CN116019543A - Integrated medical equipment combining radio frequency ablation with internal heating needle soft tissue heating - Google Patents
Integrated medical equipment combining radio frequency ablation with internal heating needle soft tissue heating Download PDFInfo
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- CN116019543A CN116019543A CN202310102751.3A CN202310102751A CN116019543A CN 116019543 A CN116019543 A CN 116019543A CN 202310102751 A CN202310102751 A CN 202310102751A CN 116019543 A CN116019543 A CN 116019543A
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- 238000010438 heat treatment Methods 0.000 title claims abstract description 104
- 210000004872 soft tissue Anatomy 0.000 title claims abstract description 27
- 238000007674 radiofrequency ablation Methods 0.000 title claims abstract description 22
- 239000011159 matrix material Substances 0.000 claims abstract description 27
- 238000012544 monitoring process Methods 0.000 claims description 21
- 238000001514 detection method Methods 0.000 claims description 17
- 230000007935 neutral effect Effects 0.000 claims description 17
- 230000003321 amplification Effects 0.000 claims description 2
- 238000003199 nucleic acid amplification method Methods 0.000 claims description 2
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- 238000011282 treatment Methods 0.000 abstract description 22
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- 238000000034 method Methods 0.000 description 4
- 238000001467 acupuncture Methods 0.000 description 3
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- 208000008930 Low Back Pain Diseases 0.000 description 1
- 208000007101 Muscle Cramp Diseases 0.000 description 1
- BQCADISMDOOEFD-UHFFFAOYSA-N Silver Chemical compound [Ag] BQCADISMDOOEFD-UHFFFAOYSA-N 0.000 description 1
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Abstract
The application relates to an integrated medical device combining radio frequency ablation and internal heating needle soft tissue heating, which comprises a radio frequency electrode, an internal heating needle and a heating device, wherein the internal heating needle soft tissue heating device comprises a radio frequency electrode, a heating device and a heating device; the first control module is used for outputting a start signal or a close signal; the radio frequency module is connected with the first control module and used for outputting a radio frequency signal after receiving the starting signal and stopping outputting the radio frequency signal after receiving the closing signal; the internal heating pin heating module is connected with the first control module, and is used for outputting a heating signal after receiving a starting signal and stopping outputting the heating signal after receiving a closing signal; the relay/optocoupler switching matrix is respectively connected with the radio frequency module and the internal heating pin heating module, and is used for sending radio frequency signals to the radio frequency electrode after receiving the radio frequency signals and sending heating signals to the internal heating pin after receiving the heating signals. The application has the effect of improving the convenience and the flexibility of medical personnel treatment.
Description
Technical Field
The present application relates to the field of medical devices, and in particular, to an integrated medical device incorporating radio frequency ablation with internal hot needle soft tissue heating.
Background
Radiofrequency ablation (RFA) has been widely, safely and effectively used as a minimally invasive thermal ablation technique for the treatment of neurosurgery and pain. The radio frequency current of the radio frequency treatment equipment generates a high-density alternating current power line between a loop formed by the exposed end (RFA) of the radio frequency electrode and the neutral electrode (RFN), so that water molecules serving as polar molecules rotate at a high speed under the action of an alternating electric field, and generate heat by friction, the temperature of the exposed end of the electrode is increased, if the temperature is high enough, the tissue is coagulated, the biological activity is lost, and the treatment effect is achieved.
The traditional acupuncture treatment of nine needles is used from ancient times in China, and later, the acupuncture treatment of the injury is developed by using gold needles, silver needles, external heat needles and internal heat needles. The needling to ease pain and treat pain has been widely used in clinic and is spread throughout the world. The internal heat needle soft tissue treatment adopts advanced technology, the heating wire and the temperature measuring wire are wound in the medical stainless steel needle, and the heating of the needle body is dynamically controlled through the hardware of a microprocessor and the real-time algorithm software, so that the needle body can precisely heat and control the temperature in a human body. Not only maintains the essence of intensive acupuncture heat conduction therapy, but also avoids the clinical problems caused by traditional moxa heating. The therapy of the internal heat needle soft tissue treatment needs to strictly select an internal heat needle with proper specification for puncturing according to the surgical dissection of the soft tissue of a human body and the distribution rule of soft tissue pressure pain points, and the treatment temperature and the treatment time required by a patient are set, so that aseptic inflammation is eliminated, muscle spasm is loosened, local blood supply is increased, tissue repair and muscle cell regeneration are promoted, and soft tissue pain is relieved.
