connector, and the optical fiber is integrally fixed to the sleeve member by a fixing member such as a resin. That is, the laser irradiation part formed in the front-end
- a jet generating device in which an optical fiber is fixedly arranged at a predetermined position in the liquid chamber, that is, the length of the expansion chamber is fixed
- the inner surface of the cylindrical liquid chamber B160 is formed as a rough surface B160r.
- the laser F is irradiated with the pulsed laser light from the laser beam irradiation unit 21 at the tip of the optical fiber 22
- the liquid F in the vicinity of the tip is heated, as shown in FIG.
- bubbles G are generated in the vicinity of the tip, and the liquid F is pushed out from the nozzle B165.
- the bubble G expands and the liquid F is ejected from the nozzle B165 along with the expansion.
- the light irradiated to the rough surface B160r on the inner surface of the liquid chamber B160 is easily scattered and absorbed by the rough surface B160r.
- the energy of the laser beam reaching the boundary surface FG of the bubble G is small.
- the absorption coefficient in water of laser light having a wavelength ⁇ of 2100 nm is about 50 cm ⁇ 1 .
- the laser beam travels 1 mm in water, 99.3% of the light energy is absorbed by water.
- the absorption of laser light into water is based on the vibration level of water molecules, and the absorption rate is proportional to the molecular density.
- the water at 100 ° C. undergoes phase transition to 100 ° C. water vapor having a volume of about 1700 times by vaporization. Due to the phase transition from liquid to water vapor, the molecular density is reduced to about 1/700. For this reason, in order for 99.3% of the energy of light to be absorbed by water vapor, the optical path length in the water vapor needs about 1700 mm.
- the maximum length of the expansion gas (water vapor) in the narrow tube (liquid chamber 160 (B160)) having an absorption scatterer (rough surface) formed on the inner surface will be described (see FIG. 12).
- NA 0.22
- liquid chamber B160 when a thin tube having a rough surface formed on the inner surface is used as the liquid chamber B160, an expansion gas (bubble G) having a maximum length of about 20 mm is generated due to the loss of light energy, and the end of the liquid chamber B160.
- Liquid F is ejected from an opening-shaped nozzle 165 (B165) formed in the portion 160a.
- the catheter described in Patent Document 2 includes a reinforcing member made of a material having a high melting point that can withstand the heat generated by the optical fiber and a predetermined rigidity, on the inner surface of the tube near the irradiation position of the laser beam.
- the laser-induced liquid jet generating device described in Patent Document 3 has a jet generating tube portion into which an optical fiber is inserted, and this jet generating tube portion performs laser irradiation inside, so that laser light and heat induced by the laser beam are generated.
- it is made of a material such as gold, platinum, silver, copper, aluminum, and an alloy thereof (for example, 18 gold or platinum iridium).
- the maximum value of the length G1 of the inflation gas (bubble G) is only slightly increased. Specifically, since the light emitted from the tip of the optical fiber 22 is easily scattered and absorbed by the rough surface on the inner surface of the liquid chamber B160, the intensity of the reflected light from the rough surface is small. The energy of light reaching the boundary surface FG of the bubble F, which is the liquid F and the gas, from the distal end portion of the optical fiber 22 decreases as the distance between the distal end portion of the optical fiber and the boundary surface FG increases.
- a jet is generated by vaporization and expansion of the liquid F due to absorption of the pulsed laser light.
- the volume of the expanded gas bubble G
- the liquid chamber B160 has a small diameter cylinder.
- the distance between the tip of the optical fiber 22 and the boundary surface FG (gas-liquid interface) increases, and the injected laser light cannot be efficiently absorbed by the liquid F.
- the injected laser light is directly irradiated onto the gas-liquid interface and absorbed.
- the laser light emitted from the tip of the optical fiber 22 is irradiated on the inner surface of the liquid chamber B160 and is scattered and absorbed to be attenuated. Since the amount of light energy that acts on the vaporization of the liquid F decreases, the jet strength decreases.
- the catheter described in Patent Document 2 includes a reinforcing member made of a material having a high melting point and a predetermined rigidity capable of withstanding the heat generated by the optical fiber, on the inner surface of the tube near the irradiation position of the laser beam.
- This reinforcing member does not contribute to increasing the maximum length of the inflation gas (bubbles).
- the laser-induced liquid jet generating device described in Patent Document 3 has a jet generating tube portion into which an optical fiber is inserted, and this jet generating tube portion performs laser irradiation inside, so that laser light and heat induced by the laser beam are generated.
- the jet generating tube portion does not contribute to increasing the maximum value of the length of the expansion gas (bubble).
- the liquid jet knife in order to increase the pulse width of the jet flow output from the nozzle, as a condition A for the distance L1 from the optical fiber emitting end to the nozzle, the liquid jet knife is high temperature and high pressure from the viewpoint of safety.
- the condition of L1> G1 is required so that the expanded gas (bubble G) is not ejected from the nozzle.
- W1 L1 ⁇ G1 needs to be a slight size.
- This W1 is a value obtained by subtracting the length G1 of the expansion gas (bubble G) from the distance L1 from the optical fiber emitting end to the nozzle when the expansion gas (bubble G) is generated, and the length of the liquid remaining in the pipe near the nozzle That's right. If W1 increases, fluid resistance accompanying the movement of the liquid F increases and the energy of the liquid jet is lost, so it is necessary to set W1 to a small value such as about 10 mm. In order to make the pulse energy E0 and the pulse width Tl variable as laser irradiation conditions while satisfying the above conditions A and B, it is necessary to make the distance L1 variable.
- the optical fiber is fixed to the Y connector, and the laser irradiation part formed at the tip of the optical fiber is fixed at a predetermined position inside the jet generating pipe part.
- the distance L1 is not variable.
- a general pulse jet knife (surgical instrument) is a function in which only the output related to the laser, such as adjustment of the pulse width and pulse energy of the laser beam, is set to a predetermined value, and the specific jet output and jet output time are fixed. It can be used only for a single purpose such as removing a specific biological tissue.
- the crushing force (striking force) of the jet of the pulse jet knife is an impulse of forces acting on the living tissue in a very short time.
- the speed of the jet is proportional to the acting force. Therefore, the product of the jet velocity (initial velocity) and the duration is proportional to the impulse, and the crushing force is proportional to the product of the velocity (initial velocity) and the duration of the liquid jet.
- the present invention is an example of a problem to deal with such a problem. That is, to provide a jet generating device that generates a high-speed jet, to provide a jet generating device with a simple configuration capable of generating a liquid jet with high efficiency, and to simplify the flow velocity and energy of the jet. Providing a jet generating device that can be made variable in structure, providing a jet generating device that can easily control the jet flow time with a simple configuration, and when using the jet generating device as a surgical device, To limit the propagation range of pressure waves in the living body by intermittently generating jets.
- An object of the present invention is to provide a jet generating method for a jet generating device.
- a jet generating device comprises at least the following configuration.
- a jet generating device for generating a liquid jet A cylindrical liquid chamber; A nozzle that opens an end of the liquid chamber and ejects the liquid in the liquid chamber to the outside; A liquid supply path for supplying a liquid into the liquid chamber; A laser beam irradiation unit that irradiates the liquid chamber with pulsed laser light and vaporizes the liquid in the liquid chamber; It has a laser oscillator that controls laser light intensity and laser light pulse width independently, The inner surface of the liquid chamber has a mirror surface that reflects the pulse laser beam emitted from the laser beam irradiation unit and guides it to the end portion, An adjusting means for adjusting a distance between the nozzle and the laser beam irradiation unit is provided.
- the jet generating method of the jet generating apparatus of this invention comprises at least the following structures.
- a jet generating method of a jet generating device for generating a liquid jet The jet generating device includes a cylindrical liquid chamber, A nozzle that opens an end of the liquid chamber and ejects the liquid in the liquid chamber to the outside; A liquid supply path for supplying a liquid into the liquid chamber; A laser beam irradiation unit that irradiates the liquid chamber with pulsed laser light and vaporizes the liquid in the liquid chamber; It has a laser oscillator that controls laser light intensity and laser light pulse width independently, The inner surface of the liquid chamber has a mirror surface that reflects the pulse laser beam emitted from the laser beam irradiation unit and guides it to the end portion, An adjusting means for adjusting a distance between the nozzle and the laser beam irradiation unit; The distance between the nozzle and the laser light irradiation unit is adjusted by the adjusting means before or during irradiation of the pulsed laser light by
- the present invention it is possible to provide a jet generating device that generates a jet with a high speed with a simple configuration. Further, according to the present invention, it is possible to provide a jet generating device that generates a liquid jet with high efficiency with a simple configuration. Moreover, according to this invention, the jet flow production
- generation apparatus which can make the flow velocity and energy of a jet flow variable with a simple structure can be provided. In addition, according to the present invention, it is possible to provide a jet flow generating device that can easily adjust the jet flow time with a simple configuration.
- the jet generating device when the jet generating device is used as a surgical device, by intermittently generating the jet, the propagation range of the pressure wave in the living body can be limited, and safety is improved.
- the jet generating device when the jet generating device is used as a surgical device, the differentiation of the incision / crushing effect by the liquid jet utilizing the elastic difference of the living tissue is controlled at a fine level, and the crushing region and the preservation region Therefore, it is possible to provide a jet generating device capable of performing an operation with a minute distinction, and capable of performing incision, crushing, preserving and the like of a complicated shape that does not depend on the skill of the operator.
- generation apparatus can be provided.
- the whole lineblock diagram showing an example of the jet generating device concerning the embodiment of the present invention.
- generation apparatus which concerns on embodiment of this invention (a) is before pulse laser beam irradiation, (b) is the pulse laser beam irradiation initial stage (at the time of bubble generation initial stage), (c) is a pulse.
- (D) is a figure which respectively shows the state at the time of a pulse laser beam non-irradiation at the time of laser beam irradiation and bubble expansion.
- (a) is a figure which shows an example of pulse laser beam and a fluid jet initial velocity
- (b) is a laser beam
- the conceptual diagram which shows an example of the laser beam pulse width dependence of the liquid jet pulse width in the jet generating apparatus which concerns on embodiment of this invention, and the jet generating apparatus of a comparative example.
- FIG. 6 (a) is a figure which shows an example in the state which the front-end
- generation apparatus which has a rotation stop member (a) is a cross-sectional view, (b) is sectional drawing along the AA of (a).
- generation apparatus of a comparative example (a) is before pulse laser beam irradiation, (b) is the pulse laser beam irradiation initial stage (at the time of bubble generation initial stage), (c) is pulse laser beam irradiation and The figure which shows each time of bubble expansion.
