CN216319437U - Medical device - Google Patents

Abstract

The utility model relates to a medical device which comprises a catheter body, a balloon and an energy generation component, wherein the energy generation component comprises at least one electrode pair, the at least one electrode pair is arranged at the tail end of the catheter body and is positioned in the balloon, a conductive medium is stored in the balloon, the balloon is made of a high-elasticity material, and the balloon in a contraction state is sleeved at the tail end of the catheter body in a non-folding mode. By the configuration, the passing outer diameter of the medical device based on the hydro-electric effect can be reduced, so that the treatment of the narrow lesion can be realized, and the treatment difficulty is reduced.

Description

Medical device

Technical Field

The utility model relates to the technical field of medical instruments, in particular to a medical device.

Background

The shock wave balloon catheter based on the hydro-electric effect is a new medical instrument for blood vessel formation, is widely concerned by medical fields at home and abroad, and can effectively reduce the damage of balloon mechanical force expansion to blood vessels while increasing the inner diameter of the blood vessel cavity at the stenotic lesion.

Before this, in the case of a severely calcified lesion, it is often the case that the conventional dilatation balloon cannot achieve the lesion dilatation, and special instruments, such as a rotational grinding catheter, a cutting balloon, a spinous process balloon and the like, are required to be used for pretreatment of the calcified area. The shock wave balloon catheter directly acts the sound pressure on the hard calcified layer by utilizing the liquid-electricity effect to realize the destruction of the calcified structure and achieve the rapid destruction and expansion of calcified lesions. Meanwhile, due to the selectivity of the liquid-electric effect, the liquid-electric effect can directly penetrate through a soft vascular layer and only acts on a hard calcified layer, so that under the treatment scheme, the rapid damage and expansion of calcified lesions are realized, the damage to blood vessels is small, the complications of PCI (percutaneous coronary intervention) operations can be greatly reduced, and even the incidence of the complications is lower than that of the pure balloon catheter expansion.

However, the blast balloon catheter based on the electrohydraulic effect shows excellent treatment effect, and simultaneously, the defects of the apparatus are revealed, the main problems are that the trafficability is poor, when the narrow lesion is treated, a balloon needs to be pre-expanded or a rotational grinding catheter needs to be used after the narrow lesion is opened by performing rotational grinding assistance, the operation is very complicated, the operation efficiency is low, the fitting capacity with the lesion is poor, the size of the applicable blood vessel is limited, and the application range is limited.

SUMMERY OF THE UTILITY MODEL

In order to solve the problems in the prior art, an object of the present invention is to provide a medical device, which includes a balloon catheter configured with an electrode pair, wherein the outer diameter of the whole balloon catheter can approach the level of a microcatheter, so that the medical device can be used for interventional therapy of stenotic lesions even extremely stenotic lesions through a narrower lesion region, thereby reducing the difficulty of treatment of stenotic lesions and improving the treatment effect.

In order to achieve the above purpose, the present invention provides a medical device, which includes a catheter body, a balloon and an energy generating component, wherein the energy generating component includes at least one electrode pair, the at least one electrode pair is disposed at a distal end of the catheter body and located in the balloon, a conductive medium is stored in the balloon, the balloon is made of a high-elasticity material, and the balloon in a contracted state is sleeved on the distal end of the catheter body in a non-folding manner.

Optionally, the elongation at break of the balloon is greater than 300%.

Optionally, the elongation at break of the balloon is 500% to 800%.

Optionally, the catheter body includes a fixed tube, the balloon is sleeved on the fixed tube in a non-folding manner in a contracted state, the electrode pair is disposed on the fixed tube, the medical device further includes an internal lead connected to the electrode pair, and the internal lead is embedded in the fixed tube.

Optionally, the fixed tube is a hollow tube or a solid tube.

Optionally, the fixed pipe and the internal conductor are connected in an integrally extruded manner, or the fixed pipe includes an inner layer and an outer layer, a mounting groove is formed on the surface of the inner layer, and after the internal conductor is embedded in the mounting groove, the outer layer is sleeved on the inner layer to coat the inner layer and the internal conductor.

Optionally, the medical device further comprises a connection medium connected to the inner lead and the electrode pair, respectively.

Optionally, the pair of electrodes comprises a first electrode and a second electrode, the internal lead comprises a first lead and a second lead, and the connection medium comprises a first connection medium and a second connection medium;

the first and second wires extend axially inside the fixed tube and are spaced apart from each other; the first electrode is connected with the first lead through the first connecting medium; the second electrode is connected with the second lead through the second connecting medium.

Optionally, the medical device further includes the conductive medium, the proximal end and the distal end of the balloon are both connected to the fixing tube, a cavity is formed between the fixing tube and the balloon, and the conductive medium is enclosed in the cavity.

