DE102004043002A1 - Electro-medical implant e.g. cardiac pacemaker, for treatment of human heart, has generator with coil and magnet that are movably arranged such that relative movement between coil and magnet causes induction of voltage and/or current - Google Patents

Abstract

The implant has an electrical energy generator (10) arranged in an implantable housing and comprising an electrical coil (12) and a permanent magnet (11). The coil and magnet are movably arranged with one another such that a relative movement between the coil and the magnet causes the induction of voltage and/or current. Springs (13, 14) serve as storage for mechanical energy and connected with the coil and the magnet.

Description

The The invention relates to an energy source for an electromedical Implant. Such electromedical implants are pacemakers, cardioverter, Defibrillators or the like, for example, for therapy of a human heart with the help of electrical stimulation pulses become.

at All electromedical implants have the problem of such implants provide an energy source for the voltage needed to operate the device respectively the required electricity require. Such energy sources are common today Batteries. These batteries are designed to hold the implant for several years can supply with energy. Batteries usually do the biggest part the volume of the implants and give the implant a lifetime between usually three and eight years. To given by the exhaustion of the battery End of life of the implant must be the implant during surgery be replaced.

A alternative energy supply of an implant is a Provide external energy source and the operation of the implant needed Inductively transfer power to the implant. This requires, that the external energy source is always in sufficient proximity to the implant will be carried. Therefore, such a solution is inadequate for many patients.

Another solution is for example US 5,411,537 known. In this solution, instead of a battery, an accumulator is provided in the implant, which can be charged again and again by wireless energy transmission by means of inductive coupling. Here, the life of the implant is limited by the life of the battery. It is known that the storage capacity of the known accumulators decreases over time, so that the charging cycles must be repeated at ever shorter intervals. If the capacity of the accumulator has finally fallen below a minimum value, an exchange of the implant in an operation is also required in this case. In addition, the compulsion to regularly charge the battery an additional burden on the patient is connected.

From the US 6,640,137 A solution is known in which parallel and series thermocouples are provided to gain energy from temperature differences near the body surface. This solution has the disadvantage that there are required temperature differences only in the immediate vicinity of the body surface in the necessary order of magnitude (at least 2 ° Cal). The energy source or the energy converter must therefore be there. However, since the implant may need to be implanted somewhere else, interference-prone leads are necessary.

In front In this background, it is the object of the invention, an alternative Indicate energy source or an alternative energy converter, the one or the other for the operation of the implant required energy or Performance as appropriate as possible permanently available provides.

According to the invention this Task by a generator for an electro-medical implant and an electromedical one Implant solved with such a generator, in which the generator a electrical coil and a permanent magnet, the relative are mutually movably arranged such that a relative movement between the permanent magnet and the coil, the induction of a Voltage or a current causes, that at the coil is to tap and can serve the energy supply of the implant. Furthermore the generator has a memory for potential, mechanical Energy on, either with the permanent magnet or with the Coil or is operatively connected to both.

In alternative embodiments can electrical Coil and permanent magnet either longitudinally movable relative to each other be arranged or perform a rotational relative movement to each other. generators the mechanical energy for the purpose of powering a device into electrical Convert energy by using a permanent magnet and a coil relative are moved to each other, are basically known, but not in connection with the supply of electromedical implants.

essential Characteristic of the generator according to the invention is the memory for potential, mechanical energy, for example, a mechanical Spring element in the form of a helical spring or in the form of an elastic deflectable membrane, such as a wrinkled membrane or a membrane stretchable material (for example rubber), or a magnetic material Spring element in the form of two, repelling magnets or one pressure compressible medium, such as a gas spring or a sponge can be. Furthermore can the memory for potential, mechanical energy is an elastic extensible and compressible Have hollow chamber, which may also be designed as a wrinkle membrane in the above sense can.

With Help of the memory for Potential mechanical energy can be used to operate the implant required energy from the mechanical heart activity itself be won. The mechanical heart activity can with the generator according to the invention be used when the mechanical movements of the heart too cause a movement of the generator. In this case you can the movements of the generator for the deflection of a spring mass system to lead. The spring of this spring system serves as storage for potential, mechanical energy and is with the permanent magnet or the coil connected and causes at each deflection, the relative movement between the electric coil and the permanent magnet. In a preferred variant is the spring mass system tuned to a resonant frequency, the a typical heart rate, for example between 60 and 90 beats per minute equivalent.

