DE10132228C1 - Pacemaker with periodic modulation of individual stimulation intervals - Google Patents

Abstract

Cardiac pacemaker with a device for measuring at least one cardiac function parameter and a device that periodically modulates individual stimulation intervals in such a way that the degree of modulation is regulated depending on both the duration of the diastolic interval and the changes in the cardiac function parameter evoked by the modulations, so that certain Phases of electrical and mechanical restitution can be scanned independently of the systole duration and with constant accuracy.

Description

The invention relates to a pacemaker the preamble of the main claim.

In the further development of metrological or dia Gnostic functions of pacemakers for op The timing of the stimulation parameters is paramount distinguish between two tasks, namely the improvement of sensor technology on the one hand and the optimization of the measurement method and signal analysis on the other hand.

The present invention is based on work that are assigned to the second task, and the follow the well-known measurement method approach, through targeted stimulation of the measurement object reactions to evoke the specific functional characteristics of the measurement object and that without stimuli tion would not be detectable or differentiable.

So offers artificial stimulation of the heart through the pacemaker the possibility of being passive not measurable characteristic of electrical and mechanical restitution. Doing so by modulating individual so-called extrasystolic Pacing intervals are the duration of the diastolic Regeneration or restitution process of the heart changed what in the following (extra) systolic Interval a change in both the action pots tials as well as the contraction force of the myocardium  evokes and therefore in combination with the changed preload and afterload to a changed Stroke volume of the ventricle. Both processes, both the diastolic restitution and the with increasing, diastolic shortening decreasing reak tion of the following (extra) systolic cardiac radio functions as systolic restitution charters ristik defined have an exponential Course. Since both processes are mutually analogous correlate, it is about the restitution character tic possible to analyze the diastolic regeneration sieren, even if with the available measurement parameter is not directly measurable, such as the electri Restitution using the EKG. Central meaning the time constant of the regeneration or restitution characteristics, since they are a statement about the adaptation dynamics of the myocardium, and thus the information about the current load degree of the heart and its performance reserve. This But information is not just for the optimal Control pacemaker functions such as the Stimulation frequency essential, but also general mine for diagnostic purposes.

The modulation of individual stimulation intervals in Pacemakers and the analysis of the evo graced, specific changes in cardiac radio tion parameters to improve frequency control is known. There have been three embodiments described that apply the modulation principle. So it was suggested about in case of intracardiac Impedance measurements to determine the stroke volume calibrate the impedance measurements and noise signals to filter (EP 0 551 355) Furthermore, the Single pulse modulation with different modulations degrees and different stimulation frequencies zen suggested to characteristic reaction pattern  intracardiac measurement parameters and their change behavior for diagnosis and Fre to use frequency control (DE 44 47 447 C2). In one Another approach was the method of single pulse modulation lation applied to the gradient of the electrical Analyze restitution characteristics and as Re gel parameters for continuous frequency control use (DE 199 00 690 C1).

With the concepts mentioned, it has proven to be a disadvantage lig proved that modulation of individual stimula tion intervals (ESI) in fixed modulation periods and with a percentage of the basic cycle length or mean stimulation interval duration fixed modules tion amplitude is made. Since the duration systo lical or diastolic function intervals not only interindividually, but mainly as a result of (pa tho-) physiological changes in the myocardium strongly can fluctuate, this means in a firm on the Base cycle length related extrasystolic stimula tion pulse that the measurement is falsified because un Different phases of diastolic restitution be scanned. For example, the evaluation of the Restitution characteristics in the familiar form that with a low stimulation frequency the behavior of the slow restitution phase a time constant Tr1 of approximately 400 to 1000 ms ana is lysed and at a high stimulation frequency the influence of the rapid restitution phase with a time constant Tr2 of approximately 100 to 200 ms. That means operations that are different Reactions between the specific myocardial Time constants Tr1 and Tr2 lead, such as the gift chronotropic or inotropic drugs, not can be differentiated. They also have acute un specific fluctuations in systolic intervals, such as such as extending the QT interval at Belas  beginning, a falsification of the restitutionana result in lysis, which - if at all - only with nimble correction calculations for signal analysis can be compensated.

