Vol. 274, Issue 2, H456-H466, February 1998
Lack of beneficial effects of growth hormone treatment in
conscious dogs during development of heart failure
You-Tang
Shen,
R. F.
Woltmann,
S.
Appleby,
S.
Prahalada,
S. M.
Krause,
S. D.
Kivilghn,
R. G.
Johnson,
P. K.
Siegl, and
J. J.
Lynch
Departments of Pharmacology and Safety Assessment, Merck Research
Laboratories, West Point, Pennsylvania 19486
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ABSTRACT |
The effects of chronic treatment with growth
hormone (porcine GH, 0.56 mg · kg
1 · day1
sc) were examined in dogs with heart failure induced by rapid ventricular pacing (240 beats/min) for 4 wk. Fourteen conscious dogs
were studied 2-3 wk after surgical instrumentation with catheters in the descending aorta and left atrium, a pressure gauge in the left
ventricle (LV), a flow probe around the ascending aorta, pacing leads
on the ventricular free wall and left atrium, and ultrasonic crystals
on the opposing anterior and posterior endomyocardium of the LV. GH
treatment for 4 wk significantly increased both body weight and plasma
insulin-like growth factor 1 (IGF-1) compared with vehicle-treated dogs
(P < 0.01, +2.0 ± 0.5 vs. +0.3 ± 1.1 kg; 1,043 ± 218 vs. 241 ± 64 ng/ml, respectively).
However, the changes in resting LV systolic (i.e., both isovolumic and
ejection phases) and diastolic function (i.e., isovolumic relaxation
time constant 
) and the systemic vascular resistance were similar for the GH- and vehicle-treated groups during the development of heart
failure. LV contractile reserve, assessed with step infusion of
isoproterenol or dobutamine challenge, was markedly attenuated after
heart failure, but there were no differences between the GH- and
vehicle-treated groups. During the progression of heart failure, the
increases in plasma atrial natriuretic peptide correlated (P < 0.01) directly with left atrial
pressure and inversely with LV circumferential fiber shortening.
However, GH treatment did not substantially modify these relationships.
In addition, renal function and myocardial ultrastructure at the
advanced stage of heart failure also showed similar changes for the GH-
and vehicle-treated groups. We conclude that in conscious dogs during
the development of congestive heart failure produced by rapid
ventricular pacing, GH at a dose that increases body weight and plasma
IGF-1 levels does not affect LV performance or systemic vascular
dynamics.
insulin-like growth factor 1; left ventricular dysfunction; renal
function; myocardial contractile reserve; atrial natriuretic peptide
| |
INTRODUCTION |
ALTHOUGH A RECENT preliminary study has suggested that
growth hormone (GH) may improve hemodynamics in patients with
idiopathic dilated cardiomyopathy (1), it remains unclear whether GH
plays an important role in the experimental setting of heart failure. Several studies have reported that GH or insulin-like growth factor 1 (IGF-1) treatment enhances left ventricular (LV) performance in rats
with myocardial dysfunction induced by myocardial infarction (4, 5,
22). However, the data reported in those previous studies, particularly
regarding the changes in myocardial contractility, LV end-diastolic
pressure, ejection fraction, and cardiac index, were inconsistent among
the studies (4, 5, 22). Also, our recent study using hypophysectomized
and intact rats with moderate-to-large myocardial infarcts demonstrated
that neither GH replacement nor excess GH treatment significantly
affected myocardial function (20). Because of the limitations of the rat infarction model, including the lack of direct measurement of
cardiac and systemic hemodynamics during the progression of myocardial
dysfunction and the significant influence of anesthesia or recent
surgery on hemodynamic measurements, it is difficult to reconcile the
contradictory findings.
Accordingly, the primary goal of the present investigation was to use a
rapid ventricular pacing-induced heart failure model in chronically
instrumented, conscious dogs to determine whether chronic GH treatment
affected resting cardiac and systemic vascular function during the
development of heart failure and when severe heart failure was
manifested. A second goal was to determine whether GH treatment could
prevent the diminished LV contractile reserve, as assessed by inotropic
response to 
-adrenergic receptor stimulation, that occurs during
heart failure (10, 14, 15). The final goal of the study was to
determine whether GH treatment affected myocardial morphological
changes or renal function during the late stages of heart failure.
| |
METHODS |
Animal preparation.
