CA1320537C - Rate responsive cardiac pacemaker - Google Patents
Rate responsive cardiac pacemakerInfo
- Publication number
- CA1320537C CA1320537C CA000546713A CA546713A CA1320537C CA 1320537 C CA1320537 C CA 1320537C CA 000546713 A CA000546713 A CA 000546713A CA 546713 A CA546713 A CA 546713A CA 1320537 C CA1320537 C CA 1320537C
- Authority
- CA
- Canada
- Prior art keywords
- rate
- activity
- cardiac pacemaker
- exercise
- patient
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Fee Related
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Classifications
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61N—ELECTROTHERAPY; MAGNETOTHERAPY; RADIATION THERAPY; ULTRASOUND THERAPY
- A61N1/00—Electrotherapy; Circuits therefor
- A61N1/18—Applying electric currents by contact electrodes
- A61N1/32—Applying electric currents by contact electrodes alternating or intermittent currents
- A61N1/36—Applying electric currents by contact electrodes alternating or intermittent currents for stimulation
- A61N1/362—Heart stimulators
- A61N1/365—Heart stimulators controlled by a physiological parameter, e.g. heart potential
- A61N1/36514—Heart stimulators controlled by a physiological parameter, e.g. heart potential controlled by a physiological quantity other than heart potential, e.g. blood pressure
- A61N1/36542—Heart stimulators controlled by a physiological parameter, e.g. heart potential controlled by a physiological quantity other than heart potential, e.g. blood pressure controlled by body motion, e.g. acceleration
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61N—ELECTROTHERAPY; MAGNETOTHERAPY; RADIATION THERAPY; ULTRASOUND THERAPY
- A61N1/00—Electrotherapy; Circuits therefor
- A61N1/18—Applying electric currents by contact electrodes
- A61N1/32—Applying electric currents by contact electrodes alternating or intermittent currents
- A61N1/36—Applying electric currents by contact electrodes alternating or intermittent currents for stimulation
- A61N1/362—Heart stimulators
- A61N1/365—Heart stimulators controlled by a physiological parameter, e.g. heart potential
- A61N1/36585—Heart stimulators controlled by a physiological parameter, e.g. heart potential controlled by two or more physical parameters
Abstract
ABSTRACT OF THE DISCLOSURE
RATE RESPONSIVE CARDIAC PACEMAKER
A rate responsive cardiac pacemaker for implanta-tion in a patent, includes an activity sensor having a resp-onse characteristic limited to the frequency range below 4 Hz for detecting movement of the patient arising from physical exercise and generating an electrical signal representative thereof while discriminating against movement arising from random influences. Means is provided for generating pulses at a controllably variable rate to stimulate the patient's heart at any of a plurality of selectable rates. The pacemaker also includes means responsive to the said electrical signal for adjusting the rate of the pulse generating means relative to a base rate according to whether the patient is undergoing exercise or is at rest.
RATE RESPONSIVE CARDIAC PACEMAKER
A rate responsive cardiac pacemaker for implanta-tion in a patent, includes an activity sensor having a resp-onse characteristic limited to the frequency range below 4 Hz for detecting movement of the patient arising from physical exercise and generating an electrical signal representative thereof while discriminating against movement arising from random influences. Means is provided for generating pulses at a controllably variable rate to stimulate the patient's heart at any of a plurality of selectable rates. The pacemaker also includes means responsive to the said electrical signal for adjusting the rate of the pulse generating means relative to a base rate according to whether the patient is undergoing exercise or is at rest.
Description
~32~3~
RATE RESPONSIVE CARDIAC PACEMAKFR
BACKGROUND OF TH~ INVENTION
1. Field of _he Invention The present invention relates generally to artificial cardiac pacemakers, and more part~cularly to an implantable cardiac pacemaker which generates stimulating pulses at a physiolog1cally appropriate rate dependln~ on the overall metabolic state of the patient.
RATE RESPONSIVE CARDIAC PACEMAKFR
BACKGROUND OF TH~ INVENTION
1. Field of _he Invention The present invention relates generally to artificial cardiac pacemakers, and more part~cularly to an implantable cardiac pacemaker which generates stimulating pulses at a physiolog1cally appropriate rate dependln~ on the overall metabolic state of the patient.
2 . n ~ l ~ . .D ~ around Since the advent of the artificial implantable cardiac pacemaker, the aims of cardiac pacing have chan~ed from the initial goal o~ simply providing a lower rate limit to prevent li~e-threatening asystoly, to the present-day broad objective of improving the overall quality of life of the pacemaker patient. Quality of life, in this context, pertains to the performance of the heart under widely varying metabolic and hemodynamic conditions. Patlents with conventional single chamber pacemakers often lack adequate ~eart rate and cardiac output to sustain more than slight physical exertion, and consequently suffer severe limitations on activity and fitness.
For patients with complete AV block and normal sinoatrial node activity, the dual-chamber pacemaker can restore an adequate adaptation of heart rate to exercise; but that solution serves only a relatively small portion of the pacemaker patient popu-lation, and such pacemakers are susceptible to disturbances.
`~
~3~g~
As a result, numerous studies have been conducted over the years seeking to uncover parameters whlch act lnternal or external to the body ~or possible use ln controllin~ pacem~lcer stimulation rate. The goal io to control th~ heart rate of a pacemaker patient in a manner slmilar to the intrinsic heart rate of a healthy person with a normal functioning heart, under various conditions of rest and exercise; whlch i5 to say, in a physiologically appropriate manner. Parameters for controll~ng the pac~ng rate heretofore studied and proposed in the patent and scientif~c l~terature include the QT time interval, which varies with the electrical depolarizatlon and repolarization occurriny during exercise (e.~., U.S. paten~s 4,201,219 and 4,228,~03~; respiratlon rate, and thoracic impedance changes arising f rom increased respiration w~th exercise, using exter-nal adhesive electrode~ and an external pacemaker (e.g., U.S.
patent 3,593,718 and ~uropean pate!nt EP-A2-0135911); the blood pH balance (e.g., U.S~ patent 4,009,~21); the central venous oxygen saturation (e.g., U.S. patents 4,202,339 and 4,399,820~;
stroke volume (e.g., U.S. patent 4,535,~74); nerve activity ~e.g., German patent DE 28 o9 091 and u.s. patent 4,20~,2193;
and the central venous blood temperature (e.g., German patent DE OS 26 09 365).
Applicants's German Patent No. DE 34 l9 433 and related ~.S. patent No. 4,688,573, issued August 25, 1987, discloses techniques for rate responsive pacing which utilize both absolute temperature values and relative temperature .~,, i ~3~3~
changes of the central venous blood of the patient under various physiological conditions, and which utilize separate algorithms defining heart rate as a funct.ion of blood tempera-ture for states of rest and exercise, respectively, together with the decision rule for selecting whlch of the algorithms is appropriate at any given time.
Techniques for converting mechanical forces, accelerations and pressures into electrical energy and/or signals have also been proposed in the li-terature for use in biomedical techno-logy. These techniques include the generation of electrical energy to power implanted devices from piezoelectrlc crystals and other mechanoelectrical converters responsive to movement of the individual (e.g., U.S. patents 3,659,615 and 3,456,134);
the use of a piezoelectric crystal embedded in silicone rubber and implanted in the pleural space between lung and ribs, to detect the respiratory rate for controlling the pacing rate (see Funke's publication in Journal Biomedizinische Technik 20, pp. 225-228 ( 1975) ); the use of a piezoelectric sensor for measuring cardiac activity (U.S. patent 4,428,380); detecting patient activity with an implanted weighted cantilever arm pieæoelectric crystal, and converting the output signal of the crystal lnto a drive signal for controlling the rate of a car-diac pacemaker (U.S. patent 4,140,132); and using the amplitude of a band-passed signal whose high frequency content increases with patient movement in an activity-responsive cardiac pacemaker (e.g., U.S. patent 4,428,378).
i3~37 The afor~mentioned prior art parameters and techniques suffer various disadvantages when used in an ef~ort to control pacemaker stimulation rate. For example, control according to the QT principle cannot distinguish emotional influences on QT
interval changes from exercise induced influences, which leads to sometimes unwanted and more pronounced emotionally-induced increases in the patient's heart rate. The change of respira-tory rate with exercise varies widely hetween individual~, although le5s so with minute ventilation. Also, a person may voluntarily alter his or her respiratory rate without exercise and thereby adversely affect pacing rate. The pH level of the blood is not truly representative of patient metabolism because the significant changes toward acidity occur only at the higher levels of exercise. Similarly, changes of the central venous oxygen saturatlon are not a satisfactory indicator because a considerably greater decrease occurs at the beginning of exer-cise, even low work-load exercise, especially in those patients with limited cardiac output or tendency toward congestive heart failure, while continuing exercise may produce only slight further decreases. The stroke volume exhibits variations based on the pos~tion of the body, that is, accordlng to whether the patient is sitting, lying or standing, which are independent of the level of exercise. The detection of patient activity by means of a neurodetector for the carotid nerve, for example, has serious limitations because of the nature of the surgery and the level of patient discomfort from this type of implant.
132~ 3~7 The detection of the activity- or mot~on-induced forces within or on the body by means of a piezoelectric crystal, a microphone or other mechanoelectrical transducer exhibits the desirable characteristic of a fast response to the onset of exercise, but has certain serious disadvantages including the deleterious efEect of noise disturbances external to the body, such as from nearby operating machinery, or emanating within the body, such as from coughing, sneezlng, laughing, or the like. Accordingly, disturbances unrelated to exercise can affect the heart rate, when accelerometer-type detection is utilized for control of the pacemaker stimulation rate.
It has been assumed in the prior art that the maximum acceleratio~ values detected by an activ~ty-controlled cardiac pacemaker in a patient undergoing exercise occur in the range of the resonant frequency of the maJor body compartments such as the thorax and the abdomen, i.e. approximately 10 Hz (e.g., see Proceedings of the European Symposium on Cardia~ Pacing, editorial Grouz, pp. 786 to 790, Madrid, 1985). Thus, the prior art teaches that the maximum sensitivity should be in the ran~e above 10 Hz (e~g., see also, Biomedizinische Technik, 4, pp. 79 to 84, 1986, and the aforementioned U.S. patent 4,428,3~
11 32~7 SUMMARY OF T~E INVENTION
__ _ __ _ ____ The present invention provides a cardiac pacemaker which reliably generates stimuli at rates adapted to the overall metabolic state of the patient, and, in particular, in which the stimulation rate i9 responsive to the level of physical exertion of the patient, closely corresponding to the heart rate of a nor~al healthy person under the same conditions of physical exertion. According to an important aspect of the invention, the rate responsive cardiac pacemaker employs an accelerometer ~activity or motion sensor) in the form o~ any known type of mechanoelectrical converter or transducer of suitably small size and low power consumption, which is adapted either by vlrtue of its construction or by use of associated filter circuitry to pass signals in a preselected frequency band to be described presently.
According to another significant aspect of the invention, the rate responsive cardiac pacemaker also employs a second sensor which is adapted to detect a parameter complementary to acceleration, for dual sensor confirmation of metabolic state and selective contribution to stimulation rate. As used throughout this specification and accompanying claims, the terminology "complementary parameter" is intended to mean any physiological or other detectable parameter o~ the body or acting outside the body, whose characteristics of sensitivity and specificity to physlcal exercise contra~t with and enhance the corresponding characteristics of the activity sensor. The ~32~3~
latter has a fast response -to the onset of exercise but is not specific with respect to the 1nstantaneous metabolic level of exercise. In contrast, by way of example and not limitation, a parameter such as the central venous blood temperature responds less quickly to the onset of exercise, but is highly specific as to the metabollc level of exercise. Thus, the two para meters complement each other by mutually supplying what the other lacks.
Based on considerable data obtained from healthy subject test volunteers and, as well, from testing of cardiac pacemaker patients, the applicant has found, using a primarily linear frequency sPnsor, that contrary to the teachings of the prior art the maximum forces occurring with phy~ical activity are in the range of the frequency of the individual's steps in walk-ing. The maxlmum amplitude i5 observed with the indlvidual walking, whether on a level surface or up and down stairs, and with running, in the range of 1 to 4 Hz and depending on the speed of the walking or running. The amplitude of these motion signals far exceeds the signals produced by respiration and the beating o~ the heart. Further, the amplitude of these signals in the range of the response curve (the walking frequency), measured using a mechanoelectrical transducer which is sonfig-ured or used together with circuitry selective in this frequen-cy range, has a direct and largely linear relation to the work performed. When the amplitudes of these low frequency signals (up to about 4 H2 ) increase there is also an observable ~32~ 337 increase in the amplitudes of higher-frequency signals in the range above 4 H~, but the latter amplitudes are considerably smaller than the amplitudes of the low~frequency range slgnals arising from physical activity.
Applicant's investigations indicate that the maximum amplitude activity-sensed signals occurr.ing with exercise such as walking, climbing stairs, running and bicycling, take place with rhythmical motions of the body and are found in the low-frequency ranye below 4 Hz. Housework such as cleaning, vacuuming and the like also shows a maximum amplitude in the low-frequency range according to the applicant's data. In contrast, amplitude maxima in the higher-Prequency range are the result of ~udden spasmodic movements which do not represent true metabolic exercise, and the indicia of those movements may be readily excluded by limiting detection to only the low-frequency content, which correlates well with the metabolic demand of the body in true exercise.
Noise detected from outside the body such as when the patient is in close proximity to operating machinery, or arislng ~rom within the body -~uch as when the patient coughs, laughs, sneezes or strains, displays amplitudes in the higher-frequency range up to about tenfold the amplitudes of signals in the same range attributable to true physiologioal exercise.