- generation apparatus (a) is a cross-sectional view, (b) is sectional drawing along the AA of (a).
- a jet generating device heats a liquid in a liquid chamber (expansion chamber) with pulsed laser light, induces vaporization / expansion, and uses intermittent vapor jet (pulse jet) using vaporization expansion pressure. ) Is generated.
- the incision / crushing effect of the pulse jet in the living tissue is proportional to the product of the acting force and the acting time T0. Therefore, in order to finely control the crushing effect of the pulse jet, it is necessary to finely control the impact force F0 and the time T0.
- the impact force F0 that acts when a pulse jet ejected with a cross-sectional area S, length L, density ⁇ , and velocity V0 collides with a living tissue is determined by ignoring the effect of liquid shape deformation. It is equal to the amount of change in momentum (see Equation (1)).
- the initial speed and the working time are preferably controlled independently.
- V0 initial velocity
- T0 jet duration
- V0, T0 / P0, and Tl do not act linearly when the transmission efficiency of laser light to the liquid changes depending on the form of the liquid chamber (expansion chamber).
- the factor that changes the transmission efficiency is that the laser beam emitted from the optical fiber is absorbed by the inside of the expansion chamber before reaching the liquid. Further, when P0 or Tl becomes large, there is a danger that the expanded high-temperature vaporized gas is emitted from the nozzle. Therefore, it is necessary to keep the laser beam emission part of the optical fiber away from the nozzle for the purpose of expanding the expansion chamber volume.
- the jet generating device varies the distance between the laser light emitting portion of the optical fiber and the nozzle in order to vary P0 and Tl, vary V0 and T0, and finely control the crushing effect. In order to make it variable and further suppress the absorption of laser light on the inner surface of the liquid chamber (expansion chamber), the inner surface has a reflecting structure.
- FIG. 1 is an overall configuration diagram showing an example of a jet generating apparatus 100 according to an embodiment of the present invention.
- FIG. 2 is a partially enlarged view of the vicinity of the tip of the cylindrical liquid chamber 160 of the jet flow generating device.
- the jet generating device 100 according to the embodiment of the present invention may be referred to as a laser-induced liquid jet generating device, a pulse laser heating jet generating device having an expansion chamber (liquid chamber) having a waveguide structure, or the like.
- the jet flow generating apparatus 100 includes a Y connector 120, a liquid supply path 140 (fluid supply path), a cylindrical liquid chamber 160 (a metal thin tube or the like), and the like.
- the jet generating device 100 includes a liquid feeding device 1, a laser device 2 (laser oscillator), a suction device 3, a control device 4 (control unit), and the like.
- the Y connector 120 is a grip member that is gripped by an operator or the like.
- the Y connector 120 is a substantially Y-shaped cylindrical body, and has a first end portion 120a, a second end portion 120b, and a third end portion 120c.
- the first end 120 a is provided with a metal thin tube as a cylindrical liquid chamber 160.
- the liquid delivery device 1 is connected to the second end portion 120b via a tubular member 143 such as a tube.
- the liquid supply path 140 is provided with a filter 145 for removing impurities in the liquid.
- the laser device 2 is connected to the third end 120 c via the optical fiber 22.
- the third end portion 120c is provided with an adjustment unit 170 (adjustment means).
- the optical fiber 22 is inserted into the Y connector 120 through the adjusting portion 170 provided at the third end 120 c of the optical fiber passage 122 of the Y connector 120, and the tip of the optical fiber 22 is a cylindrical liquid chamber 160. It arrange
- the adjusting unit 170 can adjust the position of the tip of the optical fiber 22 inserted into the Y connector 120 or the liquid chamber 160. Specifically, the adjustment unit 170 is configured to adjust the distance between the laser beam irradiation unit 21 provided at the tip of the optical fiber 22 and the nozzle 165, as will be described later.
- a part of the Y connector 120 has a structure that serves as both the liquid supply path 140 and the optical fiber path 122.
- the suction connector 180 is provided in the Y connector 120, and the suction device 3 is provided in the suction channel 180 via a tubular member 144 such as a tube.
- the suction flow path 180 is provided with a filter 185 for removing impurities and the like in the liquid F.
- connection position 48 between the liquid supply path 140 and the suction flow path 180 is located between the connection position 42 of the liquid supply path 140 and the optical fiber path 122 and the first end 120a.
- a Y connector 120 is configured.
- the liquid feeding device 1 supplies the liquid to the cylindrical liquid chamber 160 such as a metal cylindrical member via the liquid supply path 140 under the control of the control device 4 (control unit).
- the liquid F in the liquid chamber 160 include water, physiological saline, and electrolyte infusion.
- Laser device 2 (laser oscillator) generates pulsed laser light under the control of control device 4 (control unit).
- the pulsed laser light output from the laser device 2 is emitted from the laser light irradiation unit 21 at the tip of the optical fiber 22 to the cylindrical liquid chamber 160 via the optical fiber 22.
- the laser device 2 (laser oscillator) can independently control the laser light intensity and the laser light pulse width.
- the control device 4 controls the laser device 2 so as to change the pulse energy, the pulse width, and the pulse repetition frequency of the pulse laser light by the laser light irradiation unit 21.
- the laser device 2 that can irradiate a pulse laser beam of about 1000 mJ at the maximum per pulse is used.
- the laser device 2 can employ a laser oscillator such as a holmium yag laser device (Ho: YAG laser: wavelength 2.1 ⁇ m) as pulsed laser light.
- a laser oscillator such as a holmium yag laser device (Ho: YAG laser: wavelength 2.1 ⁇ m) as pulsed laser light.
- the liquid F such as water, physiological saline, electrolyte infusion, or the like has an energy absorbability of pulsed laser light such as holmium yag laser.
- the laser device 2 is not limited to the laser oscillator described above.
- the suction device 3 is connected to the Y connector 120 via a tubular member 144 such as a tube, and the liquid in the cylindrical liquid chamber 160 can be sucked as needed under the control of the control device 4 (control unit). It is configured.
- the control device 4 comprehensively controls various devices such as the liquid feeding device 1, the laser device 2, and the suction device 3.
- the control device 4 is configured by a computer or the like, and realizes a function related to control according to the present invention by executing a control program stored in a memory or a storage device. Further, the control device 4 (control unit) changes the pulse energy, the pulse width, and the pulse repetition frequency of the pulsed laser light by the laser light irradiation unit 21, and either one of the amount of jet, the flow velocity of the jet, the repetition frequency of the jet, or These sets or all are variably controlled.
- control device 4 controls the adjustment unit 170 (adjustment unit) to adjust the distance between the laser beam irradiation unit 21 provided at the tip of the optical fiber 22 and the nozzle.
- the adjustment unit 170 includes a drive device such as a motor, and the control device 4 drives the drive device of the adjustment unit 170 to adjust the distance between the laser light irradiation unit 21 and the nozzle. You may be comprised so that a process may be performed.
- control device 4 causes the adjustment unit 170 to adjust the laser light irradiation unit 21 and the nozzle according to the pulse width, pulse energy, pulse repetition frequency, and the like of the pulsed laser light emitted from the laser light irradiation unit 21.
- the process of adjusting the distance between is performed.
- the control device 4 may perform the above process based on the setting information stored in the storage unit.
- the detection part which detects the flow velocity, energy, etc. of the jet flow output from a nozzle may be provided, and the control apparatus 4 may perform control regarding the said adjustment part 170 based on the detection signal from a detection part.
- the liquid chamber 160 is formed in a cylindrical shape.
- the liquid chamber 160 is formed in a cylindrical shape.
- the liquid chamber 160 is formed in a cylindrical shape having an outer diameter Po and an inner diameter Pz.
- the cylindrical liquid chamber 160 is formed of a material having high strength such as a metal material. Examples of the material for forming the liquid chamber 160 include metals such as stainless steel, titanium, gold, and silver, and materials such as ceramics.
- the inner diameter Pz of the metal thin tube as the liquid chamber 160 is about 0.5 mm to 3.0 mm, preferably about 1.0 mm.
- An opening-shaped nozzle 165 is provided at the end 160 a of the liquid chamber 160.
- the nozzle 165 is configured to be able to eject the liquid F in the liquid chamber 160 to the outside.
- the diameter Nz of the nozzle 165 is smaller than the inner diameter Pz of the cylindrical liquid chamber 160.
- the axial length NL of the nozzle 165 having a diameter Nz is smaller than the distance SD between the end 160a of the liquid chamber 160 provided with the nozzle 165 and the tip of the optical fiber 22.
- the distance SD between the end 160a of the liquid chamber 160 and the tip of the optical fiber 22 is about 50 mm to 150 mm, preferably about 100 mm. This distance SD is set such that bubbles that are generated and expanded in the liquid chamber 160 by laser light irradiation do not come out of the nozzle 165 formed at the end portion 160 a of the liquid chamber 160.
- the optical fiber 22 is inserted into the cylindrical liquid chamber 160 from the opposite side to the nozzle 165.
- the length AL of the optical fiber 22 in the cylindrical liquid chamber 160 is configured to be adjustable.
- the tip of the optical fiber 22 functions as a laser light irradiation unit 21.
- the liquid F in the liquid chamber 160 has energy absorbability with respect to the laser light irradiated from the laser light irradiation unit 21.
- the laser light irradiation unit 21 irradiates the liquid chamber 160 with pulsed laser light, and heats and vaporizes the liquid F in the liquid chamber 160.
- the diameter Az of the optical fiber 22 is smaller than the inner diameter Pz of the cylindrical liquid chamber 160.
- a gap is formed between the optical fiber 22 and the inner surface of the cylindrical liquid chamber 160, and the gap functions as the liquid supply path 140.
- the liquid supply path 140 supplies the liquid F into the liquid chamber 160 (specifically, the space between the nozzle 165 and the laser light irradiation unit 21 that is the tip of the optical fiber 22).
- the inner surface of the cylindrical liquid chamber 160 has a mirror surface 160k that reflects the pulse laser light emitted from the laser light irradiation unit 21 and guides it to the end 160a of the liquid chamber 160 or the nozzle 165 formed at the end 160a. That is, when the laser beam is reflected by the mirror surface 160k, the energy loss of the laser beam is very small. Therefore, the pulsed laser light emitted from the laser light irradiation unit 21 can be reflected once or a plurality of times on the mirror surface 160k on the inner surface of the cylindrical liquid chamber 160, and can be irradiated to the boundary surface (gas-liquid interface) of the bubbles. It is.
- the boundary surface (gas-liquid interface) between the liquid F and the bubble here refers to the boundary surface (gas-liquid interface) on the opening side (nozzle 165 side) of the cylindrical liquid chamber 160 in the bubbles in the cylindrical liquid chamber 160. ).
