Source: http://www.docstoc.com/docs/49003926/Cardioversion-Synchronization-System-And-Method-For-An-Atrial-Defibrillator---Patent-5584864
Timestamp: 2014-09-18 14:21:28
Document Index: 171984524

Matched Legal Cases: ['art 10', 'art 10', 'art 10', 'art 10', 'art 10', 'art 10', 'art 10', 'art 10', 'art 10', 'art 10', 'art 10', 'art 10', 'art 10', 'art 10']

Cardioversion Synchronization System And Method For An Atrial Defibrillator - Patent 5584864
United States Patent: 5584864
5,584,864
Cardioversion synchronization system and method for an atrial
An implantable atrial defibrillator applies cardioverting electrical energy
to the atria of a human heart. The atrial defibrillator includes a first
detector for sensing depolarization activation waves at a first area of
the heart and producing a first signal, a second detector for sensing
depolarization activation waves at a second area of the heart and
producing a second signal, an analyzing circuit for determining if the
first signal satisfies a first criterion and if the second signal
satisfies a second criterion. The atrial defibrillator includes a third
detector for sensing activity of the heart in at least one of the atria of
the heart and an atrial fibrillation detector for determining when the
atria of the heart are in need of cardioversion. The atrial defibrillator
further includes a cardioverting circuit for applying the cardioverting
electrical energy to the atria of the heart when the atria of the heart
are in need of cardioversion and when the first signal satisfies the first
criterion and when the second signal satisfies the second criterion.
White; Harley (Redmond, WA)
08/259,476
607/4,5 128/703,901,704,706,708,705
1.  An implantable atrial defibrillator for applying cardioverting electrical energy to the atria of a human heart, said atrial defibrillator comprising:
an atrial fibrillation detector responsive to sensed atrial activity for determining when the atria are in need of cardioversion;  and
cardioverting means for applying said cardioverting electrical energy to the atria of the heart when the atria of the heart are in need of cardioversion, when said first electrogram signal satisfies said first criterion, and when said second
electrogram signal satisfies said second criterion, said first and second criterion being different.
2.  An implantable atrial defibrillator as defined in claim 1 wherein said analyzing means comprises first threshold detection means for producing a first threshold indication when said first signal exceeds a first electrogram predetermined
3.  An implantable atrial defibrillator as defined in claim 2 wherein said analyzing means comprises second threshold detection means for producing a second threshold indication when said second electrogram signal exceeds a second predetermined
threshold, and wherein said cardioverting means applies said cardioverting electrical energy to the atria of the heart when the atria are in need of cardioversion, when said first electrogram signal satisfies said first criterion, when said second
electrogram signal satisfies said second criterion, and when said second threshold indication has a predetermined time relation with said first threshold indication.
4.  An implantable atrial defibrillator as defined in claim 2 wherein said analyzing means comprises first peak detecting means for detecting a first peak value of said first electrogram signal and producing a first peak indication and wherein
said cardioverting means applies said cardioverting electrical energy to the atria of the heart when the atria are in need of cardioversion, when said first electrogram signal satisfies said first criterion, when said second electrogram signal satisfies
said second criterion, and when said first peak indication has a predetermined time relation with said first threshold indication.
5.  An implantable atrial defibrillator as defined in claim 1 wherein said analyzing means comprises first peak detecting means for detecting a peak value of said first electrogram signal and producing a first peak indication and second peak
detecting means for detecting a peak value of said second electrogram signal and producing a second peak indication, and wherein said cardioverting means applies said cardioverting electrical energy to the atria of the heart when the atria are in need of
cardioversion, when said first electrogram signal satisfies said first criterion, when said second electrogram signal satisfies said second criterion, and when said first peak indication has a predetermined time relation with said second peak indication.
6.  An implantable atrial defibrillator as defined in claim 1 wherein said analyzing means further comprises first peak width detecting means for determining a peak width of said first electrogram signal and wherein said first criterion includes
said peak width of said first electrogram signal being less than a first predetermined maximum peak width.
7.  An implantable atrial defibrillator as defined in claim 6 wherein said analyzing means further comprises second peak width detecting means for determining a peak width of said second electrogram signal and wherein said second criterion
includes said peak width of said second electrogram signal being less than a second predetermined maximum peak width.
8.  An implantable atrial defibrillator for applying cardioverting electrical energy to the atria of a human heart, said atrial defibrillator comprising:
analyzing means for determining if the amplitude of the initial portion of the depolarization activation wave exceeds a minimum amplitude;  and
wherein said analyzing means further includes means for determining if the amplitude of the initial portion of the depolarization activation wave is less than a maximum amplitude and wherein said cardioverting means applies said cardioverting
electrical energy to the atria of the heart when the atria are in need of cardioversion and if the amplitude of said initial portion of said depolarization activation wave is less than the maximum amplitude and greater than the minimum amplitude.
9.  An implantable atrial defibrillator as defined in claim 8 wherein said depolarization activation wave has a final portion having an amplitude, wherein said analyzing means includes means for determining if the amplitude of the final portion
of said depolarization activation wave exceeds the minimum amplitude, and wherein said cardioverting means applies said cardioverting electrical energy to the atria of the heart when the atria are in need of cardioversion, if the amplitude of said
initial portion and the amplitude of said final portion exceed the minimum amplitude, and if the amplitude of the initial portion is less than the maximum amplitude.
10.  An implantable atrial defibrillator as defined in claim 9 wherein said analyzing means further includes means for determining if the amplitude of the final portion of the depolarization activation wave is less than the maximum amplitude and
wherein said cardioverting means applies said cardioverting electrical energy to the atria of the heart when the atria are in need of cardioversion and if the amplitude of said initial portion and the amplitude of said final portion are less than the
maximum amplitude and exceed the minimum amplitude.
11.  An implantable atrial defibrillator for applying cardioverting electrical energy to the atria of a human heart, said atrial defibrillator comprising:
analyzing means for determining if the time duration of the initial portion of the depolarization activation wave is less than a maximum time duration;  and
cardioverting means for applying cardioverting electrical energy to the atria of the heart when the atria are in need of cardioversion and if the time duration of said initial portion of the depolarization activation wave is less than the maximum
12.  An implantable atrial defibrillator as defined in claim 11 wherein said depolarization activation wave has a final portion having a time duration between an initial value and a final value, wherein said analyzing means further includes means
for determining in the duration of the final portion of the depolarization activation wave is less than a second maximum time and wherein said cardioverting means applies said cardioverting electrical energy to the atria of the heart when the atria are
in need of cardioversion, when the duration of said final portion is less than said second maximum time and when the duration of the initial portion is less than the maximum time.
13.  An implantable atrial defibrillator for applying cardioverting electrical energy to the atria of a human heart, said atrial defibrillator comprising:
means for maintaining a count of the number of electrogram signal amplitude variations greater than the preselected amplitude excursion;  and
14.  An implantable atrial defibrillator for applying cardioverting electrical energy to the atria of a human heart, said atrial defibrillator comprising:
analyzing means for determining if the amplitude of the electrogram signal exceeds a maximum amplitude;  and
15.  A method of applying cardioverting electrical energy to the atria of a human heart in need of cardioversion, the method including the steps of:
applying said cardioverting electrical energy to the atria of the heart when the atria of the heart are in need of cardioversion and when said first signal satisfies said first criterion and when said second signal satisfies said second
criterion, the first criterion being different than the second criterion.
16.  A method of applying cardioverting electrical energy to the atria of a human heart in need of cardioversion as defined in claim 15 wherein the method further comprises the step of producing a first threshold indication when said first signal
exceeds a first predetermined threshold.
17.  A method of applying cardioverting electrical energy to the atria of a human heart in need of cardioversion as defined in claim 16 wherein the method further comprises the steps of producing a second threshold indication when said signal
exceeds a second predetermined threshold, and wherein said cardioverting electrical energy is applied to the atria of the heart when said second threshold indication has a predetermined time relation with said first threshold indication.
18.  A method of applying cardioverting electrical energy to the atria of a human heart in need of cardioversion as defined in claim 16 wherein the method further comprises the steps of detecting a peak value of said first signal and producing a
first peak indication, and wherein said cardioverting electrical energy is applied to the atria of the heart when said first peak indication has a predetermined time relation with said first threshold indication.
