CN113644405A

CN113644405A - Implantable medical device

Info

Publication number: CN113644405A
Application number: CN202110913250.4A
Authority: CN
Inventors: 平利川; 丁皓; 刘威
Original assignee: Suzhou Wushuang Medical Equipment Co ltd
Current assignee: Suzhou Wushuang Medical Equipment Co ltd
Priority date: 2021-08-10
Filing date: 2021-08-10
Publication date: 2021-11-12
Anticipated expiration: 2041-08-10
Also published as: CN113644405B

Abstract

The invention proposes an implantable medical device comprising: a housing assembly; a head assembly disposed on the housing assembly; a main body circuit board disposed within the housing assembly; the capacitance adjusting circuit is arranged on the main body circuit board and comprises a varactor and a direct current bias circuit; the antenna is arranged in the head assembly, a first end of the antenna is connected with the capacitance adjusting circuit, a second end of the antenna is connected with the matching network circuit to form a ring-shaped current path, and the capacitance adjusting circuit is used for adjusting the working frequency of the antenna. The implantable medical device provided by the invention can dynamically adjust the working frequency of the antenna, can be used for correcting the working frequency of the antenna, and can also be used for adjusting the frequency to meet different working modes or applications.

Description

Implantable medical device

Technical Field

The invention relates to the field of medical equipment, in particular to implantable medical equipment.

Background

Currently, with the continuous decline of population fertility rate, the problem of population aging is continuously aggravated, which has become a common problem in all countries in the world. The aging population is increasing, and there is a great market demand for high-quality healthcare services. Based on this background of application, wireless implantable medical systems are being proposed and are continually developed and applied, particularly implantable cardiac pacemakers/defibrillators and the like. The wireless implantable medical system can monitor, prevent and treat the physical condition of the patient in real time, and greatly ensures the life safety and the happy life of the patient.

The antenna is used as a bridge for wireless communication between the wireless implanted medical equipment and external program control equipment, and is an indispensable component of a wireless implanted medical system, and the performance of the antenna can directly determine whether the implanted medical equipment can normally and controllably work. When the implantable medical device works in the body, the working frequency of the antenna may shift along with different implantation environments, so that the antenna is difficult to work normally under different implantation environments. Meanwhile, when the implantable medical device works in a human tissue environment for a long time, the implantable medical device may have problems of liquid leakage, liquid permeation and the like, which means that the environment around the antenna is not wrapped by the original material, the equivalent dielectric constant of the environment is increased, the working frequency of the antenna is shifted to a low frequency, and thus the working performance of the antenna is reduced, and in severe cases, a communication link between the middle implantable medical device and external control equipment is formed.

Disclosure of Invention

In view of the above drawbacks of the prior art, the present invention provides an implantable medical device, which can adjust the operating frequency of an antenna by adjusting an access adjustable capacitance value when the operating frequency of the antenna deviates in time according to the environmental change around the antenna, and can keep the antenna operating normally in different environments.

To achieve the above and other objects, the present invention provides an implantable medical device, comprising:

a housing assembly;

a head assembly disposed on the housing assembly;

a main body circuit board disposed within the housing assembly;

the capacitance adjusting circuit is arranged on the main body circuit board and comprises a varactor and a direct current bias circuit;

the antenna is arranged in the head assembly, a first end of the antenna is connected with the capacitance adjusting circuit, a second end of the antenna is connected with the matching network circuit to form a ring-shaped current path, and the capacitance adjusting circuit is used for adjusting the working frequency of the antenna.

Further, the antenna includes a first metal sheet, a second metal sheet, a third metal sheet and a fourth metal sheet.

Further, the first metal sheet, the second metal sheet, the third metal sheet and the fourth metal sheet are connected in sequence.

Further, the main body circuit board is connected with a flexible circuit board through a matching network, and the flexible circuit board is connected with a low-voltage circuit board.

Further, the first metal sheet is connected with the low-voltage circuit board through a feed structure.

Further, the first metal sheet is perpendicular to the second metal sheet, the second metal sheet is perpendicular to the third metal sheet, and the third metal sheet is perpendicular to the fourth metal sheet.

Further, the second metal sheet and the third metal sheet form the bent portion.

