Q-onset ventricular depolarization detection in the presence of a pacemaker

Abstract

A method utilizing computer processing for detecting, within a cardiac cycle, the earliest onset of global, Q-onset, ventricular depolarization in the presence of an operating pacemaker. The method, in general terms, features (a) gathering a plurality of ECG-obtained QRS heart-cycles waveforms, (b) identifying and categorizing of evidences and specific timings therein of intrinsic Q-onset and pacemaker spike events, (c) looking in a single, selected QRS waveform, between specific, defined first and second time marks, for the most significant slope change appearing in that waveform, and (d) designating to be the correct Q-onset that event which immediately precedes that slope change.

Description

BACKGROUND AND SUMMARY OF THE INVENTION

In electrocardiography, the so-called QRS-onset, or Q-onset, in each cardiac-beat, or cardiac cycle, marks the start of electrical depolarization of the heart ventricles. In the context of correlated electroacoustic cardiography, this well-recognized QRS-onset (or Q-onset, a term which is used herein interchangeably with QRS-onset) fiducial is important as a reference for computing the respective durations of a number of important heart-functionality time intervals, such as the electromechanical activation time interval (EMAT) between Q-onset and the closure of the mitral valve. In fact, and as those skilled in the art well know, one of the most important measurements which is relied upon in terms of assessing a person's heart functionality is this EMAT time interval, also referred to as the QS1 time interval—the time interval between Q-onset and the occurrence of the first heart sound (S1). Accordingly, accurate determination of the time of Q-onset in each cardiac cycle is extremely critical to heart-behavior assessment.

In circumstances where a pacemaker is in place in a subject, Q-onset presence and timing confusion can occur. For example, if a particular cardiac cycle is in fact initiated by a ventricular pacemaker impulse, referred to as a pacer spike, rather than by an intrinsic (anatomical) Q-onset event, then the onset of depolarization is best represented by the occurrence time of such a pacer spike. Knowing what is the truth about the time-initiation of depolarization onset is, of course, mandatory for achieving measurement accuracy based upon this initiation event, and so it is very important to distinguish these two different kinds of depolarization-initiation events so as to identify clearly what event to select as the one representing true Q-onset. Put another way, and as those skilled in the art well recognize, where a pacemaker is present, one cannot simply rely on pacemaker-activity output to describe, with confident accuracy, the reality of Q-onset, because of the fact that the relevant pacemaker (a) may be out of synchronization, (b) may possibly be an atrial rather than a ventricular pacemaker, and (c) if it is a bi-ventricular pacemaker, there must be some way of identifying which heart chamber is specifically associated with pacemaker activity.

In this setting, accordingly, the present invention is concerned particularly with identifying, with as much accuracy as possible, the time, during each heartbeat, of true Q-onset. In a more particular sense, the present invention is concerned with clearly identifying this Q-onset event in a circumstance where a subject is equipped with a pacemaker whose pacing pulses may (but not necessarily so) be the true indicators of Q-onset.

In relation to the preferred and best-mode manner of practicing the present invention, which includes algorithmically programmed computer processing, there are several categories of ECG and pacemaker information which are especially relevant. These categories define the key pieces of input information which, for a selected, predetermined time span (such as about 10-seconds), which includes a number—a collection—of successive cardiac cycles, are gathered/obtained and supplied to what is referred to herein as a Q-Onset Selection block which, essentially, takes the form of at least a portion of an appropriately algorithmically programmed digital computer that forms one of the central operational systemic “components” of the invention. It is by the operation of this block that an accurate assessment of Q-onset is made.

Such input information supplied to this block preferably includes conventional, multi-lead (such as 12-lead, though a lesser number of leads may be employed if desired) ECG information which also carries accompanying information defining, for each cardiac cycle in the collection of the mentioned number of gathered, successive cardiac cycles, the time locations of conventionally detected (intrinsic) Q-onset events and of pacemaker spike events. Another piece of input information is derived directly from a selected, single ECG lead, such as the so-called V-4 ECG lead. Also supplied to the Q-Onset Selection block is information specifically relevant to pacemaker, or pacer, operation, derived synchronously from the just-mentioned, conventionally acquired ECG information. This pacemaker-operation information specifically includes pacer spike information in terms of the time occurrences of pacer spikes, as well as their types, i.e., as being either atrial, ventricular, first bi-ventricular, or second bi-ventricular, and more broadly speaking as being either ventricular or bi-ventricular.

