Vol. 275, Issue 3, H995-H1001, September 1998
Dynamics of heart rate response to sympathetic nerve
stimulation
Abdelkader
Mokrane and
Réginald
Nadeau
Research Center, Hôpital du Sacré-Coeur de
Montréal, and Department of Medicine, Faculty of Medicine,
Université de Montréal, Montreal, Quebec, Canada H4J 1C5
 |
ABSTRACT |
Electrical stimulation of the right cardiac
sympathetic nerve was used to achieve a step increase of norepinephrine
concentration at the sinus node. The heart rate (HR) response to
sympathetic stimulation was characterized by a first-order process with
a time delay. For moderate to high intensities of stimulation the mean
delay and time constant were 0.7 and 2.1 s, respectively, and for low
intensities of stimulation they were 0.4 and 1.1 s, respectively. From
the analysis of the HR response to different patterns of nerve
stimulation, in vivo neurotransmitter kinetics were estimated. The time
constant of norepinephrine dissipation averaged ~9 s. These results
combined with computer simulations revealed two facets of sympathetic
neural control of HR: 1) negligible role of the sympathetic system in beat-to-beat regulation of HR under
stationary conditions and 2) ability
of HR to react relatively quickly (within a few seconds) to sharp
increases in sympathetic nerve traffic.
sympathetic system; heart rate dynamics
| |
INTRODUCTION |
SINCE THE EARLY investigations of the sympathetic
nervous system, it has been observed that the heart rate (HR) step
response to sympathetic nerve stimulation is characterized by a time
delay of 1-3 s followed by a slow increase with a time constant of
10-20 s (25). HR decay after nerve stimulation cessation is even
slower and is generally preceded by a longer time delay. In the
frequency domain the HR response to sympathetic input fluctuations was
characterized by a low-pass filter system with a cutoff frequency
between 0.01 and 0.02 Hz coupled to a 1.7-s delay (1).
The sympathetic control of HR involves a cascade of biochemical
and biophysical processes (9, 11, 14):
1) Norepinephrine (NE)
released at sympathetic nerve terminals is removed from the neuroeffector space mainly through reuptake by nerve terminals and
washout by the coronary circulation.
2) NE binds to postsynaptic 
-adrenergic receptors, which are linked to stimulatory
guanosine nucleotide-binding
(Gs) proteins.
3) Ionic current channels are activated mainly through a second messenger pathway, namely, adenylate cyclase and cAMP systems. The slow development of the chronotropic response has been attributed to the slow NE dissipation rate
and/or to the sluggishness of the intracellular adrenergic
system (19). However, the relative contribution of each subsystem to
the overall dynamic response has not been quantified in vivo. Moreover,
because NE is the first link in the sympathetic neuroeffector
transmission, its slow kinetics could mask the expression of the
postsynaptic adrenergic activity.
In this study we used a sympathetic nerve stimulation protocol to
simulate a step increase of NE concentration ([NE]) at the sinus node with the aim of characterizing the dynamics of the HR
response and gaining insight into the mechanisms of sympathetic neural
control of HR.
| |
METHODS |
Animal preparation.
Eight adult mongrel dogs, weighing 18-30 kg, were anesthetized
with 
-chloralose (80 mg/kg iv) and artificially ventilated with room
air. Additional doses of anesthetic were given regularly to maintain an
appropriate level of anesthesia. The right femoral vein and the right
femoral artery were cannulated for the infusion of drugs and the
monitoring of arterial blood pressure. The right stellate ganglion was
isolated and decentralized. A pair of electrodes was attached to the
right ansa subclavia or the right stellate ganglion for stimulation.
Nerve stimulations were performed using a programmable stimulator
(BM-SCP, Institut de génie biomédical, Montreal, PQ,
Canada) coupled to a constant-current unit. Supramaximal stimulatory
current pulses (2-4 mA) of 2-ms duration each were applied.