- the mirror surface 160k is formed on the inner surface of the cylindrical liquid chamber 160 in the vicinity of the laser light irradiation unit 21 at the tip of the optical fiber 22 and in all or part of the area between the laser light irradiation unit 21 and the nozzle 165. Preferably it is formed.
- the mirror surface 160k is a surface processed by any one of electrolytic polishing processing, reamer processing processing, plating processing, vapor deposition processing, abrasive spraying processing, and the like.
- the mirror surface 160k may be formed by optically polishing the inner surface.
- the mirror surface 160k may be formed by coating with a material having a high reflectance with respect to the laser wavelength of the pulse laser beam.
- the mirror surface 160k may be coated such as gold coating or gold plating.
- the cylindrical liquid chamber 160 may have a mirror surface 160k by press-fitting a thin thin tube (gold), which is a highly reflective material, into a thin metal tube such as stainless steel or titanium.
- the abrasive spraying process include a process of spraying fine particles (fine resin particles or the like) to which the abrasive is attached into the cylindrical liquid chamber 160 at a high speed.
- the mirror surface 160k on the inner surface of the liquid chamber 160 has a reflectance of a specified value or more with respect to the pulsed laser light irradiated by the laser light irradiation unit 21.
- FIG. 3 is a diagram illustrating an example of the operation of the jet flow generating device according to the embodiment of the present invention.
- 3 (a) is before pulse laser light irradiation
- FIG. 3 (b) is at the initial stage of pulse laser light irradiation (at the beginning of bubble generation)
- FIG. 3 (c) is at the time of pulse laser light irradiation and bubble expansion
- FIG. ) Is a diagram showing a state when no pulse laser beam is irradiated.
- FIG. 4 is a diagram showing an example of pulse laser beam intensity and fluid jet initial velocity by the jet generating device.
- FIG. 4A is a diagram illustrating an example of pulse laser beam intensity and fluid jet initial velocity
- FIG. 4B is a diagram illustrating an example of time variation of laser beam intensity and liquid jet.
- the vertical axis indicates the intensity I (w) of the laser beam, and the horizontal axis indicates time T (s).
- the vertical axis represents the liquid jet velocity (liquid jet initial velocity) V0 (m / s).
- control device 4 controls the laser device 2, and as shown in FIG. 4A, the pulse width Tl (s) of the pulse laser beam and the repetition period of the pulse laser beam.
- a pulse laser beam of TR (s) is irradiated from a laser beam irradiation unit via an optical fiber.
- the jet ejected from the nozzle has a liquid jet pulse width Tj.
- the liquid F is filled. Specifically, by supplying the liquid F from the supply unit (liquid feeding device) into the cylindrical liquid chamber 160 via the liquid supply path 140, the liquid F is filled in the liquid chamber 160. Yes. In this case, the liquid F is not ejected from the nozzle 165. That is, the liquid jet velocity V0 is 0 (m / s).
- the supply timing of the liquid F into the cylindrical liquid chamber 160 by the supply unit for example, a small amount (for example, 0.2 cc / s) of liquid F is constantly supplied, and only when no laser light is irradiated. For example, the liquid F is supplied and the supply of the liquid F is stopped when the laser beam is irradiated. It is preferable that the control device 4 (control unit) appropriately controls the supply timing of the liquid F according to the use of the jet flow generating device 100.
- control device causes the laser device to emit pulsed laser light.
- the pulse laser beam emitted from the laser device is guided into the liquid chamber 160 by the optical fiber 22 and irradiated from the laser light irradiation unit 21 at the tip of the optical fiber 22.
- the bubble G expands and the volume of the bubble G increases.
- the distance from the tip of the optical fiber 22 to the boundary surface FG (gas-liquid interface) between the liquid F and the bubble G increases.
- the intensity of this reflected light is relatively large. For this reason, even if the distance from the tip of the optical fiber 22 to the boundary surface FG (gas-liquid interface) between the liquid F and the bubble G increases due to the vaporization and expansion of the bubbles G, the boundary surface FG (gas-liquid interface) ) The intensity of the reflected light irradiated to the is high. That is, even when the distance is large, the boundary surface FG (vaporization interface) is irradiated with direct light and reflected light with relatively large intensity. For this reason, even when the distance is large, the vaporizing action at the boundary surface FG (gas-liquid interface) is large. That is, it is possible to generate a vaporizing action while chasing the boundary surface FG (gas-liquid interface) in a state where the pulse laser light is substantially kept strong until the end of irradiation with the pulse laser light.
- the boundary surface FG (gas-liquid interface) of the bubble G is irradiated with pulse laser light (direct light and reflected light) having a relatively large intensity.
- the boundary surface FG (gas-liquid interface) of the bubble G is irradiated with relatively high intensity pulsed laser light (direct light and reflected light), absorbs the light energy, and opens on the opening side of the cylindrical liquid chamber 160.
- the vaporized jet KJ is ejected in the opposite direction to the (nozzle side). For this reason, the reaction force by the vaporized jet is applied to the liquid F.
- the liquid jet velocity V0 becomes zero. Thereafter, at time D shown in FIG. 4 and the like, the liquid jet velocity V0 becomes a negative value. In this case, the liquid F flows backward from the nozzle 165.
- the control device 4 controls the liquid F so as to supply the liquid F into the liquid chamber 160 through the liquid supply path 140 so that the liquid jet velocity V0 does not become a negative value. You may go.
- the inner surface of the liquid chamber 160 the mirror surface 160k
- the absorption of the laser beam to the inner surface of the liquid chamber 160 is small, and the laser beam can be efficiently irradiated onto the gas-liquid interface.
- the inner surface of the liquid chamber 160 a mirror surface 160k
- a pulse liquid jet having a large intensity can be jetted for a long time even when the distance L1 from the optical fiber emitting end to the nozzle is large.
- FIG. 5 is a conceptual diagram showing an example of the dependence of the liquid jet pulse width on the laser light pulse width in the jet generating apparatus 100 according to the embodiment of the present invention and the jet generating apparatus 100B of the comparative example (see FIG. 10).
- the vertical axis represents the liquid jet pulse width Tj (s)
- the horizontal axis represents the laser light pulse width Tl (s).
- the curve regarding the jet generating apparatus 100 which concerns on embodiment of this invention is shown as a continuous line
- the curve regarding the jet generating apparatus 100B of a comparative example is shown with a dotted line.
- a rough surface B160r is formed on the inner surface of a cylindrical liquid chamber B160 (see FIG. 10).
- the ratio of the laser light emitted from the tip of the optical fiber is scattered and absorbed by the rough surface B160r on the inner surface of the liquid chamber B160. For this reason, when the pulse width of the laser beam is increased, the liquid jet pulse width Tj (s) does not exceed a relatively small predetermined value. That is, in the jet flow generating device 100B of the comparative example, the upper limit value of the energy of the jet flow ejected from the nozzle is relatively small.
- a mirror surface 160k is formed on the inner surface of a cylindrical liquid chamber 160 (see FIG. 2). Therefore, in the jet generating device 100, the larger the pulse width Tl of the laser light, the larger the value of the liquid jet pulse width Tj (s) than in the comparative example, and a large value without being saturated with the predetermined value of the comparative example. . That is, in the jet flow generating device 100 of the present invention, the energy of the jet flow ejected from the nozzle 165 is relatively large.
- FIG. 6 is a diagram showing a specific example of the jet flow generating device 100 according to the embodiment of the present invention.
- FIG. 7 is a diagram showing an example of the operation of the adjusting unit 170 of the jet flow generating device 100 shown in FIG. Specifically, FIG. 7A shows an example of a state where the tip of the optical fiber 22 has moved to the nozzle 165 side, and FIG. 7B shows the tip of the optical fiber 22 moved to the opposite side with respect to the nozzle 165. It is a figure which shows an example of the state which carried out.
- the adjustment unit 170 (adjustment unit) is configured to be able to adjust the distance between the nozzle 165 and the laser beam irradiation unit 21 provided at the tip of the optical fiber 22.
- the adjustment unit 170 includes a small-diameter cylindrical portion 172, a large-diameter cylindrical portion 171 as an optical fiber holding member, and the like.
- the small diameter cylindrical portion 172 has a structure communicating with the liquid chamber 160.
- a large-diameter cylindrical portion 171 is disposed on the outer peripheral side of the small-diameter cylindrical portion 172.
- the small-diameter cylindrical portion 172 and the large-diameter cylindrical portion 171 are configured to be engaged by, for example, screwing portions 172a and 171a.
- An opening into which the optical fiber 22 is inserted is formed at the end of the large diameter cylindrical portion 171, and a sealing member 176 such as an O-ring is provided in the opening to prevent the liquid F from flowing out. is doing.
- a groove is formed in the opening, and a sealing member 176 is disposed in the groove.
- the sealing member 176 is in close contact with the optical fiber 22 and is substantially fixed.
- a sealing member 175 such as an O-ring is provided between the small-diameter cylindrical portion 172 and the large-diameter cylindrical portion 171 to prevent the liquid F from flowing out.
- a groove portion is formed on the inner peripheral surface of the large-diameter cylindrical portion 171, and a sealing member 175 is disposed in the groove portion.
- the sealing member 175 such as an O-ring is configured to slide on the outer peripheral surface of the small-diameter cylindrical portion 172.
- the structure which provided the groove part in the edge part of the small diameter cylindrical part 172, and provided the sealing member 175, such as an O-ring, in the groove part may be sufficient.
- the small-diameter cylindrical portion 172 and the large-diameter cylindrical portion 171 move relative to each other in the axial direction.
- the laser light irradiation unit 21 provided at the tip is configured to be movable within a variable range.
- the small-diameter cylindrical portion 172 and the large-diameter cylindrical portion 171 have a screwed structure. By rotating the large-diameter cylindrical portion 171 with respect to the small-diameter cylindrical portion 172 with the axial direction as a rotation axis, laser light is obtained.
- the position of the irradiation unit 21 is configured to be adjustable.
- the drive motor may be configured to rotate the large-diameter cylindrical portion 171 with respect to the small-diameter cylindrical portion 172 with the axial direction as the rotation axis.
- the inner surface of the liquid chamber 160 is formed with a mirror surface 160k over at least the variable range of the tip of the laser beam irradiation unit 21 that emits pulsed laser light.
- the condition A for the distance L1 from the laser beam irradiation unit 21 provided at the tip of the optical fiber 22 to the nozzle 165 is a high temperature and high pressure from the viewpoint of safety.