Optionally, the catheter body further includes an outer tube, the outer tube is sleeved on the fixed tube, the distal end of the fixed tube extends out of the outer tube, the distal end of the balloon is connected with the distal end of the fixed tube, and the proximal end of the balloon is connected with the distal end of the outer tube;

a conductive medium conveying channel is formed between the fixed tube and the outer tube, a cavity is formed between the fixed tube and the balloon, the conductive medium conveying channel is communicated with the cavity, and the conductive medium is used for entering the cavity through the conductive medium conveying channel.

Optionally, the outer tube has an elongation at break less than the elongation at break of the balloon.

Optionally, the electrode pair comprises a ring electrode and/or a patch electrode.

Optionally, the energy generating component includes a plurality of patch electrodes, and the patch electrodes are symmetrically arranged along the circumferential direction of the catheter body.

Optionally, the patch electrode is arc-shaped and is fixed on the outer surface of the catheter body in an adhering manner.

Optionally, the conductive medium is normal saline, conductive hydrogel, oxidation-resistant conductive fluid, or contrast fluid.

Optionally, the catheter body comprises a distal tip configured for piercing a target site.

Optionally, the medical device further comprises an internal lead, an external lead and a high voltage generation controller, the internal lead is respectively connected with the electrode pair and the external lead, and the external lead is connected with the high voltage generation controller.

The medical device is characterized in that the balloon in a contraction state is sleeved on the catheter body in a non-folding manner, and the balloon has a smaller outer diameter size by virtue of the high elasticity of the balloon, so that the dilatation treatment of the narrow or extremely narrow pathological changes can be realized easily through the narrow or extremely narrow calcified pathological changes. In particular, the balloon in the medical device is not folded and has excellent elasticity when being contracted, so that the balloon can be deformed to a smaller outer diameter during the conveying process and even can be tightly attached to the outer surface of the catheter body, the size of the whole outer diameter is very small, and the trafficability is good. Therefore, the medical device has excellent passing performance, can better realize the expansion of the stenosis, avoids the auxiliary operations such as pre-expanding a balloon or using a rotary grinding catheter and the like, ensures that the operation process is simpler and more convenient, improves the operation efficiency, shortens the operation time, and reduces the difficulty of interventional therapy of the stenosis, particularly the stenosis.

The medical device can embed the internal lead into the fixed tube carrying the saccule, so that the outer diameter of the saccule can be further reduced, and the integrity and the insulativity of a circuit can be protected. The medical device can encapsulate the conductive medium in the cavity of the balloon in advance, and at the moment, the medical device can omit a conductive medium conveying channel and an outer tube, so that the passing outer diameter is further reduced, and the passing performance is better.

Drawings

Fig. 1 is a schematic structural view of a medical device according to a first preferred embodiment of the present invention.

Fig. 2 is a schematic structural view of a medical device according to a first preferred embodiment of the present invention in use.

Fig. 3 is a schematic structural view of a medical device according to a second preferred embodiment of the present invention.

Fig. 4 is a schematic structural view of a medical device according to a second preferred embodiment of the present invention in use.

FIGS. 5a and 6a are cross-sectional views of a medical device according to a preferred embodiment of the present invention cut at the ring electrode;

fig. 5b and 6b are cross-sectional views of a medical device according to a preferred embodiment of the utility model, cut at a patch electrode.

Detailed Description

In order to make the content of the present invention more comprehensible, the present invention is further described below with reference to the accompanying drawings and examples. It is to be understood that the utility model is not limited to the specific embodiments described below, and that general alternatives known to those skilled in the art are intended to be included within the scope of the utility model. It is to be noted that the drawings are in a very simplified form and are not to precise scale, which is merely for the purpose of facilitating and distinctly claiming the embodiments of the present invention.

It should be understood that in the following description, references to "upper" and "lower" components may be made based on the accompanying drawings. Spatial terms such as "below …", "below …", "below", "above", and the like are intended to facilitate describing the positional relationship of one element to another element as illustrated in the figures, and may encompass a variety of different orientations of the device in use or operation in addition to the orientation depicted in the figures. The device may be otherwise oriented, such as rotated 90 degrees or at other orientations, and the spatially relative descriptors used herein interpreted accordingly. It should also be understood that in the following description, the term "connected" includes direct connection between systems, components and parts, and also includes connection between systems, components and parts through a medium, i.e. indirect connection. It should be understood that in the following description, "first" and "second" are not limitations on the number of components, but are merely used to distinguish one component from another.