Finally, a pair of electrodes was implanted on the right atrial
epicardium to record an atrial electrogram. Atropine (0.2 mg/kg) was
injected intravenously to block parasympathetic effects.
Stimulation protocol.
To analyze the HR response to a step increase of [NE] at
the sinus node, we used the stimulation protocol illustrated in Fig. 1A. At
the start of the stimulation, a rapid increase of [NE] is
obtained by delivering an impulse train. [NE] is then
maintained at a constant level by application of a constant-frequency
pulse stimulation. However, to obtain a steplike increase of
[NE], the initial increase of [NE] should match
the [NE] reached at the steady state. Because the NE
removal rate is unknown, the number of impulses per train must be
adjusted by trial and error to obtain as close a match as possible.
With the assumption that the HR response to NE stimulation is a
first-order process, a steplike increase of [NE] should
induce a monoexponential HR increase. On the basis of this assumption,
an overshoot (undershoot) observed in the HR response should indicate
that the number of initial impulses per train is overestimated
(underestimated) (Fig. 1B). Consequently, the optimal number of impulses per train was chosen so
that only a negligible overshoot or undershoot could be observed in the
HR response.
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Fig. 1.
Sympathetic nerve stimulation protocol.
A: burst of
N stimulatory pulses at a frequency of
50 Hz followed by a constant stimulation frequency between 0.5 and 4 Hz
is used to raise abruptly norepinephrine concentration
([NE]) at synaptic cleft.
B: typical example of heart rate (HR)
response to pattern of stimulation in
A as a function of number of impulses
(N). Optimal number
N corresponding to a close step
increase of [NE] was 7, and steady-state stimulation
frequency was 1 Hz. N = 1 coincides
with constant nerve stimulation frequency.
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|
Data analysis.
HR increase and decay were fitted by time-delay monoexponential
functions using a Levenberg-Marquardt nonlinear regression algorithm
(21) provided by the Sigmaplot software package (Jandel Scientific)
![<IT>y</IT>(<IT>t</IT>) = &Dgr;HR[1 − <IT>e</IT><SUP>−(<IT>t</IT> − <IT>d</IT>)&tgr;<SUB>HR</SUB></SUP>]](/content/vol275/issue3/fulltext/H995/img001.gif)
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(1)
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for
HR increase and
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(2)
|
for
HR decay, where
y(t)
is the HR time increase or decay and
HR,
d, and 
HR represent the unknown
time constant, time delay, and steady-state amplitude to be estimated,
respectively. These parameters were estimated for four levels of
sympathetic nerve stimulation: 0.5, 1, 2, and 4 Hz.
For comparison between groups, statistical analyses were carried out by
means of Student's paired t-test.
P < 0.05 was considered significant.
Averaged data are given as means ± SE.
| |
RESULTS |
Parameters of NE kinetics.
A step increase of [NE] is obtained when the initial rise
of [NE] (left-hand side of Eq. 3) equals the mean steady-state [NE] (right-hand side of Eq. 3)
|
(3)
|
where
N is the number of train impulses,
q is the [NE] quantum
released by one stimulatory pulse,
NE is the time constant of the
NE removal process, and f is the
steady-state sympathetic stimulation frequency. The right-hand side of
Eq. 3 was obtained by integrating
steady-state [NE] over one heart period. Computational details are given in the APPENDIX.
From Eq. 3, the time constant of the
removal process was estimated by
|
(4)
|
where
NE values ranged from 7 to 12 s
and averaged 9.1 ± 1.9 s.
Dynamic parameters of the postsynaptic noradrenergic response.
The HR response to a steplike increase of [NE] was
adequately fitted by a time-delay monoexponential rise. The time
constants and delays of HR increase were roughly constant for
frequencies of sympathetic nerve stimulation 
1 Hz (1, 2, and 4 Hz)
and averaged 2.1 ± 0.26 and 0.7 ± 0.09 s, respectively (Fig.
2A).
