CN210078264U

CN210078264U - External shock wave treatment equipment

Info

Publication number: CN210078264U
Application number: CN201920579641.5U
Authority: CN
Inventors: 何永正; 李华玉; 徐昆仑; 信焕玲
Original assignee: Henan Xiangyu Medical Equipment Co Ltd
Current assignee: Henan Xiangyu Medical Equipment Co Ltd
Priority date: 2019-04-25
Filing date: 2019-04-25
Publication date: 2020-02-18
Anticipated expiration: 2029-04-25

Abstract

The utility model discloses an external shock wave treatment device, include: the musculoskeletal ultrasonic detection device is used for carrying out ultrasonic detection on the musculoskeletal of the patient to obtain a musculoskeletal ultrasonic image of the patient; the massage pistol is used for carrying out muscle relaxation operation on the pathological change part of the patient; the shock wave treatment pistol is used for carrying out shock wave treatment on the diseased region with relaxed muscles after the self treatment parameters are adjusted; the host is used for determining the lesion part and the lesion parameters of the patient according to the musculoskeletal ultrasonic image; the treatment parameters of the shock wave treatment pistol are adjusted to the parameter values matched with the pathological change part and the pathological change parameters thereof. Therefore, the in-vitro shock wave treatment equipment has the musculoskeletal ultrasonic detection function, the massage function and the shock wave treatment function simultaneously, so that the treatment efficiency and treatment experience of a patient are improved; moreover, the data checked by each instrument in the extracorporeal shock wave treatment equipment can be shared in real time and is relatively intelligent.

Description

External shock wave treatment equipment

Technical Field

The utility model relates to a shock wave treatment field especially relates to an external shock wave treatment equipment.

Background

Shock wave therapy is currently a new type of therapy between conservative and surgical treatments. In the prior art, the shock wave therapy needs to be completed under the coordination of imaging examination and massage therapists' manipulation therapy, but the prior shock wave therapy equipment only has a single shock wave function, so that before a patient enters a department where the shock wave therapy equipment is located for therapy, the patient needs to be subjected to imaging examination in the department where the imaging equipment is located, and the massage therapists need to perform manipulation therapy in a massage department. Therefore, the patient needs to use different devices in a plurality of departments to complete the treatment, which wastes time, so that the treatment efficiency is low and the treatment experience of the patient is poor; moreover, data checked by equipment of different departments cannot be shared in real time, and can only be presented through paper reports, so that the data checking system is not intelligent enough.

Therefore, how to provide a solution to the above technical problem is a problem that needs to be solved by those skilled in the art.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing an external shock wave treatment device which has the muscle bone ultrasonic detection function, the massage function and the shock wave treatment function simultaneously, thereby improving the treatment efficiency and the treatment experience of patients; moreover, the data checked by each instrument in the extracorporeal shock wave treatment equipment can be shared in real time and is relatively intelligent.

In order to solve the above technical problem, the utility model provides an external shock wave treatment device, include:

the musculoskeletal ultrasonic detection device is used for carrying out ultrasonic detection on a musculoskeletal of a patient to obtain a musculoskeletal ultrasonic image of the patient;

a massage pistol for performing muscle relaxation operation on the lesion site of the patient;

the shock wave treatment pistol is used for carrying out shock wave treatment on the diseased region with relaxed muscles after the self treatment parameters are adjusted;

the main machine is respectively connected with the musculoskeletal ultrasonic detection device, the massage pistol and the shock wave treatment pistol and is used for determining the lesion part and lesion parameters of the patient according to the musculoskeletal ultrasonic image; and adjusting the treatment parameters of the shock wave treatment gun to the parameter values matched with the pathological change part and the pathological change parameters thereof.