Herein, "proximal" and "distal" are relative orientations, relative positions, and directions of elements or actions with respect to each other from the perspective of a physician using the medical device, although "proximal" and "distal" are not limiting, but "proximal" generally refers to the end of the medical device that is distal from the patient and closer to the operator during normal operation, and correspondingly "distal" or "distal" generally refers to the end of the medical device that is proximal to the patient and further from the operator during normal operation. Herein, "axial" refers to a direction parallel to the axis; "radial" refers to a direction perpendicular to the axis; "circumferential" refers to a direction about an axis. As used herein, the meaning of "plurality" generally refers to two or more.

As background technology, the shock wave balloon catheter based on the liquid electricity effect can destroy the calcified structure of pathological changes of blood vessels through the liquid electricity effect under a conductive medium, so as to realize the expansion of the inner diameter of the inner cavity of the blood vessels and achieve the purpose of treating the blood vessel occlusion. However, with the advance of large-scale clinical research, the balloon catheter has a plurality of disadvantages, wherein the most important problem is that the trafficability of the balloon catheter is poor, that is, the overall trafficability outer diameter of the balloon catheter is large, so that the balloon catheter is difficult to reach the narrow, especially the extremely narrow lesion position, and the treatment is limited. In more detail, the existing balloon catheter based on the electrohydraulic effect generally adopts a balloon with high pressure resistance, has poor compliance and small deformation amount, so that the original size of the balloon is large, and the balloon is usually folded on the catheter before delivery. In addition, the existing balloon catheter based on the electrohydraulic effect is difficult to be well attached to a lesion due to poor balloon compliance, and is also difficult to be attached to various lesion structures such as tortuous lesion, so that the energy transfer is influenced, and the treatment effect is reduced. In addition, the existing balloon catheter based on the electrohydraulic effect has limited adaptability to blood vessels, can only be applied to the condition of certain larger lumen diameters, such as 3.8-4.2 mm lumens, and reduces the application range of the balloon catheter based on the electrohydraulic effect.

In order to solve the technical problems of the existing blast wave balloon catheter, the utility model provides a medical device, which can also be understood as a balloon catheter based on a liquid-electricity effect, the balloon catheter comprises a balloon, a catheter body and an energy generation component, the energy generation component comprises at least one electrode pair, the at least one electrode pair is arranged at the tail end of the catheter body and is positioned in the balloon, a conductive medium is stored in the balloon, the balloon is made of a high-elasticity material, and the balloon in a contraction state is sleeved at the tail end of the catheter body in a non-folding manner. In the utility model, the conductive medium can be pre-packaged in the balloon or can be subsequently injected into the balloon, so long as the purpose of storing the conductive medium through the balloon is achieved.

So configured, the present invention is effective in reducing the outer diameter of the medical device during delivery, even to the extent that the outer diameter of the medical device can approach the level of the microcatheter. The utility model reduces the outer diameter size of the medical device in the conveying process, so that the medical device can pass through the stenotic and extremely-narrow regions of blood vessels, such as serious stenotic calcified lesions, and realizes the expansion and the electrohydraulic treatment at the lesions after reaching the lesions, thus realizing the interventional treatment of the stenotic lesions and even extremely-narrow lesions, expanding the application range of the shock wave balloon catheter based on the electrohydraulic effect, reducing the difficulty in treating the stenotic lesions and improving the treatment effect.

More specifically, the balloon is made of a high-elasticity material, the balloon is good in compliance and large in deformation amount, so that the original size of the balloon can be made smaller, the balloon can be fixed on the catheter without being folded before delivery, and the smaller passing outer diameter can be guaranteed through larger deformation even if the balloon is not folded. More than this, the balloon catheter based on the hydroelectricity effect provided by the utility model has good balloon compliance, so that the balloon can be well attached to pathological changes, and can also be attached to pathological change structures in various shapes, including tortuous pathological changes, thereby having good adaptability and good attachment effect, and ensuring the treatment effect. The balloon catheter based on the electrohydraulic effect can be suitable for blood vessels with more sizes, such as 2.0-5.0 mm lumens, and the application range of the balloon catheter based on the electrohydraulic effect is expanded.

It should be understood that the microcatheter referred to in this disclosure is generally a microcatheter for coronary intervention that has very small dimensions on the outside diameter, such as the currently more commonly used coronary microcatheter having an outside diameter of about 0.024 inches and an inside diameter of about 0.017 inches. The medical device of the present invention has a minimum outer diameter of up to 0.02 inches during delivery, which is close to the outer diameter of a microcatheter, and thus has good passability.

The medical device proposed by the present invention will be described in detail below with reference to the accompanying drawings and preferred embodiments.

