JP7472283B2 - Wearable flexible ultrasonic urethral scar treatment device - Google Patents

Description

The present invention relates to a wearable, flexible ultrasonic urethral scar treatment device, which belongs to the technical field of postoperative scar treatment in urological surgery.

The formation of urethral scarring is the result of the concerted action of several factors. The profibrotic protein TGF-β is the most closely related and representative growth factor currently known to be involved in scarring. Factors such as inflammation and matrix metalloproteinases (MMPs) also play important roles in the scarring process. The formation of urethral scarring after urethral surgery is a common complication that often affects the postoperative recovery of urethral patients and continues to be a vexing problem faced by urological surgeons.
At present, in clinical practice, the treatment methods for urethral scar and urethral stricture mainly include surgical treatment and drug treatment.Traditional urethral dilation is painful and difficult to cure.Open surgery includes urethral scar segment resection, transurethral rotational resection and endoplasty, but it has high treatment costs, large surgical wounds, many complications such as impotence and penile curvature, and is prone to postoperative restenosis.

With the development of intraurethral techniques, the surgical effect has gradually improved through the use of many new methods such as endoscopic cryoprope incision of urethral stricture, scar electrovaporation, bipolar plasma incision and urethral scar electroresection, and ureteroscope direct holmium laser incision, but each method has its own limitations. For example, endoscopic urethral cryoprope incision can only make radial incisions, making it difficult to remove scar tissue and stop bleeding, resulting in poor long-term postoperative effects and a high recurrence rate. Monopolar high-frequency electric scalpel can remove scar tissue and produce a clean wound surface, but it has a high temperature and deep thermal radiation, which causes different degrees of thermal damage to the tissues around the urethra, making it easy for the tissue to necrotize and form new fibrous scar tissue. Holmium laser incision under ureteroscope direct vision is only suitable for cases with mild stricture, and in cases with long and severe strictures, it is difficult to achieve the purpose of releasing the blockage and improving the passage of the urethra. Currently, the success rate of surgical treatment remains at around 75%, and patients are prone to falling into a loop of reoperation and restenosis, and often require multiple urethral dilation procedures after surgery.

The drugs used to treat urethral scar mainly include triamcinolone, verapamil, hyaluronic acid, etc. Drug therapy has some effect, but it is often used as a postoperative adjuvant treatment, and it is difficult to exert a suitable effect by itself. The method of injecting drugs into scar has some difficulty in operation, and multiple injections increase the pain of the patient.
The existing conventional treatment for urethral scarring requires incision of the urethra in severe cases to remove scar tissue, with regular postoperative urethral dilation to prevent urethral stricture.

Recent studies have shown that ultrasound has the effects of promoting angiogenesis, anti-inflammatory, anti-fibrotic, anti-capsular contracture, suppressing TGF-β expression, and promoting MMP expression. Low-frequency ultrasound has an anti-inflammatory effect, and early inflammatory reactions are a factor in scar formation. Low-frequency ultrasound promotes the reduction of expression of TGF-β, a pro-fibrotic protein, and the increase of expression of MMP2, an anti-fibrotic protein, and can significantly resist fibrosis, thereby suppressing scar formation. Low-frequency ultrasound also stimulates the release of vascular growth factors, accelerating blood vessel generation and wound healing. However, there have been no reports yet on the preventive or therapeutic effects of ultrasound on urethral scarring.

Chinese patent CN106390278A discloses an ultrasonic therapy device including an ultrasonic therapy patch and a therapy host, the ultrasonic therapy patch including a patch substrate provided with at least one drug chamber and at least one ultrasonic transducer, and an adhesive unit distributed around the bottom of the patch substrate for attaching to the surface of the skin. The invention has a complex structure and is not flexible, and is mainly used for the penetration of drugs into the surface of the skin by ultrasound, whereas the present invention has a simple structure, good flexibility, strong adhesion, and is used for the treatment and/or prevention of urethral scars. Chinese patent CN208599011U and CN107789751A disclose a flexible ultrasonic probe array and an ultrasonic two-dimensional array therapy band, both of which include a skin contact layer, an ultrasonic wafer, and a sound-absorbing protective layer, and the skin contact layer is provided with a groove for placing the ultrasonic wafer, and are mainly used in the fields of ultrasonic treatment of fractures and osteoporosis treatment. The ultrasonic treatment probe and ultrasonic two-dimensional array treatment band have a multi-layer structure, a large overall thickness, poor curvature, normal adhesion, and require a fixed bandage to be installed to fix it to the treatment site. In comparison, the patch-type flexible ultrasonic probe of the present invention has an integrated flexible structure, a tip is embedded in a flexible material, a small overall thickness, good flexibility, strong adhesion, and is used in the treatment and/or prevention of urethral scars. Chinese patent CN109758180A discloses a flexible ultrasonic probe, which includes a flexible substrate and an ultrasonic conversion unit, and is used for ultrasonic diagnosis. In comparison, the probe of the device of the present invention mainly generates low-frequency ultrasound and utilizes the mechanical and thermal effects of low-frequency ultrasound to treat and/or prevent urethral scars.