Furthermore, they make it symmetrical to the middle one Duration of the stimulation intervals performed In tervallmodulationen required, either the maxi male stimulation frequency or the degree of modulation with increased stimulation frequency from the outset severely restrict to the shortened stimula intervals a stimulation in the refractory Be range of the myocardium. This limitation kung leads to a critical reduction of the Sensitivity of the measurement method, which is different in the In principle, the pacemaker area must be taken into account the major interferences as critical for the one set of measurement method can prove. Especially after This has a partial effect with the previous modulation shape out when turned into dual chamber pacemakers is set, since the modulation dynamics are additional here is limited by the duration of the AV interval.

Another concept involved modulation described individual stimulation intervals of the atrium to analyze the extent to which changes result the duration between atrial and autonomous ventri stimulation (AV interval) (DE 36 25 894). This modulation ultimately serves also the optimization of the stimulation frequency but like the previous approaches unregulated, d. H. without control of systolic or diastolic radio tion courses, apart from that this principle only suitable for the special case of atrial stimulation is because here a parameter, namely the AV inter vall, which is examined in normal bicameral pacemaker is regulated by the system itself.  

DE 100 29 677 A1 describes a pacemaker with regulation for load-dependent control of the known atrial pacing rate. Here is a calculation unit is provided, which is a rule unit which contains the values for the stimula frequency by means of a recursive difference equation chung calculated using the control unit as a controller input variable a measured by a sensor unit Measured value and as a reference variable for one step makers specific reference value can be specified.

From WO 99/44680 and WO 01/17608 A1 are white tere pacemakers known to have a device for measuring at least one cardiac function parameter comprise, wherein further devices for production of stimulation pulses are provided.

The invention is based, at heart pacemakers modulate individual stimulations Control intervals so that an analysis of the elec trical or mechanical restitution not only phase-specific, but also in the entire area the stimulation rate more accurate and reliable is possible.

This object is achieved by the features of the main claim solved.

The pacemaker according to the invention modulates in Contrary to the previous systems the stimulati ons intervals not fixed in relation to the basic cycle length or mean stimulation interval duration, son depending on the duration of the diastole as well of the value evoked by the interval modulations modulations of the cardiac function to be examined parameters. This will not only cover the area of Stimulation rate expanded, within which the Method can be used, but it will a more precise and phase-specific analysis of the elec trical and mechanical restitution characteristics possible.

For phase-specific scanning of the diastolic Restitution first becomes an extrasystolic module ration value calculated at which the diastole duration of the modulated interval one from the program control tion has a predeterminable value which is the middle of the scanning phase defined, and the, since firmly related to the Be beginning of the diastole, regardless of fluctuations in the systolic interval. Related to the so be agreed mid-phase then two more extra systolic modulation values calculated so that a symmetrical modulations take place in the middle of the phase det, the modulation stroke, which is the width of the  probing phase determined depending on the measurement Value modulation is regulated on the one hand a minimal modulation level and thus a mini to ensure basic accuracy as well as on the on the other hand, the modulation of the stimulation inter to keep valle as small as possible to as little as possible possible to deviate from normal stimulation.

The beginning of the electrical restitution will be there by default by triggering the ventri's T-wave kular EKG's detected. In contrast, a ge accurate detection of the beginning of the mechanical restitu tion an additional sensor, such as pressure sensors or acoustic sensors is able to do that Opening or closing the pulmonary valves and the AV To display flaps.

When using interval modulation in two chambers pacemakers must be checked whether one of the two extrasystolic interval changes the duration of Ventri's electrical diastole kels multiplied by an amount that is smaller than 1, shortened to a value that is less than the AV interval at base cycle length. In this case the AV interval of the extrasystolic inter valls can be shortened accordingly to a stimula tion in the area of the refractory phase of the myocardium avoid. But because of an AV interval shortening flow on the restitution characteristics - specifically the mechanical - can have, it is for compensation this influence appropriately, at all extrasystoli modulations the same AV interval shortening perform.