19.  An method of applying cardioverting electrical energy to the atria of a human heart in need of cardioversion as defined in claim 15 wherein the method further comprises the step of detecting a first peak width of said first signal and
wherein said cardioverting electrical energy is applied to the atria of the heart when said first peak width is greater than a first predetermined minimum peak width and less than a first predetermined maximum peak width.
20.  A method of applying cardioverting electrical energy to the atria of a human heart in need of cardioversion as defined in claim 19 wherein the method further comprises the step of detecting a second peak width of said second signal and
wherein said cardioverting electrical energy is applied to the atria of the heart when said second peak width is greater than a second predetermined minimum peak width and less than a second predetermined maximum peak width.
21.  A method of applying cardioverting electrical energy to the atria of a human heart in need of cardioversion as defined in claim 15 wherein the method further comprises the steps of detecting a first peak value of said first signal and
producing a first peak indication and detecting a second peak value of said second signal and producing a second peak indication, and wherein said cardioverting electrical energy is applied to the atria of the heart when said first peak indication has a
predetermined time relation with said second peak indication.
22.  A method of applying cardioverting electrical energy to the atria of a human heart in need of cardioversion as defined in claim 15 wherein the method further comprises the step of detecting a first initial portion of said first signal and
wherein said cardioverting electrical energy is applied to the atria of the heart when the amplitude of said first initial portion exceeds a first predetermined minimum amplitude.
23.  A method of applying cardioverting electrical energy to the atria of a human heart in need of cardioversion as defined in claim 22 wherein said cardioverting electrical energy is applied to the atria of the heart when said amplitude of said
first initial portion is less than a first predetermined maximum amplitude.
24.  A method of applying cardioverting electrical energy to the atria of a human heart in need of cardioversion as defined in claim 15 wherein the method further comprises the steps of detecting a first initial portion of said first signal and a
first final portion of said first signal and wherein said cardioverting electrical energy is applied to the atria of the heart when the amplitude of said first initial portion and the amplitude of said first final portion exceeds a first predetermined
minimum amplitude.
25.  A method of applying cardioverting electrical energy to the atria of a human heart in need of cardioversion as defined in claim 24 wherein said cardioverting electrical energy is applied to the atria of the heart when said amplitude of said
first initial portion and said amplitude of said first final portion are less than a first predetermined maximum amplitude.
26.  A method of applying cardioverting electrical energy to the atria of a human heart in need of cardioversion as defined in claim 15 wherein the method further comprises the step of detecting a second initial portion of said second signal and
wherein said cardioverting electrical energy is applied to the atria of the heart when the amplitude of said second initial portion exceeds a second predetermined minimum amplitude.
27.  A method of applying cardioverting electrical energy to the atria of a human heart in need of cardioversion as defined in claim 26 wherein said cardioverting electrical energy is applied to the atria of the heart when the amplitude of said
second initial portion is less than a second predetermined maximum amplitude.
28.  A method of applying cardioverting electrical energy to the atria of a human heart in need of cardioversion as defined in claim 15 wherein the method further comprises the steps of detecting a second initial portion of said second signal and
a second final portion of said second signal and wherein said cardioverting electrical energy is applied to the atria of the heart when the amplitude of said second initial portion and the amplitude of said second final portion exceeds a second
predetermined minimum amplitude.
29.  A method of applying cardioverting electrical energy to the atria of a human heart in need of cardioversion as defined in claim 28 wherein said cardioverting electrical energy is applied to the atria of the heart when the amplitude of said
second initial portion and the amplitude of said second final portion are less than a second predetermined maximum amplitude.
30.  A method of applying cardioverting electrical energy to the atria of a human heart in need of cardioversion as defined in claim 15 wherein the method further comprises the step of detecting a first initial portion of said first signal and
wherein said cardioverting electrical energy is applied to the atria of the heart when said first initial portion varies from a first initial value to a first final value in a time less than a first predetermined maximum time and greater than a first
predetermined minimum time.
31.  A method of applying cardioverting electrical energy to the atria of a human heart in need of cardioversion as defined in claim 30 wherein the method further comprises the step of detecting a second initial portion of said second signal and
wherein said cardioverting electrical energy is applied to the atria of the heart when said second initial portion varies from a second initial value to a second final value in a time less than a second predetermined maximum time and greater than a
second predetermined minimum time.
32.  A method of applying cardioverting electrical energy to the atria of a human heart in need of cardioversion as defined in claim 15 wherein the method further comprises the steps of detecting an initial portion of said first signal and a
final portion of said first signal, and wherein said cardioverting electrical energy is applied to the atria of the heart when said first initial portion varies from a first initial value to a first final value in a time less than a first predetermined
maximum time and greater than a first predetermined minimum time and said first final portion varies from a second initial value to a second final value in a time less than a second predetermined maximum time and greater than a second predetermined
33.  A method of applying cardioverting electrical energy to the atria of a human heart in need of cardioversion as defined in claim 32 wherein the method further comprises the steps of detecting a second initial portion of said second signal and
a second final portion of said second signal, and wherein said cardioverting electrical energy is applied to the atria of the heart when said second initial portion varies from a second initial value to a second final value in a time less than a third
predetermined maximum time and greater than a third predetermined minimum time and said second final portion varies from a second initial value to a second final value in a time less than a fourth predetermined maximum time and greater than a fourth
34.  A method of applying cardioverting electrical energy to the atria of a human heart in need of cardioversion as defined in claim 15 wherein the method further comprises the steps of detecting a first plurality of signal portions of said first
signal and a second plurality of signal portions of said second signal and wherein said cardioverting electrical energy is applied to the atria of the heart when the number of portions of said first plurality of portions having an amplitude less than a
first predetermined amplitude is less than a first predetermined number and when the number of portions of said second plurality of portions having an amplitude less than a second predetermined amplitude is less than a predetermined number.
35.  A method of applying cardioverting electrical energy to the atria of a human heart in need of cardioversion as defined in claim 15 wherein said first signal comprises a first time varying signal having a first maximum amplitude and said
second signal comprises a second time varying signal having a second maximum amplitude and wherein said cardioverting electrical energy is applied to the atria of the heart when said first maximum amplitude and said second maximum amplitude are less than
a predetermined amplitude limit.
36.  An implantable atrial defibrillator for applying cardioverting electrical energy to the atria of a human heart, said atrial defibrillator comprising:
atrial fibrillation detecting means for determining when the atria of the heart are in need of cardioversion;  and
cardioverting means for applying said cardioverting electrical energy to the atria of the heart when the atria of the heart are in need of cardioversion and when said first detecting means and said second detecting means sense said depolarization
activation wave within a time span from zero seconds to a predetermined fraction of a second.
37.  An implantable atrial defibrillator as defined in claim 36 wherein said cardioverting means comprises timer means for determining the time span between a depolarization activation wave being sensed by said first detecting means and being
sensed by said second detecting means.
38.  An implantable atrial defibrillator for applying cardioverting electrical energy to the atria of a human heart, said atrial defibrillator comprising:
atrial fibrillation detecting means responsive to said third detecting means for determining when the atria of the heart are in need of cardioversion;  and
cardioverting means for applying said cardioverting electrical energy to the atria of the heart when the atria of the heart are in need of cardioversion and when said first signal satisfies said first criterion and when said second signal
satisfies said second criterion, said first criterion being different than the second criterion.  Description
particularly, the atrial defibrillator of the present invention assures that cardioverting electrical energy is applied to the atria of the heart only in synchronism with a detected depolarization activation wave which corresponds to a true
depolarization activation wave of the heart.
Atrial fibrillation is probably the most common cardiac arrhythmia.  Although it is not usually a life-threatening arrhythmia, it is associated with strokes thought to be caused by blood clots forming in areas of stagnant blood flow as a result
commonly referred to as synchronized cardioversion and, as its name implies, involves applying cardioverting or defibrillating electrical energy to the heart in synchronism with the detected depolarization activation wave (R wave) of the heart.  The
treatment is very painful and, unfortunately, most often only results in temporary relief for patients, lasting but a few weeks.