Still a further piece of information which is relevant, and which may be supplied by the same equipment and methodology which supplies the mentioned, conventionally acquired ECG information, is a characterization of the types of heartbeats, or cardiac cycles, which have been detected during the above-mentioned, predetermined time span. In this regard, there are recognized, for the purpose of the description of the present invention, to be two, different, so-called cardiac cycle types, one of which is referred to as being an intrinsically, or internally (i.e., by the anatomy), initiated cardiac cycle, and the other of which is referred to as being a pacer-spike-initiated cardiac cycle.

With such input information, the Q-onset selection activity of the invention functions to produce, among other things as reportable output information, the relevant, confirmation, Q-onset timing and identity output information. This output information fundamentally, and variously, defines, for each cardiac cycle involved in an investigation, (a) the times within these cycles of “best-determined” Q-onset, (b) the identifying class (per cycle) of the associated, selected, Q-onset event as being either an intrinsic event or a pacer event, and (c) the associated cycle class-identity (intrinsic or pacer).

In general terms, such Q-onset selection, per cardiac cycle, uniquely involves (1) during a predetermined time span which includes a plurality of successive, QRS cardiac cycles, gathering both ECG and pacemaker-spike information for, and within, each such cycle, (2) with respect to each such gathered cardiac cycle, time-locating, identifying and time-position sorting, first to last, each intrinsic Q-onset and each pacemaker-spike event, including specifically identifying each pacemaker-spike event as being one of ventricular or bi-ventricular, (3) also with regard to each such cardiac cycle, evaluating, with respect a single, selected, QRS waveform, the waveform slope therein from (a) a time just preceding, to (b) a time just following, the mentioned, time-position sorted, first-in-time and last-in-time one of such time-located, identified and sorted events, respectively, (4) from the mentioned slope evaluating practice, finding the time, in the mentioned, single, selected QRS-waveform, of the first substantial QRS-waveform slope change, (5) in each cardiac cycle, selecting to be the correct Q-onset therein the time-sorted event in that cycle whose time position most immediately precedes the time of the mentioned, found, first-substantial slope change, and (6) with respect to each cardiac cycle, maintaining the identity of the selected to-be-correct Q-onset event.

Such Q-onset determination is followed, among other things, by appropriate presenting and/or reporting of the determination outcome so as to enable thereafter, and as an illustration of special utility, accurate calculation of the kinds of important heart-functionality time intervals, like the EMAT interval mentioned earlier herein.

These and other features, advantages and reportable Q-onset outcomes which are offered by the present invention will become more fully apparent as the detailed description of the invention which follows below is read in conjunction with the accompanying drawings. This detailed invention description is specifically presented in block/schematic structural and methodologic drawings, and in text terminology, both very familiar to those generally skilled in the relevant art. Accordingly, unnecessary details that define medical terminology are not included herein. Also not specifically included are lines/details of computer-programming code which may conventionally be employed by ones skilled in the programming art to implement the two algorithms which are set forth herein in very understandable, high-level, algorithmic terminology and architecture.

DESCRIPTION OF THE DRAWINGS

FIG. 1 is a high-level, block/schematic diagram generally illustrating the preferred and best-mode embodiment of, and the manner of practicing, the methodology of the present invention.

FIG. 2 is a more elaborated, block/schematic diagram illustrating in somewhat greater detail that which is pictured more generally in FIG. 1. FIG. 2 specifically shows practice of the invention employing a pacemaker (pacer) spike detector and a pacemaker (pacer) spike classifier for providing pacemaker spike information relevant to Q-onset detection and identification.

FIG. 3 is a fragmentary, block/schematic diagram describing one modified form of the invention. This figure shows practice of the invention wherein pacemaker information is supplied by a conventional pacemaker (pacer) programmer device.

DETAILED DESCRIPTION OF THE INVENTION

Turning now to the drawings, and referring first of all to FIG. 1, here, illustrated generally at 10, and including four, “high-level” blocks 12 (Input ECG Information), 14 (Input Pacer Spike Information), 16 (Q-Onset Selection), 18 (Output) is a broad, overview illustration of the preferred and best-mode embodiment of, and manner of practicing, the present invention. A lateral bracket 20 in this figure represents the presence and utilization of a suitably programmed digital computer which performs all required data processing in the practice of the invention. More will be said about this computer, and its operation, shortly.