Fourteen adult mongrel dogs, weighing 18.4 ± 0.4 kg, were
anesthetized with thiopental sodium (12-15 mg/kg iv).
After tracheal intubation and ventilation with a ventilator (North
American Dräger, Telford, PA), isoflurane anesthesia
(1.0-2.0 vol% in oxygen) was maintained during surgery. With
sterile technique, a left thoracotomy was performed at the fifth
intercostal space. Tygon catheters (Norton Plastics, Akron, OH) were
implanted in the descending aorta and left atrium for measurement of
their respective pressures. A solid-state miniature pressure gauge
(Konigsberg Instruments, Pasadena, CA) was implanted in the LV cavity
through the apex for high-fidelity measurements of LV pressure and rate
of change of LV pressure (LV dP/dt).
A flow probe (Transonic Systems, Ithaca, NY) was placed on the
ascending aorta to measure aortic blood flow. One pair of piezoelectric
ultrasonic dimension crystals was implanted on opposing anterior and
posterior endocardial surfaces of the LV to measure LV internal
diameter. Proper alignment of the crystals was achieved during surgical
implantation by positioning the crystals so as to obtain a signal with
the greatest amplitude and shortest transit time. A pacing lead
(Medtronic, Minneapolis, MN) was attached to the right
ventricular free wall. Additionally, stainless steel pacing
leads were attached to the left atrial appendage. The pericardium was
left open. Catheters and leads were externalized between the scapulae,
and the thoracotomy was closed in layers. An additional two dogs not
surgically instrumented or subjected to rapid pacing-induced heart
failure served as controls for histological studies. The dogs used in
this study were maintained in accordance with the National Institutes
of Health (NIH) Guide for the Care and Use of
Laboratory Animals [DHHS Publication No. (NIH)
85-23, Revised 1985], and the studies were
approved by the Merck Research Laboratories (West Point, PA)
Institutional Animal Care and Use Committee.
Physiological studies.
Hemodynamic recordings were made using a data tape recorder (TEAC,
Montebello, CA) and a multiple-channel oscillograph (Gould, Cleveland,
OH). Aortic and left atrial pressures were measured using strain-gauge
manometers (Argon, Athens, TX), which were previously calibrated using
a mercury manometer, connected to the fluid-filled catheters. The
solid-state LV pressure gauge was cross-calibrated with aortic and left
atrial pressure measurements. LV dP/dt
was obtained by electronically differentiating the LV pressure signal
with a frequency response of 700 Hz. A triangular wave signal was
substituted for the pressure signals to directly calibrate the
differentiator (Triton Technology, San Diego, CA). Aortic blood flow
was measured using a volume flowmeter (Transonic Systems). Mean
arterial pressure, left atrial pressure, and ascending aortic blood
flow (cardiac output) were measured using an amplifier filter. Stroke
volume was calculated as the quotient of cardiac output and heart rate.
Cardiac output was normalized by body weight to yield cardiac index. LV
dimension was measured with an ultrasonic transit-time dimension gauge
(Triton Technology). Total peripheral resistance was calculated as the
quotient of mean arterial pressure and cardiac output. LV end-diastolic
dimension (EDD) was measured at the beginning of the upstroke of the LV
dP/dt signal. LV end-systolic dimension (ESD) was defined as the point of maximum negative
dP/dt. The percent shortening of LV
internal diameter was calculated as [(EDD 
ESD)/EDD] × 100. Mean velocity of LV circumferential fiber
shortening corrected for heart rate
(Vcfc) was
calculated as [(EDD ESD)/EDD]/(ET/
), where ET and R-R denote
ejection time and R-R interval (in s), respectively. Ejection time was
measured as the interval between maximum and minimum LV
dP/dt. The LV isovolumetric relaxation
time constant () was calculated beat by beat, on-line, from the
minimum value of the time derivative of the LV pressure signal (LV
dP/dtmax) to 36% of LV
dP/dtmax
(Modular Instruments, Malvern, PA) (12). A cardiotachometer triggered
by the LV pressure pulse provided instantaneous and continuous records
of heart rate.
Experiments were initiated 2 wk after recovery from surgical
instrumentation, while the dogs were fully awake and lying quietly on
their left side. Hemodynamics were recorded in 14 dogs at baseline (before initiation of pacing), and arterial blood samples were taken
for the measurement of plasma levels of IGF-1, ANP, and renal function.