Implantable atrial defibrillators have been proposed to provide relief to patients suffering from occurrences of atrial fibrillation.  Unfortunately, to the detriment of such patients, none of these atrial defibrillators have become a commercial
Implantable atrial defibrillators proposed in the past have exhibited a number of disadvantages which probably have been the cause of these defibrillators failing to become a commercial reality.  Two such proposed defibrillators, although
represented as being implantable, were not fully automatic, requiring human interaction for cardioverting or defibrillating the heart.  Both of these defibrillators require the patient to recognize the symptoms of atrial fibrillation with one
defibrillator requiring a visit to a physician to activate the defibrillator and the other defibrillator requiring the patient to activate the defibrillator from external to the patient&#39;s skin with a magnet.
Improved atrial defibrillators and lead systems which exhibit both automatic operation and improved safety are fully described in U.S.  Pat.  No. 5,282,837, issued Feb.  1, 1994 in the names of John M. Adams and Clifton A. Alferness for &quot;Improved
Atrial Defibrillator and Method&quot;, and co-pending U.S.  application Ser.  No. 07/856,514, filed Mar.  24, 1992 in the in the names of John M. Adams, Clifton A. Alferness, and Paul E. Kreyenhagen for &quot;Improved Atrial Defibrillator, Lead Systems, and
Method&quot;, now U.S.  Pat.  No. 5,433,729, which patent and application are assigned to the assignee of the present invention and incorporated herein by reference.  As disclosed in the aforementioned referenced patent and application, synchronizing the
delivery of the defibrillating or cardioverting electrical energy to the atria with a ventricular electrical activation (R wave) of the heart is important to prevent induced ventricular fibrillation.  Ventricular fibrillation is a fatal arrhythmia which
can be caused by electrical energy being delivered to the heart at the wrong time in the cardiac cycle, such as during the T wave of the cycle.  The atrial defibrillators of the aforementioned referenced applications exhibit improved safety from inducing
ventricular fibrillation by sensing ventricular activations of the heart in a manner which avoids detecting noise as ventricular electrical activations for generating reliable synchronization signals.  Hence, these implantable atrial defibrillators, by
providing such noise immunity in R wave detection, assure reliable synchronization.
The aforementioned U.S.  Pat.  No. 5,282,837 describes non-coincident sensing of an electrical activation such as an R wave at two different areas of the heart to provide a reliable indication that the sensed electrical activation is a real or
legitimate electrical activation and not noise or other interference.  Non-coincidentally sensed electrical activations, in accordance with the teachings of U.S.  Pat.  No. 5,282,837, are considered to be legitimate electrical activations.  Others are
considered to be noise or other interference.  The non-coincidentally sensed electrical activation thus can be relied upon for synchronizing the delivery of a defibrillating or cardioverting electrical pulse to the atria.
It has further been observed that during episodes of atrial fibrillation, the cardiac rate increases to a high rate and/or becomes extremely variable.  At high cardiac rates, the R wave of each cardiac cycle becomes closely spaced to the T wave
of the immediately preceding cardiac cycle.  This may lead to a condition known in the art as an &quot;R on T&quot; condition, which is believed to contribute to induced ventricular fibrillation if the atria are cardioverted in synchronism with an R wave close to
a T wave.
An atrial defibrillator and method which greatly reduces the risk of inducing ventricular fibrillation during atrial cardioversion or defibrillation by avoiding applying the cardioverting electrical energy to the atria at those instances when
increased vulnerability to ventricular fibrillation may be present is described in U.S.  Pat.  No. 5,207,219, issued May 4, 1993 to John M. Adams, Clifton A. Alferness, Kenneth R. Infinger, and Joseph M. Bocek, which patent is assigned to the assignee of
the present invention and incorporated herein by reference.  As described in the referenced patent, this is accomplished by interval timing prior to applying the cardioverting or defibrillating electrical energy.  The time interval between immediately
successive R waves is timed and the cardioverting or defibrillating electrical energy is only applied when a timed interval is greater than a preselected minimum interval.  Synchronization pulses (or signals) are generated to synchronize delivery of the
cardioverting or defibrillating electrical energy to a detected R wave.  This provides protection from the increased vulnerability to ventricular fibrillation condition resulting from a high cardiac rate.
It is most desirable to sense depolarization activation waves of the heart to generate the synchronization pulses (or signals) in a manner which avoids detecting noise as a depolarization activation wave.  Also, it is desirable to sense
depolarization activation waves in a manner which does not fail to detect extremely low amplitude depolarization activation waves yet does not erroneously detect low amplitude noise or T waves.  In addition to noise, a further problem in reliably
detecting depolarization activation waves for generating synchronization pulses is the variability of the amplitudes of depolarization activation waves.  Particularly during atrial fibrillation, depolarization activation waves are characterized by
extreme variability.  An extremely low amplitude depolarization activation wave may be followed immediately by an extremely high amplitude depolarization activation wave.
The atrial defibrillator and method of the present invention greatly reduces the risk of inducing ventricular fibrillation during atrial cardioversion or defibrillation by avoiding applying cardioverting electrical energy to the atria at those
instances when increased vulnerability to ventricular fibrillation may be present.  As will be seen hereinafter, this is accomplished by sensing a depolarization activation wave in one of a first area and a second area of the heart to assure that only
legitimate R waves are used for synchronizing application of the cardioverting electrical energy to the atria with the detected R wave.  In addition, to verify that a detected depolarization activation wave is a legitimate depolarization activation wave,
the detected depolarization activation wave must be detected in each of the two areas of the heart within predetermined time criteria and must pass separate noise and consistency criteria tests.
The present invention therefore provides an implantable atrial defibrillator for applying cardioverting electrical energy to the atria of a human heart.  The atrial defibrillator includes first detecting means for sensing depolarization
activation waves at a first area of the heart and producing a first signal and second detecting means for sensing depolarization activation waves at a second area of the heart and producing a second signal.  The atrial defibrillator further includes
analyzing means for determining if the first signal satisfies a first criterion and the second signal satisfies a second criterion.  The atrial defibrillator still further includes third detecting means for sensing activity of the heart in at least one
of the atria of the heart, and atrial fibrillation detecting means responsive to the third detecting means for determining when the atria of the heart are in need of cardioversion.  The atrial defibrillator still further includes cardioverting means for
applying the cardioverting electrical energy to the atria of the heart when the atria of the heart are in need of cardioversion and when the first signal satisfies the first criterion and when the second signal satisfies the second criterion.
The invention further provides a method for applying cardioverting electrical energy to the atria of a human heart in need of cardioversion.  The method includes the steps of detecting a first depolarization activation wave of the heart at a
first area of the heart, generating a first signal indicative of the first depolarization activation wave, and determining if the first signal satisfies a first criterion.  The method further includes the steps of detecting a second depolarization
activation wave of the heart at a second area of the heart, generating a second signal indicative of the second depolarization activation wave, and determining if the second signal satisfies a second criterion.  The method still further includes the
steps of detecting atrial activity of the heart and determining when the atria of the heart are in need of cardioversion.  The method still further includes the steps applying the cardioverting electrical energy to the atria of the heart when the atria
of the heart are in need of cardioversion and when the first signal satisfies the first criterion and when the second signal satisfies the second criterion.
The present invention still further provides an implantable atrial defibrillator for applying cardioverting electrical energy to the atria of a human heart.  The atrial defibrillator comprises first detecting means for sensing a depolarization
activation wave at a first area of the heart and second detecting means for sensing the depolarization activation wave at a second area of the heart.  The atrial defibrillator further includes atrial fibrillation detecting means for determining when the
atria of the heart are in need of cardioversion.  The invention still further includes cardioverting means for applying the cardioverting electrical energy to the atria of the heart when the atria of the heart are in need of cardioversion and when the
first detecting means and the second detecting means sense the depolarization activation wave within a predetermined time .