Currently, in the pain department, orthopedics department and rehabilitation department of hospitals, there are two very popular treatment modes for treating lumbago and skelalgia, soft tissue pain and other pains, one is a radio frequency ablation treatment mode and one is a hot needle heating treatment mode, so that the department generally has both radio frequency ablation equipment and internal heat needle soft tissue treatment equipment.
When medical staff treats patients, repeated movement of the two devices is often required, so that the problem that the medical staff is inconvenient in the process of treating the patients is caused.
Disclosure of Invention
In order to improve the convenience and flexibility of medical personnel treatment, the application provides integrated medical equipment combining radio frequency ablation with internal hot needle soft tissue heating.
An integrated medical device combining radio frequency ablation and internal heating needle soft tissue heating comprises a radio frequency electrode, an internal heating needle and a heating device;
the first control module is used for outputting a start signal or a close signal;
the radio frequency module is connected with the first control module and used for outputting radio frequency signals after receiving the starting signal and stopping outputting radio frequency signals after receiving the closing signal;
the internal heating needle heating module is connected with the first control module, and is used for outputting a heating signal after receiving a starting signal and stopping outputting the heating signal after receiving a closing signal;
the relay/optocoupler switching matrix is respectively connected with the radio frequency module and the internal heating pin heating module, and is used for sending radio frequency signals to the radio frequency electrode after receiving the radio frequency signals and sending heating signals to the internal heating pin after receiving the heating signals.
Through adopting above-mentioned technical scheme, after the first control module output start signal, radio frequency module and interior hot needle module simultaneous working uses radio frequency electrode or interior hot needle to treat for patient according to patient's needs of treatment to do not need the repeated removal treatment facility, can improve medical personnel's convenience and flexibility of treatment, simultaneously, concentrate radio frequency module and interior hot needle heating module on an equipment, can reduce hospital purchase cost, and then reduce patient treatment cost.
Optionally, the radio frequency module includes;
the radio frequency power supply unit is connected with the first control module, and is used for starting working after receiving the starting signal and outputting radio frequency power;
the radio frequency amplifying unit is connected with the radio frequency power supply unit and is used for receiving power and amplifying the power.
Optionally, the radio frequency module further includes;
the radio frequency protection unit is connected with the radio frequency amplifying unit, the second control module and the relay/optocoupler switching matrix respectively, and is used for detecting radio frequency power and transmitting radio frequency signals to the second control module and the relay/optocoupler switching matrix.
By adopting the technical scheme, the radio frequency protection unit can monitor the radio frequency power output by the black spliced power supply unit in real time, if the radio frequency power is abnormal, the radio frequency power can be automatically disconnected, and further the danger to the patient is avoided.
Optionally, further comprising;
the heating energy monitoring module is connected with the inner hot needle heating module respectively and used for monitoring the heating frequency of the inner hot needle heating module and outputting an energy monitoring signal, and the second control module is used for outputting a stop signal to the first control module after receiving the energy monitoring signal.
Optionally, further comprising;
the temperature detection module is respectively connected with the radio-frequency electrode, the internal heating needle and the first control unit, and is used for detecting the temperature of the radio-frequency electrode and/or the internal heating needle in real time and outputting a temperature signal; the first control module is used for sending the temperature signal to the second control module after receiving the temperature signal.
Optionally, further comprising;
the display module is connected with the second control module, the second control module is used for uploading the value reflected by the radio frequency signal and the value reflected by the energy monitoring signal to the display module, and the display module is used for visually displaying the value reflected by the radio frequency signal and the value reflected by the energy monitoring signal.
Optionally, the device further comprises a host, an internal heat needle port and a radio frequency electrode port, wherein the first control module, the second control module, the radio frequency module, the internal heat needle heating module and the relay/optocoupler switching matrix are all positioned in the host; the port of the internal heat needle is respectively connected with the internal heat needle and the relay/optocoupler switching matrix, and the port of the radio frequency electrode is respectively connected with the radio frequency electrode and the relay/optocoupler switching matrix.
Optionally, the host is further provided with a neutral electrode port and a neutral electrode, and the neutral electrode port is respectively connected with the neutral electrode and the relay/optocoupler switching matrix.
Alternatively, the rf electrode port may provide for use with an inner heat pin.
Optionally, the temperature detection module adopts time-sharing detection.