After baseline hemodynamics were recorded and blood samples taken,
inotropic responses to -adrenergic receptor stimulation were
assessed. Five-minute intravenous infusions of each dose of
isoproterenol (0.05, 0.1, 0.2, and 0.4 µg · kg1 · min1)
and dobutamine (2.5, 5.0, 7.5, and 10.0 µg · kg1 · min1)
were performed. After baseline experiments, rapid right ventricular pacing at a rate of 240 beats/min was initiated using a programmable pacemaker (Medtronic). Dogs were treated subcutaneously with either porcine GH (Harbor UCLA Research & Education Institute, Torrance, CA)
at a dose of 0.56 mg/kg (n = 7) or
vehicle (30 mM NaHCO3 and 150 mM
NaCl, pH 7.5) (n = 7) once daily for 4 wk. The dose of GH selected in the present study was based on our
previous studies with GH in normal dogs (16). Hemodynamic states and
inotropic responses to isoproterenol and dobutamine were reassessed
weekly for 4 wk after initiation of pacing when heart failure was
evident. Body weights and blood samples also were taken weekly. Before studies were initiated and completed, the dogs were placed in a
metabolic cage for 24 h to collect urine for measurement of electrolytes and protein excretion.
After the final hemodynamic measurement, i.e., after 4 wk of pacing,
the dogs were euthanized with pentobarbital sodium (30-50 mg/kg
iv). LV tissue was taken for histological analysis. Body weight was
measured before and after the abdominal fluid was removed, because
during the late stages of congestive heart failure significant ascites
is often evident.
Biochemical and morphological analysis.
Plasma and urine electrolyte concentrations were measured by
ion-selective electrode methodology (Beckman Synchro Elise). Urine
protein concentration was measured by the Coomassie blue technique.
Blood urea nitrogen (BUN) levels were measured with an automated blood
analyzer (Gem Profiler: Schiapparelli Biosystems, Fairfield, NJ).
Plasma ANP levels were measured by standard radioimmunoassay (American
Laboratory Products, Windham, NH). Plasma IGF-1 levels were assessed by a previously described method (3). A total of eight
hearts (3 vehicle-treated failure dogs, 3 GH-treated failure dogs, and
2 normal dogs) were perfused with saline followed by a 4%
formaldehyde-2% glutaraldehyde solution. The fixed tissues were
processed for light and transmission electron microscopic evaluation.
Data analysis.
Data before and after development of heart failure, and responses to
inotropic challenge were compared using the Student's t-test for paired data with a
Bonferroni correction. Data between the GH-treated and vehicle-treated
groups were compared using unpaired Student's
t-test. Analysis by two variable
linear regression and by multiple linear regression was used to compare
plasma ANP with left atrial pressure and LV
Vcfc.
All values are expressed as means ± SE. Statistical significance
was accepted at the P < 0.05 level.
| |
RESULTS |
Effects of GH on body weight and plasma level of IGF-1.
The baseline values of body weight, i.e., before the
initiation of treatment and rapid ventricular pacing, were 18.7 ± 0.6 and 18.0 ± 0.6 kg in the vehicle-treated and GH-treated groups, respectively. The changes in body weight after 2, 3, and 4 wk of pacing
were significantly (P < 0.05)
greater in the GH-treated group than in the vehicle-treated group (Fig.
1). After 4 wk of pacing, the body weight
significantly (P < 0.05) increased
to 21.1 ± 0.7 kg in the GH-treated group, whereas in the
vehicle-treated group, body weight was 19.2 ± 1.1 kg. Because body
weight can be affected by ascites at the late stage of heart failure,
body weight also was measured after removing the abdominal fluid at the
final experiment, i.e., after 4 wk of pacing. Under this condition, body weight still was significantly (P < 0.01) increased by 2.0 ± 0.5 from 20.0 ± 0.6 kg in the
GH-treated group and was significantly (P < 0.05) greater than the
vehicle-treated group, in which the body weight was decreased by
0.3 ± 1.1 from 18.4 ± 1.0 kg.
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Fig. 1.
A: plasma levels of insulin-like
growth factor 1 (IGF-1) at baseline (C) and after 1-4 wk of rapid
ventricular pacing in growth hormone (GH)- and vehicle-treated dogs.