- the condition of L1> G1 is required so that the expansion gas (bubble G) is not ejected from the nozzle 165.
- G ⁇ b> 1 indicates the length of the expansion gas (bubble G that is water vapor) generated in the liquid chamber 160.
- W1 L1 ⁇ G1 needs to be a slight size.
- This W1 is a value obtained by subtracting the length G1 of the expansion gas (bubble G) from the distance L1 from the optical fiber emitting end to the nozzle when the expansion gas (bubble G) is generated, and the length of the liquid remaining in the pipe near the nozzle It corresponds to.
- W1 increases, the fluid resistance accompanying the movement of water increases and the energy of the liquid jet is lost. Therefore, it is desirable to set W1 to a small value such as about 5 mm to 15 mm, preferably about 10 mm.
- the adjusting unit 170 (adjusting unit) satisfies the above conditions A and B, and makes the pulse energy E0 and the pulse width Tl variable as laser irradiation conditions.
- L1 can be adjusted.
- W1 the variable range of the distance between the nozzle 165 and the laser beam irradiation unit 21 is obtained by removing the minimum range of W1 and G1 from the distance L1 between the nozzle 165 and the laser beam irradiation unit 21.
- a range is preferable.
- the jet flow generation device 100 (pulse jet knife) according to the embodiment of the present invention generates an intermittent jet using the vaporization expansion pressure using the pulsed laser light emitted from the laser light irradiation unit 21. Then, the length of the liquid chamber 160 (expansion chamber) is varied corresponding to the laser output (variable expansion chamber length type).
- the jet flow generating device 100 has a reflection structure on the inner wall in order to transmit light in the long liquid chamber 160 (expansion chamber).
- the jet flow generating device 100 according to the embodiment of the present invention includes an adjustment unit 170 that has a mirror surface 160 k formed on the inner surface of the liquid chamber 160 and adjusts the distance between the laser beam irradiation unit 21 and the nozzle 165.
- the liquid chamber Since the light absorption on the inner surface of 160 is very small, the pulse laser beam can be reflected by the mirror surface 160k of the liquid chamber 160 and guided to the nozzle 165 side formed at the end 160a of the cylindrical liquid chamber 160. By expanding the bubbles G greatly, the duration of the liquid jet can be made relatively long.
- the inner surface of the liquid chamber 160 is a mirror surface 160k, and the adjustment unit 170 irradiates the laser beam according to the pulse width of the pulsed laser beam emitted from the laser beam irradiation unit 21.
- the distance between the section 21 and the nozzle 165 variable, the length of the duration of the liquid jet emitted from the nozzle can be controlled.
- the jet generating device 100 controls the intensity of the pulsed laser beam and the pulse width of the laser beam independently, so that the liquid jet is proportional or substantially proportional to the intensity of the pulsed laser beam.
- the velocity and the liquid jet duration proportional to or approximately proportional to the pulse width of the laser beam can be variably controlled independently of each other.
- FIG. 8 is a diagram showing an example of temporal changes in laser light intensity and liquid jet velocity.
- the horizontal axis represents time T (s).
- the vertical axis indicates the intensity I (W) of the pulse laser beam.
- the vertical axis represents the liquid jet velocity (initial velocity) V0 (m / s).
- the pulse width of the pulse laser beam is relatively short, the laser beam intensity is relatively small, and the distance between the laser beam irradiation unit 21 and the nozzle 165 is set to be relatively short by the adjustment unit 170, so that it is relatively small.
- a jet having a short duration can be generated at the jet velocity (see FIGS. 8A and 8B).
- the pulse width of the pulse laser beam By setting the pulse width of the pulse laser beam to be relatively long, the laser beam intensity to be relatively small, and the distance between the laser beam irradiation unit 21 and the nozzle 165 to be relatively long, it is long with a relatively low jet velocity. It is possible to generate a jet having a duration (see FIGS. 8C and 8D).
- the pulse width of the pulse laser beam By setting the pulse width of the pulse laser beam to be relatively short, the laser beam intensity to be relatively large, and the distance between the laser beam irradiation unit 21 and the nozzle 165 to be relatively short, it is short at a relatively large jet velocity.
- a jet of duration can be generated (see FIG. 8 (e), FIG. 8 (f), etc.).
- the pulse width of the pulse laser light By setting the pulse width of the pulse laser light to be relatively long, the laser light intensity to be relatively large, and the distance between the laser light irradiation unit 21 and the nozzle 165 to be relatively long, it is long at a relatively high jet velocity.
- a jet having a duration can be generated (see FIG. 8G, FIG. 8H, etc.).
- the jet generating apparatus 100 can variably control the speed (initial speed) of the liquid jet emitted from the nozzle and the duration of the liquid jet independently. This is very effective, for example, when the jet flow generating device 100 is applied to a pulse jet knife that performs crushing of living tissue.
- a surgical instrument pulse jet knife
- a pulsed liquid jet sorts and crushes biological tissue using the difference in elastic characteristics of the biological tissue.
- the crushing force (striking force) of a liquid jet can be thought of as the impulse that is the product of the large force that the liquid jet acts on the living tissue and the short duration (jet time) that the liquid jet acts on the living tissue. it can.
- the speed of the liquid jet (initial speed) is proportional to the force of the liquid jet. Therefore, the product of the liquid jet velocity (initial velocity) and the liquid jet duration is proportional to the impulse. For this reason, the crushing force (striking force) of the liquid jet is proportional to the product of the velocity (initial speed) of the liquid jet and the duration.
- the jet flow generating device 100 In order to finely control the crushing force on the living tissue by the liquid jet in the pulse jet knife and search for the boundary condition between crushing and preservation of the living tissue, the velocity of the liquid jet (initial velocity) and the duration of the liquid jet are determined. Variable control is very important.
- the jet flow generating device 100 has the mirror surface 160k on the inner surface of the liquid chamber 160, and includes the adjustment unit 170 that adjusts the distance between the laser light irradiation unit 21 and the nozzle 165, and By adjusting the distance and the intensity and pulse width of the pulse laser beam, the speed (initial speed) and duration of the liquid jet can be controlled independently, which is very useful for a pulse jet knife and the like.
- a laser beam irradiation unit 21 In crushing operations such as blood clots, a laser beam irradiation unit 21 outputs a pulse laser beam with a low intensity for a short time, and applies a jet of weak jet pressure to the site for a certain period of time, thereby reducing damage to the preserved portion. It can be performed.
- the intensity of the pulsed laser light is gradually increased, and the intensity of the jet is gradually increased to minimize the damage to the preserved part and to remove the thrombus.
- the intensity and pulse width of the pulse laser beam from the pulse laser beam irradiation unit are adjusted, and the adjustment unit 170 adjusts the distance between the nozzle and the laser beam irradiation unit to control the duration of the jet.
- the variable control of the duration enables fine control of the crushing force, and even if the difference in elastic properties between the crushing part and the preserved part of the living tissue is minute, the crushing part and the preserved part of the living tissue can be easily Can be sorted.
- the intensity and duration of the jet can be independently and freely controlled during surgery, various surgical techniques can be provided.
- the adjustment unit 170 is not limited to the above-described configuration, and may have a mechanism that can adjust the distance between the nozzle 165 and the laser light irradiation unit 21.
- FIG. 9 is a diagram illustrating an example of the jet flow generating device 100 having the rotation stopper member 179.
- FIG. 9A is a cross-sectional view of the jet flow generating device 100
- FIG. 9B is a cross-sectional view taken along line AA of FIG. 9A.
- the adjustment unit 170 includes a small-diameter cylindrical part 172 that communicates with the liquid chamber 160, a cylindrical part 178 that holds the optical fiber 22, a rotating member 177, an anti-rotation member 179, and the like. Have.
- the small diameter cylindrical portion 172 has a structure communicating with the liquid chamber 160.
- the cylindrical part 178 is arranged along the axial direction of the small diameter cylindrical part 172 at a predetermined interval.
- a cylindrical rotating member 177 is disposed on the outer peripheral side of the small diameter cylindrical portion 172 and the cylindrical portion 178.
- the rotating member 177 and the small-diameter cylindrical portion 172 are configured to be engaged by screwing portions 177a and 172a, and the rotating member 177 and the cylindrical portion 178 are configured to be engaged by screwing portions 177b and 178b. ing.
- the screwing portions 177a and 172a and the screwing portions 177b and 178b are configured to have a reverse screw relationship.
- An opening into which the optical fiber 22 is inserted is formed at the end of the cylindrical portion 178, and a sealing member 176 such as an O-ring is provided in the opening, and the sealing member 176 is attached to the optical fiber 22. It is in a state of being in close contact with and substantially fixed.
- One or a plurality of sealing members 175 such as O-rings are provided between the rotating member 177 and the small-diameter cylindrical portion 172, and one or a plurality of sealing members 175 such as an O-ring are provided between the rotating member 177 and the cylindrical portion 178.
- a sealing member 174 such as an O-ring is provided to prevent the liquid F from flowing out.
- the rotation-stop member 179 causes the small-diameter cylindrical portion 172 and the cylinder to be separated. The shape portion 178 is prevented from relatively rotating around the axis.
- the rotation stop member 179 is formed, for example, in a U-shaped cross section, and has a structure in which the nozzle-side end portion 179b and the other end portion 179c are connected by a connecting portion 179a.
- the nozzle-side end portion 179 b is fixed to the small diameter cylindrical portion 172.
- the cylindrical portion 178 is loosely fitted in an opening 179h formed in the other end portion 179c with a gap, and the cylindrical portion 178 is held by the end portion 179c so as to be movable in the axial direction. .
- a groove 178u is formed on the outer periphery of the cylindrical portion 178, and the groove 178u extends in the axial direction.
- a protrusion 179t formed on the inner periphery of the opening 179h of the end 179c of the rotation stop member 179 is engaged with the groove 178u so as to suppress rotation about the axis of the cylindrical portion 178 as a rotation center. It is configured.
- the protrusion 179t can be easily formed by providing a member such as a set screw 179n, for example.
- the rotation angle of the rotation member 177 relative to the small diameter cylindrical portion 172 (or the cylindrical portion 178) is recognized in the visible portion of the outer peripheral portion of the rotation member 177 and the outer peripheral portion of the small diameter cylindrical portion 172 (or the cylindrical portion 178).
- a scale may be provided so that it is possible.
- the rotation angle of the rotating member 177 with respect to the small-diameter cylindrical portion 172 is a moving distance in a direction in which the small-diameter cylindrical portion 172 and the cylindrical portion 178 approach or separate from each other, that is, laser light irradiation provided at the tip of the optical fiber 22. This corresponds to the moving distance of the part 21.