By adopting the technical scheme, the temperature detection module adopts time-sharing detection to reduce the volume of the host.
In summary, the present application includes at least one of the following beneficial technical effects:
1. after the first control module outputs the starting signal, the radio frequency module and the internal heating needle module work simultaneously, and the radio frequency electrode or the internal heating needle is used for treating the patient according to the treatment requirement of the patient, so that repeated moving treatment equipment is not needed, and the convenience and the flexibility of treatment of medical staff can be improved.
2. The internal heat needle is connected with the port of the internal heat needle, the radio frequency electrode is connected with the port of the radio frequency electrode, the disassembly of the internal heat needle and the radio frequency electrode is convenient, and the convenience and the flexibility of the medical staff in treatment are improved.
Drawings
Fig. 1 is a schematic overall structure of an embodiment of the present application.
Fig. 2 is a diagram of output circuitry according to an embodiment of the present application.
Fig. 3 is a system diagram of a power module according to an embodiment of the present application.
Reference numerals illustrate: 10. a host; 20. a radio frequency electrode port; 30. an internal heat needle port; 40. a radio frequency electrode; 50. an internal heat needle; 60. an output circuit; 61. a first control module; 62. a second control module; 63. a radio frequency module; 631. a radio frequency power supply unit; 632. a radio frequency amplifying unit; 633. a radio frequency protection unit; 64. an inner heating pin heating module; 65. a relay/optocoupler switching matrix; 66. a heating energy monitoring module; 70. a neutral electrode port; 80. a neutral electrode; 90. a temperature port; 100. a temperature detection module; 110. a power module; 120. a display module; 130. starting a key; 140. the key is turned off.
Detailed Description
The present application is described in further detail below in conjunction with figures 1-3.
The embodiment of the application discloses integrated medical equipment combining radio frequency ablation with internal hot needle soft tissue heating.
Referring to fig. 1, 2 and 3, an integrated medical device for rf ablation combined with heating of soft tissue by an inner heat needle includes a main body 10, an rf electrode port 20 mounted on the main body 10, an inner heat needle port 30 mounted on the main body 10, an rf electrode 40, an inner heat needle 50, an output circuit 60 connected to both the rf electrode port 20 and the inner heat needle section port, the output circuit 60 being located inside the main body 10.
In order to enable the single rf electrode 40 to be used, the host 10 is further provided with a neutral electrode port 70 and a neutral electrode 80, the neutral electrode port 70 is respectively connected with the neutral electrode 80 and the output circuit 60, and in the use process of the neutral electrode 80 and the single rf electrode 40, a high-density ac electric line is generated between the neutral electrode 80 and the rf electrode 40 through a loop formed by the output circuit 60, so that water molecules serving as polar molecules rotate at a high speed under the action of an alternating electric field, and rub against each other to generate heat, thereby raising the temperature of the exposed end of the electrode, and if the temperature is high enough, the tissue is coagulated, so that the biological activity is lost, and the therapeutic effect is achieved.
The number of the radio frequency electrode ports 20 is 4, the radio frequency electrode ports 20 can support a single radio frequency electrode 40 to be used, and the radio frequency electrode ports 20 can also support any two radio frequency electrodes 40 to be used, and the number of the internal heat needle ports 30 is 36. Because the rf electrode port 20 is 4Pin and the inner heat Pin port 30 is 6Pin, the inner heat Pin port 30 is only used by the inner heat Pin 50 during use, and the rf electrode port 20 is used by the rf electrode 40 and the inner heat Pin 50. It should be noted that when the rf electrode port 20 is used by the inner heat Pin 50, an adaptor wire is required to convert the 4Pin of the rf electrode port 20 into the 6Pin. In other embodiments, the number of rf electrode ports 20 is set according to the actual situation, and the number of inner heat pin ports 30 is also set according to the actual situation.
The host 10 is also provided with a start button 130 and a close button 140.
The output circuit 60 includes a first control module 61, a second control module 62, a radio frequency module 63, an inner hot pin heating module 64, a relay/optocoupler switching matrix 65, and a power module 110.
The power module 110 is connected to the first control module 61, the second control module 62, the radio frequency module 63, the inner heat pin heating module 64 and the relay/optocoupler switching matrix 65, and the power module 110 is configured to provide power to the first control module 61, the second control module 62, the radio frequency module 63, the inner heat pin heating module 64 and the relay/optocoupler switching matrix 65.
