Department of Pharmacological and Physiological Science, St. Louis
University School of Medicine, St. Louis, Missouri
Several agents may treat cocaine addiction and toxicity including
bromocriptine, desipramine, GBR 12909 [1-(2-(bis(4-fluorphenyl)-methoxy)-ethyl)-4-(3-phenyl-propyl)piperazine], diazepam, buprenorphine and dizocilpine. In this study, we sought to
determine whether these specific therapeutic agents alter
cardiovascular responses to cocaine in conscious rats. Arterial
pressure responses to cocaine (5 mg/kg, i.v.) were similar in all rats
whereas cardiac output responses varied widely. In 26 of 33 rats (named
vascular responders), cocaine induced a decrease in cardiac output of
8% or more. The remaining rats with little change or an increase in
cardiac output were classified as mixed responders. Pretreatment with
bromocriptine (0.1 mg/kg) or desipramine (1 mg/kg) increased cardiac
output in mixed responders and increased systemic vascular resistance
in vascular responders similar to the differential effects noted with
cocaine. GBR 12909 (0.5-10 mg/kg) elicited a decrease in cardiac
output at higher doses. Diazepam (0.1 and 0.5 mg/kg) had small,
short-lasting effects on cardiovascular parameters. Buprenorphine (0.3 mg/kg) or the NMDA (N-methyl-D-aspartic acid) receptor
antagonist, dizocilpine (0.05 mg/kg), increased arterial pressure,
heart rate and cardiac output in vascular responders. Bromocriptine and
desipramine prevented the difference in cardiac output responses in
vascular and mixed responders by reducing the cocaine-induced decrease
in cardiac output in vascular responders. Pretreatment with GBR 12909 (1 mg/kg) had little effect on cardiovascular responses to cocaine
except to depress the increase in cardiac output noted in mixed
responders. Buprenorphine selectively enhanced the increase in systemic
vascular resistance whereas dizocilpine enhanced the pressor response.
These data suggest that several treatment regimens for cocaine
addiction alter the cardiovascular responses to cocaine and that
dopamine D2 receptor activation may be necessary for the
decrease in cardiac output noted in vascular responders.
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Introduction |
Cocaine
is a highly addictive agent that has been associated with myocardial
ischemia, infarction and arrhythmias, sudden cardiac death and
cardiomyopathies (for review see Minor et al., 1991
).
Several agents have been proposed as possible treatments for cocaine
addiction and/or toxicity (Witkin, 1994). These include other reuptake
blockers such as desipramine (Gawin and Kleber, 1984; Tennant and
Rawson, 1983) and GBR 12909 (Rothman and Glowa, 1995; Rothman et
al., 1989, 1991), dopamine agonists such as bromocriptine (Dackis
and Gold, 1985; Hubner and Koob, 1990) and the mixed opiate agonist-antagonist, buprenorphine (Mello et al., 1989). In
addition, several agents have been suggested to reduce toxicity to
cocaine including the benzodiazepine, diazepam (Catravas and Waters,
1981; Derlet and Albertson, 1990), buprenorphine (Shukla et
al., 1991; Witkin et al., 1991) and the NMDA receptor
antagonist, MK-801 (Derlet and Albertson, 1990; Rockhold et
al., 1991).
The mechanisms by which these agents act on the central nervous system
and on behavior have been investigated by many laboratories. In
contrast, the effects of these agents alone or in combination with
cocaine on cardiovascular function are poorly understood. For example,
bromocriptine and buprenorphine have been reported to produce modest
decreases in arterial pressure in humans (Preston et al.,
1992; Scott et al., 1980) whereas desipramine does not change arterial pressure in rabbits (Dorward et al., 1991).
MK-801 has little effect in anesthetized dogs (Hageman and Simor, 1993) but increases arterial pressure and heart rate in conscious rats (Lewis
et al., 1989). Because most data available are limited to
studies of arterial pressure or heart rate, our study was conducted to
better characterize the hemodynamic responses to these agents and their
response profiles in combination with cocaine.