Preferably, the massage pistol comprises a pistol shell, a press switch, a control panel, a motor and a massage head; wherein:

the first end of the press switch is connected with the host, the second end of the press switch is connected with the power supply end of the control panel, and the control end of the control panel is connected with the motor; the push switch is arranged on the surface of the pistol shell, the control board and the motor are both arranged inside the pistol shell, and the massage head is arranged at the single-opening position of the pistol shell;

the host is also used for supplying power to the control panel after the push switch is pressed; stopping power supply to the control board after the push switch is bounced; the control panel is used for controlling the motor to rotate after being electrified so as to enable the motor to drive the massage head to move; and after the power is cut off, the motor is stopped to control the rotation of the motor, so that the massage head stops moving.

Preferably, the massage pistol further comprises:

the knob switch is arranged on the surface of the pistol shell and connected with the control panel;

the control panel is specifically used for determining a target rotating speed corresponding to the current gear according to the corresponding relation between the current gear of the knob switch and a preset gear rotating speed after the control panel is electrified, and controlling the motor to rotate at the target rotating speed.

Preferably, the massage head includes:

a plurality of sub-massage heads with the same mounting structure and different sizes and specifications.

Preferably, the musculoskeletal ultrasonic testing device comprises a probe array, an electronic switch module, a control signal generator, a pulse generator, a scanning signal generator, a receiving amplifier and a data transmission module; the probe array comprises N piezoelectric wafer array elements, the electronic switch module comprises N electronic switches, and N is an integer greater than 1; wherein:

the N piezoelectric wafer array elements are connected with first ends of the N electronic switches one by one, second ends of the N electronic switches are connected with each other, common ends of the N electronic switches are respectively connected with an output end of the pulse generator and an input end of the receiving amplifier, an output end of the receiving amplifier is connected with the data transmission module, the data transmission module is connected with the host, and the control signal generator is respectively connected with a control end of the pulse generator and a control end of the scanning signal generator;

the control signal generator is used for controlling the pulse generator to generate an excitation waveform when in work and controlling the electronic switch module to be conducted according to a preset conduction rule through the scanning signal generator, so that the pulse generator excites the corresponding piezoelectric wafer array element to generate ultrasonic waves after the electronic switch is conducted, and the ultrasonic detection of the musculoskeletal muscle of the patient is realized;

the receiving amplifier is used for amplifying the echo generated by the human tissue and received by the corresponding piezoelectric wafer array element after the electronic switch is switched on, and transmitting the amplified echo data to the host machine through the data transmission module, so that the host machine obtains the musculoskeletal ultrasonic image of the patient after analyzing the amplified echo data.

Preferably, the data transmission module is specifically a wireless transmission module; correspondingly, the wireless transmission module is in wireless connection with the host through a wireless network card.

Preferably, the extracorporeal shock wave treatment apparatus further includes:

a display connected with the host;

the host is further used for outputting the musculoskeletal ultrasonic image to the display for display after the musculoskeletal ultrasonic image is obtained.

Preferably, the extracorporeal shock wave treatment apparatus further includes:

a memory connected to the host;

the host computer is also used for storing the musculoskeletal ultrasonic image, the lesion part, the lesion parameter of the lesion part, the treatment parameter, the treatment starting time and the treatment ending time which are related to the current treatment of the patient into the memory in the process of each treatment of the patient.

The utility model provides an external shock wave treatment device, include: the musculoskeletal ultrasonic detection device is used for carrying out ultrasonic detection on the musculoskeletal of the patient to obtain a musculoskeletal ultrasonic image of the patient; the massage pistol is used for carrying out muscle relaxation operation on the pathological change part of the patient; the shock wave treatment pistol is used for carrying out shock wave treatment on the diseased region with relaxed muscles after the self treatment parameters are adjusted; the host is respectively connected with the musculoskeletal ultrasonic detection device, the massage pistol and the shock wave treatment pistol and is used for determining the lesion part and lesion parameters of a patient according to the musculoskeletal ultrasonic image; the treatment parameters of the shock wave treatment pistol are adjusted to the parameter values matched with the pathological change part and the pathological change parameters thereof.