The mechanical heart activity also leads to pressure changes for example, in the bloodstream. These can also be achieved by the generator according to the invention be converted into electrical energy. In this case will be the pressure changes in relative movements between permanent magnets and electrical Coil converted by, for example, one with coil or permanent magnet or both coupled hollow chamber periodically compressed and expanded or by providing an elastic membrane which is as a result of the pressure changes periodically deflects. Subvariants of this embodiment provide that the stretchable or compressible hollow chamber a wrinkle membrane or a flexible or elastic wall that covers when compression or Expansion of the hollow chamber is deflected. The stretchable and compressible Hollow chamber can also be two rigid, relatively movable Have chamber capsules which are sealed from the environment Complete cavity, such that a stretching or compression of the hollow chamber leads to a relative movement leads from coil and permanent magnets.

in the The following will be aspects of various embodiments of a generator the transformation of heart-driven movements or pressure changes called, the objects of alternative or preferred embodiments of the Invention are.

to Conversion of kinetic energy into electrical energy can be the Generator, for example, have a hollow coil in which a permanent magnet movably housed. Such a generator can be on or to be fastened in the heart and "shaken" when the heart beats, due to the inertia of his Mass moves the permanent magnet relative to the coil, if this moved by the heart. Due to the relative movement of permanent magnet and electrical coil, a current is induced in the coil, the tapped and rectified.

permanent magnet and electric coil can each cylindrical be formed, so that the permanent magnet substantially only in a longitudinal direction the arrangement given spatial direction in the coil can move. But they are also spherical Magnets and / or ball or ellipsoidal Coils conceivable in which the magnet in the coil "umolles".

advantageously, the permanent magnet is suspended resiliently and thus directly with the Memory for potential, mechanical energy connected in the form of a spring element. This prevents a striking of the magnet in its movement end positions, so that as possible no energy is lost (respectively transformed into heat or deformation becomes). Furthermore forms the permanent magnet together with the spring element before described spring-mass system. The suspension may e.g. by mechanical Springs or in turn formed by magnetic magnets repulsed by repulsive magnets be realized. The kinetic energy is thereby during the Movement of the arrangement partially transformed into potential energy, the is cached in the spring or in the magnetic field. comes the arrangement to rest, the potential energy becomes kinetic again reconverted which then in turn converted by induction into electrical energy becomes.

advantageously, is in such a generator, which initially discontinuous electrical power a charge storage device (e.g., a capacitor or a so-called "gold cap") is provided the discontinuous energy supply compensates and so a continuous Ensuring the supply of the implant.

In In another embodiment, the permanent magnet on a attached resilient diaphragm which is attached to a housing is, in which the coil is housed. If the arrangement moves, the membrane vibrates so that the attached permanent magnet more or less deep in the coil - more precisely: one of the electrical Coil enclosed cavity - immersed and in this way induces a current in this coil. Of course you can the arrangement also be reversed, i. the coil is attached to the diaphragm and the permanent magnet is rigidly attached to the housing.

Such a membrane may for example be made of substantially smooth, elastic (rubbery) material. In other embodiments The diaphragm may contain bellows-shaped parts which (similar to a loudspeaker) provide for deformability.

One Generator that can convert pressure into electrical energy can do so be designed that a permanent magnet and an electric coil mounted in or on a hermetically sealed hollow chamber which is filled with a compressible or expansible fluid, wherein at least one of the two elements (magnet or coil) with a movable element is connected, which sets in motion becomes when the ambient pressure changes. The compressible fluid For example, a noble gas (e.g., helium, argon) may also be used other gas (e.g., carbon dioxide). Preferably, the fluid a gas that is biocompatible, for the Case that the hollow chamber is leaking. The movable element can For example, a membrane in the already described above Design forms or a sealed slide (a chamber capsule in the sense described above) or via a flexible element (e.g. Bellows) suspended Be plate or a flexible or elastic wall. At rest of the Arrangement prevail both inside and outside of the hollow chamber the same pressure conditions. As the ambient pressure increases, pressed the movable element inward, as the internal pressure then is less than the ambient pressure. When the ambient pressure decreases, the movable element is pulled outwards. In this way become the pressure changes translated into a movement. Since such variants designed this way are that a relative movement of permanent magnet and electric coil arises, is at every pressure change induces a current in the coil, which in the same way as described above for the supply of the electromedical implant can be used.

to Increase in effectiveness can Means for the transformation of kinetic energy and the conversion of pressure changes be combined into electrical energy also in a generator.