Further, the fourth metal sheet is connected with the capacitance adjusting circuit through a metal probe.

Further, the fourth metal sheet and the capacitance adjusting circuit are located on two sides of the main body circuit board.

Further, the length of the third metal sheet is greater than the length of the second metal sheet.

Further, the antenna comprises at least one bending part.

Furthermore, the second metal sheet and the third metal sheet are coplanar and are connected perpendicularly to each other, the first metal sheet and the fourth metal sheet are perpendicular to a plane where the second metal sheet and the third metal sheet are located, and the first metal sheet and the fourth metal sheet are located on the same side of the plane where the second metal sheet and the third metal sheet are located.

In summary, the present invention provides an implantable medical device, which includes a housing assembly and a head assembly, wherein a main circuit board is disposed in the housing assembly, and a capacitance adjusting circuit is disposed on the main circuit board. An antenna is arranged in the head assembly, one end of the antenna is connected with the capacitance adjusting circuit, and the capacitance adjusting circuit comprises a varactor. When the environment around the antenna changes, the capacitance adjusting circuit can change the capacitance value of the series-connected antenna by changing the direct current bias circuit, so that the working frequency of the antenna can be adjusted, the working frequency of the antenna can meet the working requirements of different implantation environments, and the working requirements under different frequency band modes can be met.

Drawings

FIG. 1: the invention discloses an appearance structure of an implanted medical device and a schematic diagram of relative positions of components of the implanted medical device in a human body when the implanted medical device is implanted in the human body.

FIG. 2: the invention is a structural diagram of an implantable medical device.

FIG. 3: the position of the antenna and housing assembly of the present invention is illustrated.

FIG. 4: the invention relates to a connection diagram of an antenna and a main circuit board.

FIG. 5: the structure of the antenna of the present invention.

FIG. 6: another structural diagram of the antenna of the present invention.

FIG. 7: the invention discloses a PI type circuit.

FIG. 8: response diagrams of the operating bandwidth of the antenna of the present invention.

FIG. 9: another block diagram of an implantable medical device of the present invention.

FIG. 10: another connection diagram of the antenna and the main body circuit board in the invention.

FIG. 11: another structural diagram of the antenna of the present invention.

FIG. 12: the invention discloses a schematic diagram of a capacitance adjusting circuit.

FIG. 13: another response plot of the operating bandwidth of the antenna of the present invention.

Detailed Description

The embodiments of the present invention are described below with reference to specific embodiments, and other advantages and effects of the present invention will be easily understood by those skilled in the art from the disclosure of the present specification. The invention is capable of other and different embodiments and of being practiced or of being carried out in various ways, and its several details are capable of modification in various respects, all without departing from the spirit and scope of the present invention.

It should be noted that the drawings provided in the present embodiment are only for illustrating the basic idea of the present invention, and the components related to the present invention are only shown in the drawings rather than drawn according to the number, shape and size of the components in actual implementation, and the type, quantity and proportion of the components in actual implementation may be changed freely, and the layout of the components may be more complicated.