Therefore, the external shock wave treatment equipment has the musculoskeletal ultrasonic detection function, the massage function and the shock wave treatment function, so that a patient can finish shock wave treatment only by using the integrated external shock wave treatment equipment, time is saved, and the treatment efficiency and treatment experience of the patient are improved; moreover, each instrument in the external shock wave treatment equipment is uniformly managed by the same host, so that the data checked by each instrument can be shared in real time and is relatively intelligent.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required in the prior art and the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

Fig. 1 is a schematic structural diagram of an extracorporeal shock wave treatment apparatus provided in an embodiment of the present invention;

fig. 2 is a schematic structural view of a massage pistol according to an embodiment of the present invention;

fig. 3 is a schematic structural diagram of an ultrasonic musculoskeletal testing device according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram of a probe array according to an embodiment of the present invention.

Detailed Description

The core of the utility model is to provide an external shock wave treatment device which has the muscle bone ultrasonic detection function, the massage function and the shock wave treatment function, thereby improving the treatment efficiency and treatment experience of patients; moreover, the data checked by each instrument in the extracorporeal shock wave treatment equipment can be shared in real time and is relatively intelligent.

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1, fig. 1 is a schematic structural diagram of an extracorporeal shock wave treatment apparatus according to an embodiment of the present invention.

The extracorporeal shock wave treatment apparatus includes:

the musculoskeletal ultrasonic detection device 1 is used for carrying out ultrasonic detection on musculoskeletal of a patient to obtain a musculoskeletal ultrasonic image of the patient;

the massage pistol 2 is used for carrying out muscle relaxation operation on the pathological change part of the patient;

the shock wave treatment pistol 3 is used for carrying out shock wave treatment on the pathological change part with relaxed muscle after the self treatment parameters are adjusted;

the host machine 4 is respectively connected with the musculoskeletal ultrasonic detection device 1, the massage pistol 2 and the shock wave treatment pistol 3 and is used for determining the lesion part and lesion parameters of a patient according to the musculoskeletal ultrasonic image; the treatment parameters of the shock wave treatment pistol 3 are adjusted to the parameter values adapted to the lesion part and the lesion parameters thereof.

Specifically, the external shock wave treatment equipment of this application includes flesh bone ultrasonic testing equipment 1, massage pistol 2, shock wave treatment pistol 3 and host computer 4, and its theory of operation is:

firstly, the musculoskeletal ultrasonic detection device 1 carries out ultrasonic detection on the musculoskeletal of a patient, so as to obtain a musculoskeletal ultrasonic image showing the health state of the musculature or bone of the patient. After obtaining the musculoskeletal ultrasonic image of the patient, the musculoskeletal ultrasonic testing apparatus 1 transmits the musculoskeletal ultrasonic image to the host computer 4. After receiving the musculoskeletal ultrasound image, the host computer 4 compares the received musculoskeletal ultrasound image with a musculoskeletal ultrasound image of a normal user by using an image analysis algorithm, thereby determining a lesion of the patient, and simultaneously determining lesion parameters of the lesion of the patient (for example, parameters representing the severity of the lesion, such as lesion area, lesion depth, and the like, such as fracture of the patient, the length of a crack at the fracture of the patient can be determined, inflammation exists under the skin of the patient, and the area and depth of the inflammation can be determined). Compared with a common mode of pressing or visually searching for a focus, the method for searching for the focus by using the musculoskeletal ultrasonic detection device 1 can accurately and scientifically detect the position of the focus and lesion parameters of the focus.

Then, the patient's lesion with muscular tissue (obtained from the main machine 4) is subjected to a muscle relaxation operation by the massage pistol 2, with the aim of subsequently better absorbing the shock wave energy, improving the therapeutic effect. Compared with the traditional manipulation operation of a common masseur or a professional doctor, the massage pistol 2 can reduce labor intensity and improve operation efficiency; moreover, under the guidance of the results of the analysis of the musculoskeletal ultrasound images of the patient, the massage part of the massage pistol 2 is positioned more accurately, thereby improving the massage effect.