B: effects of GH on body weight in
conscious dogs during the development of heart failure. Data are
changes from baseline (i.e., before initiation of treatment and rapid
ventricular pacing).
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Plasma levels of IGF-1 were similar for the vehicle-treated (298 ± 38 ng/ml) and GH-treated (294 ± 23 ng/ml) groups before initiation
of treatment and rapid ventricular pacing. GH treatment resulted in a
significant (P < 0.05) elevation of
plasma IGF-1 level after 1 wk (781 ± 80 ng/ml). After 3 wk, the
plasma level of IGF-1 was significantly
(P < 0.05) elevated by approximately threefold in the GH-treated (1,089 ± 169 ng/ml) compared with the
vehicle-treated (265 ± 51 ng/ml) groups (Fig. 1).
Effects of GH on basal hemodynamics before and after heart failure
development.
Figure 2 shows representative waveforms
from vehicle-treated and GH-treated conscious dogs before and after the
development of heart failure. Note that in the vehicle-treated dog, LV
dP/dt was decreased, whereas mean left
atrial pressure, LV dimension, and heart rate were increased after
heart failure (Fig. 2, left). However, similar changes in these parameters also were observed in the
GH-treated dog (Fig. 2, right).
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Fig. 2.
Representative waveforms of left ventricular (LV) pressure, rate of
change of LV pressure (LV dP/dt),
aortic pressure, left atrial pressure, LV short axis diameter, and
heart rate from a conscious dog treated with vehicle
(left) and from a conscious dog
treated with GH (right) before and
after heart failure. Note that after heart failure, LV
dP/dt decreased, whereas left atrial
pressure, LV diameter, and heart rate markedly increased in both dogs.
bpm, Beats/min.
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Basal systemic hemodynamics and LV function in the GH-treated and
vehicle-treated groups at baseline and 2 and 4 wk after initiation of
treatment and rapid ventricular pacing are shown in Tables
1 and 2. During the
development of heart failure, LV
dP/dt, stroke volume,
cardiac index, LV fractional shortening, and
Vcfc were
significantly decreased, whereas mean left atrial pressure, LV
end-diastolic diameter, and heart rate were significantly increased.
After 4 wk of pacing, total peripheral resistance was elevated in both
groups but did not reach statistical significance in the
vehicle-treated group. The change in both groups, however, was almost
identical (vehicle: +0.24 ± 0.08 from 0.77 ± 0.07 mmHg · ml1 · min · kg;
GH: +0.25 ± 0.04 from 0.66 ± 0.06 mmHg · ml1 · min · kg).
After the development of heart failure, was significantly (P < 0.05) increased to 47.8 ± 4.5 and 47.9 ± 2.1 ms from the baseline levels of 32.2 ± 1.2 and 30.6 ± 2.2 ms in the vehicle- and GH-treated groups,
respectively. Figures 3 and
4 compare the progressive changes in hemodynamic
measurements between the two groups during the development of heart
failure.
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Fig. 3.
Effects of GH on resting systemic hemodynamics in conscious dogs during
the development of heart failure. Values are %changes from baseline
(C) levels. After 4 wk of rapid ventricular pacing, left atrial
pressure, total peripheral resistance, and heart rate increased,
whereas cardiac index and stroke volume index decreased. There were no
differences in any of these parameters between the GH- and
vehicle-treated groups.
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Fig. 4.
Effects of GH on resting LV function in conscious dogs during the
development of heart failure. Values are %changes from baseline (C)
levels. After 4 wk of rapid ventricular pacing, LV systolic pressure,
LV dP/dt, LV fractional shortening,
and LV velocity of circumferential fiber shortening corrected for heart
rate (Vcfc)
decreased, whereas LV end-diastolic and end-systolic diameters
increased. There were no differences in any of these parameters between
the GH- and vehicle-treated groups.
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Effects of GH on inotropic response to -adrenergic
receptor challenge.
The basal hemodynamics and response to isoproterenol (0.2 µg · kg1 · min1)
before and after 2 and 4 wk of pacing in the GH- and vehicle-treated groups are shown in Table 3. After 2 and 4 wk of pacing, LV dP/dt and heart rate
responses to isoproterenol were markedly attenuated compared with
control, i.e., before heart failure. However, the changes in LV
systolic pressure, LV dP/dt, mean
arterial pressure, mean atrial pressure, LV end-diastolic diameter, and
heart rate induced by isoproterenol were similar in the two treatment
groups. Figure 5 shows the dose-response
effects of isoproterenol on LV dP/dt
after 3 wk of pacing in the GH- and vehicle-treated groups. Clearly,
isoproterenol elicited similar inotropic responses in these two groups
at each dose.