Thus, the noise signals tend to swamp the activity-induced signals at the higher frequencies. Light knocks upon, bumps against or touching of the pacemaker are picked up by the ~32~37 internally mounted activity sensor and present impulse charac-teristlcs detected ln the higher-frequency range, but are detected, if at all, with very low amplitudes in the low-frequency range up to 4 Hæ. Also, because the duration o~ the pulse wave deriving from the propagation of the pulse with every heart beat is in the range of about ~0 to 120 ms, it has an impulse characteristic with maximum ampli-tude in the higher-frequency range at about 10 Hz, despite the fact that the heart rate itself is in the range from ~0 to 1~0 beats per minute (bpm) corresponding to a frequency of 1 to 3 Hz.
External noise caused by machines, motors and vehicle~
also displays maximum amplitudes in the higher-frequency range.
According to the applicant'~ measurements, riding in a car- or on a bicycle on an uneven road suriace produces some noise in the low-frequency range, but considerably below the amplitude maxima detected wlthin the higher-frequency range. In general, the activity-induced signal to di~turbance-created noise ratio in the low-~requency range is considerably better than in the higher-frequency range, and the low-frequency noise i5 readily discriminated from those signals representative of physical activity of the patient.
A further advan-taye of using the low-frequency spectrum i8 that reliable detection of the amplitude maxima and minima is achievable with a relatively low sampling rate, ln compariscn to the high-frequency range, with an attendant saving of con-siderable enersy. Since the energy capacity of an implanted ~3~53 1 pacemaker is limited, any saving of energy is important.
A further aspect of the present lnvention is the achieve-ment of rate control wlth an activity transducer in such a way that the relative changes of amplitude of the processed activity-induced signal are used for adjusting the stimulation rate, rather than the absolute signal values. This is quite dif~erent from the teachings of the prior art, which invariably relies on the absolute values of the signals. The use of relative chanyes makes it possible to avoid false triggerings caused by even minor noise since a rate increase is dictated only when the value calculated from the signal exceeds a pre-cletermined activity baseline. The amount of the rate increase is a function not only of whether the predetermined baseline value is exceeded, but also of the rate at the time this cri-terion is met. This means that the extent of the rate increase will be less with increasing pacing rate, i.e., the specific amount of the increase will be smaller at the higher rates.
on the other hand, both the absolute amplitude and the relative change o~ amplitude of the activity signal are evaluated to determine a stimulation rate increase, in part because o~ the relatively slower response of the second complementary parameter.~
As pointed out above, the rate responsive cardiac pace-maker exercises control of stlmulation rate not only by use of a mechanoelectrical transducer (activity sensor), but also by detecting a second complementary parameter. ~ate control is ~32~37 optimized through -the complementary parameter to avoid the prolonged false trlggerings which might otherwise be encoun-tered using the activity sensor alone. In a presentation at the Fall 1985 meeting o~ the German, Austrian and Swiss Cardio-logical Society in Vienna, applicant discussed the possible use of a temperature sensor with an activity sensor of the type taught by the aforementioned U.S. Patent No. ~,428,3~ (see Zeitschrift ~ur Kardiologie, vol. 75, Abstract 69, 1985). An attendee of that presentation and hls colleagues subsequently investigated whether the central venous blood temperature ls a suitable measurable variable for use in combination with the speciflc activity control according to the latter patent ~see ~erzschrittmacher 6: 64 to 67, 1985).
The present invention teaches not only the use of a com-plementary ~econd parameter to limit a noise-related false triggering of a rate increase by the relative change in the signal level o~ the mechanoelectrical transducer, but ~150 the use of the output signal o~ the transducer to determine whether an increase in the stimulation rate attributable to the value of the complementary second parameter is appropriate. In an example of the latter, if venous blood temperature is chosen as the complementary second parameter, fever is ~readily detected (or confirmed) by the absence of an activity (motion) si~nal from the transducer; and in those circumstances the increase in stimulation rate of the pacemaker according to the invent~on will be less than a rate increase appropriate in the presence ~32~3~
of an activity signal. In other words, the newly calculated heart rate i5 based on the signal representative of the meas-ured second complementary parameter when the absolute signal level of the activity transducer is below a predetermined minimum. Absence of detected motion indicates not only an absolute rate, but tha~ the minimum rate is to be determined according to the state of the complementary second parameter.
After physical exercise, the stimulation rate of the pacemaker according to the invention is decreased to a quiescent base rate (resting rate) according to a ~all-back program (i.e., a rate reduction routine) as a functlon of the drops of the signals from both sensors. However, another function of the activity sensor (transducer) is that a decrease in stimulation rate to this base rate i5 inhibited so long as the processed absolute signal amplitude of the ~ransducer exceeds a predetermined level indicative of body activity.
Thus, the invention provldes rate control using, on the one hand, the low frequency band and the relative chan~e of the transducer signal amplitude in that band: and, an the other hand, the absolute signal amplitude of the low-frequency pro-cessed transducer output to determine an absence of motion calling for rate control according to a baseline characteristic relating heart rate to the complementary second parameter, or to determine a presence of motion calling for the suppression of a rate fall-back program. The mechanoelectrical transducer thereby provides the desirable fast response for rate control ~32~537 at the onset of exercise and change of the workload, provides a shift to a resting baseline control by the complementary second parameter in the absence of an activity-induced ~ignal, and prevents a rate fall-back or too rapid a rate reduction in the presence of an activity-induced signal characteristic oP
exercise by the patient.
It is a feature of the invention that a new baseline or threshold level for activity i5 established according to the specific inertia criteria or characteristics of a complementary second parameter, such as the exemplary parameters mentioned above or the natural sinus node actlvity in a dual chamber pacemaker. That is, after a certain time interval (e.g., a few minutes) in which there has been no confirmation of the trans-ducer signal by the second complementary parameter sensor signal, the then-current activ~ty signal amplitude i8 assumed to be the new baseline, zero or quiescent value of activity.
Accordingly, a prolonged împroper rate increase attr~butable to false triggering oP the activity sensor is avoided even in a noisy environment.
If there is no signal from the mechanoelectrical trans-ducer or if the transducer signal amplitude fail~ to achieve a predetermined minimum absolute amplitude, and, in either event, t~e detected value of the complementary second parameter is increasing, the pacemaker of the present invention will initiate a fall-back program to return the stimulation rate toward a predetermineq base or resting rate. Such circum-~ 3 ~ C~ 7 BRIEF D~SC~IPTION OF THE DRAWINGS
. _ ",._= . _ The above ~nd other objects, aspects, features andadvantages o~ the present in~entiQn will become more apparent from a con~ideration of ~he ensuing detailed description of a pr~ently pr~ferred embodiment thPreof, tak~n in conjunction with the accompanying drawin~s, in which:
FIG. 1 i~ a block diagram of a cardiac pacemaker according to the invention;
FIG. 2a is a schematic diagram of a frequency spectrum of the low-pass (band-pass) æignals of a mechanoel~ctrical ~rans-ducer (activity senqor) used in the pacemaker of FIG~ 1;
FIG, 2b ~hows a Fourier analysis with respect to the frequency and amplitude of the ~ignals from the mechano-electrical transducer for the activity o~ slow walking;
FIG5~ 2c through 2f each show fre~uency and amplltude spectra for di~feren~ typeQ of activity and di~turbance~;
FIGS. 3 to 7 are diagrams of signals developed in the .
pacemaker of FI&. ~ for indicated types of activity;
FIG. 8 is a flow chart of the functioning of the cardiac pacemaker of FIG. 1;
FIGS. 9a and 9b are respectively a front view and a cross-sectional view of one example of a mechanoelectrical transducer which could possibly be used in the pacemaker of FIG. l; and FIGS. 10a to 10d are diagrams of signals developed in the pacemaker of FIG. 1 for indicated types of activity.
;....................................... 15 ~L32~37 stances indicate that the patient is not undergoing physical exertion, and that it is appropriate at this point to reduce the stimulation rate to the base rate. Thls feature may be utilized to discriminate and halt reentry tachycardias in atrial P-wave triggered DDD pacemakers.
It may be seen that, among other features, the pacemaker of the present invention not only protects against prolonged improper rate increases from false triggerings of the mechano-electrical transducer, but also protects against prolonged rate increases attributable solely to the sensed value oP the second complementary parameter. Furthermore, the extent of rate control accorded to that complementary second parameter can differ according to the nature of the signal (or lack thereof) deriving from the mechanoelectrical transducer.
The mechanoelectrical transducer may be of any known type, such as a pieæoelectr~c, piezoresistive or piezocapacitive sensor of the semico~lductor type, which can even be integrated with signal processing circuitry in a silicon chip. Such integrated circuits are manufactured using conventlonal semi-conductor process technology. By fabricating the sensor with appropriate geometrical configuration, the sensor itself can provide the desired frequency bandpass characteristics to capture the proper signal. Por example, the transducer may comprise a vibratory cantilever arm of material and length selected to provide it with the desired resonant frequency.
132~3~
DETAILED DE5CRIPTI_N OF THE PREFERRED _ oDIMENT
Referring now to FIG. l, a cardiac pacemaker 1 includes a case 2 in which the various components are housed, including evaluation circuitry lOa and activity sensor (mechanoelectrical transducer) 3. The circuitry within case 2 is connected via a conventional connector 4 to a pacing lead 5 with a stimulating electrode tip 6. The pacin~ lead(s), for example, is of the endocardial catheter type for insertion intravenously to posi-tion the stimulating electrode(s) relative to excitable myocar-dial tissue in the appropriate chamber(s) of the right side of the patient's heart. The pacemaker may be arranged in conven-tional fashion for unipolar or bipolar stimulation, and may include known sensing electrode(s) and processing circuitry therefor as well.
A ~econd sensor 7, electrically connected to the pacemaker circuitry via a su~table connector 4a, for example, is provided for d~ecting a second complementary physiological parameter, such as the natural atrial rate, the QT interval, the pH value of the blood, the blood oxygen saturatlon, the respiration, the central venous blood temperature, or other recognized parameter of or actiny on the body, whose value is related to heart rate.
In the preferred embodiment, the central venous blood tempera-ture is chosen as the complementary second parameter and will be referred to in that respect throughout the ensuing descrip-tion, but the invention i8 not limited to the use of blood tem-perature. By using blood temperature as the complementary ~ 3 2 0 ~ ~ rl parameter all of the teachings of U.S. patent No. 4,688,573, issued August 25, 1987, are readily and advantageou~ly employed. Sensor 7 in this ~mbodiment, therefore, may b~ a thermi~tor or other suitable temperature sensing element located in the pacing lead 5, in the manner descr.ibed in the '573 patent, or sensing the blood temperature in the atrium or ventricle o~ the right side of the patien~'s heart.
The implanted pacemaker case 2 further houses a battery 8;
a pulse generator 9, whose pulse rate is controllably variable, for generating the stimulating pulses to be delivered to pacing e~ectrode 6 for stimulating the patient's heart; evaluation circuits lOa, lOb for processing and evaluating the signals deriving from activity sensor 3 and temperature sensor 7, respectively; a memory 11 for storing data, such as programmed values in con~unction with a conventional external programmer and other data of the type to be described, includin~ a base-line curve and exercise curves (algorithms~ representing heart rate as a function of blood temperature, as set forth in the '111 application; and a logic circuit 12 for controlling the sampling of signals from the ~ensors and the rate of the pulse generator.
Activity sensor 3 is a small mechanoelectrical transducer, preferably of a type mentioned above, which is either fabricat-ed in a conventional manner to provide an inherent frequency band characteristic selected according to the teachings of the pre~ent invention, or i5 coupled to a filter circuit to pass 1 'I
132~53 l signals in that selected band. The fre~uency spectrum of the band-passed signals from activity sensor 3 is represented in FIG. 2a, with low pass filtering produclng a rapid drop-off at frequencies exceeding 4 Hz, and with high pass filtering to eliminate DC and frequencies below the 0.3 Hz level.
In FIGS. 2b to 2f, the output signals of sensor 3 are ana-lyxed for several di~ferent types of activity. FIG. 2b is a Fourier analysis of the processed signals of the activ~ty sen-sor showing frequency measured in Hz and amplitude measured in dB, detected in a slowly walking test subject. FIG. 2c charts the amplitude relative to time of the low-pas~ signal (i.e., in the band Prom about 0.3 Hz to 4 Hz) processed from the act~vity sensor for successive intervals of rest, walking, running, walking and return to rest by the subject. FIG. 2d illu5-trates, in three separate charts, the unfiltered complete out-put signal of the activity sensor ~upper chart), the high-pass portion (i.e., above ~he selected band) of ths signal (middle chart), and the low-pass portion of the signal (lower chart), detected from a walking subject in which successive intervals of noise are encountered by touching of the pacemaker, coughing and laughing by the subject.
As will be observed from FIG. 2b, the frequency spectrum for movem~nt oP the sub~ect by foot indicates a clear maximum amplitude at a frequency of approximately 2 Hz; and signifi-cantly declining signal amplitudes in the ranye exceeding 4 Hz.
FIG. 2c shows an increase in the amplitude of the low-pass ac-~32~37 tivity signal with increasing exercise as the subject goes fromwalkin~ to running, and an amplitude decrease as the subject returns to walking and ultimately to a state of rest. FIG. 2d clearly demonstrates that the low-pass activity signal is vir-tually unencumbered by the noise generated from lmpact on the pulse generator case, coughing, laughing or the like, the sig-nal indicative of walking being cleanly deteoted. In contrast, the higher frequency range is significantly affected by that noise, so much so that the signal representative of the walking is buried in the noise.
FIGS. 2e and 2f show the signal amplitudes over time for the entire frequency spectrum (upper chart), the high-pass portion (middle chartJ, and ~he low~pass portion (lower chart), when the sub~ect is riding in a car and bicycling on an uneven road, respectively. Here again, it is abundantly clear from the test results that the frequency range below g Hz provides an indication of true activity, virtually uninfluenc~d by any noise peaks~ In FIG. 2e, the higher frequency range ls replete with noise including splke~ at the resonance of the moving car.