< example one >

Referring to fig. 1, the present embodiment provides a medical device including a catheter body, a balloon 12, and an energy generating component. The tail end of the catheter body is accommodated in the balloon 12, the balloon 12 is sleeved at the tail end of the catheter body, and the near end and the far end of the balloon 12 are fixedly connected with the catheter body respectively. The interior of the balloon 12 is used to store a conductive medium. The energy generating means comprises at least one electrode pair comprising a first electrode 15 and a second electrode 16, one of the first electrode 15 and the second electrode 16 being a positive electrode and the other being a negative electrode. At least one electrode pair is arranged at the tail end of the catheter body and is positioned inside the balloon 12, and the use safety is ensured. At least one of the electrode pairs is adapted to receive a high voltage pulse to generate a shock wave. In one embodiment, the catheter body comprises a fixed tube 13 and an outer tube 14, the fixed tube 13 is arranged in the outer tube 14, the distal end of the fixed tube 13 extends out of the outer tube 14 and is arranged in the balloon 12, and the fixed tube 13 can be understood as an inner tube.

The balloon 12 has a deflated state and an inflated state; the balloon 12 in the contracted state is sleeved on the fixed tube 13 in a non-folding manner, that is, the balloon 12 is sleeved on the structure of the fixed tube 13 extending out of the distal end of the outer tube. The far end of the sacculus 12 is fixedly connected with the far end of the fixed tube 13, the near end of the sacculus 12 is fixedly connected with the far end of the outer tube 14, and at least one electrode pair is arranged on the fixed tube 13. And the balloon 12 is made of a highly elastic material to obtain a super-compliant balloon 12. Herein, a highly elastic material refers to an elastomeric material having a material elongation at break (or elongation at break) of more than 300%, i.e., the elongation at break of the balloon 12 is greater than 300%. Preferably, the elongation at break of the balloon 12 is 500% to 800%. In an exemplary embodiment, the material of the balloon 12 is selected from an elastomeric material such as Pebax (polyether block polyamide), TPU (thermoplastic polyurethane elastomer), TPE, and the like. Further, the material of the balloon 12 is selected from materials having high elongation at break and high strength at break, such as TPU materials.

The balloon 12 is made of high-elasticity materials, so that the balloon 12 has excellent elasticity, good compliance and strong deformability, on one hand, the balloon 12 can be fully expanded and better attached to pathological changes, particularly to pathological changes of various shapes and sizes, and the pathological change attachment effect is good, on the other hand, the balloon 12 can be sleeved on the fixed tube 13 in a non-folding manner in a contraction state and is even closely attached to the outer surface of the fixed tube 13, so that the balloon catheter has a smaller passing outer diameter, on the other hand, the pressure resistance (rated burst pressure) of the balloon 12 made of the high-elasticity materials is good, for example, the rated burst pressure can reach about 12atm, the actual instrument working pressure generally does not exceed 10atm, and the good expansion performance can be ensured while fracture is prevented.

It should be understood that, by sleeving the balloon 12 in the contracted state on the fixing tube 13 without folding, and by means of the high elasticity of the balloon 12, the balloon 12 can be almost tightly attached to the outer surface of the fixing tube 13, so that the balloon 12 can have a smaller outer diameter size, and the dilatation treatment of the stenosis or the very-narrow lesion can be easily realized through the calcification lesion of the stenosis or the very-narrow lesion. In the prior art, the balloon is folded and then pressed on the catheter in a conventional operation, and the elasticity of the balloon is poor, in this case, even if the balloon is folded, the outer diameter of the folded balloon is still large, because the folded balloon forms a plurality of folding wings in the circumferential direction, and is usually overlapped in a radial direction in multiple layers at the same position, and the elasticity of the balloon is poor, the overall outer diameter of the balloon in the conveying process is large, and the balloon cannot pass through a narrow or extremely narrow calcified lesion. The balloon 12 of the present invention has no folding and excellent elasticity in the contracted state, and therefore can be deformed to a smaller outer diameter during the delivery process, even can be tightly attached to the outer surface of the fixed tube 13, and obviously, the outer diameter size is very small and the passability is good. Herein, "close fitting" means that the inner wall of the balloon is in contact with the outer wall of the tube, so that the balloon is almost linear in the contracted state.

Further, the catheter body further comprises a distal tip 11, and the distal tip 11 is connected with the distal end of the fixing tube 13. The distal tip 11 is disposed outside the distal end of the balloon 12, and may be fabricated separately from or integrally with the fixation tube 13. The distal tip 11 is similar to a needle, and serves the purpose of piercing the calcified area.

Further, the electrode pair in the present application may be a ring electrode and/or a patch electrode, and the number of the positive electrode may be one or more, the number of the negative electrode may also be one or more, and the numbers of the positive electrode and the negative electrode may be the same or different.