The purpose of the present invention is to overcome the difficulties in the treatment and prevention of urethral scarring following urethral surgery in the existing technology, and invent a wearable flexible ultrasonic urethral scarring treatment method; at the same time, it solves the problem that the normal ultrasonic probe is too stiff and cannot effectively conform to the surface of the penis, and invents a wearable flexible ultrasonic urethral scarring treatment device.
Research has shown that low-frequency ultrasound has the effects of promoting angiogenesis, anti-inflammatory, anti-fibrotic and anti-capsular contracture, and can be used to treat and/or prevent urethral scar disease. The clinical application of low-frequency ultrasound to urethral scarring, and regular low-frequency ultrasound treatment for patients after minimally invasive urethral surgery can effectively inhibit the development of pathological scarring.
In addition, the current conventional ultrasonic probe is too hard and cannot effectively conform to the surface of the penis, so the present invention simultaneously introduces a polymer composite material, that is, ceramic array elements are distributed in a silica gel material to form a flexible ultrasonic probe, which can be appropriately attached to the surface of the penis and used in conjunction with the control end through wired transmission to obtain a wearable flexible ultrasonic urethral scar treatment device.

Means for solving the problem

The wearable flexible ultrasonic urethral scar treatment device of the present invention includes two parts: a patch-type flexible ultrasonic probe and a control end. The patch-type flexible ultrasonic probe is attached to the surface of the skin on the ventral side of the patient's penis to perform ultrasonic treatment, and the control end is connected to the patch-type flexible ultrasonic probe and outputs an excitation signal to control the patch-type flexible ultrasonic probe. Here, the patch-type flexible ultrasonic probe is provided with one or more sets of tips so as to emit ultrasonic waves to the surface of the patient's skin when it receives the excitation signal output by the control end. The probe and the control end may be used together via wired transmission.

The patch type flexible ultrasonic probe is made of a silica gel material, and the tip is distributed in the silica gel material.
The shape of said patch type flexible ultrasonic probe is circular, elliptical, square, rectangular, rounded rectangular or irregular, the shape of which is determined according to actual needs, and the thickness of which is 1-5 mm.
Preferably, the patch type flexible ultrasonic probe has a rectangular shape.
The tips are in a 4x2 rectangular array and are made of piezoelectric ceramic or single crystal silicon, are flexible, the emitting surface of the tips faces the surface of the patient's skin, the tips are rectangular in shape, and the thickness of the tips is less than the thickness of a patch-type flexible ultrasound probe.
The center frequency of the piezoelectric ceramic or single crystal silicon is 0.4-4 MHz.
An electrode for collecting signal lines of the chip is provided on the surface of the chip.
A signal line connection port is provided on the side of the patch type flexible ultrasonic probe, and the control end is connected to the signal line connection port through wired transmission to control the patch type flexible ultrasonic probe.
The ultrasonic waves generated by the patch-type flexible ultrasonic probe have an output of 30 mW/cm ² -1.5 W/cm ² and a frequency of 1 MHz -3 MHz.

In the treatment and/or prevention of urethral scar disease, a patch-type flexible ultrasound probe is attached to the ventral skin of the penis to perform low-frequency ultrasound treatment. Preventive use is mainly used after various urethral surgeries (e.g. urethroplasty, end-to-end urethral anastomosis, etc.) that are accompanied by urethral scarring. After removing the covering material on the skin of the penis after surgery, ultrasound treatment is started, and treatment may be performed once a day during hospitalization, and after discharge, treatment may be performed several times a week in the outpatient clinic to regularly check the urethral adhesion level and urination status. Therapeutic use is mainly used when urethral scarring has already been observed, and may be used alone as a conservative treatment or in combination with urethral dilation. It can also be used in combination with surgery to enhance the postoperative treatment effect in patients who have already developed obvious stricture due to severe scarring and require surgical treatment.