In FIG. 2, the noise is also pronounced at the higher frequen-cies, with a more homogeneous noise distribution attributable to t~e uneven road surface traversed by the bicycle. In both cases the true activity signal is masked. It will thus be apparent, contrary to the teachings of the prior art, that processing only the lower frequency band of the activity sen30r output provides a considerably more accurate indication of true ~ 3 ~
exercise while avoiding the many false triggerings of rate increases by the pacemaker which can result from noise detected in the higher frequency band.
FIG. 3 shows ~he behavior of the cardiac pacemaker of the present invention when sub~ected to a false triggering attrib-utable to noise, encoun~ered while the patient i5 riding in a car for example. Part (P) of FIG. 3 and also of similarly for-matted FIGS. 4 to 7 indicates the nature of the exercise work-load. In each of these FIGS. the time scale i~ partly com-pressed and does not correspond to actual time. ~or example, the interval between times tl and t2 is typically only two or three seconds in durat~on, whereas at least some of the subse-quent time intervals ~ay be of several minutes duration each.
In the example of FIG. 3, the "exercise" is fictitious, with the signal detection resulting strictly from noise. Part (a) shows the processed output of activity sensor 3 for the aforesaid low frequency band. Up to time tl the pacemaker patient i~ merely sitting in the stationary car; hence, no signal or only small signal variations (attributable to slight movement of the patient in the idling vehicle, for example) are detected. At tl, the ~ar starts moving and a higher signal level is detected. It is important to observe~ that the signal amplitude is exaggerated for the sake of explaining this exam-ple; as was observed in FIG. 2e, the low frequency band is quite effective to filter disturbances arising from the moving car.
1 3 2 ~ 3 3 ~
Processing of the signal after ~iltering may be accom~
pllshed in different ways. For example, the evaluation circuit lOa may be adapted to operate on the band-passed signal over succes~ive blocks of time o~, say, three seconds each. The difference between the maximum and minimum signal amplitudes i~
calculated for samples taken at predetermined intervals of, say, 300 milliseconds each. The calculated amplitude differ-ence is then added to the calculation for the pxevious sample for all X samples of Block 1 (i.e., the first three ~econd per-iod, in this example), and the value obtained i5 then averaged for Block 1 by dividing that value by the number of samples taken. I~ the di~erence between that avera~e and the average for Block 2 (i.e., the next three second period) exceeds a pre-determined activity baseline related to unit~ o~ gravity, and i~ this is con~irmed over the next few blocks of time, it is indicative of activity or of a significant increase o~ activ-ity (additional activity). This is the post-filtered signal processing technique employed in the preferred embodimen~ of the invention, although various other suitable techniques will be apparent to the skilled artisan. In this manner, random or spasmodic movements which might otherwise be regarded as exercise can be disregarded.
Re~erring again to part (a~ of FIG. 3, the jump in the flltered activity signal occurs at time tl (or an instant later depending on the response time o~ the activity sensor). The processed data is compared with predetermined baseline or 132~337 threshold value~ of activity A1, A2, and 50 forth, each of which may be freely programmable and stored ln the memory 11 (wh.ich, incidentally, was also used to store sampled values for the aforementioned data processing)0 The initial activity thresholds may be selected according to the particular patient and the type of accelerometer (activity sensor) employed for the pacemaker. By way of example, 0.15 g (unit of gravity) was deemed an acceptable level indicative of patient activity for one test subject, using an embodiment of an activity ~ensor for which that level of movement produced a signal level of about 60 millivolts.
If the previously described processing calculation exceeds the first threshold A1, the logic c:ircuit 12 controllably ini-tiates an increase in the rate at which stimulating pulses are generated by the pulse generator 9 by an amount of, say, 15 pulses per minute (ppm, equivalent to bpm~. If the second threshold A2 were exceeded at tl, the pulse rate would be in-creased by a greater amount, say, 25 ppm. This rate increase is accomplished as follows. Logic circuit 12 responds to threshold A1 having been exceeded at tl, by initiating at t2 a preset timing function of a rate controller 21 to which it is connected within housing 2, to increase the pacing rate of the pulse generator g by 15 bpm. This timing function produces a predetermined transition to the higher pacing rate, as repre-sented in part (b) of FIG. 3. If there is no further signifi-cant change in the processed signal calculations as described ~ 32~37 above, this increased stimulation rate will continue in effect.
At the same time that the rate increase ls initiated, the ex-ceeded activity threshold Al is designated as the new activity baseline, and a higher activity threshold A1' (and A2', etc.) is set from which to determine additional activity, as will be further explained presently.
At any time that the absolute amplitude of the activity signal drops to 25% of the activity threshold which was exceed-ed to cause the rate increase, the logic circuit initiates a fall-back program through another timing function of rate con-troller 21 to gradually reduce the stimulation rate of the pulse generator back to a preprogrammed base rate. As shown in FIG. 3(f), the car comes to a stop at t5. The absolute level of the detected activity signal drops to 25% of activity threshold A1 an instant thereafter (FIG. 3(a)), and the pacing rate is decreased commencing at that time (FIG. 3(b)).
However, the present invention also serves to avoid pro-longed rate increases from false triggerings of the pacemaker as a re~ult of high lev21s of noise in the ~iltered output of the activity sensor, even in those instances where the noise is present in the low frequency band and is not rejected by the aforementioned signal processing calculations. To that end, the logic circuit 12 actuates a timer 22 at t2, coincident with the triggering of the rate increase via rate controller 21, to commence timing a predetermined period ~FIG. 3(b)~ whose dura-tion i5 preset according to the response time of the selected ~32D337 second comple~entary parameter to the onset of exercise or to abrupt changes in level of exercise. In the presently prefer-red embodiment, where blood temperature is the complementary parameter, the period of timer 22 may be set, for example, at two to three minutes. In general, sensors of the physiological parameters mentioned earlier herein are less sensitive to the onset of exercise than an activity sensor, but as previously noted herein, each of these other parameters is a suitable com-plementary parameter to acceleration because of their greater specificity ln indicating the varying level of ongoing exer-cise. If one of these other parameters were used in place of blood temperature~ the timer 22 period would be set according-ly. The duration of the timer period is important because if, during that period, the stimulation rate dictated by the second complementary parameter exceeds the rate dictated by the activ-ity signal, the latter relin~uishes and the former assumes con-trol of the stimulation rate. On the other hand, if the second complementary parameter fails to assume such control, this con-stitutes a lack oP confirmation of the activity si~nal and an indication oX no true activity or of insuficient activity to warrant the rate increase. Accordinyly, ln the latter circum-stance the logic circuit 12 actuates the rate~controller 21 to initiate a rate reduction routine (fallback program) at the end oX the period of timer 22.
The blood temperature measured by thermistor 7 over the timer period is represented in FIG. 3(c). The stimulation rate 3 ~
is calculated from the measured blood temperature as described in U.S. patent No. 4,688,573, issued August 25, 1987, and is represented in FIG.3(d). Of courser in this example the "exercise"
is fictitious, and consequently the temporal increase, i~ any, in the blood temperature would be insuffici.ent to produc~ a stimulation rate othe.r than is commensurate with the baseline resting curve. In fact, there is no substantial change in the blood temperature according to FIG. 3(c), and therefore virtually no change in the rate determined from the blood temperature as shown in FIG. 3(d). H~nce, at time t3, when the timer period expires, lo~ic circuit 12 initiates the rate fallback program of rate controller 21 to gradually reduce the stimulation rate of pulse generator 9 to the programmed base rate at t4. This assures that the patient will not be subjected to improper rate increases as a result of false triggerings for more than the relatively short duration of the timer period, rather than experiencing a prolonged rate increase, for example, over a four hour car ride.
If the evaluation of the filtered activi.ty sensor output indicates a reduction in the averaged maxima and minima of the signal by ~5~ or more to a value of 25% or less of the activity threshold which has just been exceeded, it is assumed that exercise has ceased. At that point, the lo~ic circuit will in~tiate the ~allback program of rate controller Zl to return the pulse rate of pulse generator 9 to the base rate. The various threshold values and the criterion of reduction of below last-exceeded activity threshold may be selected (pro-~- 25 132~37 grammed) according to the individual patient.
The arrangement of the diagrams in FIG. 3 is repeated in FIGS. 4 to 7, inclusive. In each FIG.: part (a) r0presents the filtered low-frequency band output signal of activity sensor 3, part (bJ illustrates the stimulation rate ~heart rate) attrib-utable to the signal of part (a); part ~c) ~hows the value or the signal representative thereof for the second complementary parameter -- in the presently preferred embodiment, the blood temperature detected by sensor ~; part (d) represents the stim-ulation rate determined according to the value shown in part (c~; part (el shows the effective stimulation rate derived from both parameters (activity and blood temperature); and part tf) schematically represents the exercise level or workload.
FIG. 4 is a diagram representing the behavior of the pace-maker for a patient who commences walking for a period of time and then returns to a state of rest. Part (f) indicates that the ex~rcise starts at time tl, and i5 thereupon detected by the activity sensor (part (a)). The filtered signal amplitude is processed b~ the evaluation circuit lOa and, after a brief interval, the calculated value is found to exceed activity threshold A1. Accordingly, pulse generator 9 is ad~usted via rate controller 21, under the control of logic circuit 12, to increase the pacing rate by 15 bpm commencing at time t2, as shown in FIG. 4(b~. At time t4, the exercise ceases and this is reco~nized at time t5, when the calculated value of the pro-ces~ed activity signal has dropped to 25% of the activity 132~ 7 threshold Al. ln those circumstances, if the rate control were based strictly on the output of the activity sensor the stlmu-lation rate would be reduced gradually toward the programmed base rate under the rate reduction routine of rate controller 21, as was described in connection with FIG. 3.
Here, however, the blood temperature increases with the exercise, after the characteristic dip at the onset thereof, and continues to increase until it reaches a steady state value FIG. 4(c). At time t3, before the timer 22 period haR expired, the stimulation rate determined according to blood temperatur~
exceeds the rate determined from the activity signal (FI~.
For patients with complete AV block and normal sinoatrial node activity, the dual-chamber pacemaker can restore an adequate adaptation of heart rate to exercise; but that solution serves only a relatively small portion of the pacemaker patient popu-lation, and such pacemakers are susceptible to disturbances.
`~
~3~g~
As a result, numerous studies have been conducted over the years seeking to uncover parameters whlch act lnternal or external to the body ~or possible use ln controllin~ pacem~lcer stimulation rate. The goal io to control th~ heart rate of a pacemaker patient in a manner slmilar to the intrinsic heart rate of a healthy person with a normal functioning heart, under various conditions of rest and exercise; whlch i5 to say, in a physiologically appropriate manner. Parameters for controll~ng the pac~ng rate heretofore studied and proposed in the patent and scientif~c l~terature include the QT time interval, which varies with the electrical depolarizatlon and repolarization occurriny during exercise (e.~., U.S. paten~s 4,201,219 and 4,228,~03~; respiratlon rate, and thoracic impedance changes arising f rom increased respiration w~th exercise, using exter-nal adhesive electrode~ and an external pacemaker (e.g., U.S.
patent 3,593,718 and ~uropean pate!nt EP-A2-0135911); the blood pH balance (e.g., U.S~ patent 4,009,~21); the central venous oxygen saturation (e.g., U.S. patents 4,202,339 and 4,399,820~;
stroke volume (e.g., U.S. patent 4,535,~74); nerve activity ~e.g., German patent DE 28 o9 091 and u.s. patent 4,20~,2193;
and the central venous blood temperature (e.g., German patent DE OS 26 09 365).
Applicants's German Patent No. DE 34 l9 433 and related ~.S. patent No. 4,688,573, issued August 25, 1987, discloses techniques for rate responsive pacing which utilize both absolute temperature values and relative temperature .~,, i ~3~3~
changes of the central venous blood of the patient under various physiological conditions, and which utilize separate algorithms defining heart rate as a funct.ion of blood tempera-ture for states of rest and exercise, respectively, together with the decision rule for selecting whlch of the algorithms is appropriate at any given time.
Techniques for converting mechanical forces, accelerations and pressures into electrical energy and/or signals have also been proposed in the li-terature for use in biomedical techno-logy. These techniques include the generation of electrical energy to power implanted devices from piezoelectrlc crystals and other mechanoelectrical converters responsive to movement of the individual (e.g., U.S. patents 3,659,615 and 3,456,134);
the use of a piezoelectric crystal embedded in silicone rubber and implanted in the pleural space between lung and ribs, to detect the respiratory rate for controlling the pacing rate (see Funke's publication in Journal Biomedizinische Technik 20, pp. 225-228 ( 1975) ); the use of a piezoelectric sensor for measuring cardiac activity (U.S. patent 4,428,380); detecting patient activity with an implanted weighted cantilever arm pieæoelectric crystal, and converting the output signal of the crystal lnto a drive signal for controlling the rate of a car-diac pacemaker (U.S. patent 4,140,132); and using the amplitude of a band-passed signal whose high frequency content increases with patient movement in an activity-responsive cardiac pacemaker (e.g., U.S. patent 4,428,378).
i3~37 The afor~mentioned prior art parameters and techniques suffer various disadvantages when used in an ef~ort to control pacemaker stimulation rate. For example, control according to the QT principle cannot distinguish emotional influences on QT
interval changes from exercise induced influences, which leads to sometimes unwanted and more pronounced emotionally-induced increases in the patient's heart rate. The change of respira-tory rate with exercise varies widely hetween individual~, although le5s so with minute ventilation. Also, a person may voluntarily alter his or her respiratory rate without exercise and thereby adversely affect pacing rate. The pH level of the blood is not truly representative of patient metabolism because the significant changes toward acidity occur only at the higher levels of exercise. Similarly, changes of the central venous oxygen saturatlon are not a satisfactory indicator because a considerably greater decrease occurs at the beginning of exer-cise, even low work-load exercise, especially in those patients with limited cardiac output or tendency toward congestive heart failure, while continuing exercise may produce only slight further decreases. The stroke volume exhibits variations based on the pos~tion of the body, that is, accordlng to whether the patient is sitting, lying or standing, which are independent of the level of exercise. The detection of patient activity by means of a neurodetector for the carotid nerve, for example, has serious limitations because of the nature of the surgery and the level of patient discomfort from this type of implant.