Block 12 represents the action of conventional ECG-lead collection, and thereafter the inputting from block 12 to block 16, via a data-flow connection 12a, of the several kinds of relevant ECG information mentioned above herein, as well as certain, relevant pacemaker (pacer) spike information which is naturally acquired over the employed ECG leads. Block 14 represents the gathering from block 12, over a data-flow connection 12b, and the inputting, via a data-flow connection 14a also to block 16, of similar, relevant pacemaker spike information, as generally mentioned earlier herein, derived from block 12. To the extent that data processing is, or may be, required in the handling of the flow of information within, and from, blocks 12, 14, computer 20 takes care of these tasks.

Information provided over connections 12a, 14a by blocks 12, 14, respectively, to block 16, wherein Q-Onset Selection takes place in accordance with practice of the present invention, is appropriately computer processed by computer 20 within the environment of block 16 utilizing a unique algorithm identified herein (and described architecturally in instructive detail below) as Algorithm I. Such information processing within block 16 results, as will shortly be explained, and through a block 16 to block 18 data-flow connection 16a, in the supply, to and via Output block 18, of accurately determined Q-onset timing information, as well as Q-onset type classification/identification, and certain other pieces of important information for, and in relation to, each of the earlier mentioned, selected-time-span number of successive cardiac cycles. In this regard, it should be understood that the illustrative selection of ten-seconds for a useful, predetermined time span is not a required, or “magic”, time-span number. Any appropriate, predetermined time span may be chosen, though ten-seconds for such a span has proven to be entirely satisfactory.

From the computer-processed information presented as output information by Output block 18, accurate Q-onset, and certain other, valuable information is made available for all subsequent purposes, such as for calculating the time durations of various important heart-functionality parameters, like the previously mentioned EMAT parameter.

Turning attention now to FIG. 2, as can be seen, several of the blocks which appear in this figure are the same as several, like blocks which appear in just-described FIG. 1. More specifically, previously mentioned blocks 12, 16, 18 appear in FIG. 2, along with two additional blocks 22, 24. Also appearing similarly in FIG. 2 is lateral bracket 20 representing the previously mentioned, algorithmically programmed digital computer which furnishes all data processing required in accordance with practice of the invention.

Block 22 takes the form of a conventional pacer spike detector. Block 24 takes the form of a unique, computer-20-implemented pacer spike classifier which is constructed, and which performs, in accordance with a unique algorithm, described below as Algorithm II, created and operational in accordance with features of the present invention. Blocks 22, 24 collectively function as previously mentioned block 14 which appears in FIG. 1.

As will be mentioned further, computer 20 implements Algorithms I and II, and the operations and behaviors of blocks 16, 24, respectively, will shortly be described in the contexts of these two algorithms.

Completing a description of what is shown specifically in FIG. 2, several additional data-flow connections are shown variously interconnecting the several blocks pictured in this figure. In particular, a data-flow connection 26 carrying multiple-lead ECG information connects block 12 to the pacer spike detector. A data-flow connection 28, carrying the same ECG information, connects block 12 with the pacer spike classifier. Connections 26, 28 collectively make up previously described data-flow connection 12b. A data-flow connection 30 supplies information from the pacer spike detector to the pacer spike classifier.

From block 12, a data-flow connection 32 provides Q-Onset Selection block 16 with multi-lead ECG information, and a data-flow connection 34 supplies, from block 12 to Q-Onset Selection block 16, single-ECG-lead V4 ECG information. The information supplied over connection 32 includes, for each of the previously mentioned, successive cardiac cycles, the perceived times of intrinsic Q-onset and pacer spike events present during those cycles. Connections 32, 34 collectively make up previously mentioned data-flow connection 12a.

Extending from the pacer spike classifier 24 is a data-flow connection 36 which is the same as previously described data-flow connection 14a, and which supplies, from the classifier to Q-Onset Selection block 16, pacer spike times and classifications detected and processed by blocks 22, 24 during the predetermined time span of cardiac-cycle gathering. As was mentioned earlier, the manner of operation of classifier 24 in accordance with Algorithm II will be explained shortly.

Within the control of block 16, in cooperation with blocks 12, 22 and 24, under the operation of digital computer 20, and under circumstances wherein information, as generally described above, is supplied to block 16 via connections 32, 34, 36, which information has been gathered and processed by blocks 12, 22, 24 over the period of time embracing the above-mentioned gathering of successive cardiac cycles, Q-onset determination/selection is performed in accordance with the following Algorithm I.