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Table 3.
Effects of systemic isoproterenol infusion on LV function in conscious
dogs before and during heart failure
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Fig. 5.
Dose-dependent effects of isoproterenol on LV
dP/dt in GH- and vehicle-treated
conscious dogs at baseline (control) and after 3 wk of pacing. Values
are %changes from baseline levels. After heart failure, LV
dP/dt responses to isoproterenol were
attenuated compared with control. However, there was no difference
between these two groups.
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The effects of dobutamine (10 µg · kg1 · min1)
on hemodynamics in the GH- and vehicle-treated groups before and after
2 and 4 wk of pacing are shown in Table 4.
Dobutamine increased LV dP/dt
significantly but did not markedly change mean arterial pressure, mean
left atrial pressure, LV end-diastolic diameter, or heart rate compared
with those observed with isoproterenol. However, the increased LV
dP/dt induced by dobutamine was
attenuated after heart failure compared with control, i.e., before
heart failure. The patterns of changes in LV
dP/dt were similar for these two
groups. The LV dP/dt responses to each
dose of dobutamine at control and after 2, 3, and 4 wk of pacing in the
GH- and vehicle-treated groups are presented in Fig.
6.
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Table 4.
Effects of systemic dobutamine infusion on LV function in conscious
dogs before and during heart failure
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Fig. 6.
Dose-dependent effects of dobutamine on LV
dP/dt in GH-treated
(A) and vehicle-treated conscious
dogs (B) at baseline (control) and
after 2, 3, and 4 wk of pacing. Values are %changes from baseline
levels. After heart failure, LV dP/dt
responses to dobutamine were attenuated compared with control. However,
there was no difference between these 2 groups.
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Effects of GH on plasma ANP and renal function.
The relationships between the plasma level of ANP and left atrial
pressure or LV
Vcfc during the
development of heart failure are shown in Fig.
7. The release of ANP correlated with the
level of left atrial pressure and
Vcfc. The
correlation coefficient was significant
(P < 0.01) for all groups studied.
GH treatment did not significantly modify these relationships.
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Fig. 7.
Relationships between plasma atrial natriuretic peptide (ANP) levels
and left atrial (LA) pressure (A)
and LV Vcfc
(B) in conscious dogs before and during heart failure. Data
are absolute values. Both LA pressure and LV
Vcfc were
correlated with plasma ANP level. However, slopes for the GH-treated
dogs (dotted line) were similar to those for the vehicle-treated dogs
(solid line).
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Plasma Na+, creatinine, glomerular
filtration rate (GFR), blood urea nitrogen (BUN), urine volume, and
urine Na+ excretion are shown in
Table 5. BUN and GFR increased similarly after heart failure in both groups, but these increases were not statistically significant. There were no significant differences in any
of the other plasma or urine chemistry measurements between the
baseline and after heart failure, and no marked differences in these
parameters between the GH- and vehicle-treated groups.
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Table 5.
Effects of GH on plasma and urine electrolytes and renal function in
conscious dogs before and after heart failure
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Myocardial morphological evaluation.
Light microscopic evaluation of hematoxylin- and eosin-stained sections
of LV showed no apparent changes among heart failure dogs treated with
GH or vehicle, as well as control dogs without heart failure. However,
light microscopic evaluation of Epon-embedded, toluidine
blue-stained sections revealed clear cytoplasmic vacuolation in
myocardial fibers of both the GH- and vehicle-treated dogs with heart
failure. Transmission electron microscopic evaluation indicated the
presence of myocardial fibers with vacuoles filled with cytoplasmic
debris sometimes with a myelin-like structure. In addition, the Z bands
in myocardial fibers appeared slightly distorted in both the GH- and
vehicle-treated dogs with heart failure. These changes were not
observed in control dogs without heart failure. Overall, no
morphological differences between the GH- and vehicle-treated heart
failure dogs were observed. Figure 8 shows
representative transmission electron micrograph of LV myocardium from a
control dog without pacing-induced heart failure (Fig.
8A) and a GH-treated
dog with heart failure (Fig. 8B).