Furthermore, it has been shown that it is mainly at frequent changes between spontaneous and artificial Cardiac muscle stimulation is appropriate, not  the errors that occur only when the signal is evaluated to correct, but already the modulation of the Type and duration of the previous stimulation pulses addictive. Because the stimulus spread and accordingly the contraction of the heart muscle depends change from the form of stimulation and this change processing process at least over two pulse cycles interacts, it is advantageous to modulate early at least two cycles after spontaneous stimulation start. On the other hand, the spontaneous stimulation lasts several pulse cycles, it is advisable, after that as many cycles, but a maximum of one minute until to wait for the next modulation because the contraction usually also the cardiac output and hence the hemodynamic values of the entire circle can change running system.

The first step in analyzing the investigate The restitution phase is the determination of through the two changes in interval evoked measured values requirements. First the values of a Mo dulation each following extrasystolic pulse cycle len as well as that of the next so-called postextrasystoli pulses and then the Difference values determined. In addition to the extrasystolic Difference values that show the course of the respective Res title characteristic within a defined Reflect phase, but are also the difference values of the subsequent so-called post-extrasystolic Readings are physiologically interesting as they reflect the degree describe the compensatory effects in the myocardium.

Because the time constant of the exponential Restitution processes the most accurate information about the rapidity of myocardial regeneration finished, their determination is the real goal of Signal evaluation. However, this requires  perform at least a third interval change ren, which is convenient to a simple Ver being able to use the calculation algorithm, half as much is as large as the sum of the other two, that is scans the center of the phase.

As mentioned above, the restitu tion of the electrical as well as the mechanical egg properties of the myocardium two characteristic pha distinguish why the interval modulations are to be dimensioned accordingly so that these two phases, namely the early and late diasto phase, can be recorded separately. there it has proven beneficial that dependent from the one to be optimized with the help of the modulation Pacemaker function controlling modulation periods is designed so that both a parallel as well as a sequential recording of the parameters both restitution phases is possible.

For the acceptance of the modulation of individual stimula It is not intervals for restitution analysis only advantageous, the modulation as small as possible, but also rarely as possible. of half it is useful in long periods of rest to use the late diastolic sampling phase and a longer modulation period, in contrast with larger Be load fluctuations or higher loads the early diastolic phase, to feel and the shorter modu setting periods.

Because the phase-specific analysis of the electromechani restitution can provide information about both the power reserve of the myocardium as well as over the adaptation dynamics, it is practical for everyone frequency-controlled pacemaker systems can be used. Because all systems allow ventricular ECG measurement  lichen, is the analysis of electrical restitution practically universally applicable during analysis mechanical restitution only for the systems for Use comes, which additionally a sensor to Kon have traction measurement.

So the analysis of the electrical restitu is suitable tion is very good for a pacemaker to be used, the stimulation frequency depending on the duration of the QT or Stim-T interval is regulated. Here it becomes larger in phases Load fluctuations or higher loads Pacing rate depends only on that Control signal set that regulates the inter vallmodulationen delivers while in phases of rest or the Sti at a constant low load simulation frequency depending on the value of the Stim-T-Inter valls is determined. Because the restitution analysis is not only the faster, but also the more precise Be provides load parameters (such as the time constant), it is possible to use the control range of the QT control Using the restitution analysis to dynamically calibrate ren, so that the transition from one to the other re gel parameters without critical frequency jumps can.

After the behavior of the time constant of the mechani restitution especially in the higher load range indicates very precisely whether the adaptation dynamics of the Heart muscle is already exhausted, d. H. whether the An the stimulation rate increased to an improved one Pump performance or not, the Ana is suitable lysis of mechanical restitution for hemodynamic Optimization of pacemakers with an intra cardiac sensor mechanical cardiac function parameters to capture.  

In patients who have a prophylactic pacemaker have implanted for technical reasons, the Inter vallmodulation with the help of artificial extrasystoli an additional analytical pulse approach for diagnostic purposes, the main one for the early detection of pathological changes in the Myocards can be used as ischemia.

An embodiment of the invention is in the Drawings and is shown in the following Description explained. Show it:

Figure 1 shows the characteristic time delay between electrical and mechanical resti tution courses during diastole in the right ventricle.

