WO2004110554A1 - Implantable electric therapy device - Google Patents

Abstract

The invention relates to an implantable electric therapy device comprising a hermetically sealed housing, a sensor inlet, an outlet for the connection of a therapy output unit and a control unit, which is arranged in the housing, and which is connected to the sensor inlet and the outlet. The invention is characterised by an interface unit which is connected to the control unit and is formed in such a way that it can emit control signals to a second implantable therapy device and/or can receive control signals from a second implantable therapy device.

Description

 Implantable electrotherapy device

The invention relates to an implantable electrotherapy device, such as a pacemaker, defibrillator, cardioverter or the like. Such electrotherapy devices usually have a hermetically sealed housing, which enables the implantation of the therapy device and has inputs for sensors and outputs for connecting a therapy delivery unit. In the simplest case, the sensors and the therapy delivery units are electrodes to be placed intracardially, which are connected to the electrotherapy device via an electrode line. A control unit is usually arranged in the interior of the housing and controls a respective electrotherapy as a function of input signals sensed by sensors.

In connection with pacemakers, in particular with rate-adaptive pacemakers that are based on a physiological If a patient needs to react, it is known to record, for example, electrical potentials intracardially as input signals and to feed them to the control unit of the pacemaker via the electrode line for further evaluation and control of the electrotherapy. Further possible input signals are those which indicate the physiological need or the physical activity of a patient, for example an acceleration sensor or a sensor for blood oxygen saturation or else pressure sensors. The therapy delivery unit connected to the output of a pacemaker is usually an electrode line with stimulation electrodes in the region of the distal end of the electrode line. In principle, however, other therapy delivery units, such as pumps for delivering pharmaceutical active ingredients or nerve stimulation electrodes, are also known.

Pacemakers for the pure electrode therapy of a heart with the usual sensing and stimulation electrodes have a control unit with which the pacemaker can be operated in the stimulation modes, for example DDD or WI. Depending on the control unit and electrode configuration, the pacemaker can only stimulate the right ventricle, right ventricle and right atrium or, for example, left and right ventricles or record signals there. The delivery of a stimulation pulse is suppressed in a demand mode known per se, if a natural heart contraction occurs within the specified times (escape interval). In addition, known pacemakers are also designed to recognize, for example, ventricular or atrial tachycardias and to treat them with antitachycade stimulation therapy. A well-known antitachycade stimulation is, for example, overdrive stimulation.

To supply the control unit and to provide the necessary energy for the stimulation pulses, a pacemaker usually has a battery as an energy source. In contrast to pacemakers, defibrillators are of a comparatively simple nature. Defibrillators respond to the detection of, for example, ventricular fibrillation and emit an electrostimulation pulse, the energy of which is sufficient to stimulate an entire ventricular muscle. For pacemaker stimulation, on the other hand, it is sufficient to induce local stimulation, since the excitation that leads to contraction of the heart muscle spreads itself. Defibrillation is all about preventing an independent, for example circulating, excitation of the heart chamber muscle. A defibrillator also usually has a battery in order to provide the energy for controlling the defibrillator and for delivering defibrillation pulses.

Depending on the patient's need for therapy, it is known to integrate pacemaker and defibrillator functions in a single implant.

Alternatively, it is also known in some countries to implant, for example, two separate electrotherapy devices, namely a two-chamber pacemaker and a single-chamber cardioverter / defibrillator.

The first-mentioned variant has the disadvantage that a relatively expensive device must be replaced at regular intervals, the service life of which is determined by the part of the therapy device that is most stressed.

The second-mentioned variant has the disadvantage that pacemaker, cardioversion and defibrillation therapies are difficult to optimally coordinate with one another.

Accordingly, there is a need to avoid as far as possible the disadvantages associated with the various variants associated with the prior art. - A -

In order to meet this need, it is proposed according to the invention to provide an interface unit in an electrotherapy device of the type mentioned at the outset which is connected and designed to the control unit of the electrotherapy device, to transmit control signals to a second implantable therapy device and / or to transmit control signals from a second implanted therapy device receive.