During the ultrasonic treatment process, the ultrasonic treatment parameters are set at the control end, the ultrasonic power range is 30 mW/ ^cm2-1.5 W/ ^cm2 , the ultrasonic frequency range is 1 MHz-3 Mhz, and the treatment time is 5 min-30 min. During treatment, the ultrasonic probe needs to be moved periodically to avoid tissue damage caused by local excessive heat effect.

Compared with existing technologies, the present invention has the following beneficial effects:
(1) The wearable patch type low frequency ultrasound of the present invention has no radiation, no pain, no side effects, and is easy to use.
(2) The present invention solves the technical problem of attaching ultrasound to the penis, and uses low-frequency ultrasound technology to treat urethral scarring. It is expected to be a technological expansion in a new field and solve the difficult problem of preventing and treating urethral scarring in clinical practice, and there are currently no related products in the world.
The above description is merely a summary of the technical solution of the present invention, in order to make the technical means of the present invention more clearly understood and to be able to implement the present invention according to the content of the specification, the preferred embodiments of the present invention will be described in detail below with reference to the drawings. Specific embodiments of the present invention are shown in the following examples and their drawings.

In order to more clearly explain the technical solutions in the embodiments of the present invention, the drawings necessary for the description of the embodiments are briefly introduced below. Of course, the drawings in the following description are only some of the embodiments of the present invention, and those skilled in the art can derive other drawings from these drawings without creative labor.

FIG. 1 is a schematic diagram of a wearable flexible ultrasonic urethral scar treatment device of the present invention. FIG. 2 is a cross-sectional schematic diagram of the flexible ultrasound patch of the present invention when applied to the penis. 3 is a structural schematic diagram of the patch-type flexible ultrasonic probe of the present invention, in which 1 is the patch-type flexible ultrasonic probe and 2 is the control end.

In the following, the present invention will be clearly and completely described with reference to drawings 1-3 and specific examples so that the objectives, technical solutions and advantages of the present invention can be more clearly understood. In describing the present invention, it is necessary to explain the following points. The orientations or positional relationships indicated by the terms "upper", "middle", "lower", etc. are based on the orientations or positional relationships shown in the drawings, and are merely for the purpose of describing and simplifying the description of the present invention, and do not indicate or suggest that the devices or elements shown have a specific orientation or need to be configured and operated in a specific orientation, and therefore should not be understood as limitations on the present invention.

As shown in Figure 1-3, the wearable flexible ultrasonic urethral scar treatment device in this embodiment includes two parts: a patch-type flexible ultrasonic probe (1) and a control end (2). The patch-type flexible ultrasonic probe (1) is rectangular in shape and 2 mm thick, with a rectangular tip made of piezoelectric ceramic on top and a signal line connection port on the bottom. The patch-type flexible ultrasonic probe (1) is made of silica gel material, and the tip is distributed in the silica gel material, and both have a certain degree of flexibility. The control end (2) is connected to the signal line connection port through a flexible wiring to control the patch-type flexible ultrasonic probe (1).

Example 1
Example 1 is the preventive use of the device of the present invention in patients after surgery. 50 hypospadias patients who were hospitalized and treated in the urological surgery department were selected, and preventive ultrasound treatment was performed from the day when the covering material of the penis was removed after urethroplasty (generally about 3-5 days after surgery). The treatment area was the skin on the ventral side of the penis corresponding to the formed urethra area, and a patch-type flexible ultrasound probe was attached to the surface of the skin. The parameters of the device were output 0.2 W/ ^cm2 , frequency 1 MHz, and treatment time 20 min per session (during treatment, the ultrasound probe needs to be moved periodically to avoid tissue damage caused by excessive heat effect in the local area). During hospitalization, treatment was performed once a day (generally hospitalized for 7-14 days after surgery), and after discharge, treatment was performed once or twice a week in the outpatient department. After 4 and 8 weeks after surgery, the urethra recovery level, urination situation, postoperative complications, etc. were evaluated, and the incidence rate of urethral scarring and the severity of scarring were statistically calculated. Treatment effect: After surgery for hypospadias, the use of this preventive ultrasound treatment method can reduce the incidence and severity of postoperative urethral scarring, reduce the incidence of postoperative complications, and reduce the pain suffered by patients due to postoperative urethral dilation and therefore secondary surgery.