132~ 3~7 The detection of the activity- or mot~on-induced forces within or on the body by means of a piezoelectric crystal, a microphone or other mechanoelectrical transducer exhibits the desirable characteristic of a fast response to the onset of exercise, but has certain serious disadvantages including the deleterious efEect of noise disturbances external to the body, such as from nearby operating machinery, or emanating within the body, such as from coughing, sneezlng, laughing, or the like. Accordingly, disturbances unrelated to exercise can affect the heart rate, when accelerometer-type detection is utilized for control of the pacemaker stimulation rate.
It has been assumed in the prior art that the maximum acceleratio~ values detected by an activ~ty-controlled cardiac pacemaker in a patient undergoing exercise occur in the range of the resonant frequency of the maJor body compartments such as the thorax and the abdomen, i.e. approximately 10 Hz (e.g., see Proceedings of the European Symposium on Cardia~ Pacing, editorial Grouz, pp. 786 to 790, Madrid, 1985). Thus, the prior art teaches that the maximum sensitivity should be in the ran~e above 10 Hz (e~g., see also, Biomedizinische Technik, 4, pp. 79 to 84, 1986, and the aforementioned U.S. patent 4,428,3~
11 32~7 SUMMARY OF T~E INVENTION
__ _ __ _ ____ The present invention provides a cardiac pacemaker which reliably generates stimuli at rates adapted to the overall metabolic state of the patient, and, in particular, in which the stimulation rate i9 responsive to the level of physical exertion of the patient, closely corresponding to the heart rate of a nor~al healthy person under the same conditions of physical exertion. According to an important aspect of the invention, the rate responsive cardiac pacemaker employs an accelerometer ~activity or motion sensor) in the form o~ any known type of mechanoelectrical converter or transducer of suitably small size and low power consumption, which is adapted either by vlrtue of its construction or by use of associated filter circuitry to pass signals in a preselected frequency band to be described presently.
According to another significant aspect of the invention, the rate responsive cardiac pacemaker also employs a second sensor which is adapted to detect a parameter complementary to acceleration, for dual sensor confirmation of metabolic state and selective contribution to stimulation rate. As used throughout this specification and accompanying claims, the terminology "complementary parameter" is intended to mean any physiological or other detectable parameter o~ the body or acting outside the body, whose characteristics of sensitivity and specificity to physlcal exercise contra~t with and enhance the corresponding characteristics of the activity sensor. The ~32~3~
latter has a fast response -to the onset of exercise but is not specific with respect to the 1nstantaneous metabolic level of exercise. In contrast, by way of example and not limitation, a parameter such as the central venous blood temperature responds less quickly to the onset of exercise, but is highly specific as to the metabollc level of exercise. Thus, the two para meters complement each other by mutually supplying what the other lacks.
Based on considerable data obtained from healthy subject test volunteers and, as well, from testing of cardiac pacemaker patients, the applicant has found, using a primarily linear frequency sPnsor, that contrary to the teachings of the prior art the maximum forces occurring with phy~ical activity are in the range of the frequency of the individual's steps in walk-ing. The maxlmum amplitude i5 observed with the indlvidual walking, whether on a level surface or up and down stairs, and with running, in the range of 1 to 4 Hz and depending on the speed of the walking or running. The amplitude of these motion signals far exceeds the signals produced by respiration and the beating o~ the heart. Further, the amplitude of these signals in the range of the response curve (the walking frequency), measured using a mechanoelectrical transducer which is sonfig-ured or used together with circuitry selective in this frequen-cy range, has a direct and largely linear relation to the work performed. When the amplitudes of these low frequency signals (up to about 4 H2 ) increase there is also an observable ~32~ 337 increase in the amplitudes of higher-frequency signals in the range above 4 H~, but the latter amplitudes are considerably smaller than the amplitudes of the low~frequency range slgnals arising from physical activity.
Applicant's investigations indicate that the maximum amplitude activity-sensed signals occurr.ing with exercise such as walking, climbing stairs, running and bicycling, take place with rhythmical motions of the body and are found in the low-frequency ranye below 4 Hz. Housework such as cleaning, vacuuming and the like also shows a maximum amplitude in the low-frequency range according to the applicant's data. In contrast, amplitude maxima in the higher-Prequency range are the result of ~udden spasmodic movements which do not represent true metabolic exercise, and the indicia of those movements may be readily excluded by limiting detection to only the low-frequency content, which correlates well with the metabolic demand of the body in true exercise.
Noise detected from outside the body such as when the patient is in close proximity to operating machinery, or arislng ~rom within the body -~uch as when the patient coughs, laughs, sneezes or strains, displays amplitudes in the higher-frequency range up to about tenfold the amplitudes of signals in the same range attributable to true physiologioal exercise.
Thus, the noise signals tend to swamp the activity-induced signals at the higher frequencies. Light knocks upon, bumps against or touching of the pacemaker are picked up by the ~32~37 internally mounted activity sensor and present impulse charac-teristlcs detected ln the higher-frequency range, but are detected, if at all, with very low amplitudes in the low-frequency range up to 4 Hæ. Also, because the duration o~ the pulse wave deriving from the propagation of the pulse with every heart beat is in the range of about ~0 to 120 ms, it has an impulse characteristic with maximum ampli-tude in the higher-frequency range at about 10 Hz, despite the fact that the heart rate itself is in the range from ~0 to 1~0 beats per minute (bpm) corresponding to a frequency of 1 to 3 Hz.
External noise caused by machines, motors and vehicle~
also displays maximum amplitudes in the higher-frequency range.
According to the applicant'~ measurements, riding in a car- or on a bicycle on an uneven road suriace produces some noise in the low-frequency range, but considerably below the amplitude maxima detected wlthin the higher-frequency range. In general, the activity-induced signal to di~turbance-created noise ratio in the low-~requency range is considerably better than in the higher-frequency range, and the low-frequency noise i5 readily discriminated from those signals representative of physical activity of the patient.
A further advan-taye of using the low-frequency spectrum i8 that reliable detection of the amplitude maxima and minima is achievable with a relatively low sampling rate, ln compariscn to the high-frequency range, with an attendant saving of con-siderable enersy. Since the energy capacity of an implanted ~3~53 1 pacemaker is limited, any saving of energy is important.
A further aspect of the present lnvention is the achieve-ment of rate control wlth an activity transducer in such a way that the relative changes of amplitude of the processed activity-induced signal are used for adjusting the stimulation rate, rather than the absolute signal values. This is quite dif~erent from the teachings of the prior art, which invariably relies on the absolute values of the signals. The use of relative chanyes makes it possible to avoid false triggerings caused by even minor noise since a rate increase is dictated only when the value calculated from the signal exceeds a pre-cletermined activity baseline. The amount of the rate increase is a function not only of whether the predetermined baseline value is exceeded, but also of the rate at the time this cri-terion is met. This means that the extent of the rate increase will be less with increasing pacing rate, i.e., the specific amount of the increase will be smaller at the higher rates.
on the other hand, both the absolute amplitude and the relative change o~ amplitude of the activity signal are evaluated to determine a stimulation rate increase, in part because o~ the relatively slower response of the second complementary parameter.~
As pointed out above, the rate responsive cardiac pace-maker exercises control of stlmulation rate not only by use of a mechanoelectrical transducer (activity sensor), but also by detecting a second complementary parameter. ~ate control is ~32~37 optimized through -the complementary parameter to avoid the prolonged false trlggerings which might otherwise be encoun-tered using the activity sensor alone. In a presentation at the Fall 1985 meeting o~ the German, Austrian and Swiss Cardio-logical Society in Vienna, applicant discussed the possible use of a temperature sensor with an activity sensor of the type taught by the aforementioned U.S. Patent No. ~,428,3~ (see Zeitschrift ~ur Kardiologie, vol. 75, Abstract 69, 1985). An attendee of that presentation and hls colleagues subsequently investigated whether the central venous blood temperature ls a suitable measurable variable for use in combination with the speciflc activity control according to the latter patent ~see ~erzschrittmacher 6: 64 to 67, 1985).
The present invention teaches not only the use of a com-plementary ~econd parameter to limit a noise-related false triggering of a rate increase by the relative change in the signal level o~ the mechanoelectrical transducer, but ~150 the use of the output signal o~ the transducer to determine whether an increase in the stimulation rate attributable to the value of the complementary second parameter is appropriate. In an example of the latter, if venous blood temperature is chosen as the complementary second parameter, fever is ~readily detected (or confirmed) by the absence of an activity (motion) si~nal from the transducer; and in those circumstances the increase in stimulation rate of the pacemaker according to the invent~on will be less than a rate increase appropriate in the presence ~32~3~
of an activity signal. In other words, the newly calculated heart rate i5 based on the signal representative of the meas-ured second complementary parameter when the absolute signal level of the activity transducer is below a predetermined minimum. Absence of detected motion indicates not only an absolute rate, but tha~ the minimum rate is to be determined according to the state of the complementary second parameter.
After physical exercise, the stimulation rate of the pacemaker according to the invention is decreased to a quiescent base rate (resting rate) according to a ~all-back program (i.e., a rate reduction routine) as a functlon of the drops of the signals from both sensors. However, another function of the activity sensor (transducer) is that a decrease in stimulation rate to this base rate i5 inhibited so long as the processed absolute signal amplitude of the ~ransducer exceeds a predetermined level indicative of body activity.
Thus, the invention provldes rate control using, on the one hand, the low frequency band and the relative chan~e of the transducer signal amplitude in that band: and, an the other hand, the absolute signal amplitude of the low-frequency pro-cessed transducer output to determine an absence of motion calling for rate control according to a baseline characteristic relating heart rate to the complementary second parameter, or to determine a presence of motion calling for the suppression of a rate fall-back program. The mechanoelectrical transducer thereby provides the desirable fast response for rate control ~32~537 at the onset of exercise and change of the workload, provides a shift to a resting baseline control by the complementary second parameter in the absence of an activity-induced ~ignal, and prevents a rate fall-back or too rapid a rate reduction in the presence of an activity-induced signal characteristic oP
exercise by the patient.
It is a feature of the invention that a new baseline or threshold level for activity i5 established according to the specific inertia criteria or characteristics of a complementary second parameter, such as the exemplary parameters mentioned above or the natural sinus node actlvity in a dual chamber pacemaker. That is, after a certain time interval (e.g., a few minutes) in which there has been no confirmation of the trans-ducer signal by the second complementary parameter sensor signal, the then-current activ~ty signal amplitude i8 assumed to be the new baseline, zero or quiescent value of activity.
Accordingly, a prolonged împroper rate increase attr~butable to false triggering oP the activity sensor is avoided even in a noisy environment.
If there is no signal from the mechanoelectrical trans-ducer or if the transducer signal amplitude fail~ to achieve a predetermined minimum absolute amplitude, and, in either event, t~e detected value of the complementary second parameter is increasing, the pacemaker of the present invention will initiate a fall-back program to return the stimulation rate toward a predetermineq base or resting rate. Such circum-~ 3 ~ C~ 7 BRIEF D~SC~IPTION OF THE DRAWINGS
. _ ",._= . _ The above ~nd other objects, aspects, features andadvantages o~ the present in~entiQn will become more apparent from a con~ideration of ~he ensuing detailed description of a pr~ently pr~ferred embodiment thPreof, tak~n in conjunction with the accompanying drawin~s, in which:
FIG. 1 i~ a block diagram of a cardiac pacemaker according to the invention;
FIG. 2a is a schematic diagram of a frequency spectrum of the low-pass (band-pass) æignals of a mechanoel~ctrical ~rans-ducer (activity senqor) used in the pacemaker of FIG~ 1;
FIG, 2b ~hows a Fourier analysis with respect to the frequency and amplitude of the ~ignals from the mechano-electrical transducer for the activity o~ slow walking;
FIG5~ 2c through 2f each show fre~uency and amplltude spectra for di~feren~ typeQ of activity and di~turbance~;
FIGS. 3 to 7 are diagrams of signals developed in the .
pacemaker of FI&. ~ for indicated types of activity;
FIG. 8 is a flow chart of the functioning of the cardiac pacemaker of FIG. 1;
FIGS. 9a and 9b are respectively a front view and a cross-sectional view of one example of a mechanoelectrical transducer which could possibly be used in the pacemaker of FIG. l; and FIGS. 10a to 10d are diagrams of signals developed in the pacemaker of FIG. 1 for indicated types of activity.
;....................................... 15 ~L32~37 stances indicate that the patient is not undergoing physical exertion, and that it is appropriate at this point to reduce the stimulation rate to the base rate. Thls feature may be utilized to discriminate and halt reentry tachycardias in atrial P-wave triggered DDD pacemakers.
It may be seen that, among other features, the pacemaker of the present invention not only protects against prolonged improper rate increases from false triggerings of the mechano-electrical transducer, but also protects against prolonged rate increases attributable solely to the sensed value oP the second complementary parameter. Furthermore, the extent of rate control accorded to that complementary second parameter can differ according to the nature of the signal (or lack thereof) deriving from the mechanoelectrical transducer.
The mechanoelectrical transducer may be of any known type, such as a pieæoelectr~c, piezoresistive or piezocapacitive sensor of the semico~lductor type, which can even be integrated with signal processing circuitry in a silicon chip. Such integrated circuits are manufactured using conventlonal semi-conductor process technology. By fabricating the sensor with appropriate geometrical configuration, the sensor itself can provide the desired frequency bandpass characteristics to capture the proper signal. Por example, the transducer may comprise a vibratory cantilever arm of material and length selected to provide it with the desired resonant frequency.