Such an interface unit, for example provided in two separate electrotherapy devices, such as a defibrillator on the one hand and a pacemaker on the other hand, makes it possible to allow the therapies to be delivered by both therapy devices to interact and in this way both to avoid undesired interactions and also to prevent the interactions here and from to optimally support therapy to be delivered by one device by therapy to be delivered by the other device.

In particular, with such a configuration, it is possible to use the relatively more complex control part (control unit) of the pacemaker to control the defibrillator.

Such an implantable electrotherapy device is preferably either a pacemaker or a defibrillator. Preferred variants of a corresponding pacemaker include two-chamber pacemakers for the stimulation of the right ventricle and right atrium of a heart as well as biventricular pacemakers for the stimulation of the right and left ventricles of a heart, optionally in combination with an atrial stimulation. Preferred pacemakers are designed as demand pacemakers, preferably as rate-adaptive pacemakers.

The interface unit is preferably at least partially arranged in a connection housing which is tightly connected to the sealed housing of the electrotherapy device. Such a thing

Junction boxes are usually referred to and serve as headers in known electrotherapy devices, the connection of the above-mentioned electrode line. Accordingly, an electrotherapy device is preferred in which a header has at least one electrode line connection, which is connected to the sensor input to the output for connecting the therapy delivery unit to the electrode line connection.

The header preferably comprises a molded body made of transparent plastic.

The interface unit preferably comprises an infrared transmitter and / or an infrared receiver. Infrared transmitters and receivers are preferably tuned to a wavelength for which blood has a high transmittance, so that infrared signals between

Transmitter and receiver inside the patient's body are damped as little as possible. This also benefits from a header with molded plastic body.

As an alternative or in addition to an interface unit with an infrared transmitter and receiver, the interface unit can also include a radio transmitter and / or receiver. This is also preferably housed in a header made of non-conductive material, such as plastic, in order not to shield the radio transmitter and / or receiver.

In order to avoid undesirable effects of a therapy delivered by an electrotherapy device, for example a pacemaker, on the therapy of an electrotherapy given by another electrotherapy device, for example a defibrillator, the control unit is preferably designed to generate inhibition signals for a second therapy device and to transmit them via the interface unit.

The control unit of the second therapy device or also the control unit of the same therapy device is preferably designed to match one on the interface unit to address the inhibition signal present. This makes it possible, for example, to coordinate the delivery of defibrillation pulses, for example to an atrium, with the cardiac cycle in the ventricle of the same heart such that the defibrillation pulse is not delivered during the vulnerable phase of the heart.

Overall, two electrotherapy devices of the type described above preferably form a system with two coordinated interface units, one of which is accommodated in one electrotherapy device, for example a pacemaker and the other in the other electrotherapy device, for example in the defibrillator.

The invention will now be explained in more detail using three exemplary embodiments with the aid of the attached sketches. From the figures show:

Figure 1: a pacemaker and a defibrillator with radio-separated interface unit

Figure 2: a pacemaker and a defibrillator, which are connected to each other via an interface cable and

Figure 3: a pacemaker and a defibrillator, which are telemetrically connected to each other via an optical infrared interface.

The figure shows a sketch of a human heart 10 as well as a pacemaker 12 and a defibrillator 14.

An atrial electrode line 20 and a ventricular electrode line 22 are connected to the pacemaker (IPM) 12 and end in the right atrium 24 and right ventricle 26 of the heart 10, respectively.

The pacemaker 12 is essentially designed as a conventional two-chamber pacemaker, preferably as a rate-adaptive pacemaker. A defibrillation electrode line 30 is connected to the defibrillator (ICD) 14 and also ends in the right ventricle 26 of the heart 10. For this purpose, the defibrillation electrode line 30 has a large-area defibrillation electrode 32 at its distal end.