Because the pathological changes of different patients and the pathological changes of the pathological changes are different, the shock wave treatment pistol 3 should adjust the intensity of the shock wave according to the actual conditions of the current patient, so that the shock wave treatment is more scientific, and the treatment effect is improved. Specifically, after determining the lesion site and the lesion parameters of the current patient, the host 4 adjusts the treatment parameters (determining the intensity of the shock wave) of the shock wave treatment gun 3 to the parameter values adapted to the lesion site and the lesion parameters of the current patient, specifically, adjusts the pressure value, the working frequency value, and the treatment time of the shock wave treatment gun 3.

More specifically, the host 4 of the present application utilizes a deep learning technique to realize reasonable adjustment of the treatment parameters of the shock wave treatment pistol 3: the method and the device train a parameter adaptation model which takes the lesion part and lesion parameters of a patient (or converts the lesion parameters into lesion grades) as input and takes the treatment parameters of the shock wave treatment pistol 3 as output in advance according to a deep learning algorithm (training data is a shock wave treatment scheme of historical cases), and can be applied to actual treatment after the parameter adaptation model is trained. In the subsequent actual treatment process of the patient, the lesion part and the lesion parameters of the patient are input into the parameter adaptation model (which is equivalent to retrieving adapted treatment parameters from the existing prescription library according to the lesion part and the lesion parameters thereof), so as to obtain the preferred treatment parameters of the shockwave treatment gun 3 (which is used as the basis for adjusting the treatment parameters of the shockwave treatment gun 3). Therefore, the treatment parameters are specifically adjusted under the condition that the diseased region is clear and the severity of the disease is visible, and the treatment effect can be improved.

Alternatively, the host 4 of the present application may retrieve several commonly used prescriptions from an existing prescription library according to the lesion site and the lesion parameters thereof, and provide the prescriptions to the treating doctor for selection, and the treating doctor inputs the treatment parameters corresponding to the selected prescription into the shockwave treatment pistol 3 after selecting the prescription, thereby realizing the targeted adjustment of the treatment parameters of the shockwave treatment pistol 3.

Finally, after the treatment parameters of the shock wave treatment pistol 3 are adjusted, the shock wave treatment pistol 3 is used for carrying out shock wave treatment on the diseased region with relaxed muscles, and therefore the whole shock wave treatment is completed. In addition, considering that the diseased part (such as a blood vessel or a fracture part) of the patient is not suitable for shock wave treatment, the host machine 4 of the application can also judge whether the diseased part is suitable for shock wave treatment according to the diseased part of the patient, if the diseased part is not suitable for shock wave treatment (the diseased part which is not suitable for shock wave treatment is called a non-target diseased part), the treatment parameters of the shock wave treatment gun 3 are not adjusted according to the non-target diseased part of the patient and the diseased parameters thereof, but the treatment parameters of the shock wave treatment gun 3 are directly adjusted to 0, so that the shock wave treatment gun 3 does not perform shock wave treatment on the non-target diseased part of the patient.

It should be noted that the musculoskeletal ultrasonic testing device 1, the massage pistol 2 and the shock wave treatment pistol 3 can work simultaneously, and a plurality of massage pistols 2 and/or a plurality of shock wave treatment pistols 3 can be arranged according to actual requirements, so that treatment services can be provided for a plurality of people simultaneously. For example, the present application may be provided with one massage pistol 2 and two shock wave treatment pistols 3, so that three persons may be served simultaneously. In this case, the host computer 4 uses a unified job management system to centrally manage information data and treatment job data of different patients, thereby automatically controlling treatment procedures and processes of different patients.

On the basis of the above-described embodiment:

referring to fig. 2, fig. 2 is a schematic structural diagram of a massage pistol according to an embodiment of the present invention.