FIG. 1 is a schematic block diagram of a fully implantable atrial defibrillator embodying the present invention in accordance with the preferred embodiment thereof and shown in association with a human heart in need of atrial fibrillation
monitoring and potential cardioversion of the atria;
FIG. 4 is a flow diagram illustrating the manner in which the atrial defibrillator of FIG. 1 may be implemented in accordance with the present invention for reliably detecting depolarization activation waves of the heart and applying
cardioverting electrical energy to the heart; and
FIG. 5 is a flow diagram illustrating the manner in which the atrial defibrillator of FIG. 1 may be implemented in accordance with the present invention for performing morphological consistency analysis on detected depolarization activation waves
in conjunction with the flow diagram of FIG. 4.
cardioversion of the atria.  The portions of the heart illustrated in FIG. 1 are the right ventricle 12, the left ventricle 14, the right atrium 16, the left atrium 18, the superior vena cava 20, the coronary sinus channel 21 which, as used herein,
denotes the coronary sinus 22 and the great cardiac vein 23, the coronary sinus ostium or opening 24, the left ventricular free wall 26 and the inferior vena cava 27.  In addition, as used herein, the term &quot;depolarization activation waves&quot; denotes R
waves of the heart cardiac cycle which induce depolarizations of the ventricles 12 and 14.
The atrial defibrillator 30 generally includes an enclosure 32 for hermetically sealing the internal circuit elements of the atrial defibrillator 30, an endocardial first lead 34 and an intravascular second lead 36.  The second lead 36 may
alternatively comprise two leads.  A single lead is illustrated in FIG. 1 so as to not unduly complicate the figure.  The enclosure 32 and the first and second leads 34 and 36 are arranged to be implanted beneath the skin of a patient so as to render the
atrial defibrillator 30 fully implantable.
The endocardial first lead 34 preferably comprises an endocardial bipolar lead having electrodes 38 and 40 arranged for establishing electrical contact with the right ventricle 12 of the heart 10.  The electrodes 38 and 40 permit bipolar sensing
of depolarization activation waves in the right ventricle between a first pair of locations 38a and 42a within the right ventricle 12.  As illustrated, the lead 34 is fed through the superior vena cava 20, into the right atrium 16, and then into the
right ventricle 12.  As will be appreciated by those having ordinary skill in the art, a second path for lead 34 could alternatively be through the inferior vena cava 28, into the right atrium 16, and then into the right ventricle 12.
The second lead 36 generally includes a first or distal electrode 42 and a second electrode 46.  As illustrated, the second lead 36 is flexible and arranged to be passed down the superior vena cava 20, into the right atrium 16, into the coronary
sinus ostium 24, and advanced into the coronary sinus channel 21 of the heart near the left side thereof.  The first or distal electrode 42 is preferably within the coronary sinus 22 or the great vein 23 of the heart adjacent to the left ventricle 14 at
a location 42a.  The electrode 42 is preferably elongated such that the electrode 42 is within the coronary sinus 22 and/or the great cardiac vein 23 adjacent the left ventricle 14 and beneath the left atrium 18.  The second electrode 46 is preferably
located at a location 46a within either the right atrium 16 or the superior vena cava 20 and preferably within the right atrium 16.
As indicated above, the second lead 36 may comprise two leads.  In this preferred embodiment, one of the two leads may include the first electrode 42 and the other of the two leads may include the second electrode 46.  As noted above, the first
electrode 42 and the second electrode 46 are illustrated in FIG. 1 as combined on a single lead, the second lead 36, so as not to unduly complicate the figure.
The first electrode 42 together with the second electrode 46 of the second lead 36 provide for the delivery of defibrillating or cardioverting electrical energy to the atria.  Because the first electrode 42 is located beneath the left atrium 18
near the left ventricle 14 and the second electrode 46 is within either the right atrium 16 or the superior vena cava 20 and above the coronary sinus ostium 24, the electrical energy applied between these electrodes will be substantially confined to the
atria 16 and 18 of the heart 10.  As a result, the electrical energy applied to the right ventricle 12 and left ventricle 14 when the atria are cardioverted or defibrillated will be minimized.
Within the enclosure 32, the atrial defibrillator 30 includes a first or right ventricular (RV) channel 60, a second or right ventricular-coronary sinus (RVCS) channel 62 and a third or atrial channel 64.  The RV channel 60 includes a first sense
amplifier 50, a first filter 52, a second filter 54 and an R wave detector 56.  The RVCS channel 62 includes a second sense amplifier 70, a third filter 72, a fourth filter 74 and a second R wave detector 76.  The atrial channel 64 includes a third sense
amplifier 80, a fifth filter 82, a sixth filter 84 and an atrial activity detector 86.  Within the enclosure 32, the atrial defibrillator 30 also includes a microprocessor 88 and a memory 90.
The first sense amplifier 50 includes a first input 92 which is coupled to electrode 38 of the first lead 34 and a second input 94 which is coupled to electrode 40 of the first lead 34.  The first sense amplifier 50 amplifies the sensed
electrical activity of the heart.  The first filter 52 conditions the sensed electrical activity of the heart and provides at an output 96 an amplified input signal representative of the electrical activity of the heart such as depolarization activation
waves sensed by the bipolar electrodes 38 and 40 in the right ventricle 12 of the heart 10.  The first sense amplifier 50 may include one or more gain stages, and the order of the first sense amplifier 50 and the first filter 52 may be reversed.  That
is, the first filter 52 may be coupled between the electrodes 38 and the first sense amplifier 50.  The second filter 54 further conditions the sensed electrical activity of the heart.
The first R wave detector 56 has an input 98 coupled to the second filter 54.  The first R wave detector 56 produces an electrical output or an initiation signal corresponding to the depolarization activation wave sensed by the first sense
amplifier 50 when the amplified input signal received at the input 98 of the first R wave detector 56 exceeds a threshold.
As a result, the RV channel 60, including electrodes 38, 40, the sense amplifier 50, the first filter 52, the second filter 54 and the R wave detector 56, forms a first detecting means for sensing a depolarization activation wave in general at a
first location of the heart, and more specifically, between a first pair of locations 38a and 42a of the heart for generating a first initiation signal.  The electrodes 38 and 40 and the first sense amplifier 50 form a first sensing means for sensing the
depolarization activation wave.  The first R wave detector 56 forms a first output means for generating the first initiation signal in response to the first sensing means.
The RVCS channel 62 preferably operates in a manner similar to the operation of the RV channel 60.  The second sense amplifier 70 includes a first input 100 which is coupled to the electrode 42 of the second lead 36 and a second input 102 which
is coupled to electrode 38 of the first lead 34.  The second sense amplifier 70 amplifies the sensed electrical activity of the heart.  The third filter 72 conditions the sensed electrical activity and provides at an output 104 an amplified signal
representative of the electrical activity of the heart, such as depolarization activation waves sensed by electrodes 38 and 42.  The second sense amplifier 70 may include one or more gain stages.  The fourth filter 74 further conditions the amplified
The second R wave detector 76 includes an input 106 for receiving the amplified signal.  The second R wave detector 76 produces an electrical output or an initiation signal when the amplified input signal provided at the input 106 exceeds a
As a result, the RVCS channel, including the electrode 42, the electrode 38, the second sense amplifier 70, the third filter 72, the fourth filter 74 and the R wave detector 76, form a second detecting means for sensing a depolarization
activation wave in general at a second location of the heart, and more specifically, between a second pair of locations 38a and 42a of the heart and generating a second initiation signal.  The second sense amplifier 70 and the third filter 72 form a
second sensing means for sensing the depolarization activation wave.  The R wave detector 76 forms a second output means for generating the second initiation signal in response to the second sensing means.
The third sense amplifier 80 senses electrical activity in the atria 16 and 18 of the heart 10.  To that end, the third sense amplifier 80 includes a first input 110 which is coupled to electrode 46 and a second input 112 which is coupled to
electrode 42.  The fifth filter 82 and the sixth filter 84 condition the amplified electrical activity sensed by the third sense amplifier 80.  The atrial activity detector 86 includes an input 114 for receiving the conditioned, amplified electrical
activity and an output 114 for providing an indication of electrical activity of the heart sensed by the third sense amplifier 80.  As a result, the atrial channel 64, including the electrodes 42 and 46, the third sense amplifier 80, the fifth filter 82,
the sixth filter 84 and the atrial activity detector 86, form a third detecting means for sensing activity of the heart in at least one of the atria of the heart.