Note that myocardial fibers contained vacuoles filled with cytoplasmic debris and that the Z bands were distorted in the GH-treated dog compared with nonfailure control. These findings were similar to those
observed in the vehicle-treated heart failure dogs and also were
consistent with previous findings in this canine heart failure model
(11).
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Fig. 8.
Representative transmission electron micrographs of LV myocardium from
a control dog without pacing-induced heart failure
(A) and a GH-treated dog with heart
failure (B). Note that myocardial
fibers contain vacuoles filled with cytoplasmic debris and that the Z
bands were distorted in the GH-treated dog compared with nonfailure
control. These findings were similar to those observed in the
vehicle-treated heart failure dogs.
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DISCUSSION |
The present study demonstrates that GH treatment at a dose that
increases body weight and plasma IGF-1 level does not significantly improve cardiac and systemic function in conscious dogs with congestive heart failure induced by rapid ventricular pacing. This conclusion is
based on several findings: 1) the
impairment of resting LV systolic (i.e., both isovolumic and ejection
phases) and diastolic function (i.e., isovolumic relaxation time
constant ) were similar for the GH- and vehicle-treated groups
during the development of heart failure;
2) LV contractile reserve, as
assessed with -adrenergic receptor stimulation, was attenuated
similarly after heart failure for both GH- and vehicle-treated groups;
3) GH treatment did not modify the
relationships between plasma ANP release and left atrial pressure or LV
Vcfc during the
development of heart failure; and 4)
peripheral vascular resistance, renal function, and myocardial
morphology were also similar for GH-treated and vehicle-treated dogs
with heart failure.
A major concern with our conclusion was whether the dose of GH used was
sufficient to produce any impact on the heart. In the present study,
the plasma IGF-1 level was 3.5-fold higher in the GH-treated group than
in the vehicle-treated group. Also, body weight in the treated animals
was increased by 17% compared with control. These data are comparable
to those from a previous study, in which administration of IGF-1 was
shown to significantly enhance LV hypertrophy in rats (4). In addition,
our previous study also demonstrated a dose-related increase in plasma
IGF-1 levels associated with increased body weight in normal dogs (16). For example, administration of GH at a dose of 0.1 IU · kg1 · day1
increased body weight almost as much as a dose of 1 IU · kg1 · day1
(0.56 mg · kg1 · day1),
which was the dose used in the present study, further indicating that 1 IU · kg1 · day1
can be considered as a maximal dose. Therefore, the negative results of
the current study are unlikely to be related to an insufficient dose of
GH.
Although the mechanism of rapid ventricular pacing-induced heart
failure utilized in the present study is still unclear and does not
ideally mimic the process of chronic congestive heart failure that
occurs in humans, it meets many of the criteria for heart failure (19,
21). Indeed, in the present study, we observed progressive decreases in
LV dP/dt, stroke volume, LV fractional shortening, and
Vcfc, while the
isovolumetric , total peripheral resistance, left atrial pressure,
and LV end-diastolic and end-systolic diameters were increased after
multiple weeks of rapid ventricular pacing. At the final stage of
pacing, altered myocardial ultrastructure also was observed. In
addition, several prior studies have shown that rapid pacing-induced
heart failure in dogs is characterized by a blunted inotropic response
to catecholamine stimulation (14, 15), which is thought to be related
to an impairment of -adrenergic receptor signal transduction
pathways, including decreased -adrenergic receptor density,
uncoupling of -adrenergic receptors, and a defect in the adenyl
cyclase catalytic units (10, 14). In the present study, a marked
attenuation of the isoproterenol-induced increase in LV
dP/dt was observed during the
development of heart failure. Because isoproterenol stimulates both
1- and
2-adrenergic receptors, which
could indirectly affect LV dP/dt via
loading condition and heart rate, we also examined the effects of a
selective 1-adrenergic receptor
agonist, dobutamine, during the development of heart failure. Without
significantly changing the loading condition or heart rate, dobutamine
induced dose-dependent inotropic responses that were similar to those
produced by isoproterenol. Under these circumstances, we did not detect
any significant differences between the GH-treated and vehicle-treated
dogs, suggesting that GH does not play a role in preserving cardiac
function either at rest or during inotropic stimulation in heart
failure.