Fig. 1 is a schematic structural diagram of an external appearance structure of an implanted medical device and relative positions of components of the external appearance structure in a human body when the external appearance structure is implanted in the human body. Using ICD100 as an example, the specific operation of an implantable medical device when implanted in a region of the heart 114 of a human body 200 is described. ICD100 is comprised of a housing assembly 101, a head assembly 102, and a lead 109. ICD100 has mounted therein a host circuit board, power supply, capacitors, transformers, feedthrough assemblies, feedthrough buffer assemblies, and antennas. The implantable medical device has four functions 120: a processor function 122, a memory function 124, a telemetry function 126, and an interface function 128. Typically, ICDs are also capable of performing user display functions by interfacing with an in vitro programmer or remote follow-up. The processor function 122 means that the ICD can autonomously sense cardiac electrical signals or physiological parameters of the human body 200 through the electrodes, autonomously perform diagnosis, and issue treatment commands. If ICM, the processor function means that it is capable of performing a diagnosis based on the cardiac electrical signal parameters, excluding treatment commands. The memory function 124 means that the ICD has a function of storing the cardiac electrical signal for a period of time and searching or reading the cardiac electrical signal parameters recorded at the period of time at a later time. The feedthrough assembly of the implantable medical device encapsulates the antenna feedthrough and the lead feedthrough inside. The ICD feed-through component is provided with a high-voltage part and a low-voltage part, and the high-voltage part is connected with a high-voltage electrode of a lead; the low-voltage part is a sensing part and an antenna part, the sensing part is connected with the wire sensing electrode, and the antenna part is connected with the antenna. The ICD function can be achieved through two modes, one mode is that the ICD body can be regulated and controlled independently, and manual triggering and control are not needed. The other is to control the ICD by communicating through an external programming device, which is generally a programming device, a patient assistant, or other devices capable of issuing commands to the ICD or sensing internal signals. The communication mode between the ICD and the external program control equipment can be one or more of wireless communication networks such as wired communication, Bluetooth, WIFI, LTE or CDMA and the like. While the ICD needs to have interface functionality 128, for example, the ICD needs to implement far-field telemetry monitoring and control via a bluetooth interface, a wireless interface, or a wired interface, the implantable medical device has at least one of these interface functionalities. The lead 109 shown in fig. 1 is a single lead, and may be a double lead, a triple lead, or a quadruple lead during clinical use. Lead 109 is comprised of defibrillation coil 111, pacing sensing electrode ring end 112, and pacing sensing tip end 113. Lead 109 is connected to ICD device body 116 through head assembly 102. The lead 109 passes through the superior vena cava 132 and the atrium 130 of the body 200 and can be implanted inside the ventricle 110. Coil 111 is capable of defibrillation therapy of the diagnosed ventricular fibrillation event by delivering a pulse. During treatment, the device body shell 118 itself is used as an electrode, and a voltage difference is formed between the electrode and the coil 111, so that the ventricle is electrically stimulated to achieve the treatment purpose. The pacing sensing electrode ring end 112 is capable of sensing cardiac electrical signals and physiological parameters within the heart 114. The pacing sensing head 113 is a spiral fixed head, the pacing sensing head 113 rotates in the lead before use, and when the pacing sensing head is implanted in the heart of a human body, the pacing sensing head 113 rotates out of the lead from one end of the lead and is connected and fixed with the myocardial tissue in the heart. The electrode lead needs to be coated by insulating materials such as silica gel, polyurethane or epoxy resin.

As shown in fig. 2, the present embodiment proposes an implantable medical device 100, where the implantable medical device 100 is, for example, a cardiac pacemaker or a defibrillator, and the present embodiment takes the implantable medical device 100 as a cardiac defibrillator as an example for illustration. The implantable medical device 100 may include a housing assembly 101 and a head assembly 102, the head assembly 102 being disposed on the housing assembly 101. The material of the load bearing components of the housing assembly 101 is biocompatible metal titanium, such as titanium or titanium alloy or stainless steel, and the material of the load bearing components of the head assembly 102 is injection molded of biocompatible high molecular polymer, for example. The head assembly 102 has embedded therein a metal connector that needs to be connected to the circuitry of the titanium housing portion via the metal pins of the feedthrough assembly, while the metal connector is in conductive communication with the electrode leads to effect targeted position treatment of the patient.

As shown in fig. 2-5, in the present embodiment, an antenna 103 is disposed within the head assembly 102, the antenna 103 also being located outside of the housing assembly 101. A main body circuit board 104 is provided inside the housing assembly 101. An antenna 103 may be connected to the main body circuit board 104. A flexible circuit board 107 is disposed on the main body circuit board 104, and a low voltage circuit board 106 is disposed on the flexible circuit board 107, that is, both ends of the flexible circuit board 107 are connected to the main body circuit board 104 and the low voltage circuit board 106, respectively. A through hole may be provided on the low-voltage circuit board 106, and then the feedthrough 105 may be provided in the through hole, so that the connection of the low-voltage circuit board 106 to the antenna 103 may be achieved. In this embodiment, feed structure 105 may feed an RF signal (an alternating current signal) into antenna 103, creating a resonance, thereby generating radiation. In the present embodiment, the flexible circuit on the flexible circuit board 107 is connected to the main body circuit on the main body circuit board 104.