However, these parameters were significantly lower for 0.5-Hz
stimulation intensity (0.5 vs. 1 and 2 Hz) and averaged 1.1 ± 0.32 and 0.44 ± 0.11 s, respectively. The average magnitude of the
steady-state HR increase (HR) vs. frequency of sympathetic
stimulation was fitted by the Hill equation (Fig.
2B)
|
(5)
|
where
f is sympathetic stimulation
frequency, HRmax is the maximum
value of HR,
Kf is the
stimulation frequency producing a half-maximum response, and
n is the Hill coefficient.
HRmax and
Kf were 72.6 beats/min and 1.21 Hz, respectively; n
was 1.97.
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Fig. 2.
A: mean time constant ( ) and delay
( ) of exponential rise of HR after a step increase of
[NE] as a function of sympathetic nerve stimulation
frequency. B: steady-state HR increase
as a function of sympathetic nerve stimulation frequency. Continuous
line, Hill equation curve fit of experimental data. Error bars, SE.
* P < 0.05 compared with 0.5 Hz.
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Mathematical model.
Considering the results obtained above, we propose a mathematical model
of the sympathetic neural control of HR. The model is composed of a
cascade of two functional blocks: 1)
NE kinetics and 2) postsynaptic
noradrenergic dynamics.
NE kinetics are described by a first-order process
![<FR><NU>d[NE]</NU><DE>d<IT>t</IT></DE></FR> + &agr;<SUB>NE</SUB>[NE] = <IT>q</IT> <LIM><OP>∑</OP><LL><IT>i</IT></LL></LIM> &dgr;(<IT>t</IT><SUB><IT>i</IT></SUB>)](/content/vol275/issue3/fulltext/H995/img006.gif)
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(6)
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where
NE is the NE elimination rate,
q is the [NE] quantum
released by one stimulatory pulse, and
(ti) is the
Dirac impulsion corresponding to stimulation time occurrences
(ti).
Because absolute values of [NE] are unknown,
q can be fixed to 1 without loss of
generality.
Postsynaptic dynamics are given by
![<FR><NU>∂hr(<IT>t</IT>, [NE])</NU><DE>∂<IT>t</IT></DE></FR> = −&agr;<SUB>HR</SUB>[(<IT>G</IT>{[NE](<IT>t</IT> − <IT>d</IT>)}) − hr(<IT>t</IT>, [NE])]](/content/vol275/issue3/fulltext/H995/img007.gif)
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(7)
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where
hr is the HR variation, HR is
the variation rate, d is the time
delay of the HR response, and G is the
steady-state HR response. According to Eq. 5 and noting that [NE] is linearly related
to f (see Eq. A7), the steady-state HR response is obtained by
![&Dgr;HR = <IT>G</IT>([NE]) = <FR><NU>&Dgr;HR<SUB>max</SUB>[NE]<SUP>2</SUP></NU><DE><IT>K</IT><SUP>2</SUP><SUB>NE</SUB> + [NE]<SUP>2</SUP></DE></FR>](/content/vol275/issue3/fulltext/H995/img008.gif)
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(8)
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where
KNE is the
[NE] producing a half-maximum response. The Hill
coefficient was rounded to 2. According to the right-hand side of
Eq. 3 and with the assumption that
q = 1, it can be shown that
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(9)
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Time-domain simulation.
We used the mathematical model described above to simulate the HR
response to a squarelike function of the sympathetic nerve stimulation
frequency. Figure
3C
illustrates a comparison between experimental and simulated data.
Simulated data fit more accurately the foot of the HR onset than does a
time-delay monoexponential curve fitting. In some cases (not shown) the
simulated HR increase was slightly faster, particularly during the
second half of the increase. The theoretical [NE] time
course is illustrated in Fig. 3B. The
model fitted well the first half of HR decay but failed to fit its
tail.
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Fig. 3.
Simulation performances in time domain.
A: stimulation frequency input
function. B: simulated increase of
[NE]. C: measured HR
response (continuous line), simulated data (dashed line), and
time-delay exponential best fit of experimental data (dotted line).