An additional feature of the present study involved comparing the
relationships between the plasma levels of ANP and left atrial pressure
or Vcfc, an index
reflecting LV systolic performance, during the progression of heart
failure. It is well accepted that neurohumoral activation is evident in
congestive heart failure (2, 7). ANP specifically has been shown to
have the strongest correlation with atrial stretch and LV ejection
fraction (2), because ANP is synthesized in the myocardium and released
mainly in response to increased atrial tension (9, 18). Notably, several previous studies either in patients or in animal models demonstrated that increases in plasma ANP levels correlate with the
severity of congestive heart failure (1, 8). In the current study, we
also found strong correlations between the plasma levels of ANP and
both the increases in left atrial pressure and decreases in
Vcfc during the
development of heart failure. It is conceivable that if the GH
treatment had affected cardiac dynamics, the relationship between ANP
and LV function would have been modified. However, no differences in
these relationships were observed between the GH- and vehicle-treated
groups. Additionally, we did not find any significant differences
between the GH-treated and vehicle-treated heart failure dogs. However,
our findings do not exclude the possibility that GH affects myocardial
remodeling during the development of congestive heart failure, because
the pacing-induced heart failure model used in the current study does
not exhibit significant myocardial remodeling.
Our findings in the current study appear to conflict with those
reported by other investigators using the myocardial infarction-induced LV dysfunction rat model (4, 5, 22) but are consistent with our prior
study demonstrating that neither GH replacement in hypophysectomized
rats nor excess GH treatment in intact rats with myocardial infarction
improved LV function (20). Although it is difficult to reconcile the
controversies due to the major differences among the species, heart
failure models, and methods used, it is noteworthy that significant
inconsistencies in hemodynamic effects with GH were evident in previous
studies utilizing the rat myocardial infarction model (4, 5, 22). Yang
et al. (22) reported that treatment with GH resulted in a marked
increase in myocardial contractility, as reflected by an increase in LV dP/dt and decrease in LV end-diastolic
pressure in rats with myocardial infarction. However, Duerr et al. (5)
found no difference in LV dP/dt or LV
end-diastolic pressure between IGF-1 combined with GH-treated and vehicle-treated rats with myocardial
infarction. In addition, an earlier study by Duerr et al. (4) reported significant relationships among LV ejection fraction, infarct size, and
treatment, with a trend for ejection fraction to be higher in treated
rats with larger infarcts, which led them to conclude that IGF-1
enhances LV function in heart failure. More recently, Duerr et al. (5)
reported that there was only a significant interaction for cardiac
index, but not for ejection fraction, between treatment and infarct
size. A preliminary study in patients with dilated cardiomyopathy
reported that GH treatment increased myocardial mass and improved
cardiac hemodynamics (6). Because the treatment protocols in the
preceding clinical study and in the present experimental study differ
significantly, it is difficult to compare our data with those findings.
In addition, the preceding clinical report was based on experience with
seven treated patients without a control group (6). The ultimate
therapeutic utility of GH treatment in specific subsets of heart
failure patients should be addressed by more rigorous clinical
trials (13).
To explore the potential effects of GH on other aspects of congestive
heart failure, we examined renal function by measuring plasma and urine
samples. The results indicate that there was a similar tendency for GFR
and BUN to increase compared with baseline, i.e., before heart failure,
for the GH-treated and vehicle-treated groups. However, the changes
were not statistically significant, indicating that
despite significant ventricular dysfunction, renal function was
preserved in this model, a finding similar to data published
previously (17).
In summary, GH treatment at a dose that increases body weight and
plasma IGF-1 level does not significantly affect cardiac or systemic
vascular dynamics during the progression of congestive heart failure in
conscious dogs. However, it should be noted that because the pacing
induced-heart failure model used in the current study yields severe
failure within a relatively short period of time and the underlying
mechanism of this model may also differ from human congestive heart
failure, the potential beneficial effects of GH treatment, particularly
on a chronic basis, in patients with heart failure cannot be excluded.
| |
ACKNOWLEDGEMENTS |
We thank R. Ranaei, K. E. Lodge, and I. T. Rogers for technical
support and animal care.
| |
FOOTNOTES |
Address for reprint requests: Y.-T. Shen, Dept. of Pharmacology, Merck
Research Laboratories, WP44-B122, West Point, PA 19486.
Received 27 May 1997; accepted in final form 7 October 1997.
| |
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Abstract
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