The microprocessor 88 is preferably implemented in a manner as disclosed in the aforementioned U.S.  Pat.  No. 5,282,837 and further as described hereinafter with respect to the flow diagram of FIGS. 4 and 5.  The implementation of the
microprocessor 88 in accordance with this embodiment of the present invention results in a plurality of functional stages.  The stages include an interval timer 116, an atrial arrhythmia detector in the form of an atrial fibrillation detector 118 and a
charge delivery and energy control stage 120.  The functional stages implemented by the microprocessor 88 also include a synchronization test 119, a sample rate timer 123, a synchronization timeout timer 125, a shock delay timer 127 and an RVCS delay
timer 129, which will be discussed further in conjunction with FIGS. 4 and 5.  The microprocessor 88 is arranged to operate in conjunction with the memory 90 which is coupled to the microprocessor 88 by a multiple bit address and data bus 121.
The atrial defibrillator 30 further includes an analog multiplexer 122, an analog-to-digital converter 124 and a direct memory access (DMA) controller 126.  The output 96 of the first filter 52, the output 104 of the third filter 72 and the
output 87 of the fifth filter 82 are coupled to the analog multiplexer 122.  In response to control signals received from the microprocessor 88 at a control input 128, the analog multiplexer 122 couples signals received from either the first filter 52,
the third filter 72, the fifth filter 82, or a time sequential combination of these signals to the output 130 of the analog multiplexer 122.  The output 130 is coupled to the analog-to-digital converter 124, which converts analog signals received from
the output 130 to digital data.  The digital data are conveyed over a multiple bit data bus 132 to the direct memory access controller 126.  The direct memory access controller 126 conveys digital data, along with storage address information, over a
multiple bit bus 134 to the memory 90.  As a result, data received from either the first filter 52, the third filter 72 or the fifth filter 82 are stored by the DMA controller 126 in the memory 90, without further intervention by the microprocessor 88.
For determining if the heart 10 is in need of cardioversion or defibrillation, and to synchronize delivery of cardioverting or defibrillating electrical energy with detection of a ventricular activation, the atrial defibrillator 30 acquires an
intracardiac electrogram (EGM) segment.  To acquire a single channel EGM segment, the microprocessor 88 conveys control signals to the control input 128 of the analog multiplexer 122 to cause the analog multiplexer 122 to couple either the output 96 of
the first filter 52 or the output 104 of the third filter 72 or the output 87 of the fifth filter 82 to the output 130 of the analog multiplexer 122.  The analog-to-digital converter 124 converts analog signals from the output 130 to digital data.  The
DMA controller 126 receives the digital data and stores the data in the memory 90.
To acquire a multi-channel EGM segment, the microprocessor 88 conveys control signals to the control input 128 of the analog multiplexer 122 to cause the analog multiplexer 122 to couple a periodic time sequential combination of two or more of
the filter outputs 96, 104, or 87 to the output 130 of the analog multiplexer 122.  The analog-to-digital converter 124 converts sequential analog signals from each of the requested filter outputs 96, 104, or 87 to digital data.  The DMA controller 126
receives the digital data in a time-multiplexed format and stores the data in the memory 90.
In this manner, the atrial defibrillator 30 may store data corresponding to electrical activity of the heart sensed by each of the first sense amplifier 50, the second sense amplifier 70 and the third sense amplifier 80.  Following acquisition of
an EGM segment by the atrial defibrillator 30, the data which form the EGM segment may be analyzed by the microprocessor 88.
The atrial defibrillator 30 further includes a charger and storage capacitor circuit 140 of the type well known in the art which charges a storage capacitor to a predetermined peak voltage level and a discharge circuit 142 for discharging the
storage capacitor within the circuit 140 for a predetermined time to provide a controlled discharge output of electrical energy when required to the atria of the heart 10.  To that end, the discharge circuit 142 is coupled to the first electrode 42 and
the second electrode 46 of the second lead 36 for applying the cardioverting or defibrillating electrical energy to the atria.  The atrial defibrillator 30 further includes a depletable power source 144, such as a lithium battery, for providing power to
the electrical components of the atrial defibrillator 30.
When the atrial fibrillation detector 118 determines that the atria 16 and 18 are in fibrillation and thus in need of cardioversion, the charge delivery control 120 causes the charger and storage capacitor circuit 140 to charge the storage
capacitor within the circuit 140.  The charge delivery control 120 causes the discharge circuit 142 to discharge the capacitor of the circuit 140 for applying cardioverting electrical energy to the atria 16 and 18 in synchronism with an R wave detected
by first sense amplifier 50 and first R wave detector 56 and second sense amplifier 70 and second R wave detector 76.
For entering operating parameters into the microprocessor 88, the atrial defibrillator 30 receives programmable operating parameters from an external controller 146 which is external to the skin of the patient.  The external controller 146 is
arranged to communicate with a receiver/transmitter 148 within enclosure 32 which is coupled to the microprocessor 88 over a bidirectional bus 150.  The receiver/transmitter 148 may be of the type well known in the art for conveying various information
which it obtains from the microprocessor 88 to the external controller 146 or for receiving programming parameters from the external controller 146 which the receiver/transmitter 148 then conveys to the microprocessor 88 for storage in internal memory or
in the memory 90 within the enclosure 32.
The receiver/transmitter 148 includes a transmitting coil 152.  Such communication circuits are well known in the art and may be utilized as noted above for receiving commands from external to the implantable enclosure 32 and for transmitting
data to the external controller 146 from the implanted enclosure 32.
Referring now to FIG. 2, it shows a series of wave forms representative of electrical activity of the human heart 10 detected by the atrial defibrillator 30 of FIG. 1.  The wave forms of FIG. 2 are plotted with voltage on the vertical axis and
FIG. 2 shows a right ventricular intracardial electrogram (RV EGM) segment 160 which has been detected by the first sense amplifier 50 between a first pair of locations 38a and 40a.  The RV EGM 160 may be converted to digital data by the
analog-to-digital converter 124 and stored in the memory 90 by direct memory access controller 126 for analysis by the microprocessor 88.  The RV EGM segment 160 includes a representation of a detected depolarization activation wave or R wave 162 which
has a peak 164.  The RV EGM 160 further has an initial portion 166 with a negative slope and a final portion 168 with a positive slope.  The RV EGM 160 has a peak width 165 measured at a predetermined voltage 167.
FIG. 2 further shows a representation of a detected threshold event 170, as detected by the first R wave detector 56.  The second filter 54 receives the RV EGM 160 from the first filter 52 and, after further conditioning, provides the RV EGM to
the first R wave detector 56.  When the signal level of the RV EGM exceeds a predetermined threshold, the R wave detector 56 provides an electrical indication such as RV threshold event 170 to the microprocessor 88.  The detected RV threshold event 170
may be stored in memory 90 as the time at which the first R wave detector 56 detected a threshold event in the right ventricle 12 of the heart 10.  The microprocessor 88 uses the detected threshold event 170, for example, to compare the time at which the
threshold event 170 is detected with the timing of the RV EGM 160, as will be discussed further in conjunction with the flow diagram of FIGS. 4 and 5.
FIG. 2 further shows a right ventricular-coronary sinus intracardial electrogram (RVCS EGM) segment 172 which has been detected by the second sense amplifier 70 between a second pair of locations 38a and 42a.  The RVCS EGM 172 may be converted to
digital data by the analog-to-digital converter 124 and stored in the memory 90 by DMA controller 126 for analysis by the microprocessor 88.  The RVCS EGM segment 172 includes a representation of a detected depolarization activation wave or R wave 174
which has a peak 176.  The RVCS EGM 172 further has an initial portion 178 with a positive slope and a final portion 180 with a negative slope.  The RVCS EGM 172 has a peak width 177 measured at a predetermined voltage 179.