In special designs Of the embodiments described above, the movement is through translates a gear or linkage and / or converted into a rotary motion, allowing a faster relative movement of permanent magnet and electric coil is to generate, as it would be possible with the simple embodiments described above. Thereby More kinetic energy can be converted into electrical energy.

The Conversion of pressure changes in Electrical energy can also be done by means of a turbine, the in a current is arranged, which is caused by the pressure changes. This flow can be directly the bloodstream, which is generated by the heart or it can be the flow of one Fluids, which are in an energy conversion device located.

A preferred embodiment of an electromedical implant, For example, a diagnostic or therapeutic device with a generator for Energy production of the type described is designed so that the generator is disposed within a housing of the implant is so that the unit of generator and implant completely on or in the heart is to accommodate.

A another embodiment may be such that the generator and the Implant over a supply line are connected to each other and that only the generator designed for placement in or at the heart. It can the supply line, over which the generator transfers the energy to the implant, often with such Diagnostic and therapy devices existing sensing or treatment electrode identical be.

Various concrete embodiments of inventive generator will be described below with reference to exemplary embodiments with reference closer to the figures explained. Of the figures show a total of ten different variants in each case of a generator according to the invention in sectional views.

1 shows the schematic longitudinal section through a generator according to the invention 10 for obtaining electrical energy from the movement of the heart, in which a permanent magnet 11 longitudinally movable within an electrical coil 12 is housed. The sink 12 is a hollow coil whose windings include a cavity in which the permanent magnet is arranged. The permanent magnet 11 is so between two springs 13 and 14 hung that he can swing in the axial direction when the generator 10 is moved back and forth in this direction. The feathers 13 and 14 serve as storage for potential mechanical energy.

2 shows the schematic longitudinal section through an alternative embodiment of a generator according to the invention 20 for obtaining electrical energy from the movement of the heart, in which a permanent magnet 21 similar to the embodiment according to 1 longitudinally movable in an electric coil 22 is housed. Instead of mechanical springs 13 and 14 but are two additional permanent magnets 23 and 24 provided so near the ends of the genera tors 20 housed and poled are the permanent magnet 21 from the permanent magnets 23 and 24 is repelled. This is in 2 represented by the polarity "S" and "N". The magnet strengths are designed so that the permanent magnet 21 can swing in the axial direction, without hitting the ends of the generator 20 to strike when the generator 20 in this direction is moved back and forth with the usual forces and accelerations in the heart. The permanent magnets 23 and 24 act in this embodiment as Magneffederelemente and as a position energy storage.

3 shows the schematic longitudinal section through a further embodiment of the generator according to the invention 30 for obtaining electrical energy from the movement of the heart, in which a permanent magnet 31 on a stretchable membrane 33 is attached and in one of an an electric coil 32 enclosed cavity protrudes. The elasticity of the membrane and the immersion depth of the permanent magnet 31 in the electric coil 32 are designed so that the permanent magnet 31 in its axial direction can swing freely when the generator 30 in this direction is moved back and forth with the usual forces and accelerations in the heart.

4 shows the schematic longitudinal section through a fourth embodiment of a generator according to the invention 40 for obtaining electrical energy from pressure changes in the heart. In this fourth embodiment is a permanent magnet 41 on a stretchable membrane 43 is attached and protrudes into one of an electric coil 42 enclosed cavity into it. The membrane 43 is in an opening 44 a hermetically sealed hollow chamber 45 accommodated. The pressure of a compressible medium, with which the hollow chamber 45 filled, the elasticity of the membrane 43 and the immersion depth of the magnet 41 in the coil 42 are tuned so that the magnet 41 Largely in the of the electric coil 42 enclosed cavity is pressed into it, when the ambient pressure corresponds to the maximum, prevailing in the heart pressure or is largely pulled out of the cavity, when the ambient pressure corresponds to the minimum, prevailing in the heart pressure.