The start button 130 and the close button 140 are both connected to the second control module 62, the second control module 62 is configured to output a first control signal and a second control signal, when the start button 130 is turned on, the second control module 62 outputs the first control signal, and when the close button 140 is turned on, the second control module 62 outputs the second control signal. The first control module 61 is connected to the second control module 62, the first control module 61 is configured to output a start signal after receiving the first control signal, and the first control module 61 is configured to output a close signal after receiving the second control signal. The radio frequency module 63 and the inner hot needle heating module 64 are both connected with the first control module 61, the radio frequency module 63 outputs a radio frequency signal after receiving a start signal, the radio frequency module 63 stops outputting a radio frequency signal after receiving a close signal, the inner hot needle heating module 64 outputs an inner hot needle heating signal after receiving a start signal, and the inner hot needle heating module 64 stops outputting an inner hot needle heating signal after receiving a close signal.
The relay/optocoupler switching matrix 65 is respectively connected with the radio frequency module 63 and the internal heating pin heating module 64, the relay/optocoupler switching matrix 65 comprises a relay and an optocoupler, and when the relay/optocoupler switching matrix 65 receives a radio frequency signal, the relay is conducted, so that the radio frequency electrode 40 starts to work; when the relay/optocoupler switching matrix 65 receives the heating signal from the inner heat pin 50, the optocoupler is turned on, and the inner heat pin 50 starts to work. It is appreciated that the rf electrode 40 may be heated to 95 c and the inner heat pin 50 may be heated to 60 c. In the embodiment of the application, the relay is a solid state relay or a mechanical relay, and in other embodiments, the relay is set according to the actual situation.
The rf module 63 includes an rf power supply unit 631, an rf amplifying unit 632, and an rf protection unit 633. The rf power supply unit 631 is connected to the first control module 61 and the second control module 62, where the rf power supply unit 631 outputs rf power after receiving the start signal, where the rf power is rf voltage and rf current; the radio frequency amplifying unit 632 is connected with the radio frequency power supply unit 631, the radio frequency amplifying unit 632 amplifies after receiving radio frequency power, and the amplification factor is set according to the actual situation; the rf protection unit 633 is connected to the rf amplifying unit 632, where the rf protection unit 633 is configured to detect an rf voltage and an rf current in real time, and output an rf signal, that is, a voltage signal and an rf current signal, and the second control module 62 is configured to receive the rf voltage signal and the rf current signal, and output a stop signal when a value reflected by the rf voltage signal reaches a preset voltage value or/and a value reflected by the rf current signal reaches a preset current value, and the rf power supply stops working after receiving the stop signal; the relay/optocoupler switching matrix 65 is connected to the rf protection unit 633, and the relay/optocoupler switching matrix 65 is configured to receive the rf signal, and after receiving the rf signal, the relay is turned on, so that the rf electrode 40 starts to operate. In the embodiment of the application, the preset voltage value and the preset current value are set according to actual conditions.
The output circuit 60 also includes a heating energy monitoring module 66. The heating energy monitoring module 66 is respectively connected with the inner heat pin heating module 64 and the second control module 62, and the heating energy monitoring module 66 is used for monitoring the heating power input to the inner heat pin heating module 64 in real time and outputting an energy monitoring signal; the second control module 62 is configured to receive the energy monitoring signal and output a stop signal when a value reflected by the energy monitoring signal reaches an energy preset value, and the first control module 61 outputs a closing signal after receiving the stop signal, and the inner heat pin heating module 64 receives the closing signal and stops outputting the heating signal.
The host 10 is provided with a display module 120, the display module 120 is connected with the second control module 62, and the display module 120 is used for visually displaying the radio frequency current, the radio frequency voltage and the heating power uploaded by the second control module 62, so that the medical staff can conveniently check the display. Meanwhile, the power module 110 is connected with the display module 120, and the power module 110 provides power for the display module 120.
The host 10 is further provided with a temperature port 90 and a temperature detection module 100, the temperature port 90 is respectively connected with the temperature detection module 100 and the first control module 61, the temperature detection module 100 is used for detecting the temperatures of the radio frequency electrode 40 and the inner heat needle 50 and outputting a temperature detection signal, the first control module 61 receives the temperature detection signal and transmits the temperature detection signal to the second control module 62, the second control module 62 uploads a value reflected by the temperature detection signal to the display module 120, and the display module performs visual display.