Instead of the intravascular defibrillation electrode line 30 in this and the following exemplary embodiments, subcutaneous shock electrodes (not shown in more detail) can also be provided in alternative exemplary embodiments.

The sketch of the pacemaker 12 shows a metal housing 40 and a header made of transparent plastic 42, which is tightly connected to the pacemaker housing 40. The header 42 has two connection sockets for the atrial electrode line 20 and the ventricular electrode line 22. For this purpose, the electrode lines 20 and 22 have at their proximal end connection plugs which correspond to the IS1 standard and are inserted into corresponding connection sockets 44 and 46 in the header 42. The connection sockets 44 and 46 are electrically connected to a control unit in the interior of the pacemaker housing 40.

Defibrillator 14 also has a hermetically sealed metal housing 50 with a header 52 made of transparent plastic, which is closely connected to it. In the header 52 of the defibrillator 14, a connection socket 54 is provided, into which the defibrillation electrode line 30 is inserted. The connection socket 54 is electrically connected to a control unit inside the metal housing 50 of the defibrillator 14.

A radio antenna 60 is arranged in the header 42 of the pacemaker 12 as part of an interface unit, not shown, which is connected to the control unit inside the pacemaker 12. Correspondingly, a radio antenna 62 is likewise accommodated in the header 52 of the defibrillator 14, which is part of an interface unit of the defibrillator 14 and is connected to the control unit of the defibrillator 14. The two interface units of the pacemaker 12 and the defibrillator 14 with their antennas 60 and 62 are matched to one another. The control unit of the pacemaker 12 is designed to generate inhibition signals which are emitted via the interface unit and the antenna 60. The interface unit of the defibrillator 14 is designed in connection with the antenna 62 to receive inhibition signals sent by the pacemaker 12. The control unit of the defibrillator 14 responds to these inhibition signals and prevents the delivery of defibrillation pulses as long as an inhibition signal from the pacemaker 12 is present. In this way it can be prevented that defibrillation pulses are delivered to the heart 10 at therapeutically unfavorable times.

Furthermore, the pacemaker 12 can be designed to take over the necessary processing of the intracardially recorded signals as a whole, ie to take over the entire perception and classification of the rhythm. In such a configuration, the pacemaker 12 can process and classify the heart rhythm and, in the case of bradycardia, deliver pacemaker pulses to bradycardia therapy. If the rhythm is classified as tachycardia, the pacemaker causes the implantable defibrillator 14 to deliver a defibrillation shock via the interface units.

In this way it is possible to distribute the control and delivery of the therapies to the different therapy devices that can communicate via integrated interface units. Depending on the version, a therapy device and the other therapy devices can control via interfaces and thereby initiate a corresponding therapy delivery. The embodiment variant shown in FIG. 2 essentially corresponds to the exemplary embodiment from FIG. 1. Identical features are provided with identical reference numerals.

The differences relate to the headers 42 'and 52' of the pacemaker 12 and defibrillators 14, respectively.

The header 42 'of the pacemaker 12 has an additional electrical plug contact 48 which forms part of an interface unit which is connected to the control unit of the pacemaker 12.

Correspondingly, the header 52 ′ of the defibrillator 14 has an electrical plug contact 58. This is part of an interface unit of the defibrillator 14 and connected to its control unit.

The two electrical plug contacts 48 and 58 of the pacemaker 12 or defibrillator 14 are connected to one another via a cable 66, which is used to exchange the control signals described above.

FIG. 3 shows a third embodiment variant similar to the embodiment variants from FIGS. 1 and 2. In the embodiment variant shown in FIG. 3, infrared photodiodes 66 and 68 are part of the respective header 42 "or 52" of the pacemaker 12 or the defibrillator 14 as components of an infrared transmitter or . -Receiver arranged. The infrared transmitters and receivers are part of a respective interface unit of the pacemaker 12 or the defibrillator 14, which are each connected to the control unit of the pacemaker or defibrillator.