FIG. 2 still further shows a representation of a detected threshold event 182, as detected by the second R wave detector 76.  When the signal level of the RVCS EGM received by the second R wave detector 76 exceeds a predetermined threshold, the
second R wave detector 76 provides an electrical indication such as RVCS threshold event 182 to the microprocessor 88.  The detected RVCS threshold event 182 may be stored in memory 90 as the time at which the second R wave detector 76 detected a
threshold event between locations 38a and 42a.
FIG. 3 is a block diagram of the synchronization test functional stage 119 implemented by the microprocessor 88 of FIG. 1.  In accordance with the preferred embodiment of the present invention, after the atrial fibrillation detector 118 has
detected an atrial fibrillation episode and after the storage capacitor within circuit 140 has been charged to a predetermined peak voltage, the synchronization test 119 operates to synchronize the delivery of cardioverting or defibrillating electrical
energy from the storage capacitor in circuit 140 with an R wave detected by the RV channel 60.
The synchronization test functional stage 119 preferably includes a number of independent tests or checks to verify the consistency of R waves detected by RV channel 60 and the RVCS channel 62.  Operation of the synchronization test functional
stage 119 will be discussed in further detail in conjunction with FIGS. 4 and 5.
These checks includes a timer range check 184 for verifying that the interval timed between successive R waves by the interval timer 116 is greater than a predetermined minimum and less than a predetermined maximum.  The synchronization test 119
further includes a two-channel threshold event check 186 for verifying timing between R waves or threshold events detected by RV channel 60 and RVCS channel 62.  The synchronization test functional stage 119 further includes a two-channel peak test 188
for verifying the time relationship between peak values of R waves detected by RV channel 60 and RVCS channel 62.
The synchronization test functional stage 119 still further includes an RV peak and threshold event check 190 for verifying the time relation between the peak value and the detected threshold event measured by the RV channel 60.  The
synchronization test functional stage 119 further includes a two-channel morphology check 192 for verifying the amplitudes and durations of portions of depolarization activation waves detected by the RV channel 60 and the RVCS channel 62.  The
synchronization test functional stage 119 still further includes a channel-to-channel overlap test 194 for verifying the time relationship of predetermined portions of the depolarization activation wave detected by the RV channel 60 and the RVCS channel
62.  The synchronization test functional stage 119 further includes a two-channel noise and amplitude check 196 for verifying that the depolarization activation waves detected by the RV channel 60 and the RVCS channel 62 satisfy predetermined noise and
amplitude range criteria.
The checks or tests which are included in the synchronization functional test stage 119 are preferably performed by the microprocessor 88 in response to instructions and data stored in the memory 90.  The microprocessor 88 may perform one or more
of the tests or checks illustrated in FIG. 3 and may perform other verification tests not illustrated there.
The operation of the atrial defibrillator 30 will now be described with reference to FIG. 4 and with respect to a preferred embodiment of the present invention.  For purposes of this discussion, it is assumed that the atrial fibrillation detector
118 has detected an atrial fibrillation episode and that the storage capacitor within circuit 140 has been charged to a predetermined peak voltage.
Referring now to FIG. 4, the microprocessor 88 first, in step 200, resets and initializes elements used for synchronizing delivery of cardioverting or defibrillating electrical energy to a detected R wave.  The microprocessor 88 resets the sample
rate timer 123 (FIG. 1), the synchronization timeout timer 125, the shock delay timer 127 and the RVCS delay timer 129.  Also at step 200, the microprocessor 88 starts the sample rate timer 123 and initiates a multi-channel EGM data acquisition from the
RV channel filter output 96 and the RVCS channel filter output 104.  The sample rate timer 123, upon expiration, signals that a single data sample has been acquired by the DMA controller 126 from both the RV channel filter output 96 and the RVCS channel
filter output 104.  Upon said expiration, the microprocessor 88 may then process the digital data sample acquired from each of these two channels.
Also at step 200, the microprocessor 88 starts the interval timer 116 in response to a ventricular activation (R wave) detected by either the RV channel 60 or the RVCS channel 62.  An R wave is detected if the RV EGM 160 has exceeded a
predetermined threshold in RV channel 60 and the R wave detector 56 has provided an RV threshold event or initiation signal 170 to the microprocessor 88 or if the RVCS EGM 172 has exceeded a predetermined threshold in the RVCS channel 62 and the R wave
detector 76 has provided an RVCS threshold event or initiation signal 182 to the microprocessor 88.  After this signaling of ventricular activation, step 200 is completed and step 202 is entered.
At step 202, the sample rate timer 123 is tested.  If the sample rate timer 123 has not expired, the microprocessor returns.  If the sample rate timer 123 has expired, at step 204, the microprocessor resets the sample rate timer 123 and processes
the most recently acquired digital data sample (stored in memory 90) from both the RV channel 60 and the RVCS channel 62.  These two data samples represent a single data point on an electrogram in the RV channel 60 and the RVCS channel 62.  That is,
electrical activity of the heart 10 sensed by the first sense amplifier 50 and the second sense amplifier 70 is provided by the analog multiplexer 122 to the analog-to-digital converter 124 for conversion to digital data and storage by the DMA controller
126 in the memory 90.  During this acquisition, the microprocessor 88 further processes this data stored in the memory 90 point by point as it is being acquired by the DMA controller 126 and as signaled by the sample rate timer 123.
The sample rate timer 123 may be reset to expire after a predetermined time interval, for example two milliseconds or four milliseconds.  The sample rate timer 123 thus controls the rate at which data samples representing electrocardiograms are
acquired from the RV channel 60 and the RVCS channel 62 after the atrial fibrillation detector 118 has detected an atrial fibrillation episode.  While the DMA controller 126 is acquiring electrograms from the RV channel 60 and the RVCS channel 62, the
microprocessor 88 may analyze previously-acquired electrocardiogram data, for example, by performing morphology tests described below in conjunction with FIG. 5.
It is desirable to apply cardioverting or defibrillating electrical energy to the atria of the heart immediately subsequent to detection of an R wave, to minimize the risk of induced ventricular fibrillation.  However, R waves detected by the RV
channel 60 at locations 38a and 40a (FIG. 1) tend to have widely varying amplitudes, particularly when the heart 10 is in atrial fibrillation.  Therefore, there is a risk that a low amplitude R wave may not be detected by the RV channel 60, meaning the
interval timer 116 may not be reset, and causing the interval timer 116 to measure a falsely long interval.  To ensure that all R waves are detected and cause the interval timer 116 to be reset, the atrial defibrillator 30, in accordance with the present
invention, resets the interval timer 116 in response to detection of an R wave by either the RV channel 60 or the RVCS channel 62.
Since the cardiac activity detected by the RVCS channel 62 tends to be noisy, due to atrial fibrillation and other noise, and because an R wave detected by the RVCS channel 62 tends to be spread out in time, it is preferable to apply
cardioverting or defibrillating electrical energy only in response to an R wave detected by the RV channel 60.  However, as can be seen from FIG. 2, an RVCS EGM 172 detected by the RVCS channel 62 may be spread out in time relative to an RV EGM 160
detected by the RV channel 60.  RVCS threshold event 182 may actually be detected earlier in time than an RV threshold event 170 is detected for the same depolarization activation wave.  Therefore, in accordance with the present invention, resetting of
the interval timer 116 in response to an RVCS threshold event 182 is delayed by a predetermined time, such as 20 milliseconds, which is timed by the RVCS delay timer 129.  Resetting of the interval timer 116 in response to an RV threshold event 170 is
preferably not delayed.  The RVCS delay timer 129, which establishes the delay time for resetting the interval timer 116 in response to an RVCS threshold event 182 is preferably programmable using the external controller 146.  The dual reset process,
including delaying the resetting of the interval timer 116 in response to a detected RVCS threshold event 182 allows application of cardioverting or defibrillating electrical energy to be accurately synchronized to an R wave detected in the RV channel
To begin this dual reset process, the microprocessor 88 at step 206 first determines if an RV threshold event has occurred.  An RV threshold event has occurred if the RV EGM 160 has exceeded a predetermined threshold in the RV channel 60 and the
R wave detector 56 has provided an initiation signal 170 to the microprocessor 88.  If an RV threshold event has been detected, at step 208, the microprocessor 88 determines if the time interval since the last RV threshold event or the last RVCS
threshold event, measured by the interval timer 116, is within a predetermined range.  The range is determined by minimum and maximum time intervals which may be set from external to the implanted atrial defibrillator 30 by means of the external
controller 146 and the transmitter/receiver 148.  In accordance with the preferred embodiment of the present invention, the minimum time interval may be in the range of 500 milliseconds and the maximum time interval may be in the range of 2,000
milliseconds.  If the time interval measured by the interval timer 116 is less than the minimum time interval or greater than the maximum time interval, the microprocessor 88 restarts the interval timer at step 212.  No cardioverting or defibrillating
electrical energy will be applied in response to the RV threshold event detected at step 206, and the microprocessor 88 will wait until a subsequent RV threshold event is detected before applying cardioverting or defibrillating electrical energy.  If the
time interval measured by the interval timer 116 is within the predetermined range of interval times, the microprocessor 88 at step 210 starts the shock delay timer 127 and at step 212 restarts the interval timer 116.