- the moving distance of the laser beam irradiation unit 21 provided at the tip of the optical fiber 22 can be easily quantitatively recognized from the rotation angle of the rotating member 177.
- the groove 178u of the cylindrical portion 178 and the protrusion 179t of the rotation preventing member 179 are engaged.
- the present invention is not limited to this configuration. Rotation of the cylindrical portion 178 may be suppressed by an uneven structure in which a groove portion is provided on the inner periphery of the opening 179h and a protrusion is provided on the outer periphery of the cylindrical portion 178.
- the jet generating device 100 generates a jet of the liquid F.
- the jet generating device 100 is a cylindrical liquid chamber 160 such as a metal cylinder member, and an opening provided at an end of the liquid chamber 160, and a nozzle 165 that ejects the liquid F in the liquid chamber 160 to the outside.
- a liquid supply path 140 that supplies the liquid F into the liquid chamber 160, and a laser beam that irradiates the liquid chamber 160 with pulsed laser light to vaporize the liquid F in the liquid chamber 160 and generate bubbles G.
- an irradiation unit 21 is a cylindrical liquid chamber 160 such as a metal cylinder member, and an opening provided at an end of the liquid chamber 160, and a nozzle 165 that ejects the liquid F in the liquid chamber 160 to the outside.
- a liquid supply path 140 that supplies the liquid F into the liquid chamber 160, and a laser beam that irradiates the liquid chamber 160 with pulsed laser light to vaporize the liquid F in the liquid chamber 160 and generate bubbles G.
- the inner surface of the liquid chamber 160 has a mirror surface 160k that reflects the pulsed laser light emitted from the laser light irradiation unit 21 and guides it to the end 160a of the cylindrical liquid chamber 160. That is, the cylindrical liquid chamber 160 such as a metal cylinder member functions as an optical waveguide (optical conduit).
- the jet generating device 100 includes a laser device 2 (laser oscillator) that independently controls the laser light intensity and the laser light pulse width.
- the liquid F irradiated with the pulse laser light is heated to vaporize the liquid F, and bubbles G are generated.
- the intensity of light reflected by the mirror surface of the liquid chamber 160 is relatively large. For this reason, even if the distance from the tip of the optical fiber 22 to the boundary surface FG (gas-liquid interface) between the liquid F and the bubble G increases due to the vaporization and expansion of the bubbles G, the boundary surface FG (gas-liquid interface) ) The intensity of the reflected light irradiated to the is high. That is, even when the distance is large, the boundary surface FG (vaporization interface) is irradiated with direct light and reflected light with relatively large intensity.
- the vaporizing action at the boundary surface FG is large. That is, until the end of irradiation with the pulsed laser light, the vaporizing action is generated while chasing the boundary surface FG (gas-liquid interface) in a state where the pulsed laser light keeps a strong intensity.
- the boundary surface FG (gas-liquid interface) of the bubble G is irradiated with pulse laser light (direct light and reflected light) having a relatively large intensity. For this reason, even when the distance is large, the force caused by the expansion pressure of the bubbles G and the force caused by the vaporized jet act on the liquid F. That is, due to the synergistic effect of the expansion pressure and the reaction force generated by the vaporized jet, the liquid jet velocity from the nozzle 165 is large even when the distance is large.
- the jet flow generating apparatus 100 includes an adjustment unit 170 (adjustment unit) that adjusts the distance between the nozzle 165 and the laser light irradiation unit 21.
- the laser beam irradiation unit 21 provided at the tip of the optical fiber 22 is configured to be adjustable within a movable range in the liquid chamber 160.
- the adjusting means determines the distance between the nozzle 165 and the laser light irradiation unit 21 in accordance with the pulse width of the pulse laser light emitted from the laser light irradiation unit 21 (or the energy of the pulse laser light). It is configured to be adjustable.
- a mirror surface 160k is formed on the inner surface of the liquid chamber 160 over at least a variable range of the tip of the laser beam irradiation unit 21 that emits pulsed laser light.
- the adjustment unit 170 (adjustment unit) can arbitrarily set the distance L1 from the laser light irradiation unit 21 provided at the distal end of the optical fiber 22 to the nozzle 165, and the individual difference of the living tissue and the individual part It is possible to provide a surgical apparatus (pulse jet scalpel) using a pulsed liquid jet having an optimum jet strength for the elasticity difference due to (by organ, position of organ, etc.) and the elasticity difference due to the pathological progress of the diseased part. .
- the adjusting unit 170 sets the pulse energy E0 and the pulse width Tl to desired values as the laser irradiation conditions by adjusting the distance L1 while satisfying the conditions A and B. can do.
- the distance L1 cannot be adjusted as described above, and E0 and Tl are set to desired values as laser irradiation conditions. Cannot be set.
- the jet generating tube portion into which an optical fiber is inserted, and the jet generating tube portion irradiates the laser inside, so that it counters the laser light and heat induced thereby, gold, platinum
- the distance L1 cannot be adjusted, and E0 and Tl cannot be set to desired values as laser irradiation conditions.
- the mirror surface 160k on the inner surface of the cylindrical liquid chamber 160 is processed by electrolytic polishing processing, reamer processing processing, plating processing, vapor deposition processing, abrasive spraying processing, and the like. It is the surface that was made. Specifically, for example, the mirror surface 160k can be easily formed on the inner surface of the liquid chamber 160 by performing the above-described various processes on the cylindrical liquid chamber 160 having a rough inner surface.
- the mirror surface 160k of the liquid chamber 160 has a reflectance of a specified value or more with respect to the pulsed laser light irradiated by the laser light irradiation unit.
- the reflectance above the specified value is a reflectance that allows the mirror surface 160k to reflect the pulsed laser light emitted from the laser light irradiation unit 21 and guide it to the end 160a of the cylindrical liquid chamber 160.
- the jet flow generating device 100 includes the liquid chamber 160 having the mirror surface 160k having a reflectivity equal to or higher than a specified value. Therefore, the jet flow generating device 100 reflects the pulsed laser light emitted from the laser light irradiation unit 21 to generate the cylindrical liquid chamber 160. It can be easily guided to the end 160a.
- the cylindrical liquid chamber 160 is preferably a cylindrical member.
- the liquid chamber 160 of the cylindrical member has a high propagation efficiency with respect to the pulsed laser light as compared with a liquid chamber having a polygonal cylinder shape such as a triangular cylinder shape or a square cylinder shape.
- the bubble G in the liquid chamber 160 of the cylindrical member expands and becomes a relatively large distance from the front end portion of the optical fiber 22 to the boundary surface FG of the gas G of the bubble G which is the liquid F and gas.
- the material for forming the cylindrical liquid chamber 160 of the jet flow generating device 100 is a metal such as stainless steel, titanium, gold, platinum, silver, copper, or aluminum, or Ceramics etc. can be mentioned.
- a forming material of the liquid chamber 160 any one of the above materials or a combination of two or more kinds may be used.
- the jet generating device 100 having pressure resistance against the pressure in the liquid chamber 160 is provided even when the bubble G is generated, the bubble is expanded, and the liquid is jetted. be able to.
- the mirror surface 160k can be easily formed on the inner surface of the liquid chamber 160.
- the jet generating device 100 is a supply unit that supplies the liquid F into the liquid chamber 160 via the liquid supply path 140 in synchronization with the irradiation of the pulsed laser light by the laser light irradiation unit 21.
- the liquid feeding device 1 is provided.
- the liquid feeding device 1 replenishes the liquid F so that the liquid chamber 160 is filled with the liquid F immediately before laser light irradiation. Specifically, after the bubble G is generated by laser pulse light irradiation, when the intensity of the laser pulse light becomes zero, the bubble G contracts and disappears.
- the liquid F is replenished from the liquid delivery device 1 when the laser beam is not irradiated.
- the distance SD between the end 160a of the liquid chamber 160 and the tip of the optical fiber 22 is relatively long, and a sufficient amount of water for one pulse is ensured. Tj can be increased. Further, for example, by supplying an amount of the liquid F corresponding to one pulse of the liquid F from the liquid feeding device 1 only when the laser beam is not irradiated, a pulsed jet can be stably ejected from the nozzle 165. In addition, when the liquid F flows backward from the nozzle 165 into the cylindrical liquid chamber 160, the liquid feeding device 1 preferably controls the flow rate of the liquid F according to the amount of the backward flow.
- the means for guiding the pulse laser beam from the laser device 2 into the liquid chamber 160 is the optical fiber 22.
- the optical fiber 22 By using the optical fiber 22, the pulsed laser light emitted from the laser device 2 can be guided into the liquid chamber 160 with high efficiency. Further, when the jet generating device 100 is applied to a surgical instrument, the operability of the Y connector 120 is good by using the flexible optical fiber 22.
- the jet generating apparatus 100 changes the pulse energy, the pulse width, and the pulse repetition frequency of the pulsed laser light by the laser light irradiation unit 21, and the amount of the jet and the flow velocity of the jet.
- a control device 4 as a control unit that variably controls any one or a combination or all of the jet repetition frequencies. Therefore, the control device 4 performs control to change the pulse energy, the pulse width, and the pulse repetition frequency of the pulsed laser light emitted from the laser device 2, so that the desired amount of the jet flow and the desired amount of the jet flow from the nozzle 165 can be obtained. And a desired jet repetition frequency.
- examples of the liquid F used in the jet flow generating device 100 according to the embodiment of the present invention include water, physiological saline, electrolyte infusion, and the like.
- the pulse laser light of that wavelength is liquid such as water, physiological saline, electrolyte infusion, etc. Easily absorbed by F.
- generation apparatus 100 it is preferable to use the said liquid F.
- the liquid F used in the jet generating device 100 is not limited to water, physiological saline, electrolyte infusion, or the like, and a desired liquid F depending on the use of the jet generating device 100. Can be adopted.
- the jet generating device 100 when the jet generating device 100 according to the embodiment of the present invention is employed as a surgical instrument, incision / crushing of in vivo calculus / hard tissue may be performed using the jet from the nozzle 165.
- the jet generating device 100 is capable of jetting a jet with a relatively high speed during an operation such as incision or crushing of a relatively hard calculus or hard tissue, and an optimum jet flow rate, jet flow velocity, jet flow as necessary.
- the repetition frequency can be set. For this reason, by using the jet generating device 100, it is possible to perform operations such as incision and crushing of in vivo calculus and hard tissue with high efficiency.
- the jet flow generating device 100 when the jet flow generating device 100 according to the embodiment of the present invention is employed as a surgical instrument, incision / crushing of a living tissue may be performed by a jet flow from a nozzle 165.