In some embodiments, one of the first electrode 15 and the second electrode 16 is a ring electrode, and the other is a patch electrode. In other embodiments, the first electrode 15 and the second electrode 16 are both ring electrodes. In other embodiments, the first electrode 15 and the second electrode 16 are patch electrodes. It should be understood that "ring electrode" means annular and fits over the catheter body; as shown in fig. 1, the first electrode 15 is a ring electrode and is sleeved on the fixed tube 13; the patch type electrode is an electrode slice attached to the outer surface of the catheter body; as shown in fig. 1, the second electrode 16 is a patch electrode and is attached to the outer surface of the fixed tube 13. In this embodiment, the first electrode 15 is a ring electrode and is sleeved on the fixed tube 13, and the second electrode 16 is a patch electrode and is attached to the outer surface of the fixed tube 13. In view of the high durability of the ring electrode and the high energy density of the patch electrode based on the principle of the point discharge, which can enhance the liquid-electric effect, the combination of the ring electrode and the patch electrode is preferable.

The distance between the ring electrode and the patch electrode is short, generally less than 1mm, but the ring electrode and the patch electrode are not in contact and are insulated from each other. The relative positions of the first electrode 15 and the second electrode 16 are not limited by this application, and the first electrode 15 may be closer to the distal end of the catheter body or closer to the proximal end of the catheter body than the second electrode 16. In an embodiment, the first electrode 15 is closer to the distal end of the catheter body than the second electrode 16, at this time, the first electrode 15 is preferably a ring electrode, the second electrode 16 is preferably a patch electrode, further, the number of the first electrodes 15 is one, the number of the second electrodes 16 is two and symmetrically arranged, optionally, the ring electrode is a positive electrode, the patch electrode is a negative electrode, or the ring electrode is a negative electrode, and the patch electrode is a positive electrode. The patch electrode is preferably arcuate in shape to fit the outer surface of the fixed tube 13 in such a way as to reduce the outer diameter. The plurality of patch electrodes are symmetrically arranged along the circumferential direction of the fixed tube 13, the number of the patch electrodes includes but is not limited to 2, and may also be 1 or more, and of course, the number of the ring electrodes includes but is not limited to 1.

In one embodiment, the second electrodes 16 are patch electrodes, and the number of the second electrodes is two and the second electrodes are symmetrically arranged, as shown in fig. 5b and fig. 6 b. At least two of the two patch electrodes and the ring electrode form a positive-negative electrode pair, preferably, the two patch electrodes are both negative electrodes, and the ring electrode is a positive electrode, so that the energy density is high, and the damage effect is good. Compared with the mode of stacking patch type electrodes in a multilayer mode in the prior art, the utility model arranges a plurality of patch type electrodes in a single mode along the circumferential direction, and can further reduce the overall passing outer diameter.

The medical device further comprises an inner wire 17 and an outer wire 18, the inner wire 17 comprises a first wire 171 and a second wire 172, the first electrode 15 is connected with the first wire 171, and the second electrode 16 is connected with the second wire 172. The first and second wires 171 and 172 extend in the axial direction inside the fixed pipe 13 and are spaced apart from each other. The internal lead 17 is connected to the external lead 18, and the external lead 28 is also connected to the high voltage generation controller 19.

Further, the medical device includes the high voltage generation controller 19. The high voltage generation controller 19 is disposed at the proximal end of the catheter body and is used to send high voltage pulses to the energy generating means. The electrode pair sends out electric arc after receiving high-voltage pulse, the conducting medium around the vaporization forms steam bubble, produces the shock wave after steam bubble inflation, breaks, and the shock wave passes through the conducting medium transmission in sacculus 12 and surrounding vascular wall to act on the calcification kitchen. Repeated pulses can crush calcific foci without damaging the vessel wall and surrounding soft tissue.

The external lead 18 includes a positive lead connected to the positive electrode, such as the first lead 171, so that the first electrode 15 constitutes the positive electrode, and a negative lead connected to the negative electrode, such as the second lead 172, so that the second electrode 16 constitutes the negative electrode.

It is further preferred that the inner wire 17 is buried in the fixing tube 13 to prevent the inner wire from being exposed outside the catheter. Compared with the prior art that the inner lead is exposed between the fixed tube 13 and the outer tube 14, the inner lead 17 is embedded in the fixed tube 13, so that the integrity and the insulation of a circuit can be better protected, the passing outer diameter of a medical device can be further reduced, and the passing performance of the balloon catheter based on the electrohydraulic effect is better.