The temperature detection module 100 performs independent temperature measurement on each radio frequency electrode 40 and each in-root heat pin 50, and the temperature measurement process adopts a time-sharing measurement mode, so that the volume of the output circuit 60 can be effectively reduced.
The implementation principle of the integrated medical equipment combining radio frequency ablation with internal heat needle soft tissue heating is as follows: the medical staff presses the start button 130, the second control module 62 outputs a first control signal, the first control module 61 outputs the start signal after receiving the first control signal, the radio frequency module 63 sends out the radio frequency signal after receiving the start signal, the inner heat needle heating module 64 sends out the inner heat needle heating module 64 after receiving the start signal, the relay is conducted after the relay/optocoupler switching matrix 65 receives the radio frequency signal, and then the radio frequency electrode 40 starts working; when the relay/optocoupler switching matrix 65 receives the heating signal from the inner heat pin 50, the optocoupler is turned on, and the inner heat pin 50 starts to work.
The foregoing are preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle according to the present application should be covered in the protection scope of the present application.
Claims (10)
1. An integrated medical device for radiofrequency ablation in combination with internal hot needle soft tissue heating, comprising a radiofrequency electrode (40) and an internal hot needle (50), characterized in that: also comprises;
a first control module (61), the first control module (61) being configured to output a start signal or a shut down signal;
the radio frequency module (63) is connected with the first control module (61) and is used for outputting a radio frequency signal after receiving a starting signal and stopping outputting the radio frequency signal after receiving a closing signal;
the inner hot needle heating module (64) is connected with the first control module (61) and is used for outputting a heating signal after receiving a starting signal and stopping outputting the heating signal after receiving a closing signal;
and the relay/optocoupler switching matrix (65) is respectively connected with the radio frequency module (63) and the internal heating pin heating module (64) and is used for sending radio frequency signals to the radio frequency electrode (40) after receiving the radio frequency signals and sending the radio frequency signals to the internal heating pin (50) after receiving the heating signals.
2. An integrated medical device for radio frequency ablation in combination with hot needle soft tissue heating as claimed in claim 1, wherein: the radio frequency module (63) comprises;
the radio frequency power supply unit (631), the radio frequency power supply unit (631) is connected with the first control module (61) and is used for starting working after receiving the starting signal and outputting radio frequency power;
and the radio frequency amplifying unit (632) is connected with the radio frequency power supply unit (631) and is used for receiving power and amplifying.
3. An integrated medical device for radio frequency ablation in combination with hot needle soft tissue heating as claimed in claim 1, wherein: the radio frequency module (63) further comprises;
the radio frequency protection unit (633), radio frequency protection unit (633) is connected with radio frequency amplification unit (632), second control module (62) and relay/opto-coupler switching matrix (65) respectively, radio frequency protection unit (633) is used for detecting radio frequency power to carry radio frequency signal to second control module (62) and relay/opto-coupler switching matrix (65).
4. An integrated medical device for radio frequency ablation in combination with hot needle soft tissue heating as claimed in claim 1, wherein: also comprises;
and the heating energy monitoring module (66), the heating energy monitoring module (66) is respectively connected with the second control module (62) and the inner hot needle heating module (64) and is used for monitoring the heating frequency of the inner hot needle heating module (64) and outputting an energy monitoring signal, and the second control module (62) is used for outputting a stop signal to the first control module (61) after receiving the energy monitoring signal.
5. An integrated medical device for radio frequency ablation in combination with hot needle soft tissue heating as claimed in claim 1, wherein: also comprises;
the temperature detection module (100) is respectively connected with the radio frequency electrode (40), the inner heating needle (50) and the first control module (61) and is used for detecting the temperature of the radio frequency electrode (40) and/or the inner heating needle in real time and outputting a temperature signal; the first control module (61) is used for sending to the second control module (62) after receiving the temperature signal.
6. An integrated medical device for radio frequency ablation in combination with hot needle soft tissue heating as claimed in claim 1, wherein: also comprises;
the display module (120), the display module (120) is connected with the second control module (62), the second control module (62) is used for uploading the value reflected by the radio frequency signal and the value reflected by the energy monitoring signal to the display module (120), and the display module (120) is used for carrying out visual display on the value reflected by the radio frequency signal and the value reflected by the energy monitoring signal.