Algorithm I

• • 1. With respect to each gathered cardiac cycle, time-locate, identify and time-position sort, first to last, each intrinsic Q-onset, and each pacemaker-spike, event, including specifically identifying each pacemaker-spike event as being one of ventricular or bi-ventricular;
  • 2. Also with regard to each such cardiac cycle, evaluate, with respect a single, selected, QRS waveform, the waveform slope therein from (a) a time just preceding, to (b) a time just following, the mentioned, time-position sorted, first-in-time and last-in-time one of such time-located, identified and sorted events, respectively;
  • 3. Based on such slope evaluating, find the time, in the mentioned, single, selected QRS-waveform, of the first substantial QRS-waveform slope change;
  • 4. In each cardiac cycle, select to be the correct Q-onset therein the time-sorted event in that cycle whose time position most immediately precedes the time of the mentioned, found, first-substantial slope change, and
  • 5. With respect to each cardiac cycle, maintain the identity of the selected-to-be-correct Q-onset event.

In the preferred implementation of Algorithm I by computer-20 processing, slope evaluating is performed by the computer effectively using a line having a length of about 14-milliseconds in duration as a projection on the QRS-waveform time axis of the subject, single, selected QRS-waveform wherein slope is being evaluated, (a) with both ends of this line lying on that waveform, (b) by moving the line from a first time which is just before the above-mentioned, first-in-time, time-sorted event, to a second time, which is just after the above-mentioned, last-in-time, time-sorted event, and (c) by noting the magnitude of the slope in existence at points distributed on the subject waveform between these just-stated first and second times. In this slope-evaluating practice, the single, selected waveform employed for this purpose is that which comes from the V4 ECG lead via connection 34.

In the invention practice illustrated in FIG. 2, pacer spike information delivered to block 16 over connection 36 from the pacer spike classifier is developed in the classifier in accordance with the implementation by computer 20 of what has been referred to above as being Algorithm II.

The steps of this algorithm, expressed in terms well understood by those skilled in the relevant art, and performed in relation to the totality of the successive cardiac cycles gathered during the predetermined time span, are as follows.

Algorithm II

• • 1. Compute the “forward difference” time intervals between each pacer spike in the preceding, two pacer spikes;
  • 2. Compute the “backward difference” time intervals between each pacer spike and the subsequent, two pacer spikes;
  • 3. Associate each pacer spike with the cycle having the most proximal QRS-onset time;
  • 4. Compute the “Q. difference” as the time interval between each pacer-spike time and the QRS-onset time of the associated cycle;
  • 5. For each pacer spike time, compute three similarity scores against each of the other pacer times as
  • (a) the absolute difference between the forward differences,
  • (b) the absolute difference between the backward differences, and
  • (c) the absolute difference between the Q. difference;
  • 6. Combine the three similarity scores as appropriate, taking into account the validity of each;
  • 7. Group with each pacer spike all other pacer spikes having a similarity score below a predetermined threshold;
  • 8. Allow only one pacer spike per cycle to be in each pacer-spike group, discarding duplicates;
  • 9. Allow only three pacers spikes to be associated with each cycle;
  • 10. For each cycle, assign each pacer spike to the appropriate type (atrial, ventricular, bi ventricular) based on its timing relative to QRS-onset and the presence of other pacers spikes in that cycle;
  • 11. Ensure that all pacer spikes in a group have the same type by looking across all cycles;
  • 12. Check for consistency of timing relative to QRS-onset of pacer spikes of the same type;
  • 13. Require biventricular pacer spikes to come in pairs, discarding the ones that are not paired; and
  • 14. Report the times, types, and cycle associations of the valid pacer spikes.

Following implementation of both algorithms in the full practice of the invention, output information is reported/presented, etc., by block 18. This output information preferably includes, for each cardiac cycle involved in a plural-cycle investigation seeking Q-onset as described above, (a) the times within the plural cycles of “best-determined” Q-onset, (b) the identifying class (per cycle) of the associated, selected, Q-onset event as being either an intrinsic event or a pacer event, and (c) the associated cycle class-identity (intrinsic or pacer). The output information made available by practice of the invention is highly accurate in terms of the key task of reliably identifying “real” Q-onset notwithstanding the possible confusing presence of a pacemaker, and therefore sets the stage for reliable and accurate determinations of various, Q-onset-dependent, heart-functionality time-duration parameters, such as the earlier-mentioned, important EMAT parameter.