132~3~
DETAILED DE5CRIPTI_N OF THE PREFERRED _ oDIMENT
Referring now to FIG. l, a cardiac pacemaker 1 includes a case 2 in which the various components are housed, including evaluation circuitry lOa and activity sensor (mechanoelectrical transducer) 3. The circuitry within case 2 is connected via a conventional connector 4 to a pacing lead 5 with a stimulating electrode tip 6. The pacin~ lead(s), for example, is of the endocardial catheter type for insertion intravenously to posi-tion the stimulating electrode(s) relative to excitable myocar-dial tissue in the appropriate chamber(s) of the right side of the patient's heart. The pacemaker may be arranged in conven-tional fashion for unipolar or bipolar stimulation, and may include known sensing electrode(s) and processing circuitry therefor as well.
A ~econd sensor 7, electrically connected to the pacemaker circuitry via a su~table connector 4a, for example, is provided for d~ecting a second complementary physiological parameter, such as the natural atrial rate, the QT interval, the pH value of the blood, the blood oxygen saturatlon, the respiration, the central venous blood temperature, or other recognized parameter of or actiny on the body, whose value is related to heart rate.
In the preferred embodiment, the central venous blood tempera-ture is chosen as the complementary second parameter and will be referred to in that respect throughout the ensuing descrip-tion, but the invention i8 not limited to the use of blood tem-perature. By using blood temperature as the complementary ~ 3 2 0 ~ ~ rl parameter all of the teachings of U.S. patent No. 4,688,573, issued August 25, 1987, are readily and advantageou~ly employed. Sensor 7 in this ~mbodiment, therefore, may b~ a thermi~tor or other suitable temperature sensing element located in the pacing lead 5, in the manner descr.ibed in the '573 patent, or sensing the blood temperature in the atrium or ventricle o~ the right side of the patien~'s heart.
The implanted pacemaker case 2 further houses a battery 8;
a pulse generator 9, whose pulse rate is controllably variable, for generating the stimulating pulses to be delivered to pacing e~ectrode 6 for stimulating the patient's heart; evaluation circuits lOa, lOb for processing and evaluating the signals deriving from activity sensor 3 and temperature sensor 7, respectively; a memory 11 for storing data, such as programmed values in con~unction with a conventional external programmer and other data of the type to be described, includin~ a base-line curve and exercise curves (algorithms~ representing heart rate as a function of blood temperature, as set forth in the '111 application; and a logic circuit 12 for controlling the sampling of signals from the ~ensors and the rate of the pulse generator.
Activity sensor 3 is a small mechanoelectrical transducer, preferably of a type mentioned above, which is either fabricat-ed in a conventional manner to provide an inherent frequency band characteristic selected according to the teachings of the pre~ent invention, or i5 coupled to a filter circuit to pass 1 'I
132~53 l signals in that selected band. The fre~uency spectrum of the band-passed signals from activity sensor 3 is represented in FIG. 2a, with low pass filtering produclng a rapid drop-off at frequencies exceeding 4 Hz, and with high pass filtering to eliminate DC and frequencies below the 0.3 Hz level.
In FIGS. 2b to 2f, the output signals of sensor 3 are ana-lyxed for several di~ferent types of activity. FIG. 2b is a Fourier analysis of the processed signals of the activ~ty sen-sor showing frequency measured in Hz and amplitude measured in dB, detected in a slowly walking test subject. FIG. 2c charts the amplitude relative to time of the low-pas~ signal (i.e., in the band Prom about 0.3 Hz to 4 Hz) processed from the act~vity sensor for successive intervals of rest, walking, running, walking and return to rest by the subject. FIG. 2d illu5-trates, in three separate charts, the unfiltered complete out-put signal of the activity sensor ~upper chart), the high-pass portion (i.e., above ~he selected band) of ths signal (middle chart), and the low-pass portion of the signal (lower chart), detected from a walking subject in which successive intervals of noise are encountered by touching of the pacemaker, coughing and laughing by the subject.
As will be observed from FIG. 2b, the frequency spectrum for movem~nt oP the sub~ect by foot indicates a clear maximum amplitude at a frequency of approximately 2 Hz; and signifi-cantly declining signal amplitudes in the ranye exceeding 4 Hz.
FIG. 2c shows an increase in the amplitude of the low-pass ac-~32~37 tivity signal with increasing exercise as the subject goes fromwalkin~ to running, and an amplitude decrease as the subject returns to walking and ultimately to a state of rest. FIG. 2d clearly demonstrates that the low-pass activity signal is vir-tually unencumbered by the noise generated from lmpact on the pulse generator case, coughing, laughing or the like, the sig-nal indicative of walking being cleanly deteoted. In contrast, the higher frequency range is significantly affected by that noise, so much so that the signal representative of the walking is buried in the noise.
FIGS. 2e and 2f show the signal amplitudes over time for the entire frequency spectrum (upper chart), the high-pass portion (middle chartJ, and ~he low~pass portion (lower chart), when the sub~ect is riding in a car and bicycling on an uneven road, respectively. Here again, it is abundantly clear from the test results that the frequency range below g Hz provides an indication of true activity, virtually uninfluenc~d by any noise peaks~ In FIG. 2e, the higher frequency range ls replete with noise including splke~ at the resonance of the moving car.
In FIG. 2, the noise is also pronounced at the higher frequen-cies, with a more homogeneous noise distribution attributable to t~e uneven road surface traversed by the bicycle. In both cases the true activity signal is masked. It will thus be apparent, contrary to the teachings of the prior art, that processing only the lower frequency band of the activity sen30r output provides a considerably more accurate indication of true ~ 3 ~
exercise while avoiding the many false triggerings of rate increases by the pacemaker which can result from noise detected in the higher frequency band.
FIG. 3 shows ~he behavior of the cardiac pacemaker of the present invention when sub~ected to a false triggering attrib-utable to noise, encoun~ered while the patient i5 riding in a car for example. Part (P) of FIG. 3 and also of similarly for-matted FIGS. 4 to 7 indicates the nature of the exercise work-load. In each of these FIGS. the time scale i~ partly com-pressed and does not correspond to actual time. ~or example, the interval between times tl and t2 is typically only two or three seconds in durat~on, whereas at least some of the subse-quent time intervals ~ay be of several minutes duration each.
In the example of FIG. 3, the "exercise" is fictitious, with the signal detection resulting strictly from noise. Part (a) shows the processed output of activity sensor 3 for the aforesaid low frequency band. Up to time tl the pacemaker patient i~ merely sitting in the stationary car; hence, no signal or only small signal variations (attributable to slight movement of the patient in the idling vehicle, for example) are detected. At tl, the ~ar starts moving and a higher signal level is detected. It is important to observe~ that the signal amplitude is exaggerated for the sake of explaining this exam-ple; as was observed in FIG. 2e, the low frequency band is quite effective to filter disturbances arising from the moving car.
1 3 2 ~ 3 3 ~
Processing of the signal after ~iltering may be accom~
pllshed in different ways. For example, the evaluation circuit lOa may be adapted to operate on the band-passed signal over succes~ive blocks of time o~, say, three seconds each. The difference between the maximum and minimum signal amplitudes i~
calculated for samples taken at predetermined intervals of, say, 300 milliseconds each. The calculated amplitude differ-ence is then added to the calculation for the pxevious sample for all X samples of Block 1 (i.e., the first three ~econd per-iod, in this example), and the value obtained i5 then averaged for Block 1 by dividing that value by the number of samples taken. I~ the di~erence between that avera~e and the average for Block 2 (i.e., the next three second period) exceeds a pre-determined activity baseline related to unit~ o~ gravity, and i~ this is con~irmed over the next few blocks of time, it is indicative of activity or of a significant increase o~ activ-ity (additional activity). This is the post-filtered signal processing technique employed in the preferred embodimen~ of the invention, although various other suitable techniques will be apparent to the skilled artisan. In this manner, random or spasmodic movements which might otherwise be regarded as exercise can be disregarded.
Re~erring again to part (a~ of FIG. 3, the jump in the flltered activity signal occurs at time tl (or an instant later depending on the response time o~ the activity sensor). The processed data is compared with predetermined baseline or 132~337 threshold value~ of activity A1, A2, and 50 forth, each of which may be freely programmable and stored ln the memory 11 (wh.ich, incidentally, was also used to store sampled values for the aforementioned data processing)0 The initial activity thresholds may be selected according to the particular patient and the type of accelerometer (activity sensor) employed for the pacemaker. By way of example, 0.15 g (unit of gravity) was deemed an acceptable level indicative of patient activity for one test subject, using an embodiment of an activity ~ensor for which that level of movement produced a signal level of about 60 millivolts.
If the previously described processing calculation exceeds the first threshold A1, the logic c:ircuit 12 controllably ini-tiates an increase in the rate at which stimulating pulses are generated by the pulse generator 9 by an amount of, say, 15 pulses per minute (ppm, equivalent to bpm~. If the second threshold A2 were exceeded at tl, the pulse rate would be in-creased by a greater amount, say, 25 ppm. This rate increase is accomplished as follows. Logic circuit 12 responds to threshold A1 having been exceeded at tl, by initiating at t2 a preset timing function of a rate controller 21 to which it is connected within housing 2, to increase the pacing rate of the pulse generator g by 15 bpm. This timing function produces a predetermined transition to the higher pacing rate, as repre-sented in part (b) of FIG. 3. If there is no further signifi-cant change in the processed signal calculations as described ~ 32~37 above, this increased stimulation rate will continue in effect.
At the same time that the rate increase ls initiated, the ex-ceeded activity threshold Al is designated as the new activity baseline, and a higher activity threshold A1' (and A2', etc.) is set from which to determine additional activity, as will be further explained presently.
At any time that the absolute amplitude of the activity signal drops to 25% of the activity threshold which was exceed-ed to cause the rate increase, the logic circuit initiates a fall-back program through another timing function of rate con-troller 21 to gradually reduce the stimulation rate of the pulse generator back to a preprogrammed base rate. As shown in FIG. 3(f), the car comes to a stop at t5. The absolute level of the detected activity signal drops to 25% of activity threshold A1 an instant thereafter (FIG. 3(a)), and the pacing rate is decreased commencing at that time (FIG. 3(b)).
However, the present invention also serves to avoid pro-longed rate increases from false triggerings of the pacemaker as a re~ult of high lev21s of noise in the ~iltered output of the activity sensor, even in those instances where the noise is present in the low frequency band and is not rejected by the aforementioned signal processing calculations. To that end, the logic circuit 12 actuates a timer 22 at t2, coincident with the triggering of the rate increase via rate controller 21, to commence timing a predetermined period ~FIG. 3(b)~ whose dura-tion i5 preset according to the response time of the selected ~32D337 second comple~entary parameter to the onset of exercise or to abrupt changes in level of exercise. In the presently prefer-red embodiment, where blood temperature is the complementary parameter, the period of timer 22 may be set, for example, at two to three minutes. In general, sensors of the physiological parameters mentioned earlier herein are less sensitive to the onset of exercise than an activity sensor, but as previously noted herein, each of these other parameters is a suitable com-plementary parameter to acceleration because of their greater specificity ln indicating the varying level of ongoing exer-cise. If one of these other parameters were used in place of blood temperature~ the timer 22 period would be set according-ly. The duration of the timer period is important because if, during that period, the stimulation rate dictated by the second complementary parameter exceeds the rate dictated by the activ-ity signal, the latter relin~uishes and the former assumes con-trol of the stimulation rate. On the other hand, if the second complementary parameter fails to assume such control, this con-stitutes a lack oP confirmation of the activity si~nal and an indication oX no true activity or of insuficient activity to warrant the rate increase. Accordinyly, ln the latter circum-stance the logic circuit 12 actuates the rate~controller 21 to initiate a rate reduction routine (fallback program) at the end oX the period of timer 22.
The blood temperature measured by thermistor 7 over the timer period is represented in FIG. 3(c). The stimulation rate 3 ~
is calculated from the measured blood temperature as described in U.S. patent No. 4,688,573, issued August 25, 1987, and is represented in FIG.3(d). Of courser in this example the "exercise"
is fictitious, and consequently the temporal increase, i~ any, in the blood temperature would be insuffici.ent to produc~ a stimulation rate othe.r than is commensurate with the baseline resting curve. In fact, there is no substantial change in the blood temperature according to FIG. 3(c), and therefore virtually no change in the rate determined from the blood temperature as shown in FIG. 3(d). H~nce, at time t3, when the timer period expires, lo~ic circuit 12 initiates the rate fallback program of rate controller 21 to gradually reduce the stimulation rate of pulse generator 9 to the programmed base rate at t4. This assures that the patient will not be subjected to improper rate increases as a result of false triggerings for more than the relatively short duration of the timer period, rather than experiencing a prolonged rate increase, for example, over a four hour car ride.
If the evaluation of the filtered activi.ty sensor output indicates a reduction in the averaged maxima and minima of the signal by ~5~ or more to a value of 25% or less of the activity threshold which has just been exceeded, it is assumed that exercise has ceased. At that point, the lo~ic circuit will in~tiate the ~allback program of rate controller Zl to return the pulse rate of pulse generator 9 to the base rate. The various threshold values and the criterion of reduction of below last-exceeded activity threshold may be selected (pro-~- 25 132~37 grammed) according to the individual patient.
The arrangement of the diagrams in FIG. 3 is repeated in FIGS. 4 to 7, inclusive. In each FIG.: part (a) r0presents the filtered low-frequency band output signal of activity sensor 3, part (bJ illustrates the stimulation rate ~heart rate) attrib-utable to the signal of part (a); part ~c) ~hows the value or the signal representative thereof for the second complementary parameter -- in the presently preferred embodiment, the blood temperature detected by sensor ~; part (d) represents the stim-ulation rate determined according to the value shown in part (c~; part (el shows the effective stimulation rate derived from both parameters (activity and blood temperature); and part tf) schematically represents the exercise level or workload.