In view of the small size of the fixed pipe 13, if the lead is embedded inside, there is a certain difficulty in the process, and the processing precision is difficult to ensure. In order to overcome these difficulties, in an embodiment, as shown in fig. 5a and 5b, the fixing tube 13 is processed into a solid structure (i.e., a solid tube), and at this time, the difficulty of embedding the wire is reduced by increasing the wall thickness of the fixing tube 13 without increasing the outer diameter of the fixing tube 13, so as to ensure the processing precision. That is, the fixed pipe 13 may be a pipe having the same outer diameter as that of the conventional one, and the lead wires may be embedded in the wall of the solid pipe. Further, during processing, the fixed pipe 13 with the internal lead 17 embedded therein can be obtained by integral extrusion molding, that is, the internal lead 17 is embedded into the fixed pipe 13 during the extrusion process. In other embodiments, the fixing tube 13 may also be processed into a two-layer tube, specifically, the fixing tube 13 includes an inner layer and an outer layer, the inner layer is, for example, a solid tube or the hollow tube in fig. 6a and 6b, in actual operation, the inner layer with the installation groove on the surface may be extruded first, then the inner wire 17 is embedded in the installation groove of the inner layer, then a layer of material is covered outside the inner layer to obtain the outer layer, and the outer layer covers the inner layer and the inner wire 17, so as to obtain the fixing tube 13 with the inner embedded inner wire 13, thereby reducing the processing difficulty and ensuring the processing precision.

In one embodiment, as shown in fig. 1, a conductive medium delivery channel 142 is formed between the outer tube 14 and the fixing tube 13, a cavity 141 is formed between the balloon 12 and the fixing tube 13, and the conductive medium delivery channel 142 is communicated with the cavity 141 in the balloon 12, so that a conductive medium 143 is delivered to the cavity 141 in the balloon 12 through the conductive medium delivery channel 142. Conductive medium 143 may not only conduct electricity, but may also fill balloon 12, causing balloon 12 to expand. The present application is not limited to a specific type of conductive medium 143. The conductive medium 143 may be physiological saline, conductive hydrogel, antioxidant conductive liquid, contrast liquid, or the like. The oxidation-resistant conductive liquid can prevent the conductive medium from damaging the electrode so as to improve the durability of the electrode. In this embodiment, after the balloon 12 reaches the lesion site, the conductive medium 143 may be injected into the balloon 12, which is beneficial to evacuating the cavity 141 in the balloon during the delivery process, so that the balloon 12 may be closely attached to the outer surface of the fixing tube 13 before filling, and the passing outer diameter of the balloon 12 is very small.

Further, the fracture elongation of the outer tube 14 is preferably smaller than that of the balloon 12, so as to control the deformation amount of the outer tube 14 during the subsequent expansion of the balloon 12, and ensure that the balloon 12 can smoothly and closely fit with the lesion position. Therefore, the material of the outer tube 14 is different from that of the balloon 12, for example, Nylon (Nylon) with low elongation percentage, polyether block polyamide (Pebax), etc. can be used for the outer tube 14.

Please refer to fig. 2, which shows the actual clinical use of the medical device. After the intervention, the medical device, by virtue of its ultra-low through-outer diameter, can pass through the stenotic lesion to reach the location of the targeted lesion 121 (the targeted lesion calcified area). After reaching the target lesion 121, a conductive medium is injected into the cavity 141 in the balloon through a conductive medium delivery channel 142 communicated with the cavity 141 in the balloon. By controlling the amount and pressure of the injected conductive medium, the expanded diameter of the balloon 12 can be controlled until the balloon 12 conforms to the targeted lesion 121. Preferably, the injected conductive medium has X-ray developability, and after the balloon 12 is expanded, an operator can observe the expansion condition of the balloon 12 and the fitting condition of the balloon 12 and the targeted lesion 121 through X-rays, so that the operation is more convenient. After the balloon 12 and the targeted lesion 12 are fully fitted, high voltage pulses are delivered to the first electrode 15 and the second electrode 16 via the outer lead 18 and the inner lead 17 using the high voltage generator controller 19. After the high-energy electrons are gathered to the first electrode 15 and the second electrode 16, the conducting medium between the two electrodes is broken down to generate the liquid-electricity effect, and finally the generated shock wave acts on the targeted lesion 121 to realize the damage to the targeted calcified structure. The balloon 12 generates an expansion force that completes the expansion of the tube diameter of the targeted lesion 121 in synchronization with the pressure provided via the conductive medium delivery channel 142 and the lumen 141 within the balloon. In this way, pre-dilation of the stenotic lesion with a medical device may be achieved, establishing sufficient vessel lumen size to assist in subsequent access to the targeted lesion 121 through a relatively large outer diameter medical device, such as a stent transporter, a drug balloon, and the like.