Delay and time constant of exponential rise were 2.9 and 7.6 s,
respectively, and those of exponential decay were 6.1 and 19.2 s,
respectively. Inset: zoom of foot of
HR increase.
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Frequency transfer function models.
Equations 6-8 are nonlinear, and
they describe completely the response of HR and NE to sympathetic nerve
stimulation whatever the dynamic range of the input stimulation.
However, it is also interesting to analyze the behavior of the system
under stationary conditions, where input perturbations are small. This
analysis could help in understanding the mechanisms governing HR
variability, an important topic in which there was a large interest in
the last decade (18). We used the transfer function approach to analyze
the input vs. output relationships in the frequency domain, since it
has been found to be a useful tool to analyze the linear dynamics of a
given system (1, 22). A band-limited Gaussian white noise was used to
simulate small sympathetic input perturbations. We simulated two types
of input perturbations: 1)
modulation of the nerve stimulation frequency (1) and
2) beat-to-beat modulation of
stimulatory pulse duration. In the second mode of stimulation the
sympathetic stimulatory pulses are synchronized to the heart period
(phase-coupled stimulation), and we suppose that beat-to-beat modulation of NE release is achieved by varying pulse duration (a 2-ms
pulse releases one maximal quantum of NE). Small signal noise response
simulations based on linear approximations of the mathematical model
described above (Eqs. 6-8) were
carried out for different intensities of input nerve stimulation
(operating points). Frequency transfer functions between output and
input variables were estimated using spectral analysis methods (1, 22).
The transfer function magnitude and phase corresponding to the
different input vs. output combinations, i.e., sympathetic stimulation
vs. [NE], [NE] vs. HR, and sympathetic
stimulation vs. HR, for both modes of stimulation are shown in Figs.
4 and 5 (for
simplicity, we used the mean dynamic parameters corresponding to
moderate and high stimulation intensities only). In both modes, corner
frequencies of the low-pass filter characteristics of the different
input vs. output combinations are similar. Cutoff frequencies corresponding to nerve input vs. [NE] output and
[NE] input vs. HR output were 0.017 and 0.075 Hz,
respectively. The HR response to nerve stimulation acts as a
second-order filter with a 0.7-s delay resulting from a cascade of two
low-pass filters. In the synchronized mode of stimulation the gain of
the [NE] response to nerve input increases with the
intensity of the sympathetic stimulation (Fig.
5A), whereas in the nonsynchronized
mode the gain remains constant (Fig.
4A). The increase of the gain in the synchronized mode is attributable to the fact that the accumulated [NE] increases with the HR (see Eq. A7, where the mean stimulation frequency is HR/60).
Figure 4C shows that the gain of the
HR response to variations of the stimulation frequency decreases when
the intensity of sympathetic stimulation increases. However, a close examination of the dynamic gain curve (gain vs. stimulation frequency), obtained by a frequency derivation of Eq. 5, shows biphasic characteristics (Fig.
6). The gain increases from zero, then
decreases when the stimulation frequency increases. The maximum gain is
obtained at a frequency of 0.7 Hz. In the synchronized mode of
stimulation the gain of the HR response to nerve input decreases less
rapidly when the stimulation intensity increases (Fig.
5C) because of the increasing gain
of the NE response to nerve input (Fig.
5A).
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Fig. 4.
Frequency transfer function curves: modulation of nerve stimulation
frequency. A: transfer function
magnitudes (left) and phases
(right) from nerve input to
[NE] output. B: transfer
function magnitudes (left) and
phases (right) from [NE]
input to HR output. C: transfer
function magnitudes (left) and
phases (right) from nerve input to
HR output. Parameters used in simulations were as follows: time
constant of NE removal (NE) = 9 s, HR time constant (HR) = 2.1 s, time delay (d) = 0.7 s,
stimulation frequency producing half-maximal response
(Kf) = 1.2, maximum HR increase
(HRmax) = 72; basal
HR (no stimulation) was fixed to 120 beats/min (see text for
significance of parameters). For 0.5-Hz stimulation group, curves are
not displayed for modulation frequencies >0.25 Hz to satisfy sampling
theory, which states that modulation frequency should not exceed
one-half of sampling rate.