- the jet generating device 100 can be set to an optimal jet flow rate, jet flow velocity, jet repetition frequency, and the like as necessary during operations such as incision and crushing of relatively soft biological tissue. For this reason, by using the jet flow generating device 100, a surgical operation such as incision and crushing of a living tissue can be performed with high efficiency.
- the jet flow generation device 100 when the jet flow generation device 100 according to the embodiment of the present invention is employed as a surgical instrument, surgery such as crushing a thrombus that has been embolized in a blood vessel using a jet flow from the nozzle 165 may be performed.
- surgery such as crushing a thrombus that has been embolized in a blood vessel using a jet flow from the nozzle 165 may be performed.
- a cylindrical liquid chamber 160 metal tubule having a diameter smaller than that of the blood vessel, the metal tubule is inserted into the blood vessel, and the optimum jet flow rate, jet flow velocity, and repetition of the jet flow.
- an operation such as a thrombus embolized in a blood vessel can be easily performed.
- the propagation range of the pressure wave in the living body can be limited by intermittently generating the jet, and to the distal part The pressure damage can be prevented and the safety is enhanced.
- the differentiation of the incision / crushing effect by the liquid jet using the elastic difference of the living tissue is controlled at a fine level, and the crushing region and the preservation region are separated. It can be finely controlled, and can perform incision, crushing, and preservation of complex shapes that do not depend on the skill of the operator.
- the jet generating device 100 includes the adjusting unit 170 (adjusting means) and the like, before or during irradiation of the pulse laser beam by the laser beam irradiation unit 21.
- the distance between the nozzle 165 and the laser beam irradiation unit 21 is adjusted by the adjustment unit 170 (adjustment unit). For this reason, by adjusting the distance by the adjusting unit 170 before or during irradiation with the pulse laser beam, the jet flow having a desired jet velocity, a desired pulse width, and a desired jet energy is satisfied while satisfying the conditions A and B. It can be easily generated.
- the adjustment unit 170 (adjustment means) is not limited to the structure described above. Further, the rotation stopping member 179 is not limited to the structure described above. Any structure having each function may be used.
- the adjustment unit 170 (adjustment means) may be configured to manually adjust the distance between the nozzle 165 and the laser light irradiation unit 21.
- the jet generating device 100 of the present embodiment includes the one-hole nozzle 165 opened at the end 160a of the cylindrical liquid chamber 160 (metal tube), but is not limited to this configuration.
- the nozzle 165 may be provided in the vicinity of the end of the liquid chamber 160, in the axial center of the liquid chamber 160, in the vicinity of the axial center of the liquid chamber 160, and the like.
- the nozzle 165 may be a single hole or a plurality of holes.
- the jet flow generating device 100 is preferably configured so that the liquid F flows in the nozzle direction and does not flow backward in the fluid supply direction by the bubbles G generated in the cylindrical liquid chamber 160.
- the flow resistance defined by the inner diameter Pz of the cylindrical liquid chamber 160, the diameter Az of the optical fiber, and the length AL (optical fiber insertion length) of the optical fiber 22 in the cylindrical liquid chamber 160 is determined by the injection nozzle parameter (
- the jet flow generating device 100 is configured to be sufficiently larger than the flow resistance defined by the diameter Nz of the nozzle 165 and the axial length NL of the nozzle 165 having the diameter Nz. By doing so, the push-back (back flow) of the liquid F to the optical fiber side can be made extremely small.
- a jet generating device for generating a liquid jet A cylindrical liquid chamber; A nozzle that opens an end of the liquid chamber and ejects the liquid in the liquid chamber to the outside; A liquid supply path for supplying a liquid into the liquid chamber; A laser beam irradiation unit that irradiates the liquid chamber with pulsed laser light and vaporizes the liquid in the liquid chamber; It has a laser oscillator that controls laser light intensity and laser light pulse width independently, The inner surface of the liquid chamber has a mirror surface that reflects the pulse laser beam emitted from the laser beam irradiation unit and guides it to the end portion, An apparatus for generating a jet flow comprising adjusting means for adjusting a distance between the nozzle and the laser beam irradiation unit.
- Appendix 3 The jet generating device according to appendix 1 or 2, wherein the mirror surface is a surface processed by at least one of electrolytic polishing, reaming, plating, vapor deposition, and abrasive spraying.
- Appendix 4 Any one of appendixes 1 to 3, wherein the inner surface of the liquid chamber is formed with a mirror surface over at least a variable range of a tip portion of the laser beam irradiation unit that emits a pulsed laser beam. The jet generating device described.
- the jet generating device according to any one of appendices 1 to 7, wherein a material for forming the cylindrical liquid chamber is a metal such as stainless steel, titanium, gold, silver, or ceramics.
- a material for forming the cylindrical liquid chamber is a metal such as stainless steel, titanium, gold, silver, or ceramics.
- the liquid is supplied into the liquid chamber through the liquid supply path in synchronization with the irradiation of the pulse laser light by the laser light irradiation unit, and the liquid chamber is filled with the liquid immediately before the pulse laser light irradiation.
- the jet generating device according to any one of appendices 1 to 8, further comprising a supply unit (liquid feeding device).
- a supply unit liquid feeding device.
- the jet generating device according to any one of appendices 1 to 9, wherein the means for guiding the pulsed laser light into the liquid chamber is an optical fiber.
- [Appendix 11] Control for changing the pulse energy, pulse width, and pulse repetition frequency of the pulse laser beam by the laser beam irradiation unit, and variably controlling any one or a combination or all of the jet flow velocity, jet flow velocity, jet repetition frequency.