Referring to fig. 5a and 5b, in an embodiment, the fixing tube 13 is a solid structure and is of an integrated design, i.e. is a solid tube, which can further reduce the overall passing outer diameter of the medical device to pass through a more severe diseased blood vessel.

Referring to fig. 6a and 6b, in another embodiment, the fixing tube 13 is a hollow tube, the central hole is a guide wire cavity 131 for passing a guide wire, and the guide wire cavity 131 can establish a channel besides passing the guide wire, such as providing an injection path for drugs, and targeting the lesion. The other structure of this solution is similar to that of fig. 5a and 5b and will not be described in detail.

Further, the fixing tube 13 is made of a material with high strength, such as a medical metal material or a polymer material with good strength, such as stainless steel, nickel-titanium alloy, high-strength nylon material, and the like. By adjusting the material of the fixation tube 13, a strong support can be provided for the medical device to reach the lesion site.

Further, the medical device further includes a connection medium connected to the internal lead 17 and the electrode pair, respectively. The connecting medium serves to fix the inner lead 17 in the fixing tube 13 and also to further fix the electrode pair on the fixing tube 13. The connecting medium provides the function of physically fixing and conducting current.

As shown in fig. 5a and 6a, the first electrode 15 is a ring electrode and is connected to a first lead 171, and the first lead 171 is embedded in the fixing tube 13 and is conductively connected to the first electrode 15 through a first connecting medium 151. As shown in fig. 5b and fig. 6b, the second electrode 16 is a patch electrode and is connected to a second lead 172, and the second lead 172 is embedded in the fixed tube 13 and is conductively connected to the second electrode 16 through a second connecting medium 161. The first connecting medium 151 and the second connecting medium 161 provide functions of physically fixing and conducting current, i.e., both conductive materials, and the first electrode 15 is adhesively fixed on the surface of the fixing tube 13 through the first connecting medium 151, and the second electrode 16 is adhesively fixed on the surface of the fixing tube 13 through the second connecting medium 161. That is, the connection medium has viscosity and conductivity, and can be electrically conductive and adhesive, and the connection medium can be made of conductive adhesive, soldering, or the like. In this embodiment, the first connecting medium 151 is connected to the first wire 171 and the first electrode 15 by soldering, conductive adhesive bonding, or the like, and the second connecting medium 161 is connected to the second wire 172 and the second electrode 15 by soldering, conductive adhesive bonding, or the like.

< example two >

The structure of the medical device provided in this embodiment is substantially the same as that of the medical device in the first embodiment, and only different points will be described below, and the same portions can be referred to in the first embodiment. It should be understood by those skilled in the art that various changes described in the first embodiment are also applicable to the second embodiment, and therefore, the present invention is within the protection scope of the present invention, and the detailed description is omitted here.

Referring to fig. 3, the medical device of the present embodiment may further include a conductive medium 143, wherein the conductive medium 143 is pre-packaged in the balloon 12, that is, the position of the cavity 141 in the balloon in the first embodiment is replaced, and the outer diameter of the balloon 12 is controlled by controlling the amount and pressure of the packaged conductive medium 143. In this case, the outer tube 14 may be eliminated, and only the fixing tube 13 may be left, so that both the proximal end and the distal end of the balloon 12 are fixedly connected to the fixing tube 13, and therefore, the conductive medium delivery path 142 and the outer tube 14 may be omitted from the medical device, and the passing outer diameter may be more effectively reduced.

Please refer to fig. 4, which shows the actual clinical use of the medical device. After the intervention in the blood vessel, the medical device carries the pre-encapsulated conductive medium 143 to the location of the targeted lesion 121. The balloon 12 with the conductive medium 143 encapsulated therein is closely attached to the targeted lesion 121. High voltage pulses are delivered to the distal first electrode 15 and the distal second electrode 16 by the high voltage generation controller 19, thereby generating a hydro-electric effect and generating shock waves that destroy calcified structures of the targeted lesion 121. The expansibility of the calcified lesion which is difficult or even impossible to expand is increased through the damage to the calcified structure, so that sufficient lumens are established to assist the passage of other therapeutic instruments.