As shown in fig. 4 to 5, in the present embodiment, the antenna 103 may be a metal sheet, and the antenna 103 may be made of a common metal, so that the cutting process is easy. The antenna 103 may include a first metal sheet 1031 and a second metal sheet 1032, and the metal sheets may also be a tapered metal sheet or a flexible metal PCB structure. The antenna 103 may include a first metal sheet 1031 and a second metal sheet 1032. The first and

second metal sheets

1031, 1032 may be connected obliquely, i.e. the first and

second metal sheets

1031, 1032 are not in the same plane, and the connection angle of the first and

second metal sheets

1031, 1032 may be greater than 90 °, for example 120 ° or 150 °. The width of the first metal sheet 1031 may be smaller than that of the second metal sheet 1032. One end of the first metal plate 1031 is connected to the second metal plate 1032, the other end of the first metal plate 1031 is connected to the feeding structure 105, and the first metal plate 1031 is connected to the feeding structure 105 through a metal probe, for example, so as to connect the antenna 103 and the main circuit board 104. The first metal sheet 1031 and the second metal sheet 1032 serve as a radiation structure of the antenna 103, and the first metal sheet 1031 and the second metal sheet 1032 form a bandwidth gradually changing structure such as a butterfly structure or a planar cone structure shown in fig. 5. The second metal sheet 1032 can realize broadband response of the antenna 103, and can meet communication requirements in different environments and dynamically variable environments.

As shown in fig. 5 to 6, in the present embodiment, the width of the second metal sheet 1032 is greater than the width of the first metal sheet 1031, and the first metal sheet 1031 may be located at one end of the second metal sheet 1032. Near the connection between the first metal sheet 1031 and the second metal sheet 1032, the width of the first metal sheet 1031 gradually widens until the first metal sheet 1031 is connected with the second metal sheet 1032 to form a butterfly-shaped broadband gradual change structure, so that the operating frequency of the antenna smoothly covers from 2.2GHz to 2.8GHz, the operating frequency band of the antenna 103 is wider, and the antenna can be suitable for application requirements in different communication environments and dynamically variable environments. The connection of the first metal sheet 1031 and the second metal sheet 1032 may be a chamfered connection, or may be a direct mechanical bending of metal or a single sheet of metal in common.

As shown in fig. 4 and 7, in the present embodiment, the flexible circuit board 107 may be connected to the main body circuit board 104 through a matching network. The matching network can be used for adjusting the port impedance of the antenna 103, so that the port of the antenna 103 is in good matching, and the radiation performance of the antenna 103 is improved. The matching network may be a PI type circuit 1071, the PI type circuit 1071 being, for example, a combination of a capacitor and an inductor. The PI type circuit 1071 is connected to the feed structure 105 (i.e., RF) through the flexible circuit board 107 and the low voltage circuit board 106, that is, to the port of the antenna 103, thereby realizing that the PI type circuit adjusts the port impedance of the antenna 103, making the port of the antenna 103 in a good matching state, and thus improving the radiation performance of the antenna 103. In this embodiment, the antenna radiation can be equivalent to an RLC resonant network, Lr represents the antenna equivalent inductance, Cr represents the antenna equivalent capacitance, and Rr represents the antenna equivalent resistance.

As shown in fig. 8, which is a response diagram of the operating bandwidth of the antenna 103, it can be seen from fig. 8 that the operating frequency band of the antenna 103 is wide, the-10 dB impedance bandwidth can cover 2.2-2.8GHz, and the like, and can completely meet the 2.4GHz communication requirement. In addition, the antenna 103 has wide working frequency range coverage and flexible antenna frequency control, so that the antenna 103 can also be expanded to 400MHz implantable device application and sub 6GHz implantable/wearable device application.

As shown in fig. 2-7, in this embodiment, the antenna 103 has the advantages of small space size, compact structure, wide operating frequency band, and smart structure. The antenna 103 can meet the communication requirements of implantable medical devices with different functions and types and other narrow application environments, and can meet the application requirements of different environments and dynamic variable environments. Meanwhile, the problems of frequency deviation and the like caused by the phenomenon of liquid leakage when the implantable medical device 100 works for a long time in different positions and different tissue structures of a human body can be solved, and stable and reliable wireless communication can be realized. This antenna 103 adopts all metal construction, is fit for low-cost production and application, and antenna 103's radiation efficiency is high, and antenna 103 job stabilization nature is high, and the robustness is strong.