Understanding the interactions between cocaine and proposed treatments
is important for several reasons. First, treatments for addiction
should be examined for possible interactions with cocaine due to the
high rate of recidivism among cocaine users. Noncompliant patients may
experience additive or synergistic effects because many proposed
treatments mimic the neurochemical effects of cocaine to reduce
sensitivity to the cocaine-induced euphoria. This may result in
enhanced predisposition to cardiovascular toxicity. Second, a better
understanding of the actions of these agents on cocaine-induced
responses may help to elucidate the mechanisms by which cocaine causes
cardiovascular responses and toxicity. This may contribute to better
design of treatments for addiction that may also reduce toxicity. Our
experiment was designed to examine these interactions using doses of
proposed treatments for addiction that were both clinically relevant
and had minimal effects alone on hemodynamic variables.
It is known that individuals vary widely in their sensitivity to
cocaine-induced coronary vasoconstriction (Lange et al., 1989), myocardial ischemia (Isner et al., 1986; Minor
et al., 1991), cardiomyopathies (Minor et al.,
1991) and mortality (Mittleman and Wetli, 1987; Smart and Anglin,
1987). These observations suggest that some individuals are at greater
risk for severe cocaine-induced cardiovascular complications. We have
proposed that the rat may provide a model to determine the causes of
differential cardiovascular sensitivity and toxicity to cocaine (Branch
and Knuepfer, 1993; Knuepfer et al., 1993a). We reported
that in some but not all rats cocaine administration elicited a clear
decrease in cardiac output and a substantial (>80%) increase in
systemic vascular resistance whereas in the remaining rats cocaine
elicited consistently little change or an increase in cardiac output
and smaller increases in systemic vascular resistance (Branch and
Knuepfer, 1993, 1994a; Knuepfer and Branch, 1993). In our report, we
designated the groups vascular and mixed responders (formerly named
responders and nonresponders), respectively. The response
characteristics of individual rats appear to be consistent at several
doses and are not altered by higher doses of cocaine (Branch and
Knuepfer, 1993, 1994a). Vascular responders have a greater incidence of
cardiomyopathies and sustained hypertension after repeated cocaine
administration and both a spike in sympathetic nerve activity and a
greater pressor response under chloralose anesthesia after cocaine
administration (Branch and Knuepfer, 1994a, 1994b; Knuepfer et
al., 1993a). Because this differential sensitivity to
cardiomyopathies resembles the varying susceptibility of humans to
cocaine-induced cardiotoxicity, we have used this as a possible model
for identifying responses in more sensitive individuals although it
remains to be proven whether this differential responsiveness in rats
is truly related to differential sensitivity to toxicity in humans.
Our study was performed to determine whether several putative
treatments for cocaine addiction and toxicity alter hemodynamic responses to cocaine. We examined the effects of desipramine, GBR
12909, bromocriptine, buprenorphine, diazepam and MK-801 on cardiovascular responses to cocaine. Although the mechanism by which
these agents act varies widely, all have been used or proposed for use
in treating cocaine addiction or toxicity. The results demonstrate that
specific treatments alter hemodynamic responses to cocaine. Although
the primary goal of these studies was not to examine the mechanism of
cocaine's cardiovascular effects in detail, the results suggest
possible neurotransmitters that may facilitate or inhibit the unique
cardiac output responses to cocaine in individuals.
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Materials and Methods |
Animal preparation.
Male Sprague-Dawley rats (Harlan,
Indianapolis, IN) weighing 300 to 420 g were surgically prepared
under pentobarbital sodium (50 mg/kg, i.p.) anesthesia using aseptic
technique as previously described (Branch and Knuepfer, 1993, 1994a;
Knuepfer and Branch, 1992; 1993). Briefly, a thoracotomy was performed
and a pulsed Doppler flow probe (2.4-mm cuff diameter, 20 MHz, Iowa
Doppler Products, Iowa City, IA) filled with acoustic gel was sutured snugly on the ascending aorta. The thorax was closed and the lead wires
brought subcutaneously to a socket on the skull. Rats were treated with
cefazolin (10 mg/kg, i.m., once daily for 3 days) and allowed to
recover for a minimum of 10 days. Rats with poor or varying velocity
signals or that did not recover normal motor and feeding behavior
within 24 hr were euthanized with pentobarbital. After recovery, rats
were anesthetized with methoxyflurane for implantation of femoral
arterial and venous cannulas filled with 15 mg/ml cefazolin. In a
separate group of six rats, arterial and venous cannulas were implanted
to examine the effects of higher doses of specific agents on arterial
pressure and heart rate, only. One to two days later, each rat was
acclimated in a Plexiglas cage for 6 hr. On the next day, rats were
placed in the same cage for 2 hr before beginning experimentation.