The photodiodes 66 and 68 are tuned to an infrared wavelength at which blood has a high transmission, so that light from one to the other photodiode in the body of a patient is damped as little as possible. The headers 42 "and 52" are made of transparent Plastic, which does not dampen the infrared light sent or received by the photodiodes 66 or 68 as far as possible.

The design of the headers 42, 42 ', 42 "and 52, 52" and 52 "has the advantage in all three design variants that proper contact between, for example, the electrode lines 20, 22 and 30 and the corresponding connection sockets 44, 46 and 54 can also be checked optically.

Claims

claims

1. Implantable electrotherapy device with a hermetically sealed housing, a sensor input, an output for connecting a therapy delivery unit and with a control unit which is arranged in the housing and with the sensor input and the

Output is connected, characterized by an interface unit which is connected to the control unit and designed to emit control signals to a second implantable therapy device and / or to receive control signals from a second implantable therapy device.

2. Therapy device according to claim "!, Characterized in that the interface unit is at least partially arranged in a connection housing which is tightly connected to the sealed housing.

3. Implantable therapy device according to claim 1 or 2, characterized in that the therapy device is a pacemaker, defibrillator or cardioverter.

4. Implantable therapy device according to claim 3, characterized in that the therapy device is a pacemaker which is designed to perceive and process intracardial signals, in particular to carry out a classification of a cardiac rhythm, and from the perceived intracardial signals a control signal for a second implantable Generate therapy device and deliver it via the interface unit.

5. Implantable therapy device according to claim 4, characterized in that the therapy device is a pacemaker, which is designed to detect a bradycardia by classifying the heart rhythm and to generate pacemaker pulses for therapy of bradycardia.

6. Implantable therapy device according to claim 4 or 5, characterized in that the therapy device is a pacemaker, which is designed to detect a tachycardia by classifying the heart rhythm and to generate a control signal for a cardioverter / defibrillator as a second implantable therapy device and to emit it via the interface unit, which causes the cardioverter / defibrillator to trigger a cardioversion or a defibrillation pulse.

7. Implantable therapy device according to claim 4, characterized in that the therapy device is a cardioverter / defibrillator, which is designed to receive a control signal via the interface unit and to the

Control signal to trigger a cardioversion or a defibrillation pulse.

8. Implantable therapy device according to one of claims 3 to 7, characterized in that the sensor input and the output for connecting a therapy delivery unit with a

Electrode line connection are connected.

9. Therapy device according to claim 8, characterized in that the electrode connection and the connection housing are part of a header.

10. Therapy device according to claim 9, characterized in that the

Header includes a molded body made of transparent plastic.

11. Therapy device according to one of claims 1 to 10, characterized in that the interface unit comprises an infrared transmitter and / or receiver.

12. Therapy device according to one of claims 1 to 10, characterized in that the interface unit comprises a radio transmitter and / or receiver.

13. Therapy device according to one of claims 1 to 10, characterized in that the interface unit comprises a cable connection socket with electrical contact.

14. Therapy device according to one of claims 1 to 10, characterized in that the control unit is designed to generate inhibition signals for a second therapy device and to output them via the interface unit.

15. Therapy device according to one of claims 1 to 10, characterized in that the control unit is designed to respond to an inhibition signal applied to the interface unit.

16. Therapy device according to claim 1, characterized by an electrical energy source, preferably a battery.

17. System comprising two therapy devices according to claim 1, each with coordinated interface units.

18. System according to claim 17, characterized in that the one therapy device is a pacemaker and the other therapy device is a defibrillator.

19. System according to claim 18, characterized in that the one therapy device is designed to perceive and classify a heart rhythm and to control the other therapy device via the interface units to initiate therapy delivery.

20. System according to claim 19, characterized in that a therapy device is a pacemaker which is designed to process and classify a cardiac rhythm and in the case of bradycardia to emit pacemaker pulses for therapy of bradycardia and in the case of tachycardia

To output control signals via the interface units to the second therapy device, which is a cardioverter / defibrillator, the control signals causing the cardioverter / defibrillator to deliver a defibrillation shock.