FIG. 2 shows the time course of atrial and ventricular pacing interval and the ventricular ECG and pressure gradient dP / dt of a single pulse in interval shortening;

Fig. 3 shows the functional diagram of the extra-systolic stimulation intervals for sampling the early diastolic phase of the electrical restitution over the entire range of the basic cycle length BCL, namely

• a) the ventricular pacing inter valle ESI1 and ESI2;
• b) the associated atrial pacing intervals VAIes1 and VAIes2;

Fig. 4 shows the highly simplified block diagram of a single-chamber pacemaker according to the present invention and

Fig. 5 shows the highly simplified block diagram of a two-chamber pacemaker according to the present invention.

Fig. 1 shows on the basis of the schematic signal curve of the most important functional parameters of the right Ven tricle that when analyzing the electromechanical restitution of the heart during diastole, a distinction is to be made between three differently long, exponential processes. The temporal basis for the cardiac cycle and the ratio of systolic to diastolic time interval is primarily determined by the (basic) cycle length (BCL) between the stimulation pulses and the duration of the action potential (APD), i.e. the change between depolarization and repolarization of the muscle cells, such as Show lanes 1 and 2 in Fig. 1. Since the start of repolarization is reflected in the T-wave of the ECG and the stimulus determines the start of the QRS complex, in practice the maximum of the T-wave is defined as the end of the systole and the start of the diastole, ie as "electrical slides tole "is the TQ interval. The repolarization begins physiologically correctly with the drop in the action potential, which coincides with the beginning of the T-wave, so that the diastolic interval duration DI _E shown in track 2 must be used for a correspondingly accurate analysis of the electrical restitution.

Depolarization and repolarization, respectively subsequent contraction and relaxation of the heart muscle is characterized by four, the hemodynamics of the  Heart-defining points in time (P1 to P4) identified records the opening and closing of the two Determine flaps in the right and left ventricles. As can be seen in the 4th track, the pressure leads rise in the ventricle via the atrial pressure (str smiled lower line) to close (P1) the AV valve and in the further course when the pulmo is exceeded nalarterial pressure (upper dashed line) to open (P2) of the pulmonary valve. Conversely, the Relaxation after repolarization of the ventricle first the pulmonary valve closure (P3) and then that Open (P4) the AV valve. Defined accordingly one as mechanical or active diastole that time interval (T31) between start and end of relaxation phase, roughly with the closing of the two Heart valves collapse. Practically you can open The gradients open and close the flaps of the ventricular pressure determine how the 5th track ver interpreting light. That is, the mechanical diastole the interval between the beginning of the negative and corresponds to positive pressure gradients, detectable via a threshold trigger.

The final stage of the mechanical restitution is then the exponentially increasing filling of the ventricle after opening of the AV valve (P4), the course of which is shown in track 6 of FIG. 1. The interval of the diastolic ventricular filling, ie the time from opening (P4) to closing (P1) of the AV valve, can - as track 5 shows - also be determined using the pressure gradient via a threshold trigger.

Differentiate how the signal curves illustrate the three diastolic regeneration or res processes of title by the beginning or their duration. A phase-specific analysis of the respective resti  This is not the only reason why exacting is required Assignment at the beginning of the restitution, but before al lem also because of the possible strong fluctuations of the systolic time interval as a result of pathological Changes such as "Long QT Syndrome".

In Fig. 2, depending on the shortening of a single ventricular stimulation interval ESI shown in lane 1 , both the necessary change in the AV interval (lane 2 ) and the typical response of the ventricular ECG's (lane 3 ) are shown in the two subsequent pulse cycles ) and the pressure gradient dP / dt (lane 4 ). Since the function of the ventricle is in the foreground when analyzing the astolic restitution in the heart muscle, the ventricular stimulation pulse is defined as a time reference point for describing the temporal relationships, although the atrial stimulus functions functionally around the so-called atrioventricular interval (AVI). goes ahead. At the basic cycle length (BCL), the atrial stimulus of the next pulse follows the ventricular stimulus with an interval VAIb = BCL - AVIb.