If an RV threshold event was not detected by the microprocessor 88 at step 206, at step 214 the microprocessor 88 determines if the RVCS delay timer 129 has expired.  The RVCS delay timer 129 may have been started in response to a previously
detected RVCS threshold event.  If the RVCS delay timer has expired, at step 216, the microprocessor 88 resets and stops the RVCS delay timer and at step 212 restarts the interval timer.
At step 218, the microprocessor 88 determines if an RVCS threshold event has been detected.  An RVCS threshold event is detected if the RVCS EGM 172 has exceeded a predetermined threshold in the RVCS channel 62 and the R wave detector 76 has
provided an initiation signal 182 to the microprocessor 88.  In response to detection of an RVCS threshold event, the microprocessor 88 starts the RVCS delay timer 129 at step 220.
At step 222, the microprocessor 88 determines if the shock delay timer 127 has expired.  The shock delay timer 127 was started at step 210 in response to detection of an RV threshold event that satisfied the R-to-R interval criterion.  The shock
delay timer 127 ensures that cardioverting or defibrillating electrical energy will only be applied a predetermined delay time after detection of an RV threshold event which satisfies the R-to-R interval criterion.  For example, the shock delay timer 127
may delay application of cardioverting or defibrillating electrical energy by 30-50 milliseconds following detection of an RV threshold event which satisfies the R-to-R interval criterion.  The predetermined delay time measured by the shock delay timer
127 is preferably programmable using the external controller 146.  If the microprocessor 88 determines at step 222 that the shock delay timer has expired, at step 224 the microprocessor 88 determines if the RV EGM 160 and the RVCS EGM 172 satisfy a set
of predetermined morphological tests or checks, illustrated in FIG. 5.
Referring to FIG. 5, it shows a flow diagram illustrating the manner in which the atrial defibrillator of FIG. 1 may be implemented in accordance with the present invention for performing morphological consistency analysis on detected
depolarization activation waves in conjunction with the flow diagram of FIG. 4.  In performing the steps illustrated in FIG. 5, the microprocessor 88 analyzes data stored in the memory 90 corresponding to electrical activity of the heart 10 detected by
the first sense amplifier 50 and the second sense amplifier 70 (FIG. 1).  To the degree possible, this analysis is performed on a point-by-point basis as the data is being acquired as indicated in step 204.  This real-time analysis minimizes the
computational time required to perform the decisions shown in FIG. 5 so that defibrillating electrical energy can be delivered as quickly as possible after the expiration of the shock delay timer 127.
To ensure that the atrial defibrillator 30 does not apply cardioverting or defibrillating electrical energy to the atria of the heart 10 in response to an erroneously detected R wave or threshold event, the atrial defibrillator in accordance with
the present invention performs morphological and threshold consistency checks in addition to the R-to-R interval timing test.  The morphology of a detected depolarization activation wave is the shape, duration and amplitude characteristics of the
depolarization activation wave.  As discussed above in relation to FIG. 1, a digital representation of a detected depolarization activation wave segment is stored in the memory 90 for analysis by the microprocessor 88.  In addition, morphological
analysis and consistency checks are performed in accordance with the present invention using R wave segments and threshold events detected by both the RV channel 60 and the RVCS channel 62.  Before cardioversion or defibrillation can occur, the R wave
segments and threshold events must meet predetermined criteria to ensure that a detected R wave is a genuine or legitimate R wave.  Thus, cardioverting or defibrillating electrical energy is applied to the atria of the heart only when the atria of the
heart are in need of cardioversion and when a first signal detected by the RV channel 60 satisfies a first criterion and when a second signal produced by the RVCS channel 62 satisfies a second criterion.
At step 226, the microprocessor 88 determines if threshold events detected by the RV channel 60 and the RVCS channel 62 occurred within a predetermined time with respect to each other, for example 20 milliseconds.  The predetermined time may be
programmable using the external controller 146.  If a detected R wave is a genuine R wave, it must be detected in both the RV channel 60 and the RVCS channel 62 within a predetermined time.  If the detected depolarization activation wave does not pass
these criteria, the microprocessor 88 proceeds to step 242 (FIG. 4).
At step 228, the microprocessor 88 determines if the morphological peaks of the depolarization activation wave segments detected by the RV channel 60 and the RVCS channel 62 occur within a predetermined time period, such as 20 milliseconds.  The
predetermined time period is preferably programmable using the external controller 146.  In performing this test, the microprocessor 88 determines the peak 164 of an RV EGM 160 and the peak 176 of an RVCS EGM 172 (FIG. 2).  If the time relationships
between the peaks 164 and 176 do not satisfy these criteria, the microprocessor 88 proceeds to step 242.
Also at step 228, the microprocessor 88 determines if the widths of the morphological peaks of the detected depolarization activation wave segments are within a predetermined peak width time range.  For example, the width 165 of the RV EGM 160
(FIG. 2) must be less than a maximum width, such as 50 ms, and greater than a minimum width, such as 12 ms.  Similarly, the width 177 of the RVCS EGM 172 must be less than a maximum width and greater than a minimum width.  The respective maxima and
minima are preferably independently definable.
At step 230, the microprocessor 88 determines if the morphological peak 164 of the R wave detected by the RV channel 60 occurs within a predetermined time, such as 20 milliseconds, of the RV threshold event 170 detected by the RV channel 60.  The
predetermined time interval is preferably programmable using the external controller 146.  The peak 164 of the RV EGM 160 should occur within a predetermined time of the RV threshold event 170.  If the R wave detected by the RV channel 60 does not
satisfy these criteria, the microprocessor 88 proceeds to step 242.
At step 232, the microprocessor 88 determines if the RV EGM 160 detected by the RV channel 60 and the RVCS EGM 172 detected by the RVCS channel 62 satisfy predetermined morphology criteria.  For example, the microprocessor 88 may determine if the
amplitudes of the initial portion 166 and the final portion 168 of the RV EGM 160 are within a predetermined range of values.  Similarly, the microprocessor 88 may determine if the amplitudes of the initial portion 178 and the final portion 180 of the
RVCS EGM 172 are within a predetermined range of values.  Also, for example, the microprocessor 88 may determine if the durations of the initial portion 166 and the final portion 168 of the RV EGM 160 are within a predetermined range of values, and if
the durations of the initial portion 178 and the final portion 180 of the RVCS EGM 172 are within a predetermined range of values.  These tests ensure that cardioverting or defibrillating electrical energy will be delivered to the atria of the heart 10
only in response to a genuine R wave, and that the detected R wave is a genuine R wave and is not contaminated with noise or other interference.  If the detected RV EGM 160 and RVCS EGM 172 do not satisfy these criteria in step 232, the microprocessor 88
proceeds to step 242.
At step 234, the microprocessor 88 determines if the duration of the final portion 180 of a detected RVCS EGM 172 exceeds the duration of the final portion 168 of a detected RV EGM 160 by a predetermined time, such as four milliseconds.  The
predetermined time may be programmable in response to external controller 146.  This test helps to ensure that detected cardiac activity has a physiological origin rather than an extraneous origin, such as noise.  R waves detected by the RVCS channel 62,
such as RVCS EGM 172, generally exhibit trailing R wave durations, such as final portion 180, that exceed trailing R wave durations of R waves detected by the RV channel 60, such as final portion 168.  If the detected RV EGM 160 and the detected RVCS EGM
172 do not satisfy these criteria, the microprocessor 88 proceeds to step 242.