As an alternative embodiment, the massage pistol 2 comprises a pistol casing, a push switch 21, a control board 22, a motor 23 and a massage head 24; wherein:

the first end of the press switch 21 is connected with the host 4, the second end of the press switch 21 is connected with the power end of the control panel 22, and the control end of the control panel 22 is connected with the motor 23; the push switch 21 is arranged on the surface of the pistol shell, the control panel 22 and the motor 23 are both arranged in the pistol shell, and the massage head 24 is arranged at the single opening position of the pistol shell;

the host 4 is also used for supplying power to the control panel 22 after the push switch 21 is pressed; stopping the power supply to the control board 22 after the push switch 21 is popped up; the control panel 22 is used for controlling the motor 23 to rotate after being electrified, so that the motor 23 drives the massage head 24 to move; the control motor 23 is stopped after self-power-off to stop the movement of the massage head 24.

Specifically, the massage pistol 2 of the present application includes a pistol casing, a push switch 21, a control board 22, a motor 23 and a massage head 24, and the working principle thereof is as follows:

when the push switch 21 is pressed, the power line between the host 4 and the control board 22 is connected, and the host 4 can supply power to the control board 22. When the control board 22 is powered on, the motor 23 is controlled to start rotating, and the rotation of the motor 23 drives the massage head 24 to move, so that the massage gun 2 starts massage work. On the contrary, when the push switch 21 is popped up, the power line between the host 4 and the control board 22 is disconnected, and the host 4 stops supplying power to the control board 22. The control board 22 can not control the motor 23 to rotate after being powered off, and the massage head 24 stops moving, so that the massage gun 2 finishes the massage work. In addition, the host 4 can acquire the massage time of the massage pistol 2 according to the power-on time and the power-off time of the control board 22.

Or, the massage pistol 2 of this application also can choose for use intelligent pulse rifle, and the intelligent pulse rifle replaces bare-handed with the apparatus, utilizes the pulse that is close human resonance frequency and the pulse strength that is close human resonance effect, carries out corresponding safe painless equal frequency external force shock stimulation to each skeleton of human body and muscle position to provide accurate comfortable muscle release.

As an alternative embodiment, massage pistol 2 further comprises:

a knob switch 25 which is arranged on the surface of the pistol casing and is connected with the control panel 22;

the control board 22 is specifically configured to determine a target rotation speed corresponding to the current gear according to the corresponding relationship between the current gear of the knob switch 25 and the preset gear rotation speed after being powered on, and control the motor 23 to rotate at the target rotation speed.

Further, massage pistol 2 of this application still includes rotary switch 25, and its theory of operation is:

considering that the muscle states and the force receiving degrees of different patients are different, if the massage gun 2 adopts the same massage force when massaging different patients, the massage experience of the patients is poor, so the massage gun 2 further comprises a knob switch 25 connected with the control panel 22. Knob switch 25 contains different gears, and this application sets up the corresponding relation (gear rotational speed corresponding relation) between knob switch 25's gear and motor 23's the rotational speed in advance, thereby make control panel 22 after self electricity, at first confirm the target rotational speed of motor 23 corresponding with knob switch 25's current gear according to the gear rotational speed corresponding relation that establishes, then control motor 23 rotates under the target rotational speed (also can change knob switch 25's gear at the massage in-process, with the massage dynamics that changes massage pistol 2), and then realize the massage dynamics to different patients rationally adjust massage pistol 2, promote patient's massage experience.

As an alternative embodiment, the massage head 24 includes:

In particular, considering that the lesion areas and the lesion depths of lesion parts of different patients are usually different, the application can be provided with a plurality of sub-massage heads with different sizes and specifications, so that a proper sub-massage head is selected according to the lesion areas and the lesion depths of the lesion parts, and a larger sub-massage head is generally selected according to a larger lesion area, thereby increasing the comfort level of massage.