As tracks 1 and 2 show, in the case of a stimulation interval shortened by -ΔESI (ESI), the AV interval (AVIb) must also be shortened (by -ΔAVes) so that the atrial stimulus does not enter the refractory period (RP) of the heart muscle falls (see Fig. 1). The end of the refractory phase or period can be determined by detecting the end of the T wave or, in a simplified manner, can be calculated using the QT interval multiplied by a specific factor (a). In principle, the following applies if: ΔAVIb <DIes = ESI - RP the AV interval is reduced by ΔAVes = DIes - AVIb, and the extrasystolic atrial interval calculated from the ventricular stimulus is: VAIes = ESI - AVIb + ΔAVes.

As a result of the shortened, diastolic interval (DIes), the following "extrasystolic" interval results in a reduction of the QT interval by -ΔQTes (lane 3 ) and the maximum values of the pressure gradient dP / dtmax by -ΔdPmaxes and dP / dtmin by ΔdPmines (lane 4 ). In the second so-called "post-extrasystolic" interval following the interval change, a compensatory effect then follows, which leads to an extension of the QT interval by ΔQTpes or to exponentiation of the pressure values by dPmaxpes and dPminpes.

Based on the diagrams a) and b) in FIG. 3, it is to be shown in a playful manner how a certain phase of the electrical restitution can be scanned by extrasystolic modulations. Diagram 3 a) shows, depending on the basic cycle length (BCL), the typical course of a QT interval (QTb) and - dashed - the corresponding refractory period (RP) as well as the course of three extra-systemic intervals (ESI0, ESI1 and ESI2 ). Here ESI0 defines the middle of the diastolic restitution phase to be analyzed (sampling phase). This mean value is sampled by the interval modulation ΔESI0, the value of which is determined depending on the electrical diastole DI _E by the relationship: ΔESI0 = DI _E - K1 - K2, where K1 is a predeterminable constant interval value and K2 is a correction value dependent on the basic cycle length , The modulation values ΔESI1 and ΔESI2 and thus the modulation stroke ΔESI12 of the stimulation intervals are regulated depending on the modulation stroke or the difference (ΔMes12) of the ΔSI1 and ΔESI2 following extrasystolic measurement values (Mes1 and Mes2). The regulation of the modulation values is intended to prevent the measurement parameter modulation from dropping below a minimum level (ΔMesmin) by increasing the modulation stroke (ΔESI12). Assuming a linear relationship between ΔESI12 and ΔMes12 within the sampling phase, the modulation deviation ΔESI12 can be determined using the following simplifying equation: ΔESI12 = ΔESImax - Fv.ΔMes12, where the factor Fv is the control gain of the closed control loop and ΔESImax is one maximum permissible modulation stroke defined. This results because of the required symmetrical modulation around the phase center defined by ESI0, ie because ΔESI1 - ΔESI0 = ΔESI0 - ΔESI2:

ΔESI1 = ΔESI0 - (ΔESImax - Fv.ΔMes12) / 2 and

ΔESI2 = ΔESI0 + (ΔESImax - Fv.ΔMes12) / 2

The enlargement of the sampled time window (ESI1 - ESI2) and its distance from the refractory period (RP) with increasing basic cycle length the influence of Pacing rate on the slope of the restitution and thus compensate for the measured value modulation ΔMes12 sieren, d. H. ΔMes12 should remain the same if no additional stimulation rate Change influencing factors.

FIG. 3b) shows a function of the basic cycle length of the waveforms of the extra-systolic ventricular stimulation intervals (ESI1 and ESI2) belonging atrial pacing intervals (VAIes1 and VAIes2) when using a dual-chamber pacemaker, and the QTb- and VAIB interval. The dashed lines indicate the course of the atrial stimulation intervals if the base value of the AV interval (AVIb) were used when calculating the atrial, extra systolic intervals (VAIes1 and VAIes2). In order to prevent the shorter stimulation interval (VAIes1) from becoming smaller than the refractory period (RP = a.QTb), the AV interval must be reduced by ΔAVIes1 in the simplest form so that the VAIes1 values are equal to the RP values as shown in diagram 3 a). Since in the constellation shown the value for AVIb for each basic cycle length is greater than the difference between the shortest, extrasystolic interval ESI1 and a.QTb, all extrasystolic AV intervals AVes1 and AVes2 are shortened by the amount:

ΔAVes = ESI - a.QTb - AVIb.