- the liquid is water, physiological saline, or electrolyte infusion,
- Laser oscillator laser device
- the jet generating apparatus according to any one of appendices 1 to 12, wherein incision and crushing of calculus and hard tissue in a living body are performed using a jet from the nozzle.
- Appendix 14 14.
- Appendix 15 15.
- the adjusting means has a structure capable of adjusting a distance between a portion communicating with the liquid chamber (small-diameter cylindrical portion) and a cylindrical portion holding the optical fiber (large-diameter cylindrical portion).
- the jet generating device according to any one of 1 to 15.
- the adjusting means includes a rotation preventing member that prevents relative rotation between a portion communicating with the liquid chamber (small diameter cylindrical portion) and a cylindrical portion holding the optical fiber (large diameter cylindrical portion).
- the jet generating apparatus according to appendix 16.
- a jet generating method of a jet generating device for generating a liquid jet includes a cylindrical liquid chamber, A nozzle that opens an end of the liquid chamber and ejects the liquid in the liquid chamber to the outside; A liquid supply path for supplying a liquid into the liquid chamber; A laser beam irradiation unit that irradiates the liquid chamber with pulsed laser light and vaporizes the liquid in the liquid chamber; It has a laser oscillator that controls laser light intensity and laser light pulse width independently, The inner surface of the liquid chamber has a mirror surface that reflects the pulse laser beam emitted from the laser beam irradiation unit and guides it to the end portion, An adjusting means for adjusting a distance between the nozzle and the laser beam irradiation unit; The jet generating method of a jet generating device, wherein the distance between the nozzle and the laser light irradiation unit is adjusted by the adjusting means before or during irradiation of the pulsed laser light by the laser light
Abstract
Description
医療現場では、複雑に絡み合う生体組織の任意の部位や疾患部分のみを簡単に切り分けることができる手術用器具の開発が期待されており、液体噴流を用いたジェットメスは、生体組織の弾性特性の差異を利用して生体組織の破砕と温存を仕分けることが特徴として考えられ、手術用器具として非常に期待されている。
例えば、図10(a)に示した噴流生成装置100Bでは、筒状の液体室B160の内面が粗面B160rに形成されている。光ファイバー22の先端部のレーザー光照射部21から液体室B160内の液体Fにパルスレーザー光を照射した場合、その先端部の近傍領域の液体Fが加熱され、図10(b)に示したように、その先端部の近傍領域で気泡Gが発生し、液体FがノズルB165から押し出される。更に、レーザー光の照射を続けた場合、図10(c)に示したように、気泡Gが膨張し、それに伴いノズルB165から液体Fが噴射される。光ファイバー22の先端部のレーザー光照射部21から出射した光のうち、液体室B160の内面の粗面B160rに照射された光は、粗面B160rで散乱・吸収されやすい。気泡Gの境界面FGに到達するレーザー光のエネルギーは小さい。
つまり、内面に粗面が形成されている細管を液体室B160として用いた場合、光のエネルギーの損失により、最大20mm程度の長さの膨張ガス(気泡G)が発生し、液体室B160の端部160aに形成された開口形状のノズル165(B165)から液体Fが噴射される。
しかしながら、レーザー光のパルス幅やパルスエネルギーを増大させたとしても、膨張ガス(気泡G)の長さG1の最大値は僅かに大きくなる程度である。詳細には、光ファイバー22の先端部から出射した光が液体室B160の内面の粗面で散乱・吸収されやすいので、粗面による反射光の強度が小さい。光ファイバー22の先端部から液体Fと気体である気泡Gの境界面FGに到達する光のエネルギーは、光ファイバーの先端部と境界面FG間の距離が大きいほど、小さくなる。
液体Fのパルスレーザー光吸収による気化膨張により噴流が生成されるが、注入するパルスエネルギーの上昇、パルス幅の伸張により、膨張気体(気泡G)の容積は増大し、液体室B160が細径円筒状等である場合、光ファイバー22の先端部と境界面FG(気液界面)の距離が増大し、注入されたレーザー光は効率良く液体Fに吸収できなくなる。即ち、気液界面と光ファイバー22の先端部の間の距離が短い状態(気液界面と光ファイバー22の先端部が接近した状態)では、注入されたレーザー光は直接、気液界面に照射され吸収されるが、気液界面と光ファイバー22の先端部の間の距離の増大と共に、光ファイバー22の先端部から出射されたレーザー光は液体室B160の内面に照射され散乱・吸収を受けて減衰する。液体Fの気化に作用する光エネルギー量が低下するため、噴流強度が低下する。
上記条件A,条件Bを満たしながら、レーザー照射条件としてパルスエネルギーE0、パルス幅Tlを可変とするためには、距離L1を可変とすることを要する。
また、一般的なパルスジェットメス(手術用器具)では、疾患部分の破砕を行うために、同じ切断能力で短時間のメスとして数回に分けて実施するしかなかった。
このため、温存させる生体組織へのダメージを低減することができる手術用器具が望まれている。詳細には、噴流の速度(初速)だけでなく、噴流の持続時間を調整して噴流の破砕力を微細に制御可能な手術用器具が望まれている。
液体の噴流を生成する噴流生成装置であって、
筒状の液体室と、
前記液体室の端部を開口して該液体室内の液体を外部に噴射するノズルと、
前記液体室内に液体を供給する液体供給路と、
前記液体室内にパルスレーザー光を照射して、該液体室内の液体を気化させるレーザー光照射部と、
レーザー光強度とレーザー光パルス幅を独立に制御するレーザー発振器とを備え、
前記液体室の内面は、前記レーザー光照射部から出射したパルスレーザー光を反射して前記端部に導く鏡面を有し、
前記ノズルと前記レーザー光照射部までの間の距離を調整する調整手段を備えることを特徴とする。
液体の噴流を生成する噴流生成装置の噴流生成方法であって、
噴流生成装置は、筒状の液体室と、
前記液体室の端部を開口して該液体室内の液体を外部に噴射するノズルと、
前記液体室内に液体を供給する液体供給路と、
前記液体室内にパルスレーザー光を照射して、該液体室内の液体を気化させるレーザー光照射部と、
レーザー光強度とレーザー光パルス幅を独立に制御するレーザー発振器とを備え、
前記液体室の内面は、前記レーザー光照射部から出射したパルスレーザー光を反射して前記端部に導く鏡面を有し、
前記ノズルと前記レーザー光照射部までの間の距離を調整する調整手段を備え、
前記レーザー光照射部による前記パルスレーザー光の照射前または照射時に、前記調整手段により前記ノズルと前記レーザー光照射部までの間の距離を調整することを特徴とする。
また、本発明によれば、簡単な構成で、高効率で液体の噴流を生成する噴流生成装置を提供することができる。
また、本発明によれば、簡単な構成で、噴流の流速やエネルギーを可変とすることができる噴流生成装置を提供することができる。
また、本発明によれば、簡単な構成で、噴流時間を容易に調整可能な噴流生成装置を提供することができる。
また、本発明によれば、噴流生成装置を手術装置として用いた場合、噴流を間欠的に生成することにより、生体内での圧力波の伝播範囲を限局することができ、安全性が高まる。
また、本発明によれば、噴流生成装置を手術装置として用いた場合、生体組織の弾性差を利用した液体噴流による切開・破砕効果の差別化を微細なレベルでコントロールして破砕領域と温存領域を微細に区別して手術を行うことができ、術者の技量に依存しない、複雑形状の切開・破砕・温存などを行うことができる噴流生成装置を提供することができる。
また、本発明によれば、噴流生成装置の噴流生成方法を提供することができる。
本発明の実施形態に係る噴流生成装置は、液体室(膨張室)内の液体をパルスレーザー光で加熱して、気化・膨張を誘発し、気化膨張圧力を利用して間欠液体噴流(パルスジェット)を生成する。
断面積S、長さL、密度ρ、速度V0で射出されたパルスジェットが生体組織に衝突する際に作用する撃力F0は液体の形状変形による効果を無視すると、単位時間に衝突する液体の運動量の変化量に等しい(数式(1)参照)。
よって、破砕効果を微細に制御するためには作用する力と時間を制御すればよく、詳細には、初速と作用時間を独立に制御するとよい。破砕効果を微細に制御するためには独立した2個のパラメータで制御する事が有利である。
V0(初速)とT0(ジェットの持続時間)を独立に制御するためには加熱源となるレーザーの出力P0とレーザーのパルス幅Tlを制御すれば良い。
しかしながら、液体室(膨張室)の形態によって、レーザー光の液体への伝達効率が変化する場合、V0,T0/P0,Tlがリニアに作用しない。伝達効率が変化する要因は光ファイバーから出射されたレーザー光が液体に達する前に膨張室内面で吸収される事による。
また、P0或いはTlが大きくなった場合、膨張した高温の気化ガスがノズルから射出する危険があるため、膨張室体積を拡大する目的で光ファイバーのレーザー光の出射部分をノズルから遠ざける必要がある。
本発明の実施形態に係る噴流生成装置は、P0、Tlを可変して、V0、T0を可変し、微細に破砕効果を制御するために、光ファイバーのレーザー光の出射部分とノズルとの間隔を可変にし、更に液体室(膨張室)内面でのレーザー光吸収を抑制するために内面に反射構造を有する。
本発明の実施形態は図示の内容を含むが、これのみに限定されるものではない。なお、以後の各図の説明で、既に説明した部位と共通する部分は同一符号を付して重複説明を一部省略する。
また、制御装置4(制御部)は、調整部170(調整手段)を制御することにより、光ファイバー22の先端部に設けられたレーザー光照射部21とノズルまでの間の距離を調整する処理を行う。具体的には、例えば、調整部170はモータなどの駆動装置を備え、制御装置4は調整部170の駆動装置を駆動することにより、レーザー光照射部21とノズルまでの間の距離を調整する処理を行うように構成されていてもよい。この場合、制御装置4(制御部)は、レーザー光照射部21から出射されるパルスレーザー光のパルス幅、パルスエネルギー、パルス繰り返し周波数などに応じて、調整部170によりレーザー光照射部21とノズルまでの間の距離を調整する処理を行う。この制御装置4は、記憶部に記憶された設定情報に基づいて、上記処理を行ってもよい。また、ノズルから出力される噴流の流速やエネルギーなどを検出する検出部を設け、制御装置4は検出部からの検出信号に基づいて、上記調整部170に関する制御を行ってもよい。
図3は本発明の実施形態に係る噴流生成装置の動作の一例を示す図である。図3(a)はパルスレーザー光照射前、図3(b)はパルスレーザー光照射初期時(気泡発生初期時)、図3(c)はパルスレーザー光照射且つ気泡膨張時、図3(d)はパルスレーザー光非照射時の状態をそれぞれ示す図である。図4は噴流生成装置によるパルスレーザー光強度と流体噴流初速度の一例を示す図である。詳細には、図4(a)はパルスレーザー光強度と流体噴流初速度の一例を示す図、図4(b)はレーザー光強度と液体噴流の時間変化の一例を示す図である。図4(a)において、縦軸にレーザー光の強度I(w)を示し、横軸に時間T(s)を示す。図4(b)において、縦軸に液体噴流速度(液体噴流初速度)V0(m/s)を示す。
また、液体室160の内面を鏡面160kにすることで、任意のレーザー光を気液界面に一定して連続に到達させることができるので、安定した任意の気化ジェットKJを連続して噴出させることができる。
また、液体室160の内面を鏡面160kにすることで、光ファイバー出射端からノズルまでの距離L1が大きい場合であっても、長時間大きな強度のパルス液体噴流を噴流することができる。
図6、図7に示した例では、調整部170は、小径筒状部172と、光ファイバー保持部材としての大径筒状部171と、などを有する。小径筒状部172は、液体室160に連通した構造となっている。小径筒状部172の外周側には大径筒状部171が配置されている。この小径筒状部172と大径筒状部171は、例えば螺合部172a,171aにより係合するように構成されている。