The pistol casing with the single end opening and the sub-massage heads are detachably mounted at one time, and the mounting structure of each sub-massage head is the same, so that the pistol casing can be conveniently mounted on the sub-massage heads with different sizes.

Referring to fig. 3, fig. 3 is a schematic structural diagram of an ultrasonic testing apparatus for musculoskeletal bones according to an embodiment of the present invention.

As an alternative embodiment, the musculoskeletal ultrasonic testing device 1 comprises a probe array 11, an electronic switch module 12, a control signal generator 13, a pulse generator 14, a scanning signal generator 15, a receiving amplifier 16 and a data transmission module; the probe array 11 comprises N piezoelectric wafer array elements, the electronic switch module 12 comprises N electronic switches, and N is an integer greater than 1; wherein:

the N piezoelectric chip array elements are connected with first ends of the N electronic switches one by one, second ends of the N electronic switches are connected with each other, common ends of the N piezoelectric chip array elements are respectively connected with an output end of a pulse generator 14 and an input end of a receiving amplifier 16, an output end of the receiving amplifier 16 is connected with a data transmission module, the data transmission module is connected with a host 4, and a control signal generator 13 is respectively connected with a control end of the pulse generator 14 and a control end of a scanning signal generator 15;

the control signal generator 13 is used for controlling the pulse generator 14 to generate an excitation waveform when working, and controlling the electronic switch module 12 to be conducted according to a preset conduction rule through the scanning signal generator 15, so that the pulse generator 14 excites the corresponding piezoelectric wafer array element to generate ultrasonic waves after the electronic switch is conducted, and the ultrasonic detection of the musculoskeletal muscle of the patient is realized;

the receiving amplifier 16 is configured to amplify the echo generated by the human tissue and received by the corresponding piezoelectric wafer array element after the electronic switch is turned on, and transmit the amplified echo data to the host 4 through the data transmission module, so that the host 4 obtains the musculoskeletal ultrasound image of the patient after analyzing the amplified echo data.

Specifically, the ultrasonic musculoskeletal testing device 1 of the present application includes a probe array 11 (specifically adopting a structure as shown in fig. 4, in which piezoelectric chip array elements are arranged in sequence), an electronic switch module 12, a control signal generator 13, a pulse generator 14, a scanning signal generator 15, a receiving amplifier 16 and a data transmission module, and its working principle is:

the control signal generator 13, when operating, controls the pulse generator 14 to generate an excitation waveform, and controls the conduction of each electronic switch in the electronic switch module 12 through the scan signal generator 15, specifically, controls the conduction of each electronic switch according to a preset conduction rule. When the electronic switch is turned on, the excitation waveform generated by the pulse generator 14 can be input into the piezoelectric chip array element connected with the electronic switch, so as to excite the piezoelectric chip array element to generate ultrasonic waves. The ultrasonic wave can produce reflection and scattering because of meeting the organizational structure of different degree of depth after sending human tissue to produce the echo of different time delays, the echo can be received by piezoelectric chip array element, and send to receiving amplifier 16 through the electronic switch who switches on, then amplify the echo that receives by receiving amplifier 16, and transmit the echo data after will amplifying to host computer 4 through data transmission module. After receiving the amplified echo data, the host computer 4 analyzes the amplified echo data according to an image analysis algorithm, thereby obtaining an ultrasonic image (visual image) of the musculoskeletal of the patient.

More specifically, the control signal generator 13 of the present application can control the electronic switches to be turned on in turn through the scan signal generator 15, so as to improve the resolution and sensitivity of the system. Preferably, the control signal generator 13 controls M (M < N) electronic switches arranged in sequence to be turned on through the scanning signal generator 15, that is, M piezoelectric wafer array elements are excited simultaneously, a beam of ultrasonic waves is emitted and echoes are received, then the foremost electronic switch of the M electronic switches is turned off, the rear electronic switch of the M electronic switches is turned on simultaneously, and so on, thereby controlling the electronic switches to be turned on in turn.