5 shows a schematic longitudinal section through a fifth embodiment of a generator according to the invention 50 for obtaining electrical energy from pressure changes in the heart, in which a permanent magnet 51 at a first wrinkle membrane 53 is attached and at the permanent magnet 51 in one of an electric coil 52 enclosed cavity protrudes, wherein the electric coil 52 on a second fold membrane 54 is attached. The wrinkled membranes 53 and 54 are in two opening 55 and 56 a hermetically sealed hollow chamber 57 accommodated. The pressure of a compressible medium, with which the hollow chamber 57 filled, the elasticity of the wrinkled membranes 53 . 54 and the immersion depth of the permanent magnet 51 in the from the electric coil 52 enclosed cavity are tuned to be permanent magnet 51 and electric coil 52 be pressed into each other as far as possible when the ambient pressure corresponds to the maximum pressure prevailing in the heart or be pulled apart as far as possible, when the ambient pressure corresponds to the minimum, prevailing in the heart pressure.

6 shows a schematic longitudinal section through a sixth embodiment of a generator according to the invention 60 for obtaining electrical energy from pressure changes in the heart. In this sixth embodiment is an entire cylindrical wall 64 a housing 63 a hollow chamber is designed as a bellows. A permanent magnet 61 is inside at a first end 65 of the housing 63 attached and protrudes into one of an electric coil 62 enclosed cavity, wherein the electrical coil 62 at a second, the first end face 65 opposite face 66 of the housing 63 is attached. The pressure of the compressible medium with which the housing 63 is filled, the elasticity of the bellows 64 and the immersion depth of the permanent magnet 61 in the electric coil 62 are tuned to be permanent magnet 61 and coil 62 be pressed into each other as far as possible when the ambient pressure corresponds to the maximum pressure prevailing in the heart or be pulled apart as far as possible, when the ambient pressure corresponds to the minimum, prevailing in the heart pressure.

7 shows a schematic longitudinal section through a seventh embodiment of a generator according to the invention 70 which can convert both kinetic energy and pressure changes into electrical energy. This seventh embodiment consists of a combination of the principles to which the embodiments according to 2 and 6 based.

An elastic spring element 71 can be designed either as a bellows, which is filled with a compressible fluid hollow chamber 74 includes.

The spring element 71 However, it can also be a helical spring. In this case, close an electric coil 72 and a capsule 73 a hollow chamber extending from the hollow chamber 74 and another hollow chamber 75 is formed.

Even if the hollow chamber is not particularly dense in the latter case, the spring element act 71 and the electric coil 72 as well as the capsule 73 at least as a spring-mass system.

8th shows a schematic longitudinal section through an eighth embodiment of a generator according to the invention 80 for converting pressure changes into motion and finally into electrical energy. A balloon 81 , which is filled with a compressible medium, forms an elastic expandable and compressible hollow chamber which communicates with a flow channel 82 connected in which a turbine 83 is arranged. At the other end of the flow channel 82 there is a hollow chamber as a pressure chamber 84 , When the ambient pressure in the heart increases, the balloon becomes 81 compressed. Because the pressure in the pressure chamber 84 now lower than the one in the balloon 81 , the medium flows from the balloon 81 through the flow channel 82 in the pressure chamber 84 , where the turbine 83 is driven. Connected to the turbine is an assembly of electrical coil and permanent magnet that permits rotational turbine-induced relative movement between the permanent magnet and the electrical coil such that rotation of the turbine through the permanent magnet and electrical coil is converted to electrical energy. When the ambient pressure decreases, the reverse happens, and now in the opposite direction through the flow channel 82 flowing compressible medium in turn drives the turbine 83 at.

9 shows a schematic longitudinal section through one of the eighth similar ninth embodiment of a generator according to the invention 90 for converting pressure changes into motion and finally into electrical energy. Here the balloon encloses 91 a cavity 92 filled with a non-compressible fluid (such as water, saline, oil, etc.) and with a flow channel 93 connected in which a turbine 94 is arranged. At the other end of the flow channel 93 there is a chamber, which passes through a membrane 95 in two cavities 96 and 97 is divided. The membrane 95 seals the two cavities 96 and 97 from each other and is elastically or movably arranged or flexible and larger in area than the cross-sectional area, so that they can "fold over." The cavity 96 is also filled with non-compressible fluid and can with the cavity 92 communicate by the fluid the turbine 94 flows through. The cavity 97 is filled with a compressible medium. When the ambient pressure in the heart increases, the volume in the cavity becomes larger 97 compressed by removing fluid from the cavity 92 through the flow channel 93 in the cavity 96 flows and pushes the membrane inwards. This is where the turbine is 94 driven. Connected to the turbine is an assembly of electrical coil and permanent magnet that permits rotational turbine-induced relative movement between the permanent magnet and the electrical coil, such that rotation of the turbine through the permanent magnet and electrical coil is converted to electrical energy. When the ambient pressure decreases, the reverse happens, and now in the opposite direction through the flow channel 93 flowing fluid in turn drives the turbine 94 at. This embodiment has compared to the embodiment according to 8th Two advantages: Firstly, the total volume change of the generator caused by the pressure change in the heart as flow through the turbine becomes effective. Second, with a non-compressible fluid, a better, more lossless drive of the turbine is possible.