大径筒状部171の端部には、光ファイバー22が挿入される開口部が形成され、その開口部には、Oリングなどの封止部材176が設けられており、液体Fの流出を防止している。本実施形態では、その開口部に溝部が形成されており、溝部に封止部材176が配置されている。この封止部材176は光ファイバー22に対して密着して略固定された状態となっている。
小径筒状部172と大径筒状部171との間には、Oリングなどの封止部材175が設けられており、液体Fの流出を防止している。本実施形態では、大径筒状部171の内周面に溝部が形成されており、その溝部に封止部材175が配置されている。小径筒状部172と大径筒状部171とが軸方向に相対的に移動する場合、Oリングなどの封止部材175は、小径筒状部172の外周面を摺動するように構成されている。尚、小径筒状部172の端部に溝部を設け、その溝部にOリングなどの封止部材175を設けた構造であってもよい。
本発明の実施形態に係る噴流生成装置100は、調整部170(調整手段)が、上記条件A,条件Bを満たしながら、レーザー照射条件としてパルスエネルギーE0、パルス幅Tlを可変とするように、L1を調整することができる。
尚、W1を考慮すると、ノズル165とレーザー光照射部21までの間の距離の可変範囲は、ノズル165とレーザー光照射部21までの間の距離L1から、W1とG1の最小範囲を除いた範囲であることが好ましい。
詳細には、本発明の実施形態に係る噴流生成装置100は、液体室160の内面に鏡面160kが形成され、レーザー光照射部21とノズル165との間の距離を調整する調整部170を備えている。このため、レーザー光照射部21からパルス幅の大きいレーザー光を出射するように設定し、且つ、レーザー光照射部21とノズル165との間の距離を長く設定した場合であっても、液体室160の内面での光吸収が非常に小さいので、パルスレーザー光を液体室160の鏡面160kで反射させて、筒状の液体室160の端部160aに形成されたノズル165側に導くことができ、気泡Gを大きく膨張させることで、液体噴流の持続時間を比較的長くすることができる。
つまり、本発明の実施形態に係る噴流生成装置100は、液体室160の内面を鏡面160kとし、レーザー光照射部21から出射するパルスレーザー光のパルス幅に応じて、調整部170によりレーザー光照射部21とノズル165との間の距離を可変とすることで、ノズルから出射する液体噴流の持続時間の長短を制御することができる。
詳細には、パルス液体噴流を用いた手術用器具(パルスジェットメス)は、生体組織の弾性特性の差異を利用して、生体組織の破砕と温存を仕分ける。
具体的には、ノズルの断面積(液体噴流の断面積)を一定とした場合、液体噴流の速度(初速)は液体噴流の力に比例する。よって、液体噴流の速度(初速)と液体噴流の持続時間の積は力積に比例する。このため、液体噴流の破砕力(撃力)は液体噴流の速度(初速)と持続時間の積に比例する。
パルスジェットメスにおける液体噴流による生体組織への破砕力を微細に制御して、生体組織の破砕と温存の境界条件を探すためには、液体噴流の速度(初速)と液体噴流の持続時間とを可変制御することが非常に重要である。本発明に係る噴流生成装置100は、上述したように、液体室160の内面に鏡面160kを有し、レーザー光照射部21とノズル165との間の距離を調整する調整部170を備え、上記距離の調整とパルスレーザー光の強度およびパルス幅の調整により、液体噴流の速度(初速)と持続時間とを独立に制御可能であり、パルスジェットメスなどに非常に有用である。
血栓などの破砕手術では、レーザー光照射部21から短時間、小さい強度のパルスレーザー光を出力して、一定時間、弱い噴流圧の噴流を部位にあてることで、温存部分へのダメージの小さい施術を行うことができる。
図9に示した例では、調整部170は、液体室160に連通する小径筒状部172と、光ファイバー22を保持する筒状部178と、回転部材177と、回転止め部材179と、などを有する。
小径筒状部172および筒状部178の外周側には、筒形状の回転部材177が配置されている。回転部材177と小径筒状部172は、螺合部177a,172aにより係合するように構成され、回転部材177と筒状部178は、螺合部177b,178bにより係合するように構成されている。螺合部177a,172aと、螺合部177b,178bは互いに逆ネジの関係となるように構成されている。
回転部材177と小径筒状部172との間には、一つまたは複数のOリングなどの封止部材175が設けられ、回転部材177と筒状部178との間には、一つまたは複数のOリングなどの封止部材174が設けられており、液体Fの流出を防止している。
小径筒状部172に対する回転部材177の回転角度は、小径筒状部172と筒状部178とが近づく方向または離れる方向への移動距離、つまり、光ファイバー22の先端部に設けられたレーザー光照射部21の移動距離に対応している。
この目盛りを設けたことにより、回転部材177の回転角度から、光ファイバー22の先端部に設けられたレーザー光照射部21の移動距離を定量的に容易に認識することができる。
このように、液体室160の内面を鏡面160kにすることで、レーザー光を気液界面に一定して連続に到達させることができるので、長時間、安定した気化ジェットKJを噴出させることができる。また、調整部170(調整手段)により、光ファイバー22の先端部に設けられたレーザー光照射部21からノズル165までの距離L1を任意に設定することが可能となり、生体組織の個体差や部位別(臓器別、臓器の位置など)による弾性差や疾患部位の病理の進行状況などによる弾性差に、最適な噴流強度のパルス液体噴流を用いた手術装置(パルスジェットメス)を提供することができる。
本発明の実施形態では、調整部170(調整手段)は、条件A,条件Bを満たしながら、距離L1を調整することで、レーザー照射条件としてパルスエネルギーE0、パルス幅Tlを所望の値に設定することができる。
また、上述の各図で示した実施形態は、その目的及び構成等に特に矛盾や問題がない限り、互いの記載内容を組み合わせることが可能である。
また、各図の記載内容はそれぞれ独立した実施形態になり得るものであり、本発明の実施形態は各図を組み合わせた一つの実施形態に限定されるものではない。
[付記1]
液体の噴流を生成する噴流生成装置であって、
筒状の液体室と、
前記液体室の端部を開口して該液体室内の液体を外部に噴射するノズルと、
前記液体室内に液体を供給する液体供給路と、
前記液体室内にパルスレーザー光を照射して、該液体室内の液体を気化させるレーザー光照射部と、
レーザー光強度とレーザー光パルス幅を独立に制御するレーザー発振器とを備え、
前記液体室の内面は、前記レーザー光照射部から出射したパルスレーザー光を反射して前記端部に導く鏡面を有し、
前記ノズルと前記レーザー光照射部までの間の距離を調整する調整手段を備えることを特徴とする
噴流生成装置。
[付記2]
前記調整手段は、レーザー光照射部から出射されるパルスレーザー光のパルス幅に応じて、前記距離を調整することを特徴とする付記1に記載の噴流生成装置。
[付記3]
前記鏡面は、少なくとも、電解研磨処理、リーマ加工処理、メッキ処理、蒸着処理、研磨剤吹き付け処理のいずれかによって処理された面であることを特徴とする付記1または2記載の噴流生成装置。
[付記4]
前記液体室の内面は、少なくともパルスレーザー光を出射する、前記レーザー光照射部の先端部の可変範囲に亘って、前記鏡面が形成されていることを特徴とする付記1から3のいずれかに記載の噴流生成装置。
[付記5]
前記液体室内の前記液体は、前記レーザー光照射部から照射されるパルスレーザー光に対してエネルギー吸収性を有することを特徴とする付記1から4のいずれかに記載の噴流生成装置。
[付記6]
前記液体室の鏡面は、前記レーザー光照射部により照射されるパルスレーザー光に関して、規定値以上の反射率であることを特徴とする付記1から5のいずれかに記載の噴流生成装置。
[付記7]
前記液体室は、円筒部材であることを特徴とする付記1から6のいずれかに記載の噴流生成装置。
[付記8]
前記筒状の液体室の形成材料は、ステンレス、チタン、金、銀などの金属、または、セラミックスであることを特徴とする付記1から7のいずれかに記載の噴流生成装置。
[付記9]
前記レーザー光照射部によるパルスレーザー光の照射に同期して前記液体室内に液体を前記液体供給路を介して供給し、パルスレーザー光照射直前には前記液体室内に液体で満たされた状態とする供給部(送液装置)を有することを特徴とする付記1から8のいずれかに記載の噴流生成装置。
[付記10]
前記パルスレーザー光を前記液体室内に誘導する手段は、光ファイバーであることを特徴とする付記1から9のいずれかに記載の噴流生成装置。
[付記11]
前記レーザー光照射部によるパルスレーザー光のパルスエネルギー・パルス幅・パルス繰り返し周波数を変化させ、噴流の量、噴流の流速、噴流の繰り返し周波数のいずれか又はそれらの組、又は全てを可変制御する制御部を有することを特徴とする付記1から10のいずれかに記載の噴流生成装置。
[付記12]
前記液体は、水、生理食塩水、又は電解質輸液であり、
前記パルスレーザー光としてホルミウムヤグレーザー(波長2.1μm)を生成するレーザー発振器(レーザー装置)を有することを特徴とする付記1から11のいずれかに記載の噴流生成装置。
[付記13]
前記ノズルからの噴流を用いて生体内の結石・硬組織の切開・破砕を行うことを特徴とする付記1から12のいずれかに記載の噴流生成装置。
[付記14]
前記ノズルからの噴流を用いて生体組織の切開・破砕を行うことを特徴とする付記1から13のいずれかに記載の噴流生成装置。
[付記15]
前記ノズルからの噴流を用いて血管内に塞栓した血栓を破砕することを特徴とする付記1から14のいずれかに記載の噴流生成装置。
[付記16]
前記調整手段は、液体室に連通する部分(小径筒状部)と光ファイバーを保持する筒状部(大径筒状部)との距離を調整可能な構造となっていることを特徴とする付記1から15の何れかに記載の噴流生成装置。
[付記17]
前記調整手段は、液体室に連通する部分(小径筒状部)と光ファイバーを保持する筒状部(大径筒状部)との相対的な回転を防止する回転止め部材を有することを特徴とする付記16に記載の噴流生成装置。
[付記18]
液体の噴流を生成する噴流生成装置の噴流生成方法であって、
噴流生成装置は、筒状の液体室と、
前記液体室の端部を開口して該液体室内の液体を外部に噴射するノズルと、
前記液体室内に液体を供給する液体供給路と、
前記液体室内にパルスレーザー光を照射して、該液体室内の液体を気化させるレーザー光照射部と、
レーザー光強度とレーザー光パルス幅を独立に制御するレーザー発振器とを備え、
前記液体室の内面は、前記レーザー光照射部から出射したパルスレーザー光を反射して前記端部に導く鏡面を有し、
前記ノズルと前記レーザー光照射部までの間の距離を調整する調整手段を備え、
前記レーザー光照射部による前記パルスレーザー光の照射前または照射時に、前記調整手段により前記ノズルと前記レーザー光照射部までの間の距離を調整することを特徴とする
噴流生成装置の噴流生成方法。
2 レーザー装置(レーザー発振器)
3 吸引装置
4 制御装置(制御部)
100 噴流生成装置
120 Yコネクター(把持部材)
140 液体供給路
160 液体室(金属円筒部材)
165 ノズル
170 調整部(調整手段)
171 大径筒状部(光ファイバー保持部材)
177 回転部材
178 筒状部(光ファイバー保持部材)
179 回転止め部材
180 吸引用流路
Claims (4)
- 液体の噴流を生成する噴流生成装置であって、
筒状の液体室と、
前記液体室の端部を開口して該液体室内の液体を外部に噴射するノズルと、
前記液体室内に液体を供給する液体供給路と、
前記液体室内にパルスレーザー光を照射して、該液体室内の液体を気化させるレーザー光照射部と、
レーザー光強度とレーザー光パルス幅を独立に制御するレーザー発振器とを備え、
前記液体室の内面は、前記レーザー光照射部から出射したパルスレーザー光を反射して前記端部に導く鏡面を有し、
前記ノズルと前記レーザー光照射部までの間の距離を調整する調整手段を備えることを特徴とする
噴流生成装置。 - 前記調整手段は、レーザー光照射部から出射されるパルスレーザー光のパルス幅に応じて、前記距離を調整することを特徴とする請求項1に記載の噴流生成装置。
- 前記鏡面は、少なくとも、電解研磨処理、リーマ加工処理、メッキ処理、蒸着処理、研磨剤吹き付け処理のいずれかによって処理された面であることを特徴とする請求項1または2記載の噴流生成装置。
- 液体の噴流を生成する噴流生成装置の噴流生成方法であって、
噴流生成装置は、筒状の液体室と、
前記液体室の端部を開口して該液体室内の液体を外部に噴射するノズルと、
前記液体室内に液体を供給する液体供給路と、
前記液体室内にパルスレーザー光を照射して、該液体室内の液体を気化させるレーザー光照射部と、
レーザー光強度とレーザー光パルス幅を独立に制御するレーザー発振器とを備え、
前記液体室の内面は、前記レーザー光照射部から出射したパルスレーザー光を反射して前記端部に導く鏡面を有し、
前記ノズルと前記レーザー光照射部までの間の距離を調整する調整手段を備え、
前記レーザー光照射部による前記パルスレーザー光の照射前または照射時に、前記調整手段により前記ノズルと前記レーザー光照射部までの間の距離を調整することを特徴とする
噴流生成装置の噴流生成方法。
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WO2017126676A1 (ja) * | 2016-01-21 | 2017-07-27 | 国立大学法人東北大学 | 薬剤噴流生成装置、及び薬剤噴流生成装置の薬剤噴流生成方法 |
WO2018193701A1 (ja) * | 2017-04-17 | 2018-10-25 | 学校法人東京電機大学 | 液体噴射装置 |
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JP2003111766A (ja) * | 2001-10-03 | 2003-04-15 | Sparkling Photon Inc | 噴流生成装置 |
US20030139041A1 (en) * | 2002-01-18 | 2003-07-24 | Leclair Mark L. | Method and apparatus for the controlled formation of cavitation bubbles |
JP2005152094A (ja) * | 2003-11-21 | 2005-06-16 | Terumo Corp | カテーテル |
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WO2018193701A1 (ja) * | 2017-04-17 | 2018-10-25 | 学校法人東京電機大学 | 液体噴射装置 |
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