In Fig. 4 the highly simplified block diagram of an embodiment of the pacemaker is shown, which, in addition to the known functions, enables the modulation of individual stimulation intervals depending on the duration of the diastolic interval and the amplitude of the evoked modulations of a cardiac function parameter for the phase-specific analysis of diastolic restitution processes.

The functioning of the pacemaker can generally be divided into four higher-level functional units, namely the pacemaker circuit ( 14 ), which stimulates the heart via an electrode ( 1 ), and the program control ( 12 ), which controls all the pacemaker's functional processes either according to permanently programmed criteria or set by an external programming device ( 13 ) controlled according to variable criteria. With the pacemaker ( 1 ) itself, five higher-level function blocks can also be known, which represent the basic functions. All sensor signals used - here it is only the ECG derived via the stimulation electrode ( 11 ) - are amplified in a signal amplifier stage ( 2 ) and further processed in a signal analysis stage ( 3 ), which is primarily used to detect brady- and tachycardiac cardiac arrhythmias, but generally carries out the analysis of cardiac function parameters, the results of which are then used in the following control stage ( 4 ) to control the antibrady- and antitachycardic interventions of the pacemaker via the setting of the stimulation intervals ( 9 ) and the final stimulation pulse generator ( 10 ). In addition to the standard functions mentioned, the pacemaker according to the invention contains a function level ( 7 ) which automatically follows the chronological sequence of the modulation of individual stimulation intervals in the control stage ( 9 ) and the demodulation of the evoked modulations of the function parameter in the signal analysis stage ( 3 ) according to predetermined criteria controls. For this purpose, the period control ( 7 ) receives information via the signal analysis ( 3 ) as to whether a detected heart action is spontaneous excitation or an artificial stimulation. Accordingly, it interrupts or starts the periodic modulation of individual stimulation intervals and sets the period duration depending on the value and the change behavior of the pulse rate.

However, the essential additional function according to the invention is part of the control stage ( 4 ), which in the normal case, in addition to the antitachycardic control functions not specified here, primarily regulates the stimulation frequency (SR) or the basic cycle length (BCL) in the BCL controller ( 8 ) undertakes, in the example shown, the QT interval is used as a controlled variable which is supplied via the connection ( 31 ) by the signal analysis stage ( 3 ). In addition, the control stage ( 4 ) contains a control ( 6 ) of the extrasystolic modulation values (ΔESI) and receives from the signal analysis ( 3 ) via the connection ( 33 ) the value of the electrical diastole duration (DI _E ) and via the connection ( 34 ) the value of the modulation of the function parameter (ΔQTes12), which it uses according to the criteria explained in FIG. 3a).

With the control signal for interval modulation of the ΔESI controller ( 6 ), however, the BCL controller ( 8 ) has an additional load parameter which can be used to overcome the disadvantages of the QT interval as a control parameter, namely a lack of response speed and accuracy, to compensate. Instead of the control signal for interval modulation, the calculated time constant (Tr) of the electrical restitution for optimizing the BCL control in ( 8 ) can also be taken over directly from the signal analysis stage ( 3 ) via the connection ( 32 ).

In Fig. 5 the highly simplified block diagram of an embodiment of the pacemaker is shown, which also enables the atrial pacing intervals via the functions described in Fig. 4 in addition to modulating individual ventricular and uses a mechanical sensor ( 11 ).

The controller ( 8 ) not only determines the values of the basic cycle length (BCL), but also those of the AV interval (AVIb) and returns them to the interval control ( 9 ). Accordingly, the controller ( 6 ) not only supplies the extrasystolic modulation values ΔESI, but also - if necessary - the modulation values of the AV interval (ΔAVIes).