FIG. 4 is a diagram representing the behavior of the pace-maker for a patient who commences walking for a period of time and then returns to a state of rest. Part (f) indicates that the ex~rcise starts at time tl, and i5 thereupon detected by the activity sensor (part (a)). The filtered signal amplitude is processed b~ the evaluation circuit lOa and, after a brief interval, the calculated value is found to exceed activity threshold A1. Accordingly, pulse generator 9 is ad~usted via rate controller 21, under the control of logic circuit 12, to increase the pacing rate by 15 bpm commencing at time t2, as shown in FIG. 4(b~. At time t4, the exercise ceases and this is reco~nized at time t5, when the calculated value of the pro-ces~ed activity signal has dropped to 25% of the activity 132~ 7 threshold Al. ln those circumstances, if the rate control were based strictly on the output of the activity sensor the stlmu-lation rate would be reduced gradually toward the programmed base rate under the rate reduction routine of rate controller 21, as was described in connection with FIG. 3.
Here, however, the blood temperature increases with the exercise, after the characteristic dip at the onset thereof, and continues to increase until it reaches a steady state value FIG. 4(c). At time t3, before the timer 22 period haR expired, the stimulation rate determined according to blood temperatur~
exceeds the rate determined from the activity signal (FI~.
4(d)). Thereupon, the detected blood temperature becomes the rate-determining parameter and the stimulation rate is increas-ed according to the blood temperature (FIG. 4(e)), under the control o~ the logic circuit and the rate controller. This situation continues, with rate de~ermined by blood temperature, until the exercise ends at t4. The blood temperature begins dropping off rapidly (FIG. 4(c)), and, with it, the stimulation rate begins to decline (FIG. 4(d) and (e)). At time t5, the value ealculation from the processed activity signal drops to 25% o~ activity thre~hold Al, instituting the fallback program accordin~ to that parameter as well, and the combined stimula-tion continues its decline to the base rate (FIG. ~(e~).
FIG. 5 illustra~es the behavior of a pacemaker according to the invention when the patient undergoes gradual increases of exercise, in the stepped manner shown in part l~)- Initial-:13~3~
ly, with the patient at rest, the pacing rate i~ maintained atthe base rate. At tl, the patient begins walklng, and, ln response to detection of the rhythmical movement, the activity sensor generates a signal which is filtered in the ~requency band of interest as shown in part (a). The signal is then pro-cessed to calculate the average difference between amplitude maxima and minima for a sequence of samples over the selected time interval, as described earlier. At time t2, the evalua-tion circuit determines that the calculated average exceeds activity threshold A1, and, in response, logic circuit 12 increases the stimulation rate by 15 bpm via rate controller 21, and also actuates timer 22 (FIG. 5(b~). The exceeded threshold Al ls thereupon stored in the memory 11 as the new baseline for activity, and a new higher activity threshold Al' is established (FIG. 5ta)). The latter is also stored in the memory, along with all other data to be utilized or operated on including base stimula~ion rate and the current increased rate.
As a consequence o~ the establishment of the new activity base-line Al and new activity threshold Al', no additional activity will be deemed to have occurred (and thus, no activity signal-induced rate increa~e will be initiated) until threshold A1' is exceeded by the average peak-to-peak value of the processed ac-tivity signal.
At time t5, the patient goes from walking to running (or from walking at a slow pace to walking at a faster pace, as another example). At time t6, it is determined that the calcu-~ 3 ~
lated value o~ the processed activ.ity signal exceeds current activity threshold Al', thereby islitiating another increase in the paciny rate, e.g., by 10 bpm (FIG. 5(b)), the establishment of the now exceeded threshold Al' as the new activity baseline and of a higher level of activity as the new activity threshold Al" (FIG. 5(a)), and the restart of timer 22 (FIG. 5(b)). A
similar set of events occurs each time the then-current activ-ity threshold is exceeded. In this way, the patient is spared the posslbility of prolonged rate increases resulting from false triggerings, but will be sub~ected to the appropriately higher stimulation rates when actual exercise or a change in exercise level is detected. Put another way, the patient will not experience repeated increases in stimulation rate as the signal level hovers about the same activity threshold, but instead a new higher threshold will be applied upon each rate increase.
At time t9, the patient stops running and agaln assumes a resting state ~FIG. 5(f)). The cessa~ion of activity is sensed and, at tim~ tlO, the ca?culated value of the processed activ-ity signal has dropped to 2~ of the last exceeded threshold Al' (FIG. 5ta)) which led to the previous double rate increase (initially 15 bpm and then another 10 bpm). In response, the fallback program is initiated for gradual reduction of the stimulation rate toward the base rate (FI5. 5t~))-The foregoing discusslon of FIG. 5 assumes rate control bythe activity signal only. However, as shown in FIG. 6(c), the ~3~3~
blood temperature responds to the onset of exercîse at time tl by dropping slightly and then rising until, at t3, it is at a value determinative of a pacing rate exceeding that o~ the ac-tivity signa~-induced ra~e (FIG. 5(d)). Since t3 is within the timer period, the stimulation rate control ls thenceforth dic-tated by the sensed blood temperature, commencing from the pre-viously initiated rate increase of 15 bpm above the base rate ~FIG. 5 (e)). The blood temperature rises to a steady state value during the first stage of exercise, wh7ch is reflected in the combined stimulation rate until time t6, when the a~oremen-tioned second activity signal-induced rate increase of 10 bpm occurs. That new stimulation rate is maintained until t8, when the blood temperature-induced rate surpasses thls activity sig-nal-induced increased rate within the restarted timer period (FIG. 5(d). The sensed blood temperature again assumes control of the pacin~ rate as the temperature continue5 to rise to a new steady state value during the second stage of exercise.
After the patient stops running at time t9, and this is recognlzed ~rom the processed activity slgnal at tlO, the com-bined stimulation rate begins a gradual drop under the control o~ the fallback program (FIG. 5(e)), as prevlously described.
At that time, the blood temperature has begun to drop from its relatively high level, and at tll the temperature commences to drop at a ~aster pace with a concomitant stimulation rate, but still somewhat slower than the rate according to the fallback program. The sensed blood temperature then again assumes con-~32~337 trol of the rate reduction toward the base rate. In this manner, it i9 assured that the pacing rate reduction meets the physiological requirements of the patient to the usual after-effects of heavy exercise, including the body's demand for replenishment of depleted oxygen, which are better accommodated by rate control under the more gradual decrease of the blood temperature. If the patient had stopped exercising before the detected value of the blood temperature had assumed or re-assumed control of pacing rate from the activity signal, the stimulation rate would have returned to the base rate strictly according to the fallback program instituted in response to the drop in calclated value of the processed activity signal. How-ever, that would be compatible with the physiological needs of the patient because, in those circumstances, the exercise ses~
sion would not have extended beyond the relatively short period set by the timer 22.
FIG. 6 provides another example of exercise with increas-i~g workloads, and also with decreasing workloads, as shown in part (f). From the descriptions of FIGS. 3, 4 and 5, it will be apparent that an activity signal-induced rate increa~e takes place at time t2 (FIG. 6(e)) in response to commencement of patient exercise at time tl which exceeds the initial activity threshold. The blood temperature-dictated stimulation rate takes control at time t3 and continues to t5, when the output of the activity sensor is recognized as indicative of addition-al exercise (because the new activity threshold was exceeded at ~32~ ~37 t4), and the rate is lncreased. At t6, the rate determined from the blood temperature again assumes control.
At time t7, the level of exercise abruptly decreases, and is detected by the activity sensor, but exercise does not cease entirely and the calculated value of the processed activity signal remains higher than 25% of the last-exceeded activity threshold. Accordingly, the fallback program would not reduce the stimulation rat0 to the base rate, but only by an amount proportional to the decrease of the actlvity signal. That i5, the reduction in heart rate (- ~ HR) is a functlon of the de-crease in activity (- ~ activity), based on the activlty level observed after the decrease. If, for example, the cumulative activity-induced rate increase up to time t6 was 25 bpm, and the activity at t8 is 40~ of that at t6, the rate at t8 would be reduced by 15 bpm (i.e., ~0~ of 25 bpm) and would still remain 10 bpm above the base rate (FIG. ~(bJJ~ In term~ of the stimulation rate resulting from both the activ~ty signal and the blood temperature value, the rate reduction begins at t8 under the fallback program until the point at which the blood ~empera~ure-induced rate takes over, ~ollowed by the impact of the next fallback program at tlO, when the calculated value of the activity signal has dropped to 25% of the last-exceeded activity threshold (FIG. 6(e)).
FIG. 7 reflects a situation in which the activity sensor detects exercise at tl and a cessatlon of exercise at t4, cor-responding to that of FIG. 4. Here, however, the sensed value ~3~3~
of the blood temperature (or other slower reacting second com-plementary parameter) remains at a relativel~ high value (FIG.
7(c)), for example, because the patient has become feverish or because of defective measurement. At time t5, the timer 22 is started, commenciny the running of the preset period, and the fallback program is initiated (FIG. ~b)), as previously des-cribed. The stimulation rate is gradually reduced toward the base rate (FI~o 7(e)), but does not fully return to the base rate because of the contribution of the blood temperature-induced rate. However, for purposes cf a rat~ decrea~e, both the absolute amplitude of the activity slgnal and the relative changes in amplitude thereof are determined and assessed with respect to the value of the second complementary parameter.
From this, it i5 seen that at time t~ the absolute amplitude of the activity signal ie less than a preselected minimum level, and there~ore fails to confirm rate indicated by th~ blood temperature level. Accordingly, when the timer period expires, the fallback program resumes to reduce the rate to the prede-termined base rate. As previously noted, the timer period i~
set according to the selection o~ the second complem~ntary parameter and the sensltlvity of that parameter to exerclse.
Thus, the use of two parameters in this manner permits control of stimu~ation rate without improper tachycardia despite a slow response, false triggering or an erroneous reading.
FIG. 8 is a f low chart of the operation of a pacemaker according to the invention. If no activity is detected, the ~L32~37 stimulation rate is held at the base rate, which may be influenced by the complementary parameter. If activity is detected, the maximum and minimum amplitudes of the filtered activity signal are evaluated, and if the current activlty threshold is exceeded the stimulation rate is increased accor-dingly and i5 held at the increased rate. The timer i5 started at the instant of the increase, and the detected value of the complementary parameter i~ monitored to determine whether it will influence this rate. At the same time, the exceeded threshold becomes the new activity baseline and a higher activity threshold is established that must be exceeded for additional activity to be detected.
If the calculation oP average maximum and minimum ampli-tudes of the activity signal from several samples taken over successive predetermined time intervals exceeds the new higher activity threshold, the stimulation rate is again increased and held, and the timer is restarted to establish the period within which the influence of the complementary parameter is assessed once again. This process continues with each determination that additional activity has occurred. The increase in stimu-lation rate is ef~ected in steps which decrease in size with the higher instantaneous rates.
If the logic determines that there i5 no additional activ~
ity, the activity sensor output continues to be evaluated to assess whether there is ongoing exercise, and if there is none, the fallback program is commenced to reduce the rate toward the ~32~3~
base rate, which ayain may be influenced by the second comple-mentary parameter. If there is ongoing exercise without decreasing level, the rate is held until additional activity or a decrease ln the exercise level is detected. If a decrease, the stimulation rate is decreased accordingly. If the calcula-tion of the processed activity signal amplitude drops to 25% of the previously exceeded activity threshold, the stimulation rate is reduced to the base rate, but if the drop i5 less than ~5~ the reduction in rate is a function of the delta (i.e., the amount of the drop).
The cycle repeats itself with each detection of patient exercise (including any false triggerings as described earlier herein). After each new occurrence (e.g., onset of exercise, increase in exercise, decrease in exercise~ cessation of exer-cise) the timer i5 restarted to establish a new period during which to assess the influence of the complementary parameter on rate control.
FIGS. 9a and 9b illustrate an exemplary embodiment of a mechanoelectrical transducer whlch might be used in the pace-maker o~ the inventio~, but is to be emphasized that any trans-ducer haviny the characteristics described earlier herein may be employed satisfactorily as an activity sensor. Transducer 31 has an integrated signal filter circuit 32, to provide the proper frequency pass band. The unit 31 comprises a silicon monocrystalline substrate 33 with a 1-0 0 orientation of the crystal planes. A p~ epitaxial Gonductive layer is formed on 3 ~
the surface o~ the substrate, i.ollowed by a polycrystalline silicon layer 34 sandwiched between passivating layers 35 of silicon dioxide. By anisotropic etching, a cavity 36 is formed in the substrate 33, and portions of layers 34, 36 are removed to form a rectangular pla-t~ 3~ connected by four arms 38 to the corner~ of cavity 36. The rectangular plate 37 with arms 38 ~orm~ the element responsive to acceleration. A further layer 39 is deposited on the structure, with an opening extending conti~uous with the perimeter of cavity 36, to permlt axial movement of the rectangular plate on the arms. Finally, a protective lay~r 40, e.~., a glass plate, is placed over the structure. The integrated circuit 3~ for processing the signal generated by movemen~ of the rectangular pla~e 37 via arms 38 may be fabricated in the silicon layers by conventional semi-conductor integrated clrcuit process technology.
FIGS. lOa to lOd illustrate test results using a cardiac pacemaker according to the invention, in which central venous blood temperature of the pa~ient wa~ selected as the second complementary param~ter. The test~ were performed on a healthy person connected to (but not pacecl by) an external pacemaker otherwise conforming to the princlples o~ the present inven-tion. The natural (intrin~ic) heart rate HRint of the subject while undergo~g exercise was recorded on a str~p chart and compared to the si~ilarly recorded stimulation rate HRStim g~nerated by the pacemaker pulse generator as controlled by the control system of th~ presen~ invention. The "paced heart rate"
,~
` ~ 32~37 was detected at the lead connections of the pulse generator.