Experimental procedure.
The procedures employed in these
experiments have been described in detail (Branch and Knuepfer, 1993,
1994a; Knuepfer and Branch, 1992, 1993). During and after the daily
2-hr acclimation period, arterial pressure, heart rate and blood flows
were monitored continuously. Rats were studied for up to 10 days.
Cocaine hydrochloride (5 mg/kg, i.v., infused over 45 sec) alone or
after pretreatment with another agent was administered twice daily with
a minimum cocaine dosing interval of 4 hr. In most cases, cocaine was
delivered alone in the morning and was given 10 min after pretreatment
in the afternoon. We have not observed significant tachyphylaxis of
cardiovascular responses to cocaine when given alone in the morning and
afternoon nor when given twice daily for up to 6 days (Branch and
Knuepfer, 1994a). All experiments were conducted between the hours of 9 A.M. and 4 P.M. in a quiet room.
The contribution of several drugs used or proposed for treatment of
cocaine addiction and/or toxicity was examined. Putative therapeutic
agents were administered in random fashion before administration of
cocaine (5 mg/kg, i.v.). Doses for each agent were selected either due
to their potency in reducing cocaine-induced toxicity in animal models
(usually rat or mouse), to evoke minimal changes in hemodynamic
variables, particularly arterial pressure, or to avoid behavioral
effects (e.g., sedation). The dopamine receptor agonist,
bromocriptine (0.1-1 mg/kg, i.v.) was used. A dose of 1 mg/kg has been
reported to produce a small depressor response in rats (Nagahama
et al., 1984). The catecholamine uptake inhibitor,
desipramine (1-10 mg/kg), was used. The lower dose has relatively
small effects on arterial pressure and heart rate but does potentiate
the pressor and bradycardic responses to exogenous norepinephrine
(Tella et al., 1993).
Because little is known concerning the effects of GBR 12909 on
cardiovascular function, this agent was administered (0.5-10 mg/kg,
i.v., over 45 sec) alone in the same manner as cocaine. Only two rats
were examined at the highest dose (10 mg/kg) because responses in these
animals to subsequent administration of cocaine appeared to be altered
for up to 5 days. After obtaining dose-response data, GBR 12909 (1 mg/kg, i.v.) or vehicle (3 mg/ml tartaric acid) was administered 5 min
before cocaine administration (5 mg/kg). No more than two injections of
cocaine or GBR12909 were given each day with a minimum of 3 hr between
drug administrations with the exception of experiments where cocaine
was given 5 min after GBR 12909.
Diazepam (0.1, 0.5 and 1 mg/kg) was used in doses that had minimal
cardiovascular effects. The lower doses did not evoke noticeable behavioral (sedative) effects that have been observed at 1 mg/kg. The
mixed mu opioid receptor agonist/antagonist, buprenorphine (0.3 mg/kg) was used in a dose that protected mice from lethal doses of
cocaine (Shukla et al., 1991). Finally, the NMDA receptor antagonist, MK-801 (0.05 mg/kg), was used. This dose is approximately at the threshold for preventing cocaine-induced seizures and death (Rockhold et al., 1991).
Bromocriptine and GBR 12909 were administered 5 min before cocaine
administration. All other agents were administered 10 min before
cocaine to insure distribution to the vasculature and nervous system.
Rats were not retested after treatment with buprenorphine, diazepam and
GBR 12909 for at least 3 days due to their prolonged half-lives.
Materials.
Materials used included the methanesulfonate salt
of 2-bromo-
-ergocryptine (bromocriptine) and desipramine
hydrochloride from Sigma Chemical Company (St. Louis, MO). Cocaine
hydrochloride was obtained from the National Institute on Drug Abuse.
GBR 12909, provided by NOVO-Nordisk Pharmaceuticals, Malov, Denmark
through the Medications Development Division of the National Institute on Drug Abuse (NIDA), was prepared in 3 mg/ml tartaric acid solution (Fischer Scientific Co., Fair Lawn, NJ). Buprenorphine was obtained in
solution from Reckitt & Colman Pharmaceuticals, Inc. (Richmond, VA).
MK-801 ((+)-5-methyl-10,11-dihydro-5H-dibenzo[a,
d]cyclohepten-5,10-imine hydrogen maleate) was purchased from Research
Biochemicals. Inc. Diazepam was supplied by Hoffman-La Roche, Inc.