Claims (11)

1. pacemaker with a device for measuring at least one cardiac function parameter (M), with a device for regulating the mean stimulation intervals such as the basic cycle length (BCL) with ventricular stimulation and the AV interval (AVI) with additional atrial stimulation depending on changes (ΔM) the function parameter (M), and an apparatus for periodic modulation of individual called. extrasystolischer stimulation intervals (ESI) by a modulation value (ΔESI), characterized net gekennzeich that a device for regulating the inter vallmodulation (6) the modulation values (ΔESI) depen gig of the duration of the diastolic interval (DI) and depending on the extrasystolic modulations of the function parameter (ΔMes) evoked by the interval modulations (ΔESI). 2. Cardiac pacemaker according to claim 1, characterized in that the regulation of the interval modulation ( 6 ) preferably regulates the modulation values such that a first modulation value (ΔESI0) is determined depending on the duration of the diastolic interval at basic cycle length (DIb), so that the diastole duration before extrasystole (DIes) has a predeterminable value and that two further extrasystolic modulation values (ΔESI1 and ΔESI2) are determined, the difference between them and the first modulation value (ΔESI01 and ΔESI02) is the same size and their difference to each other (ΔESI12 ) is inversely related to the difference (ΔMes12) of the modulations of the function parameters evoked by it (ΔMes1 and ΔMes2). 3. Cardiac pacemaker according to claim 1 or 2, characterized in that the regulation of the interval modulation ( 6 ) for calculating the first modulation value (ΔESI0) preferably uses the duration of the electrical diastole (DI _E ) determined with the help of the ventricular ECG's and for Analysis of the mechanical resitution preferably the duration of the mechanical diastole (DI _M ) determined using the ventricular pressure gradient (dP / dt). 4. Cardiac pacemaker according to one of claims 1 to 3, characterized in that the regulation of the interval modulation ( 6 ) in two-chamber stimulation also modulates the atrioventricular interval (AVI), preferably in such a way that the AV at each extra systolic interval (ESI *) -Interval is shortened by an AV modulation value (ΔAVIes) if the difference between the shortest extrasystolic interval (ESI2) and the refractory period (RP) is smaller than the AV interval at the base cycle length (AVIb). 5. Cardiac pacemaker according to one of claims 1 to 4, characterized in that the control of the modulation period ( 7 ) starts the interval modulation only if at least two artificially stimulated pulse cycles of the heart preceded in phases of predominantly pacemaker stimulation or at least two self-rhythms in phases of largely autonomous stimulation , 6. Cardiac pacemaker according to one of claims 1 to 5, characterized in that the control of the modulation period ( 7 ) controls the signal analysis and demodulation ( 3 ) in such a way that in addition to the extrasystolic intervals (ESI1 and ESI2) directly following extrasystolic measured values (Mes1 and Mes2) of the function parameter (M), the post-extrasystolic measurement values (Mpes1 or Mpes2) that follow in the next pulse cycle are also determined and that the difference values of the extrasystolic and post-extrasystolic measurement values (ΔMes12 and ΔMpes12) are determined as phase-specific measurement variables. 7. Cardiac pacemaker according to one of claims 1 to 6, characterized in that the signal analysis ( 3 ) as a further characteristic variable of the restitution phase determined by the interval modulations (ΔESI1 and ΔESI2) determines the time constant of the exponential restitution characteristic (Tr) and preferably with the aid of this the first extrasystolic interval modulation (ΔESI0) and the first extrasystolic measured value (Mes0) a second extrasystolic difference value (ΔMes01) compared to the measured value (Mes1) recorded after the shorter modulation (ΔESI1). 8. Cardiac pacemaker according to one of claims 1 to 7, characterized in that the regulation of the interval modulations ( 6 ) also determines modulation values for a second sampling phase, and the control of the modulation period ( 7 ) modulates the stimulation intervals (ESI *) and The demodulation of the measured values (Mes) controls so that at least two different restitution phases can be scanned both sequentially and in parallel. 9. pacemaker according to one of claims 1 to 8, characterized in that the analysis of the elec trical restitution is preferably used to the response speed when the load changes and the accuracy of a pacemaker to opti the stimulation frequency depends on  a too slow function parameter such as that QT interval or breathing or one too unphysio logical parameters such as activity regulated becomes. 10. Pacemaker according to one of claims 1 to 9, characterized in that the analysis of the elec trical and mechanical restitution preferred is used in phases of rest or maximum Load the values for the minimum or maximum Automatically optimize stimulation rate. 11. Pacemaker according to one of claims 1 to 10, characterized in that the analysis of the electrical and mechanical restitution is used in phases of predominantly autonomous stimulation heart function of the myocardium for diagnostics monitoring purposes.