7. An integrated medical device for radio frequency ablation in combination with hot needle soft tissue heating as claimed in claim 1, wherein: the system further comprises a host (10), an inner hot needle port (30) and a radio frequency electrode port (20), wherein a first control module (61), a second control module (62), a radio frequency module (63), an inner hot needle heating module (64) and a relay/optocoupler switching matrix (65) are all positioned in the host (10); the internal heat needle port (30) is respectively connected with the internal heat needle and the relay/optocoupler switching matrix (65), and the radio frequency electrode port (20) is respectively connected with the radio frequency electrode (40) and the relay/optocoupler switching matrix (65).
8. An integrated medical device for radio frequency ablation in combination with hot needle soft tissue heating as claimed in claim 7, wherein: the main machine (10) is also provided with a neutral electrode port (70) and a neutral electrode (80), and the neutral electrode port (70) is respectively connected with the neutral electrode (80) and the relay/optocoupler switching matrix (65).
9. An integrated medical device for radio frequency ablation in combination with hot needle soft tissue heating as claimed in claim 7, wherein: the rf electrode port (20) may provide for use with an inner heat pin (50).
10. An integrated medical device for radio frequency ablation in combination with hot needle soft tissue heating as claimed in claim 5, wherein: the temperature detection module (100) adopts time-sharing detection.
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| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202310102751.3A CN116019543A (en) | 2023-02-13 | 2023-02-13 | Integrated medical equipment combining radio frequency ablation with internal heating needle soft tissue heating |
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| CN202310102751.3A CN116019543A (en) | 2023-02-13 | 2023-02-13 | Integrated medical equipment combining radio frequency ablation with internal heating needle soft tissue heating |
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Citations (8)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| US6161048A (en) * | 1997-06-26 | 2000-12-12 | Radionics, Inc. | Method and system for neural tissue modification |
| CN104706419A (en) * | 2014-12-30 | 2015-06-17 | 沈建平 | Acupuncture needle type radio frequency electric needle |
| WO2016123622A1 (en) * | 2015-01-30 | 2016-08-04 | Itrace Biomedical Inc. | Personalized pain management treatments |
| CN206910394U (en) * | 2017-01-18 | 2018-01-23 | 郑州金港医疗器械有限公司 | The radiofrequency melting instrument of multi-electrode synchronous therapeutic |
| CN108670821A (en) * | 2018-06-21 | 2018-10-19 | 潘燕 | A kind of Novel acupuncture therapeutic device |
| CN112244995A (en) * | 2020-11-13 | 2021-01-22 | 浙江伽奈维医疗科技有限公司 | Safe intelligent ablation host combined with nerve monitoring |
| CN115590602A (en) * | 2021-06-28 | 2023-01-13 | 上海锐道医疗科技有限公司(Cn) | Radio frequency ablation system and method |
| CN115634378A (en) * | 2021-07-19 | 2023-01-24 | 刘海 | Holographic photoelectron pulse therapeutic instrument, holographic photoelectron pulse needle and holographic photoelectron diaphragm |
-
2023
- 2023-02-13 CN CN202310102751.3A patent/CN116019543A/en active Pending
Patent Citations (8)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| US6161048A (en) * | 1997-06-26 | 2000-12-12 | Radionics, Inc. | Method and system for neural tissue modification |
| CN104706419A (en) * | 2014-12-30 | 2015-06-17 | 沈建平 | Acupuncture needle type radio frequency electric needle |
| WO2016123622A1 (en) * | 2015-01-30 | 2016-08-04 | Itrace Biomedical Inc. | Personalized pain management treatments |
| CN206910394U (en) * | 2017-01-18 | 2018-01-23 | 郑州金港医疗器械有限公司 | The radiofrequency melting instrument of multi-electrode synchronous therapeutic |
| CN108670821A (en) * | 2018-06-21 | 2018-10-19 | 潘燕 | A kind of Novel acupuncture therapeutic device |
| CN112244995A (en) * | 2020-11-13 | 2021-01-22 | 浙江伽奈维医疗科技有限公司 | Safe intelligent ablation host combined with nerve monitoring |
| CN115590602A (en) * | 2021-06-28 | 2023-01-13 | 上海锐道医疗科技有限公司(Cn) | Radio frequency ablation system and method |
| CN115634378A (en) * | 2021-07-19 | 2023-01-24 | 刘海 | Holographic photoelectron pulse therapeutic instrument, holographic photoelectron pulse needle and holographic photoelectron diaphragm |
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Application publication date: 20230428 |