Example 2
Example 2 is the use of the device of the present invention in the clinical treatment of patients with urethral scars. 20 patients who had undergone various urethral surgeries in the urological surgery department and developed urethral scar complications and required further treatment were selected, but no patients who had severe urethral strictures that significantly affected urination and required immediate surgical treatment were included. The treatment site was the skin on the ventral side of the penis corresponding to the urethral scar area, and a patch-type flexible ultrasound probe was attached to the surface of the skin. The parameters of the ultrasound device were output 0.5 W/ ^cm2 , frequency 1 MHz, and treatment time 30 min per session (the ultrasound probe should be moved periodically during treatment to avoid tissue damage caused by excessive local heat effects). Treatment was performed three times a week in the outpatient clinic, and indicators such as scar recovery, urethral passage and urination function were regularly evaluated by means of urethrography, urodynamics, etc. at 2, 4, 6, and 8 weeks after ultrasound treatment. Treatment effect: After ultrasonic treatment with this device, it can soften and promote the absorption of existing scars to a certain extent, inhibit the formation of new scars, reduce the probability of reoperation, improve urinary symptoms, reduce the patient's pain and improve their quality of life.

The above description of the disclosed embodiments is intended to enable a person skilled in the art to realize or use the present invention. The above is merely a preferred embodiment of the present invention, and of course, those skilled in the art may make minor improvements and supplements without departing from the principles of the present invention, and these improvements and supplements are also considered to be within the scope of protection of the present invention. Many modifications to these embodiments will be obvious to those skilled in the art, and the general principles defined herein may be realized in other embodiments without departing from the spirit or scope of the present invention. Therefore, the present invention is not limited to these embodiments shown in the present specification, but is accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (7)

A wearable flexible ultrasonic urethral scar treatment device , comprising:
A patch-type flexible ultrasound probe for attaching to the surface of the skin on the ventral side of the patient's penis to perform ultrasound treatment;
a control terminal connected to the patch type flexible ultrasonic probe and configured to output an excitation signal to control the patch type flexible ultrasonic probe;
Wherein, the patch-type flexible ultrasonic probe is provided with one or more sets of tips, so as to emit ultrasonic waves to the surface of the patient's skin when receiving an excitation signal outputted by the control end ;
The device is characterized in that the tips are in a 4x2 rectangular array and are fabricated from piezoelectric ceramic or single crystal silicon, are flexible, the emitting surface of the tips faces the surface of the patient's skin, the tips are rectangular in shape, and the thickness of the tips is less than the thickness of a patch-type flexible ultrasound probe. The wearable flexible ultrasonic urethral scar treatment device of claim 1 , characterized in that the patch-type flexible ultrasonic probe is made of silicone material, and the tip is distributed within the silicone material. The wearable flexible ultrasonic urethral scar treatment device of claim 1 or 2 , characterized in that the shape of the patch-type flexible ultrasonic probe is circular, elliptical, square, rectangular, or rounded rectangular, and its thickness is 1-5 mm. The wearable flexible ultrasonic urethral scar treatment device of claim 1 , characterized in that the center frequency of the piezoelectric ceramic or single crystal silicon is 0.4-4 MHz. The wearable flexible ultrasonic urethral scar treatment device of claim 1 or 2, characterized in that an electrode is provided on the upper surface of the chip, the electrode being for consolidating the signal lines of the chip . The wearable flexible ultrasonic urethral scar treatment device of claim 1, characterized in that a signal line connection port is provided on the side of the patch-type flexible ultrasonic probe, and the control end is connected to the signal line connection port via wired transmission to control the patch-type flexible ultrasonic probe . The wearable flexible ultrasonic urethral scar treatment device of claim 1, 2, 4 or 6 , characterized in that the ultrasonic waves generated by the patch-type flexible ultrasonic probe have an output of 30 mW/ ^cm2-1.5 W/ ^cm2 and a frequency of 1 MHz-3 MHz.