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Fig. 6.
Calculated gain from nerve input to HR output as a function of nerve
stimulation frequency. Dashed line, position of maximum gain.
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| |
DISCUSSION |
By using an original sympathetic nerve stimulation protocol, we have
been able to propose a key mechanism of sympathetic neural control of
HR. From the analysis of HR dynamics, two components were indirectly
characterized: the first was attributed to the neurotransmitter removal
process at the presynaptic level, and the second was related to the
dynamics of the intracellular response process. To our knowledge, this
is the first attempt to quantify postsynaptic noradrenergic activity in
vivo. A surprising result was that the -adrenergic pathway responded
faster than expected to sympathetic stimulation. Maximum mean time
delay and time constant were 0.7 and 2.1 s, respectively.
Different studies on the -adrenergic regulation of
neurotransmitter-sensitive currents underlying the pacemaking activity of sinus node cells, namely, the hyperpolarized-activated current (If) and the
long-lasting calcium current
(ICa), indicate
that the major action of -adrenergic stimulation occurs via a slow cytoplasmic pathway involving adenylate cyclase and cAMP activities (3,
15, 27). However, a faster pathway involving a direct G
protein-mediated mechanism has also been demonstrated (2, 24, 29).
Yatani and Brown (29) reported that the mean time constants of the
ICa-fast and
ICa-slow pathways
were 150 ms and 36 s, respectively. In another study, the same authors
reported a mean time constant of 570 ms of the
If-fast pathway
(30). In an effort to investigate the
If-slow pathway
mechanisms, DiFrancesco and Tortora (7) revealed that, in contrast to
the ICa,
If activation by
cAMP involves a direct, phosphorylation-independent interaction with
the ionic channels. They found that the action of cAMP on If induced a
relatively fast response (<5 s). The mean time constant of the
-adrenergic response obtained in this study fits well within the
range of the reported time constants of
If-fast and If-slow pathways.
Moreover, because the -adrenergic response was faster at lower
intensities of sympathetic stimulation than at higher intensities, it
is possible that low -adrenergic stimulation intensities favor the
fast cellular pathway, whereas higher intensities favor the slow
pathway. Other proofs of the existence of two different adrenergic
pathways have been reported by Choate et al. (5). Their conclusion was
based on the observation that two distinct components were involved in
the generation of pacemaker action potential during sympathetic nerve
stimulation.
It has been demonstrated that the cellular muscarinic-cholinergic
signaling activity exhibits similar dual-pathway characteristics (2).
In their analysis of the HR response to synchronized vagal stimulation,
Mokrane et al. (22) speculated that the slow component of the vagally
induced HR response could be related to the slow cholinergic pathway.
Interestingly, the time constant of the slow component of the vagally
induced HR response (2.5 s) is close to the time constant of the
-adrenergic-related component of HR revealed in this study.
It has been observed that sympathetic nerve discharge patterns can be
highly irregular (13, 17, 20). Generally, nerve impulses are grouped in
short bursts separated by long silent periods. Intraburst instantaneous
frequency can be as high as 50 Hz, although the average nerve discharge
frequency rarely exceeds 3 Hz under basal conditions (20). It has been
suggested that this physiological erratic pattern may play a critical
role in vasoconstriction activity (23). Our results favor the view that the sympathetic system is fast enough to respond to high-frequency burstlike sympathetic nerve traffic.
Another important finding of this work is the fact that the
concentration-response relationship of NE-induced HR increase was
characterized by a sigmoidal-type function with a Hill factor of 2, suggesting a positive cooperative agonist-receptor coupling process
(2:1 binding).
It is well established that the neural reuptake
(uptake 1) is the major process for
removing NE within the neuroeffector junction (8, 12). Between 70 and
95% of the NE released by cardiac sympathetic nerves is recaptured.