Th~ upper three dlagram~ of each FIG. w~re recorded as a function of time in minutes. The lowermost diagram o~ each FIG. (i.e., below ~e upper thr~e diagrams) is indicat1ve of the exercise regimen performe~ by the subject, ~or which the other dia~rams of the respective FIG. were obtained. The uppermost of the three diagrams of each ~IG. indicates the ~easured output o~ the mechanoelectrical transducer stated in digitized representations from a computer in units g related ~o gravity (curve ~) and the measured values from a blood tempera-ture probe in C (curve T). ~he middle diagram of each FIG.
shows the heart rate H~g calcula~e~ from and according to the curve g, and HRT calcula~ed from and according to the curve T, both heart rates bein~ in units of bpm, as calculated indepen-dently of ~ach other by the circuitry of the control system.
The lower o~ tho~e three diagrams of each FIG. shows a curve of the intrinsic heart rate o~ the subiect (curve HRint)~ and the stimulation rate ~curve HRStim) as calculated by the control system o~ the present inven~io~ by combining the heart rates HRg and ~RT according to th~ principles described above.
In FIG. lOa, the sub~ect underwent a treadmill test in which h~ was Qubjected to different speeds and different inclines (grades) by the treadmill. It will be ~bserved that the 6timulation rate curve closely matches the natural heart rate curve virtually throug~out the test regimen.
,; 3~
~32~3~
In FIG. lOb, the test subject underwent increasiny and decreasing ~xercise on an exercise bicycle. It is interesting to note the increase in curve g in the interval from 16 to 20 minutes despite the decrease in the level of exercise, which is also apparent from the blood temper-ature curve T. This clearly shows that the test subject was tiring, and moved more on the bicycle notwithstanding that the metabolic expenditure was decreasing. Nevertheless, the curve of stimulation rate constitutlng a combination of the rates dictated by the activity signals and the sensed blood temperature values in the manner earlier mentiolled herein, again closely corresponds to the curve of the sub~ect's natural heart rate over time.
In FIG. lOc, the test subject walked continuously at a speed of 4.2 kilometers per hour on a treadmill with an upward grade of 6~, for a period of extended duration. At about 25 minutes, the heart rate derived from the detected central venous blood temperature values fell somewhat below the rate derived from the activity values, but the combination of these rates resulted ih a stimulation rate curve which again closely approximated the ~ubject's natural heart rate curve with time.
Finally, FIG. lOd shows the test results in which the subject underwent a treadmill test at increasing speeds and grades (constantly increasing workload), with a sudden cessa-tion o~ exercise at the greatest speed and grade. As in FIG.
lOb, the HRT curve was noticeably di~ferent from the HRg curve.
In this test, the activity threshold values were exceeded 3~
~32~337 twice. The determination of rate accordi~g to the activity signal is clearly observed at the onset, and the combined stimulation rate curve again closely duplicated the sub~ect's natural heart rate curve over the test period.
While a preferred embodiment of the invention has been described, it will be apparent to those skilled in the art from consideration of the disclosure herein that various modifica-tions may be implemented without departing from the inventive principles. Again, by way of example of modifications falling within the scope of the invention, the second parameter may be respiration, minute ventilation, stroke volume, blood oxygen saturation, blood pH balance, Q-T interval, or any of other known or contemplated parameter, or the time rate of change of any such parameter. Accordingly, it is intended that the invention be limited only by the appended claims.
FIG. 5 illustra~es the behavior of a pacemaker according to the invention when the patient undergoes gradual increases of exercise, in the stepped manner shown in part l~)- Initial-:13~3~
ly, with the patient at rest, the pacing rate i~ maintained atthe base rate. At tl, the patient begins walklng, and, ln response to detection of the rhythmical movement, the activity sensor generates a signal which is filtered in the ~requency band of interest as shown in part (a). The signal is then pro-cessed to calculate the average difference between amplitude maxima and minima for a sequence of samples over the selected time interval, as described earlier. At time t2, the evalua-tion circuit determines that the calculated average exceeds activity threshold A1, and, in response, logic circuit 12 increases the stimulation rate by 15 bpm via rate controller 21, and also actuates timer 22 (FIG. 5(b~). The exceeded threshold Al ls thereupon stored in the memory 11 as the new baseline for activity, and a new higher activity threshold Al' is established (FIG. 5ta)). The latter is also stored in the memory, along with all other data to be utilized or operated on including base stimula~ion rate and the current increased rate.
As a consequence o~ the establishment of the new activity base-line Al and new activity threshold Al', no additional activity will be deemed to have occurred (and thus, no activity signal-induced rate increa~e will be initiated) until threshold A1' is exceeded by the average peak-to-peak value of the processed ac-tivity signal.
At time t5, the patient goes from walking to running (or from walking at a slow pace to walking at a faster pace, as another example). At time t6, it is determined that the calcu-~ 3 ~
lated value o~ the processed activ.ity signal exceeds current activity threshold Al', thereby islitiating another increase in the paciny rate, e.g., by 10 bpm (FIG. 5(b)), the establishment of the now exceeded threshold Al' as the new activity baseline and of a higher level of activity as the new activity threshold Al" (FIG. 5(a)), and the restart of timer 22 (FIG. 5(b)). A
similar set of events occurs each time the then-current activ-ity threshold is exceeded. In this way, the patient is spared the posslbility of prolonged rate increases resulting from false triggerings, but will be sub~ected to the appropriately higher stimulation rates when actual exercise or a change in exercise level is detected. Put another way, the patient will not experience repeated increases in stimulation rate as the signal level hovers about the same activity threshold, but instead a new higher threshold will be applied upon each rate increase.
At time t9, the patient stops running and agaln assumes a resting state ~FIG. 5(f)). The cessa~ion of activity is sensed and, at tim~ tlO, the ca?culated value of the processed activ-ity signal has dropped to 2~ of the last exceeded threshold Al' (FIG. 5ta)) which led to the previous double rate increase (initially 15 bpm and then another 10 bpm). In response, the fallback program is initiated for gradual reduction of the stimulation rate toward the base rate (FI5. 5t~))-The foregoing discusslon of FIG. 5 assumes rate control bythe activity signal only. However, as shown in FIG. 6(c), the ~3~3~
blood temperature responds to the onset of exercîse at time tl by dropping slightly and then rising until, at t3, it is at a value determinative of a pacing rate exceeding that o~ the ac-tivity signa~-induced ra~e (FIG. 5(d)). Since t3 is within the timer period, the stimulation rate control ls thenceforth dic-tated by the sensed blood temperature, commencing from the pre-viously initiated rate increase of 15 bpm above the base rate ~FIG. 5 (e)). The blood temperature rises to a steady state value during the first stage of exercise, wh7ch is reflected in the combined stimulation rate until time t6, when the a~oremen-tioned second activity signal-induced rate increase of 10 bpm occurs. That new stimulation rate is maintained until t8, when the blood temperature-induced rate surpasses thls activity sig-nal-induced increased rate within the restarted timer period (FIG. 5(d). The sensed blood temperature again assumes control of the pacin~ rate as the temperature continue5 to rise to a new steady state value during the second stage of exercise.
After the patient stops running at time t9, and this is recognlzed ~rom the processed activity slgnal at tlO, the com-bined stimulation rate begins a gradual drop under the control o~ the fallback program (FIG. 5(e)), as prevlously described.
At that time, the blood temperature has begun to drop from its relatively high level, and at tll the temperature commences to drop at a ~aster pace with a concomitant stimulation rate, but still somewhat slower than the rate according to the fallback program. The sensed blood temperature then again assumes con-~32~337 trol of the rate reduction toward the base rate. In this manner, it i9 assured that the pacing rate reduction meets the physiological requirements of the patient to the usual after-effects of heavy exercise, including the body's demand for replenishment of depleted oxygen, which are better accommodated by rate control under the more gradual decrease of the blood temperature. If the patient had stopped exercising before the detected value of the blood temperature had assumed or re-assumed control of pacing rate from the activity signal, the stimulation rate would have returned to the base rate strictly according to the fallback program instituted in response to the drop in calclated value of the processed activity signal. How-ever, that would be compatible with the physiological needs of the patient because, in those circumstances, the exercise ses~
sion would not have extended beyond the relatively short period set by the timer 22.
FIG. 6 provides another example of exercise with increas-i~g workloads, and also with decreasing workloads, as shown in part (f). From the descriptions of FIGS. 3, 4 and 5, it will be apparent that an activity signal-induced rate increa~e takes place at time t2 (FIG. 6(e)) in response to commencement of patient exercise at time tl which exceeds the initial activity threshold. The blood temperature-dictated stimulation rate takes control at time t3 and continues to t5, when the output of the activity sensor is recognized as indicative of addition-al exercise (because the new activity threshold was exceeded at ~32~ ~37 t4), and the rate is lncreased. At t6, the rate determined from the blood temperature again assumes control.
At time t7, the level of exercise abruptly decreases, and is detected by the activity sensor, but exercise does not cease entirely and the calculated value of the processed activity signal remains higher than 25% of the last-exceeded activity threshold. Accordingly, the fallback program would not reduce the stimulation rat0 to the base rate, but only by an amount proportional to the decrease of the actlvity signal. That i5, the reduction in heart rate (- ~ HR) is a functlon of the de-crease in activity (- ~ activity), based on the activlty level observed after the decrease. If, for example, the cumulative activity-induced rate increase up to time t6 was 25 bpm, and the activity at t8 is 40~ of that at t6, the rate at t8 would be reduced by 15 bpm (i.e., ~0~ of 25 bpm) and would still remain 10 bpm above the base rate (FIG. ~(bJJ~ In term~ of the stimulation rate resulting from both the activ~ty signal and the blood temperature value, the rate reduction begins at t8 under the fallback program until the point at which the blood ~empera~ure-induced rate takes over, ~ollowed by the impact of the next fallback program at tlO, when the calculated value of the activity signal has dropped to 25% of the last-exceeded activity threshold (FIG. 6(e)).
FIG. 7 reflects a situation in which the activity sensor detects exercise at tl and a cessatlon of exercise at t4, cor-responding to that of FIG. 4. Here, however, the sensed value ~3~3~
of the blood temperature (or other slower reacting second com-plementary parameter) remains at a relativel~ high value (FIG.
7(c)), for example, because the patient has become feverish or because of defective measurement. At time t5, the timer 22 is started, commenciny the running of the preset period, and the fallback program is initiated (FIG. ~b)), as previously des-cribed. The stimulation rate is gradually reduced toward the base rate (FI~o 7(e)), but does not fully return to the base rate because of the contribution of the blood temperature-induced rate. However, for purposes cf a rat~ decrea~e, both the absolute amplitude of the activity slgnal and the relative changes in amplitude thereof are determined and assessed with respect to the value of the second complementary parameter.
From this, it i5 seen that at time t~ the absolute amplitude of the activity signal ie less than a preselected minimum level, and there~ore fails to confirm rate indicated by th~ blood temperature level. Accordingly, when the timer period expires, the fallback program resumes to reduce the rate to the prede-termined base rate. As previously noted, the timer period i~
set according to the selection o~ the second complem~ntary parameter and the sensltlvity of that parameter to exerclse.
Thus, the use of two parameters in this manner permits control of stimu~ation rate without improper tachycardia despite a slow response, false triggering or an erroneous reading.
FIG. 8 is a f low chart of the operation of a pacemaker according to the invention. If no activity is detected, the ~L32~37 stimulation rate is held at the base rate, which may be influenced by the complementary parameter. If activity is detected, the maximum and minimum amplitudes of the filtered activity signal are evaluated, and if the current activlty threshold is exceeded the stimulation rate is increased accor-dingly and i5 held at the increased rate. The timer i5 started at the instant of the increase, and the detected value of the complementary parameter i~ monitored to determine whether it will influence this rate. At the same time, the exceeded threshold becomes the new activity baseline and a higher activity threshold is established that must be exceeded for additional activity to be detected.
If the calculation oP average maximum and minimum ampli-tudes of the activity signal from several samples taken over successive predetermined time intervals exceeds the new higher activity threshold, the stimulation rate is again increased and held, and the timer is restarted to establish the period within which the influence of the complementary parameter is assessed once again. This process continues with each determination that additional activity has occurred. The increase in stimu-lation rate is ef~ected in steps which decrease in size with the higher instantaneous rates.
If the logic determines that there i5 no additional activ~
ity, the activity sensor output continues to be evaluated to assess whether there is ongoing exercise, and if there is none, the fallback program is commenced to reduce the rate toward the ~32~3~
base rate, which ayain may be influenced by the second comple-mentary parameter. If there is ongoing exercise without decreasing level, the rate is held until additional activity or a decrease ln the exercise level is detected. If a decrease, the stimulation rate is decreased accordingly. If the calcula-tion of the processed activity signal amplitude drops to 25% of the previously exceeded activity threshold, the stimulation rate is reduced to the base rate, but if the drop i5 less than ~5~ the reduction in rate is a function of the delta (i.e., the amount of the drop).
The cycle repeats itself with each detection of patient exercise (including any false triggerings as described earlier herein). After each new occurrence (e.g., onset of exercise, increase in exercise, decrease in exercise~ cessation of exer-cise) the timer i5 restarted to establish a new period during which to assess the influence of the complementary parameter on rate control.