According to the technical scheme provided by the embodiment of the utility model, the medical device provided by the utility model has small overall outer diameter size which is even close to the level of a micro catheter, can be inserted into an extremely narrow blood vessel, and can release shock waves to destroy a calcified focus structure of a target blood vessel, so that the medical device has excellent trafficability and can well realize the expansion of a narrow lesion by combining a liquid-electric effect. Especially when the internal lead is embedded in the fixing tube, the outer diameter of the balloon can be further reduced, and the integrity and the insulation of the circuit are also protected. Particularly, the patch type electrode adopts a single-layer separation structure, so that the overall passing outer diameter is further reduced. Moreover, the patch type small electrode enhances the liquid electricity effect by means of the point discharge principle. In actual operation, the conducting medium can be filled into the saccule afterwards, at the moment, in the conveying process, by utilizing the super-compliance of the saccule, the saccule can be tightly attached to the surface of the catheter when the saccule is not filled, and the larger radial size expansion can be realized in the filling state, so that the soft compliance is good, and in the expansion process, the good pathological change fit can also be realized. In an alternative, the conductive medium may also be pre-encapsulated within the balloon, allowing the medical device to omit the conductive medium delivery channel and the outer tube, resulting in a further reduction in the outer diameter. It will be appreciated that the medical device of the utility model is particularly suitable for coronary interventions, but may of course be applied to interventions in other blood vessels.

The above description is only for the purpose of describing some embodiments of the present invention, and is not intended to limit the scope of the present invention, and any variations and modifications made by those skilled in the art according to the above disclosure are within the scope of the present invention.

Claims (17)

1. A medical device comprises a catheter body, a balloon and an energy generation component, wherein the energy generation component comprises at least one electrode pair, the at least one electrode pair is arranged at the tail end of the catheter body and is positioned in the balloon, a conductive medium is stored in the balloon, the balloon is made of a high-elasticity material, and the balloon is sleeved at the tail end of the catheter body in a non-folding mode in a contraction state.

2. The medical device of claim 1, wherein the balloon has an elongation at break of greater than 300%.

3. The medical device of claim 2, wherein the balloon has an elongation at break of 500% to 800%.

4. The medical device of claim 1, wherein the catheter body comprises a fixed tube, the balloon in a deflated state is fitted over the fixed tube in an unfolded manner, the electrode pair is disposed on the fixed tube, and the medical device further comprises an internal lead connected to the electrode pair, the internal lead being embedded in the fixed tube.

5. The medical device of claim 4, wherein the fixation tube is a hollow tube or a solid tube.

6. The medical device according to claim 4, wherein the fixing tube and the inner wire are connected by being integrally extruded, or wherein the fixing tube comprises an inner layer and an outer layer, wherein a mounting groove is formed on the surface of the inner layer, and after the inner wire is embedded in the mounting groove, the outer layer is sleeved on the inner layer to cover the inner layer and the inner wire.

7. The medical device of claim 4, further comprising a connecting medium connected to the internal lead and the electrode pair, respectively.

8. The medical device of claim 7, wherein the electrode pair comprises a first electrode and a second electrode, the internal lead comprises a first lead and a second lead, and the connection medium comprises a first connection medium and a second connection medium;

the first and second wires extend axially inside the fixed tube and are spaced apart from each other; the first electrode is connected with the first lead through the first connecting medium; the second electrode is connected with the second lead through the second connecting medium.

9. The medical device of any one of claims 4-8, further comprising the conductive medium, wherein the balloon is coupled to the fixation tube at both the proximal end and the distal end, wherein a cavity is formed between the fixation tube and the balloon, and wherein the conductive medium is encapsulated within the cavity.

10. The medical device of any one of claims 4-8, wherein the catheter body further comprises an outer tube, the outer tube fitting over the stationary tube, a distal end of the stationary tube extending out of the outer tube, a distal end of the balloon coupled to the distal end of the stationary tube, a proximal end of the balloon coupled to the distal end of the outer tube;

a conductive medium conveying channel is formed between the fixed tube and the outer tube, a cavity is formed between the fixed tube and the balloon, the conductive medium conveying channel is communicated with the cavity, and the conductive medium is used for entering the cavity through the conductive medium conveying channel.

11. The medical device of claim 10, wherein the outer tube has an elongation at break that is less than the elongation at break of the balloon.

12. The medical device of any one of claims 1-3, wherein the electrode pair comprises a ring electrode and/or a patch electrode.

13. The medical device of claim 12, wherein the energy generating component comprises a plurality of the patch electrodes symmetrically arranged along a circumference of the catheter body.

14. The medical device of claim 12, wherein said patch electrode is arcuate in shape and adhesively secured to the outer surface of said catheter body.

15. The medical device of any one of claims 1-3, wherein the conductive medium is physiological saline, a conductive hydrogel, an oxidation resistant conductive fluid, or a contrast fluid.

16. The medical device of any one of claims 1-3, wherein the catheter body includes a distal tip configured for piercing a target site.

17. The medical device according to any one of claims 1-3, further comprising an internal lead connected to the pair of electrodes and the external lead, respectively, an external lead connected to the high voltage generation controller, and a high voltage generation controller.

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