As shown in fig. 9-10, the present embodiment further provides an implantable medical device 100, which is different from fig. 3 in that the antenna 103 has a different structure. The antenna 103 is also disposed outside the housing assembly 101. The antenna 103 may include a first metal sheet 1031, a second metal sheet 1032, a third metal sheet 1033, and a fourth metal sheet 1034. The first metal sheet 1031, the second metal sheet 1032, the third metal sheet 1033, and the fourth metal sheet 1034 are connected in this order. The connection manner of the first metal sheet 1031 and the main body circuit board 104 may refer to the above description. The first metal sheet 1031 is vertically connected to the second metal sheet 1032, and the first metal sheet 1031 is connected to the second metal sheet 1032 by a chamfer. The second metal plate 1032 is vertically connected to the third metal plate 1033, and the second metal plate 1032 and the third metal plate 1033 are coplanar. The second metal sheet 1032 and the third metal sheet 1033 are formed in a bent shape. The third metal sheet 1033 is vertically connected to the fourth metal sheet 1034, and the third metal sheet 1033 and the fourth metal sheet 1034 are connected by a chamfer. The fourth metal piece 1034 extends in the direction of the main body circuit board 104 so as to be connected to the main body circuit board 104 by the metal probes 108. In this embodiment, the first metal plate 1031 is connected to a matching network circuit, such as a PI-type circuit, which is disposed on the main circuit board 104 and used for adjusting the port impedance of the antenna 103, so that the port of the antenna 103 is in a good matching state, and the radiation performance of the antenna 103 can be improved. The end of the fourth metal sheet 1034 is shorted to the main body circuit board 104 by the metal probe 108, so as to form a current loop of the antenna 103, thereby realizing antenna radiation. In this embodiment, the second metal sheet 1032 and the third metal sheet 1033 are coplanar, the second metal sheet 1032 and the third metal sheet 1033 are perpendicular, and the first metal sheet 1031 may be parallel to the fourth metal sheet 1034 and located on the same side of the plane where the second metal sheet 1032 and the third metal sheet 1033 are located. Since the second metal plate 1032 and the third metal plate 1033 are formed in a bent shape, the structure of the head assembly 102 can be applied.

As shown in fig. 11, in the present embodiment, the height of the first metal sheet 1031 may be smaller than the height of the fourth metal sheet 1034. The length of the second metal sheet 1032 may be less than the length of the third metal sheet 1033. Considering the shape and structure of the head assembly, the second metal plate 1032 and the third metal plate 1033 form a bending portion, and the antenna 103 is accommodated in the head assembly 102, thereby realizing a miniaturized design and a conformal design of the antenna 103. Of course, in some embodiments, two or three bending portions may also be disposed between the first metal sheet 1031 and the fourth metal sheet 1034, thereby making the antenna 103 better conformal with the head assembly 102.

As shown in fig. 10 and 12, in the present embodiment, a capacitance adjusting circuit is further disposed on the back surface of the main body circuit board 104, and one end of the fourth metal piece 1034 is connected to the capacitance adjusting circuit through the metal probe 108. The capacitance adjusting circuit is used for changing direct current bias voltage, then changing a capacitance value which is connected in a loop in series, achieving adjustment of the working frequency of the antenna 103, and being capable of meeting frequency reconfigurable requirements of different application scenarios. In this embodiment, the adjustable capacitor is in the form of a varactor, and may also be other adjustable capacitor elements, such as a variable capacitor chip, a switched capacitor array, a MEMS capacitor, and the like. In this embodiment, the varactor is flyback through a direct current signal (DC), and then controls a capacitance value of the varactor connected to the antenna or the RF circuit, the inductor LS is used in the DC bias circuit to achieve isolation (choke) of the radio frequency signal, and the capacitor Cs is used in the ac circuit to achieve isolation of the DC signal.