The remaining NE is metabolized in surrounding extraneural tissues
(uptake 2) (10, 16) and diffused
into the bloodstream. Because of the difficulties inherent in the
estimation of [NE] within the synaptic clefts, few data are
available on the time constants of NE elimination. We report the study
of Cousineau et al. (6), in which a complex kinetics model was used in
in vivo tracer NE dilution experiments. Their estimated mean time
constants for neural reuptake of NE and NE diffusion through the
capillaries were 2.5 and 14 s, respectively. On the basis of these
observations, one can speculate that the time constant of 9 s for NE
dissipation obtained in this study probably reflects the kinetics of
the neural reuptake process.
From the estimated parameters of NE and -adrenergic kinetics, we
have developed a mathematical model and carried out simulations to test
its validity. The model reproduced remarkably well the HR increase
induced by a constant sympathetic nerve stimulation frequency, although
in some cases the simulated rise was slightly faster. It is possible
that in these cases the time constant of NE removal was underestimated.
The model supports also the observation that the time delay of the HR
decay after cessation of sympathetic nerve stimulation increases with
the intensity of the stimulation (28) (these observations were also
confirmed in this study). This characteristic is attributable to the
saturation of the HR vs. [NE] response curve at high
intensities of stimulation. Unfortunately, the model failed to
reproduce the tail of the HR decay and tended to overestimate the
decline rate, although the simulated curve fitted well the first half
of HR decay. The slow decline observed in the terminal downslope of the
experimental data could be attributed to a diminished efficiency of NE
reuptake by the nerve endings (uptake
1). It is possible that when the release of NE stops, NE will diffuse away from the surface of the nerve endings into surrounding tissues, favoring gradually the slower NE dissipation system (uptake 2). An intracellular
mechanism can also be a factor of the slow HR decline. For example, the
recovery process of the adrenergic system could be slower than the
initiation process.
Simulated frequency transfer function magnitudes and phases between HR
output variations and fluctuations of the sympathetic nerve stimulation
frequency matched those obtained experimentally by Berger et al. (1).
However, a new dimension has been added in this study to the
interpretation of the transfer function curves: what was considered a
low-pass filter with a cutoff frequency between 0.01 and 0.02 Hz with a
1.7-s delay is, in fact, a cascade of two low-pass filters with cutoff
frequencies of 0.017 and 0.075 Hz (0.13 Hz at low sympathetic tones)
coupled to a 0.7-s delay (0.4 s at low sympathetic tones). On the basis
of the observation that sympathetic nerve discharges exhibit
predominantly a cardiac-related rhythm (4, 26), a synchronized mode of
input nerve stimulation was considered. Basically, the filter
characteristics of the HR response in this mode were comparable to
those in the nonsynchronized mode, confirming the hypothesis that,
under stationary conditions, the sympathetic system is unable to
modulate HR on a beat-to-beat basis and that the slow NE kinetics are
the main cause of this behavior (19). Our results support also the
finding that the 0.1-Hz baroreflex-related HR oscillations observed in
humans and some animals are not mediated by the sympathetic system
(18).
In conclusion, it is important to underline that even if the
sympathetic system plays a minor role in short-term regulation of HR
under stationary environments, it is fast enough to react within a few
seconds to emergency situations such as an acute fall of arterial blood
pressure and intense physical or emotional stress. The physiological
significance of this response remains to be established, inasmuch as it
represents a departure from the traditional role generally attributed
to the sympathetic system.
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APPENDIX |
Determination of the mean steady-state [NE] obtained
during constant sympathetic nerve stimulation frequency.