10 shows a schematic longitudinal section through a tenth embodiment of a generator according to the invention 100 for obtaining electrical energy from pressure changes in the heart. In this tenth embodiment is at least a part of the wall 104 a housing 103 a hollow chamber designed as a cylinder with a flexible lateral surface. A permanent magnet 101 is inside at a first end 105 of the housing 103 attached and protrudes into one of an electric coil 102 enclosed cavity, wherein the electrical coil 102 at a second, the first end face 105 opposite face 106 of the housing 103 is attached. The internal pressure of the housing 103 and / or the preforming of the wall 104 are advantageously designed so that the wall 104 convex is deformed when the ambient pressure is relatively small. (This state shows 10 .) With increasing ambient pressure, the medium inside the housing 103 compressed, with the wall 104 initially stretches and increasingly takes the form of a cylinder with a straight wall, causing the opposite end faces 105 and 106 move away from each other. As the pressure increases further, the wall becomes 104 concave deformed, causing the opposite end faces 105 and 106 to move towards each other. These deformations thus result in a relative movement of the permanent magnet 101 and the coil 102 , causing a voltage in the coil 102 is induced ..

Claims (17)

Electromedical implant, in particular cardiac pacemaker, defibrillator or the like, having a generator for electrical energy, characterized in that the generator has an electrical coil and a permanent magnet, which are arranged relative to each other so movable in that a relative movement between the permanent magnet and the coil causes the induction of a voltage to be tapped off the coil and a potential mechanical energy storage which is operatively connected to the permanent magnet, the coil or both. Implant according to claim 1, characterized in that that the electrical coil and the permanent magnet relative to each other longitudinally movable are arranged. Implant according to claim 1 or 2, characterized that the electrical coil and the permanent magnet relative to each other are arranged so that they have a rotational relative movement To run can. Implant according to one of claims 1 to 3, characterized that memory for potential, mechanical energy a mechanical spring element in Form of a helical spring is. Implant according to one of claims 1 to 3, characterized that memory for potential, mechanical energy a mechanical spring element in Form of an elastically deflectable membrane. Implant according to claim 5, characterized in that that the membrane is a wrinkled membrane. Implant according to one of claims 1 to 3, characterized that memory for potential, mechanical energy is a compressible or expansible Medium is. Implant according to claim 7, characterized in that that the compressible or expansible medium is a gas. Implant according to one of claims 1 to 8, characterized that memory for potential, mechanical energy at least one elastically stretchable or has a compressible hollow chamber. Implant according to claim 9, characterized in that that the hollow chamber has an opening through which a fluid into or out of the hollow chamber out of the hollow chamber can and which with a turbomachine, in particular a turbine, is in operative connection, which for Generating the relative movement between the electric coil and permanent magnets with the coil or the permanent magnet or both operatively connected is Implant according to one of claims 1 to 3, characterized that memory for potential, mechanical energy a magnetic spring element with two repelling each other is relative to each other movably arranged permanent magnet. Implant according to one of claims 1 to 11, characterized that a memory for kinetic energy (e.g., a flywheel) is provided, the with the memory for potential, mechanical energy is connected. Implant according to claim 12, characterized in that that memory for potential, mechanical energy and kinetic energy storage a periodically oscillating system, preferably a spring-mass system with form a resonant frequency that is tuned to a typical heart rate is. Implant according to claim 13, characterized in that that the resonant frequency is at a frequency between 60 and 90 per Minute is tuned. Implant according to one of claims 1 to 14, characterized that between the memory for potential, mechanical energy and the coil or permanent magnet or both a transmission is arranged. Implant according to one of claims 1 to 15, characterized that the generator within a housing of the electromedical implant is arranged. Implant according to one of claims 1 to 15, characterized that the generator is placed in a separate implantable housing and electrically connected to the electro-medical implant is.