In addition, the musculoskeletal ultrasonic testing device 1 of the present application further comprises a control button connected to the control signal generator 13, and the control signal generator 13 is further configured to identify a control function currently corresponding to the control button according to the length of time the control button is pressed, and then execute a corresponding control operation according to the identified control function. For example, the present application may be configured as follows: the long pressing of the control button for 3 seconds or more represents the power-on operation and the power-off operation, and the clicking once represents the switching (such as scanning and pausing) of the working state of the musculoskeletal ultrasonic testing device 1.

As an optional embodiment, the data transmission module is specifically a wireless transmission module 17; correspondingly, the wireless transmission module 17 is wirelessly connected with the host 4 through a wireless network card.

Specifically, the data transmission module of the present application may employ a wireless transmission module 17 (e.g., a WiFi hotspot), so that the echo data is wirelessly transmitted to the host 4. Accordingly, the host 4 matches and receives echo data through the wireless network data channel.

As an optional embodiment, the extracorporeal shock wave treatment apparatus further includes:

a display connected to the host 4;

the host computer 4 is further configured to output the musculoskeletal ultrasonic image to the display for display after obtaining the musculoskeletal ultrasonic image.

Further, the extracorporeal shock wave treatment device of the present application further includes a display for real-time playback of the musculoskeletal ultrasound image (the lesion site and lesion parameters thereof can be identified on the musculoskeletal ultrasound image). The treating doctor can further professionally analyze the patient condition through the musculoskeletal ultrasonic image, and under the condition, the treating doctor can also manually mark a more accurate lesion part on the musculoskeletal ultrasonic image.

a memory connected to the host 4;

the host 4 is further configured to store, in the process of each treatment of the patient, the musculoskeletal ultrasound image, the lesion site, the lesion parameter of the lesion site, the treatment parameter, the treatment start time, and the treatment end time related to the current treatment of the patient in the memory.

Furthermore, the extracorporeal shock wave treatment device of the application further comprises a memory, so that parameters and treatment time (including actual treatment times) used from the musculoskeletal ultrasonic image to the treatment process in each treatment process of the patient are saved, later-stage comparative analysis is facilitated, and the recovery condition of the patient is known.

In addition, the host 4 of the application can also generate a treatment report of the patient based on the data stored in the memory, and is connected with the printer to print out the treatment report, so that the later-stage research of a treating doctor is facilitated, and the formed classical case treatment scheme can guide the similar patients to refer to the treatment report, thereby greatly improving the scientific research value of the extracorporeal shock wave treatment equipment.

It should also be noted that, in the present specification, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims

1. An extracorporeal shock wave treatment apparatus, comprising:

2. The extracorporeal shock wave therapy apparatus of claim 1, wherein the massage pistol includes a pistol housing, a push switch, a control panel, a motor, and a massage head; wherein:

3. The extracorporeal shock wave treatment apparatus of claim 2, wherein the massage pistol further comprises:

4. The extracorporeal shock wave treatment apparatus of claim 3, wherein the massage head comprises:

5. The extracorporeal shock wave treatment apparatus of claim 1, wherein the musculoskeletal ultrasound testing apparatus comprises a probe array, an electronic switch module, a control signal generator, a pulse generator, a scanning signal generator, a receiving amplifier, and a data transmission module; the probe array comprises N piezoelectric wafer array elements, the electronic switch module comprises N electronic switches, and N is an integer greater than 1; wherein:

6. The extracorporeal shock wave therapy apparatus of claim 5, wherein the data transmission module is specifically a wireless transmission module; correspondingly, the wireless transmission module is in wireless connection with the host through a wireless network card.

7. The extracorporeal shock wave treatment apparatus of claim 5, further comprising:

a display connected with the host;

8. The extracorporeal shock wave treatment apparatus of claim 7, further comprising:

a memory connected to the host;