Given the time occurrences
(ti) of
stimulation pulses, [NE] at time
ti
{[NE](ti)}
is related to [NE] at time
ti 
1 {[NE](ti 1)}
by the recurrence equation
 = <IT>q</IT> + [NE](<IT>t</IT><SUB><IT>i</IT> − 1</SUB>)<IT>e</IT><SUP>−&agr;<SUB>NE</SUB> <IT>T</IT></SUP>](/content/vol275/issue3/fulltext/H995/img010.gif)
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(A1)
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with
 = <IT>q</IT>](/content/vol275/issue3/fulltext/H995/img011.gif)
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(A2)
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where
T is the time period between two
successive pulses,
t0 is the time
occurrence of the first impulse, q is
the [NE] quantum released by one pulse, and
NE is the NE elimination rate.
Combining Eqs. A1 and A2, we obtain the geometric series
 = <IT>q</IT>(1 + <IT>e</IT><SUP>−&agr;<SUB>NE</SUB><IT>T</IT></SUP> + <IT>e</IT><SUP>−2&agr;<SUB>NE</SUB><IT>T</IT></SUP> + … + <IT>e</IT><SUP>−<IT>i</IT>&agr;<SUB>NE</SUB><IT>T</IT></SUP>)](/content/vol275/issue3/fulltext/H995/img012.gif)
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(A3)
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From
Eq. A3 it can be shown that
 = <IT>q</IT> <FR><NU>1 − <IT>e</IT><SUP>−(<IT>i</IT> + 1)&agr;<SUB>NE</SUB><IT>T</IT></SUP></NU><DE>1 − <IT>e</IT><SUP>−&agr;<SUB>NE</SUB><IT>T</IT></SUP></DE></FR>](/content/vol275/issue3/fulltext/H995/img013.gif)
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(A4)
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[NE](ti)
at the steady state (i tends to
infinity) is then
 = <FR><NU><IT>q</IT></NU><DE>1 − <IT>e</IT><SUP>−&agr;<SUB>NE</SUB><IT>T</IT></SUP></DE></FR>](/content/vol275/issue3/fulltext/H995/img014.gif)
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(A5)
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At
time t between
ti 1
and ti,
[NE](t) is given by
 = <FR><NU><IT>qe</IT><SUP>−&agr;<SUB>NE</SUB>(<IT>t</IT> − <IT>t</IT><SUB><IT>i</IT> − 1</SUB>)</SUP></NU><DE>1 − <IT>e</IT><SUP>−&agr;<SUB>NE</SUB><IT>T</IT></SUP></DE></FR>](/content/vol275/issue3/fulltext/H995/img015.gif)
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(A6)
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The
mean [NE] over one period
T is then
![[NE] = <FR><NU><IT>q</IT></NU><DE>1 − <IT>e</IT><SUP>−&agr;<SUB>NE</SUB><IT>T</IT></SUP></DE></FR> <FR><NU>1</NU><DE><IT>T</IT></DE></FR> <LIM><OP>∫</OP><LL><IT>t</IT><SUB><IT>i</IT> − 1</SUB></LL><UL><IT>t</IT><SUB><IT>i</IT></SUB></UL></LIM> <IT>e</IT><SUP>−&agr;<SUB>NE</SUB>(<IT>t</IT> − <IT>t</IT><SUB><IT>i</IT></SUB>)</SUP> = <FR><NU><IT>q</IT></NU><DE>&agr;<SUB>NE</SUB><IT>T</IT></DE></FR> = <IT>q</IT>&tgr;<SUB>NE</SUB><IT>f</IT>](/content/vol275/issue3/fulltext/H995/img016.gif)
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(A7)
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where
NE is the time constant of NE
dissipation and f is the stimulation
frequency.
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ACKNOWLEDGEMENTS |
We are grateful to Pierre Fortier and Caroline Bouchard for
excellent assistance in the experimental settings.
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FOOTNOTES |
This work has been supported by the Medical Research Council of Canada.
R. Nadeau is a Career Investigator of the Medical Research Council of
Canada.
Address for reprint requests: R. Nadeau, Research Center, Hôpital
du Sacré-Coeur, Montreal, PQ, Canada H4J 1C5.
Received 13 August 1997; accepted in final form 11 May 1998.
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Abstract
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