Fig. 13 is a graph showing the operational bandwidth response of the antenna of fig. 9. As can be seen from fig. 13, the adjustable range of the operating frequency of the antenna is large, the adjustable range of the operating frequency of the antenna covers 2 to 3GHZ, and the communication requirement of 2.4GHZ can be completely covered. In actual work, because the implanted medical equipment is influenced by the surrounding implantation environment, the working frequency of the antenna deviates, the adjustable capacitance value is accessed through voltage adjustment, the working frequency of the antenna is corrected, and the 2.40GHz communication frequency band is always covered. Due to the fact that the antenna is provided with a wider frequency tuning range and a flexible tuning mode, the antenna can be expanded to 400MHZ implanted device application and implanted/wearable device application of a Sub 6GHz frequency band.

As shown in fig. 9-13, in this embodiment, an adjustable capacitor element is introduced on the main circuit board 104 to change a capacitance value entering in series, so as to change an effective capacitance value in the whole antenna resonance model, thereby realizing the reconfiguration of the antenna operating frequency. The embodiment adopts an all-metal low-loss structure and a varactor, so that the loss of the antenna is greatly reduced, and the complexity of the adjustable antenna is also reduced to the greatest extent. The working frequency of the antenna is adjustable, frequency deviation caused by liquid leakage of implantable medical equipment in different implantation environments and during long-term operation of the device can be well corrected, and the antenna is suitable for communication requirements of implantable medical equipment.

In summary, the present invention provides an implantable medical device, which includes a housing assembly and a head assembly, wherein a main circuit board is disposed in the housing assembly, and a capacitance adjusting circuit is disposed on the main circuit board. An antenna is arranged in the head assembly, one end of the antenna is connected with the capacitance adjusting circuit, the capacitance adjusting circuit comprises a varactor, and the other end of the antenna is connected with a PI type circuit matching network. When the environment around the antenna changes, the capacitance adjusting circuit can change the capacitance value of the series-connected antenna by changing the direct-current bias voltage, so that the working frequency of the antenna can be adjusted, the working frequency of the antenna can meet the requirements of different environments, and the capacitor adjusting circuit is also suitable for the application requirements of implantable equipment in other frequency band modes.

The above description is only a preferred embodiment of the present application and a description of the applied technical principle, and it should be understood by those skilled in the art that the scope of the present invention related to the present application is not limited to the technical solution of the specific combination of the above technical features, and also covers other technical solutions formed by any combination of the above technical features or their equivalent features without departing from the inventive concept, for example, the technical solutions formed by mutually replacing the above features with (but not limited to) technical features having similar functions disclosed in the present application.

Other technical features than those described in the specification are known to those skilled in the art, and are not described herein in detail in order to highlight the innovative features of the present invention.

Claims

1. An implantable medical device, comprising:

a housing assembly;

a head assembly disposed on the housing assembly;

a main body circuit board disposed within the housing assembly;

2. The implantable medical device of claim 1, wherein the antenna comprises a first metal sheet, a second metal sheet, a third metal sheet, and a fourth metal sheet.

3. The implantable medical device of claim 2, wherein the first metal sheet, the second metal sheet, the third metal sheet and the fourth metal sheet are connected in series.

4. The implantable medical device of claim 2, wherein the body circuit board is connected to a flexible circuit board through a matching network, the flexible circuit board being connected to a low voltage circuit board.

5. The implantable medical device of claim 4, wherein the first metal sheet is connected to the low voltage circuit board by a feed structure.

6. The implantable medical device of claim 3, wherein the first metal sheet is perpendicular to the second metal sheet, the second metal sheet is perpendicular to the third metal sheet, and the third metal sheet is perpendicular to the fourth metal sheet.

7. The implantable medical device of claim 6, wherein the second and third metal sheets form the bend.

8. The implantable medical device of claim 2, wherein the fourth metal sheet is connected to the capacitance adjustment circuit through a metal probe.

9. The implantable medical device of claim 2, wherein the fourth metal sheet and the capacitance adjustment circuit are located on both sides of the main body circuit board.

10. The implantable medical device of claim 2, wherein the third metal sheet has a length greater than a length of the second metal sheet.

11. The implantable medical device of claim 1, wherein the antenna comprises at least one bend.

12. The implantable medical device of claim 3, wherein the second and third metal sheets are coplanar and perpendicularly connected to each other, wherein the first and fourth metal sheets are perpendicular to a plane in which the second and third metal sheets lie, respectively, and wherein the first and fourth metal sheets are on a same side of the plane in which the second and third metal sheets lie.