Focusing attention now on the fragmentary illustration presented in FIG. 3, here the structure and methodology 10 of the present invention are illustrated in a modified form. Pacer spike “detection” and classification information is supplied to block 16 via connection 36 from a conventional pacer programmer which is represented by a block 38 in this figure. Except for the fact that here this pacer spike detection and classification information is supplied differently from the manner in which it is supplied in accordance with the illustration seen in FIG. 2, in all other respects, the operation of the methodology of the invention is identical, in terms of computer-20 implementation of Algorithms I, II to the gathered and processed ECG and pacer spike data.

Accordingly, a unique and highly accurate methodology for determining Q-onset in the presence of an operating pacemaker has been illustrated and described herein, in preferred and best-mode, and in modified, forms. And, while this is so, we recognize that a number of variations and modifications may be perceived and implemented by those generally skilled in the relevant art without departing from the scope and spirit of the invention.

Claims

1. A method utilizing computer processing for detecting, within a cardiac cycle, the earliest onset of global, Q-onset, ventricular depolarization in the presence of an operating pacemaker, said method comprising during a predetermined time span including a plurality of successive, QRS cardiac cycles, gathering both ECG and pacemaker-spike information for, and within, each such cycle,with respect to each such gathered cardiac cycle, time-locating, identifying and time-position sorting, first to last, each intrinsic Q-onset and each pacemaker-spike event, including specifically identifying each pacemaker-spike event as being one of ventricular or bi-ventricular,also with regard to each such cardiac cycle, evaluating, with respect a single, selected, QRS waveform, the waveform slope therein from (a) a time just preceding, to (b) a time just following, the mentioned, time-position sorted, first-in-time and last-in-time one of such time-located, identified and sorted events, respectively,from said slope evaluating, finding the time, in the mentioned, single, selected QRS-waveform, of the first substantial QRS-waveform slope change,n each cardiac cycle, selecting to be the correct Q-onset therein the time-sorted event in that cycle whose time position most immediately precedes the time of the mentioned, found, first-substantial slope change, andwith respect to each cardiac cycle, maintaining the identity of the selected to-be-correct Q-onset event.

2. The method of claim 1 which further comprises, for each cardiac cycle, further identifying the class of the associated, selected-to-be-correct, Q-onset event as being either an intrinsic event or a pacer event, and giving to the associated cycle, as a cycle class-identity—either intrinsic or paced—the same, related class-identity as that of the associated, selected-to-be-correct, Q-onset event—intrinsic or paced.

3. The method of claim 2 which further comprises, across all cycles gathered during the predetermined time span having the same class-identity, determining the dominant identity—intrinsic, ventricular or bi-ventricular—of the selected Q-onset event, and forcing all cycles in a given class of cycles also to have the same, dominant, Q-onset event identity—intrinsic, ventricular, or bi-ventricular.

4. The method of claim 3 which further comprises providing as output information (a) an association of each pacer spike as being one of atrial, ventricular, first bi-ventricular, or second bi-ventricular, (b) a determination for each cycle as to whether it was initiated intrinsically or with a ventricular pacer spike, and (c) for each cycle, the time of the earliest depolarization as selected between the available intrinsic QRS-onset time, and the time of any available ventricular pacing spike.

5. The method of claim 2 which further comprises providing, as output information relevant to the gathered plurality of successive, QRS cardiac cycles, the times and class identities of all of the selected-to-be-correct Q-onset events.

6. The method of claim 1 which further comprises, (a) providing a pacemaker-spike detector and a computer-based, pacemaker-spike classifier, (b) gathering pacemaker-spike occurrence and time information utilizing the pacemaker-spike detector, (c) supplying such pacemaker-spike occurrence and time information for computer processing via the provided pacemaker-spike classifier, and (d) utilizing the pacemaker-spike classifier to furnish detected pacer-spike classification.

7. The method of claim 6 wherein utilization of the provided pacemaker-spike classifier involves computer-performing of each of the processing steps as set forth hereinabove in the detailed description of Algorithm II.

8. The method of claim 1 which further comprises utilizing a pacemaker programmer to supply the gathered pacemaker-spike information.

9. The method of claim 1, wherein said slope evaluating is performed by computer processing effectively using a line having a length of about 14-milliseconds in duration as a projection on the QRS-waveform time axis of the subject QRS-waveform wherein slope is being evaluated, with both ends of the line lying on that waveform, by moving the line from a first time, which is just before the first-in-time identified intrinsic or spike event, to a second time, which is just after the last-in-time identified intrinsic or spike event, and by noting the magnitude of the slope in existence at points distributed on the subject QRS waveform between the just-mentioned first and second times.