At step 236, the microprocessor 88 determines if detected signal quality is sufficient to ensure that a genuine R wave has been reliably detected.  For example, the microprocessor 88, in analyzing RV EGM 160 stored in the memory 90, may determine
all portions of the detected RV EGM 160, such as initial portion 166 and final portions 168, which exceed a predetermined amplitude (the amplitude threshold).  If the number of such portions exceeds a predetermined number (the count threshold), then the
microprocessor 88 may conclude that the detected RV EGM is noisy and is of insufficient quality.  A similar test may be performed on the detected RVCS EGM 172.  The amplitude threshold and the count threshold are preferably programmable, for both the RV
channel 60 and the RVCS channel 62, using the external controller 146.
An additional test that may be performed at step 236 is analysis of the maximum amplitude of the detected RV EGM 160 and the detected RVCS EGM 172.  For example, the microprocessor 88 may determine that the peak value 164 of the detected RV EGM
160 is within a predetermined range of values and that the peak value 176 of the detected RVCS EGM 172 is within a predetermined range of values.  This ensures that, for example, the analog-to-digital converter 124 did not saturate during the R-to-R
interval preceding delivery of cardioverting or defibrillating electrical energy.  If the detected RV EGM 160 and the detected RVCS EGM 172 do not satisfy these criteria, the microprocessor 88 proceeds to step 242.
The precise ordering of the tests illustrated in steps 226-236 is not critical.  Preferably, the detected cardiac activity must satisfy all the criteria in these steps or tests before the discharge circuit 142 applies the cardioverting or
defibrillating electrical energy to the atria of the heart.  However, one or more of these tests may be eliminated while remaining within the scope of the present invention.  In addition, to conserve energy stored in the depletable energy source 144, it
may be preferable to perform computationally simple tests first.
Referring again to FIG. 4, at step 244, if the detected ventricular activation has satisfied each of the predetermined morphology and consistency criteria (steps 226-236), and if the time interval between the last two immediately successive
ventricular activations as measured by the interval timer is greater than the preselected minimum time interval and less than the preselected maximum time interval, and if the atrial fibrillation detector 118 has determined that the atria are in need of
defibrillation, the charge delivery control stage 120 of the microprocessor 88 causes the discharge circuit 142 to immediately discharge the electrical energy stored in the storage capacitor of the circuit 140 for applying the cardioverting or
defibrillating electrical energy to the atria 16 and 18 of the heart 10.  Since the microprocessor 88 is able to process steps 202-222 very quickly after the occurrence of the last detected ventricular activation and to process steps 226-236 very quickly
after the expiration of the shock delay timer 127, the discharge circuit 142 will apply the cardioverting electrical energy to the atria of the heart substantially coincident or in synchronism with the last detected ventricular activation, as determined
by the shock delay timer 127.  Preferably, the discharge circuit 76 will apply the cardioverting electrical energy to the atria of the heart within 30-50 milliseconds of the last detected ventricular activation.
At step 242, if the detected ventricular activity did not satisfy the predetermined morphology and consistency criteria of any of the tests of steps 226-236, the atrial defibrillator 30 will not apply cardioverting or defibrillating electrical
energy to the atria of the heart in response to the shock delay timer expiration caused by the RV threshold event detected at step 206.  Instead, the microprocessor 88 resets and stops the shock delay timer 127 until a subsequent RV threshold event is
detected which meets the R-to-R interval criteria.
If, at step 222, the shock delay timer 127 had not expired or if, at step 224, one or more of the morphological tests did not pass and the shock delay timer was reset at step 242, the microprocessor proceeds to step 246 to determine if the
synchronization timeout timer has expired.  The synchronization timeout timer 125 is used by the microprocessor 88 to interrupt the shock synchronization procedure illustrated in FIGS. 4 and 5 after a predetermined time.  For example, the synchronization
timeout timer 125 may be reset and started at step 200 when the microprocessor 88 begins searching for a detected ventricular activation suitable for synchronizing delivery of cardioverting or defibrillating electrical energy.  The synchronization
timeout timer 125 may expire after, for example, one minute, indicating that no suitable synchronization condition can be determined.  To prevent continued operation of the shock synchronization procedure illustrated in FIG. 4, which may deplete the
depletable energy source 144, if the synchronization timeout timer 125 has expired, the synchronization procedure terminates at step 248.
If at step 246 the synchronization timeout timer 125 has not expired, the microprocessor proceeds to step 202 and awaits the next expiration of the sample rate timer 123, which signals that the DMA controller 126 has acquired another digital data
sample from each of the RV and RVCS channels 60, 62.  The sample rate timer 123 expires at regular intervals, for example every two milliseconds or every four milliseconds.  After every expiration of the sample rate timer 123, the steps shown in FIG. 4
and FIG. 5 are potentially executed as indicated by the decision steps in these figures.
In addition, the atrial defibrillator of the present invention precludes application of cardioverting or defibrillating electrical energy to the atria of the heart when detected ventricular activations do not meet predefined morphological and
consistency criteria.  The atrial defibrillator of the present invention thus reduces the risk of falsely detecting ventricular activations and the risk of inducing ventricular fibrillation during the application of cardioverting or defibrillating
electrical energy to the atria of the heart in response to such a falsely detected ventricular activation.
While a particular embodiment of the present invention has been shown and described, modifications may be made.  For example, the interval timing and morphological criteria of the present invention may be utilized to advantage in an external
atrial defibrillator wherein an electrode or electrodes adhered to the surface of the skin of a patient are employed along with an R wave detector for detecting ventricular activations and surface pad electrodes are utilized for applying the
cardioverting electrical energy to the atria of the heart.  Such surface detecting and pad electrodes are well known in the art.  Additionally, the invention may be modified by deleting any or all tests shown in FIG. 5.  For example, RVCS morphology
checks could be eliminated or the RV to RVCS overlap test could be eliminated.  Hence, it is therefore intended in the appended claims to cover all such changes and modifications which fall within the true spirit and scope of the invention.
Cardioversion synchronization system and method for an atrial defibrillator, White, Harley White, Application number 08 259-476, Surgery: LightThermal And Electrical Application, atrial fibrillation, atrial defibrillator, electrical energy, atria of the heart, atrial defibrillation, internal combustion engines, PATENT NUMBER, document collection, Cardiac Pacemakers, Medtronic
The present invention generally relates to an atrial defibrillator for applying cardioverting electrical energy to the atria of a human heart in need of cardioversion. The present invention is more particularly directed to a fully automaticimplantable atrial defibrillator which exhibits improved safety by reducing the potential risk of induced ventricular fibrillation which may result from the mistimed delivery of cardioverting electrical energy to the atria of the heart. Moreparticularly, the atrial defibrillator of the present invention assures that cardioverting electrical energy is applied to the atria of the heart only in synchronism with a detected depolarization activation wave which corresponds to a truedepolarization activation wave of the heart.Atrial fibrillation is probably the most common cardiac arrhythmia. Although it is not usually a life-threatening arrhythmia, it is associated with strokes thought to be caused by blood clots forming in areas of stagnant blood flow as a resultof prolonged atrial fibrillation. In addition, patients afflicted with atrial fibrillation generally experience palpitations of the heart and may even experience dizziness or even loss of consciousness.Atrial fibrillation occurs suddenly and many times can only be corrected by a discharge of electrical energy to the heart through the skin of the patient by way of an external defibrillator of the type well known in the art. This treatment iscommonly referred to as synchronized cardioversion and, as its name implies, involves applying cardioverting or defibrillating electrical energy to the heart in synchronism with the detected depolarization activation wave (R wave) of the heart. Thetreatment is very painful and, unfortunately, most often only results in temporary relief for patients, lasting but a few weeks.Drugs are available for reducing the incidence of atrial fibrillation. However, these drugs have many side effects and many patients are resistant to them which grea
Combined Cardiac Resynchronization and Implantable Cardioversion Synchronization