FIGS. 9a and 9b illustrate an exemplary embodiment of a mechanoelectrical transducer whlch might be used in the pace-maker o~ the inventio~, but is to be emphasized that any trans-ducer haviny the characteristics described earlier herein may be employed satisfactorily as an activity sensor. Transducer 31 has an integrated signal filter circuit 32, to provide the proper frequency pass band. The unit 31 comprises a silicon monocrystalline substrate 33 with a 1-0 0 orientation of the crystal planes. A p~ epitaxial Gonductive layer is formed on 3 ~
the surface o~ the substrate, i.ollowed by a polycrystalline silicon layer 34 sandwiched between passivating layers 35 of silicon dioxide. By anisotropic etching, a cavity 36 is formed in the substrate 33, and portions of layers 34, 36 are removed to form a rectangular pla-t~ 3~ connected by four arms 38 to the corner~ of cavity 36. The rectangular plate 37 with arms 38 ~orm~ the element responsive to acceleration. A further layer 39 is deposited on the structure, with an opening extending conti~uous with the perimeter of cavity 36, to permlt axial movement of the rectangular plate on the arms. Finally, a protective lay~r 40, e.~., a glass plate, is placed over the structure. The integrated circuit 3~ for processing the signal generated by movemen~ of the rectangular pla~e 37 via arms 38 may be fabricated in the silicon layers by conventional semi-conductor integrated clrcuit process technology.
FIGS. lOa to lOd illustrate test results using a cardiac pacemaker according to the invention, in which central venous blood temperature of the pa~ient wa~ selected as the second complementary param~ter. The test~ were performed on a healthy person connected to (but not pacecl by) an external pacemaker otherwise conforming to the princlples o~ the present inven-tion. The natural (intrin~ic) heart rate HRint of the subject while undergo~g exercise was recorded on a str~p chart and compared to the si~ilarly recorded stimulation rate HRStim g~nerated by the pacemaker pulse generator as controlled by the control system of th~ presen~ invention. The "paced heart rate"
,~
` ~ 32~37 was detected at the lead connections of the pulse generator.
Th~ upper three dlagram~ of each FIG. w~re recorded as a function of time in minutes. The lowermost diagram o~ each FIG. (i.e., below ~e upper thr~e diagrams) is indicat1ve of the exercise regimen performe~ by the subject, ~or which the other dia~rams of the respective FIG. were obtained. The uppermost of the three diagrams of each ~IG. indicates the ~easured output o~ the mechanoelectrical transducer stated in digitized representations from a computer in units g related ~o gravity (curve ~) and the measured values from a blood tempera-ture probe in C (curve T). ~he middle diagram of each FIG.
shows the heart rate H~g calcula~e~ from and according to the curve g, and HRT calcula~ed from and according to the curve T, both heart rates bein~ in units of bpm, as calculated indepen-dently of ~ach other by the circuitry of the control system.
The lower o~ tho~e three diagrams of each FIG. shows a curve of the intrinsic heart rate o~ the subiect (curve HRint)~ and the stimulation rate ~curve HRStim) as calculated by the control system o~ the present inven~io~ by combining the heart rates HRg and ~RT according to th~ principles described above.
In FIG. lOa, the sub~ect underwent a treadmill test in which h~ was Qubjected to different speeds and different inclines (grades) by the treadmill. It will be ~bserved that the 6timulation rate curve closely matches the natural heart rate curve virtually throug~out the test regimen.
,; 3~
~32~3~
In FIG. lOb, the test subject underwent increasiny and decreasing ~xercise on an exercise bicycle. It is interesting to note the increase in curve g in the interval from 16 to 20 minutes despite the decrease in the level of exercise, which is also apparent from the blood temper-ature curve T. This clearly shows that the test subject was tiring, and moved more on the bicycle notwithstanding that the metabolic expenditure was decreasing. Nevertheless, the curve of stimulation rate constitutlng a combination of the rates dictated by the activity signals and the sensed blood temperature values in the manner earlier mentiolled herein, again closely corresponds to the curve of the sub~ect's natural heart rate over time.
In FIG. lOc, the test subject walked continuously at a speed of 4.2 kilometers per hour on a treadmill with an upward grade of 6~, for a period of extended duration. At about 25 minutes, the heart rate derived from the detected central venous blood temperature values fell somewhat below the rate derived from the activity values, but the combination of these rates resulted ih a stimulation rate curve which again closely approximated the ~ubject's natural heart rate curve with time.
Finally, FIG. lOd shows the test results in which the subject underwent a treadmill test at increasing speeds and grades (constantly increasing workload), with a sudden cessa-tion o~ exercise at the greatest speed and grade. As in FIG.
lOb, the HRT curve was noticeably di~ferent from the HRg curve.
In this test, the activity threshold values were exceeded 3~
~32~337 twice. The determination of rate accordi~g to the activity signal is clearly observed at the onset, and the combined stimulation rate curve again closely duplicated the sub~ect's natural heart rate curve over the test period.
While a preferred embodiment of the invention has been described, it will be apparent to those skilled in the art from consideration of the disclosure herein that various modifica-tions may be implemented without departing from the inventive principles. Again, by way of example of modifications falling within the scope of the invention, the second parameter may be respiration, minute ventilation, stroke volume, blood oxygen saturation, blood pH balance, Q-T interval, or any of other known or contemplated parameter, or the time rate of change of any such parameter. Accordingly, it is intended that the invention be limited only by the appended claims.
Claims (20)
1. A rate responsive cardiac pacemaker for implantation in a patient, comprising an activity sensor means having a response characteristic limited to the frequency range below 4 Hz for detecting movement of the patient arising from physical exercise and generating an electrical signal representative thereof while discriminating against movement arising from ran-dom influences, means for generating pulses at a controllably variable rate to stimulate the patient's heart at any of a plurality of selectable rates, and means responsive to said signal for adjusting the rate of the pulse generating means relative to a base rate according to whether the patient is undergoing exercise or is at rest.
2. The rate responsive cardiac pacemaker according to Claim 1, wherein said activity sensor means includes means for selectively establishing at least one activity threshold value indicative of exercise, and wherein said rate adjusting means includes means for setting the rate of said pulse generating means based upon the amplitude of selected portions of said signal relative to said at least one activity threshold value.
3. The rate responsive cardiac pacemaker according to Claim 2, wherein said rate setting means increases the rate by a predetermined amount when said at least one activity threshold values is exceeded.
4. The rate responsive cardiac pacemaker according to Claim 3, wherein said threshold establishing means establishes a new higher threshold each time the previous threshold is exceeded, to avoid further rate increases from false trigger-ings attributable to detected movement which is unrelated to exercise.
5. The rate responsive cardiac pacemaker according to Claim 4, wherein said rate setting means gradually reduces the rate toward said base rate when said signal amplitudes fall to a predetermined percentage of the threshold value which had been exceeded to produce the immediately preceding rate increase.
6. The rate responsive cardiac pacemaker according to Claim 5, wherein said rate setting means decreases said predetermined amount of the rate increase as each new higher threshold value is successively exceeded.
7. The rate responsive cardiac pacemaker according to Claim 6, wherein said rate setting means imposes a selectable upper rate limit, beyond which no further increase in rate is permitted.
8. The rate responsive cardiac pacemaker according to Claim 1, wherein said activity sensor means includes a mechano-electrical transducer responsive to mechanical forces.
9. The rate responsive cardiac pacemaker according to Claim 8, wherein said mechano-electrical transducer has a geometrical configuration which limits said response charac-teristic to the frequency range below 4 Hz.
10. The rate responsive cardiac pacemaker according to Claim 1, wherein said activity sensor means differentiates between the rhythmical movement characteristic of physical exercise and the random spasmodic movement characteristic of forces acting upon the sensor means which are unrelated to exercise.
11. A rate responsive cardiac pacemaker for implantation in a patient, comprising activity sensor means for detecting movement of the patient arising from exercise to generate a signal level representative thereof while discriminating against movement arising from random influences, further sensor means for detecting the value of a physiological parameter com-plementary to movement and indicative of the overall metabolic state of the patient to generate a signal level representative thereof, and means responsive to both sensor means for generat-ing pulses to stimulate the patient's heart at a physiologi-cally appropriate rate determined from the respective signal levels generated by each of said sensor means.
12. The rate responsive cardiac pacemaker according to Claim 11, wherein said pulse generating means includes means for establishing a predetermined period of time, first means for controlling the rate of said pulse generating means in response to relative changes of the signal level of said activity sensor means during said predetermined period of time, and second means for controlling the rate of said pulse generating means in response to the signal level generated by said further complementary parameter sensor means depending on the rate determined thereby compared to the rate determined by said activity sensor means during said time period.
13. The rate responsive cardiac pacemaker according to Claim 12, wherein said first controlling means retains control of the rate of said pulse generating means if the rate deter mined by said activity sensor means exceeds the rate determined by said further complementary parameter sensor means throughout said time period, and said second controlling means assumes control of the rate of said pulse generating means if the rate determined by said further complementary parameter sensor means exceeds the rate determined by said activity sensor means at any point during said time period.
14. The rate responsive cardiac pacemaker according to Claim 13, wherein said first controlling means includes means for selectively establishing an activity threshold value for detection of exercise, means for comparing a selected portion of the signal level generated by said activity sensor means to said threshold value, and means for increasing the rate of said pulse generating means when said selected portion of the activity sensor means signal level exceeds said threshold value.
15. The rate responsive cardiac pacemaker according to Claim 14, wherein said first controlling means further includes means for gradually reducing the rate of said pulse generating means when said activity sensor means signal level falls to a predetermined level below said threshold value.
16. The rate responsive cardiac pacemaker according to Claim 14, wherein said threshold establishing means establishes the exceeded threshold value as a new baseline value for activity detection.
17. The rate responsive cardiac pacemaker according to Claim 14, wherein said threshold establishing means is responsive to the threshold value having been exceeded, for establishing a new higher threshold value indicative, when exceeded, of additional exercise.
18. The rate responsive cardiac pacemaker according to Claim 17, wherein said first controlling means further includes means responsive to the establishment of a new higher threshold value for constituting the exceeded threshold value as a new baseline value linking a predetermined base rate and the higher threshold value.
19. The rate responsive cardiac pacemaker according to Claim 11, wherein said activity sensor means has a frequency response characteristic limited to the range between about 0.3 Hz and about 4 Hz.
20. A rate responsive cardiac pacemaker for implantation in a patient, comprising first sensor means for detecting rhythmic physical exercise by the patient and generating an electrical signal representative thereof while discriminating against random disturbances, second sensor means for detecting the value of a physiological parameter of the body further indicative of exercise, means for generating pulses at a controllably variable rate to stimulate the patient's heart at any of a plurality of selectable rates at which the pulses are applied to the heart, and means responsive to both said signal and the detected value of said physiological parameter for adjusting the rate of the pulse generating means according to one or the other of them at any given point in time based on the relative values of the separate rates dictated by each within a predetermined period of time and further based on the amplitude of said signal relative to a selectable threshold value indicative of exercise.
Applications Claiming Priority (2)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| DEP3631155.3 | 1986-09-12 | ||
| DE19863631155 DE3631155A1 (en) | 1986-09-12 | 1986-09-12 | FREQUENCY VARIABLE HEART PACEMAKER WITH STRESS-ADEQUATE FREQUENCY BEHAVIOR |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CA1320537C true CA1320537C (en) | 1993-07-20 |
Family
ID=6309488
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA000546713A Expired - Fee Related CA1320537C (en) | 1986-09-12 | 1987-09-11 | Rate responsive cardiac pacemaker |
Country Status (6)
| Country | Link |
|---|---|
| US (7) | US4926863A (en) |
| EP (3) | EP0259658B1 (en) |
| JP (1) | JP2767419B2 (en) |
| BR (1) | BR8704731A (en) |
| CA (1) | CA1320537C (en) |
| DE (2) | DE3631155A1 (en) |
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-
1986
- 1986-09-12 DE DE19863631155 patent/DE3631155A1/en active Granted
-
1987
- 1987-08-17 EP EP87111912A patent/EP0259658B1/en not_active Expired - Lifetime
- 1987-08-17 DE DE3751045T patent/DE3751045T2/en not_active Expired - Fee Related
- 1987-08-17 EP EP94112056A patent/EP0798015A2/en not_active Withdrawn
- 1987-08-17 EP EP94112055A patent/EP0798014A2/en not_active Withdrawn
- 1987-09-10 US US07/094,875 patent/US4926863A/en not_active Expired - Lifetime
- 1987-09-11 BR BR8704731A patent/BR8704731A/en unknown
- 1987-09-11 CA CA000546713A patent/CA1320537C/en not_active Expired - Fee Related
- 1987-09-12 JP JP62227583A patent/JP2767419B2/en not_active Expired - Lifetime
-
1989
- 1989-06-22 US US07/369,813 patent/US5044366A/en not_active Expired - Lifetime
-
1990
- 1990-04-26 US US07/514,410 patent/US5014700A/en not_active Expired - Lifetime
- 1990-04-27 US US07/515,460 patent/US5014704A/en not_active Expired - Lifetime
- 1990-04-30 US US07/516,812 patent/US5014703A/en not_active Expired - Lifetime
- 1990-05-01 US US07/517,298 patent/US5014702A/en not_active Expired - Lifetime
- 1990-05-02 US US07/518,514 patent/US5031615A/en not_active Expired - Lifetime
Also Published As
| Publication number | Publication date |
|---|---|
| EP0798014A2 (en) | 1997-10-01 |
| EP0259658A3 (en) | 1990-05-16 |
| EP0259658A2 (en) | 1988-03-16 |
| DE3751045D1 (en) | 1995-03-23 |
| DE3631155A1 (en) | 1988-03-24 |
| US4926863A (en) | 1990-05-22 |
| US5044366A (en) | 1991-09-03 |
| DE3631155C2 (en) | 1988-08-18 |
| US5014702A (en) | 1991-05-14 |
| US5031615A (en) | 1991-07-16 |
| EP0798015A2 (en) | 1997-10-01 |
| US5014700A (en) | 1991-05-14 |
| US5014704A (en) | 1991-05-14 |
| JP2767419B2 (en) | 1998-06-18 |
| DE3751045T2 (en) | 1995-09-28 |
| JPS63177872A (en) | 1988-07-22 |
| US5014703A (en) | 1991-05-14 |
| EP0259658B1 (en) | 1995-02-08 |
| BR8704731A (en) | 1988-05-03 |
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