(Nutley, NJ) in ampules containing a solution of 5 mg/ml. Drugs were
dissolved in 0.9% sterile saline and were administered i.v. in a final
volume of 1 ml/kg over a period of approximately 45 sec. Drug
concentrations were calculated as the salt form. Cefazolin (Geneva
Pharmaceuticals/Marsam Pharmaceuticals, Cherry Hill, NJ) was used
postoperatively to reduce the risk of sepsis.
Data analysis.
Data were analyzed at several time points.
First, the peak arterial pressure response to cocaine, invariably
occurring within the first minute, was recorded. A second set of values
was obtained at the time of the peak change in cardiac output if it was
not coincident with the peak change in arterial pressure. Using the data at the time of the maximum change in cardiac output, rats were
classified as mixed or vascular responders. In addition, data were
obtained during the sustained modest pressor response defined at 1, 3 and 5 min after initiating cocaine injection. Peak data points and
sustained responses were examined separately using analysis of variance
to avoid the occurrence of significant interactions. Two-way analysis
of variance (for studies of vascular and mixed responders) included a
post hoc simple main effects test to determine which groups
were different. With one exception described below, these procedures
have been used in previous reports (Branch and Knuepfer, 1994a;
Knuepfer and Branch, 1992, 1993). In our study, instead of comparing
hemodynamic responses to cocaine after drug pretreatment to the
precocaine (postpretreatment) levels, cocaine-induced changes were
determined from baseline levels before administration of the
pretreatment. This change allows for consideration of the effects of
altered baselines due to drug pretreatment on cocaine-induced
responses. The figures of drug time courses reflect any differences in
baselines that occurred with pretreatments.
All analyses were performed using CRUNCH (CRUNCH Software, Oakland,
CA). Significant differences were noted if P < .05. Data are
expressed as mean ± S.E.M.
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Results |
Conscious rats instrumented for cardiac output determination
(n = 33) had a mean arterial pressure of 117.1 ± 1.7 mmHg, a heart rate of 388 ± 4 bpm and an ascending aortic
velocity signal of 9.7 ± 0.3 kHz shift. Cocaine administration (5 mg/kg, i.v.) elicited pressor responses and variable changes
in cardiac output and systemic vascular resistance. Each rat received
cocaine alone several times (3-12 trials, mean = 7.8 ± 0.5 trials) to determine hemodynamic responsivity. Individual rats
(n = 26) were designated vascular responders if the
mean maximum decrease in cardiac output was more than 8% (mean = -15.4 ± 1%). The remaining rats, classified as mixed responders,
had smaller decreases or increases in cardiac output (mean = 8.2 ± 3.8%). The resting arterial pressures and heart rates were
not different between groups. In contrast, the mean ascending aortic
flow signals were significantly different in vascular and mixed
responders (10.0 ± 0.3 and 8.45 ± 0.5 kHz shift,
respectively). Figure 1 depicts the mean
responses to cocaine alone in all rats. Five rats were tested with two
pretreatment drugs (on different days), five were tested with three
drugs and two were examined in four different experimental protocols.
In all cases, control responses to cocaine were repeated before each pretreatment regimen to verify consistency of responses.
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Fig. 1.
Mean hemodynamic responses to intravenous cocaine
(5 mg/kg, i.v., injected over 45 sec as depicted by the bar labeled
COC) in vascular responders (open squares, n = 24)
and mixed responders (filled squares, n = 7).
Specific responses shown include mean arterial pressure (MAP, mmHg),
heart rate (HR, bpm), cardiac output (CO, % change) and systemic
vascular resistance (SysVR, % change). Control values are given in the
first sentence of "Results." Data were analyzed with an unpaired
Students' t test at the time of the peak pressor
response and with a two-way ANOVA and simple main effects test during
the sustained response (1, 3 and 5 min after cocaine administration).
Asterisks denote significant (P < .05) differences between groups
(vascular and mixed responders) at specific time points.
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In a separate group of rats instrumented for arterial pressure and
heart rate determination only (n = 7), mean arterial
pressure was 116.8 ± 2.2 mmHg and heart rate was 404 ± 9 b/min. These rats were used to determine appropriate doses of some
pretreatment drugs.
Effects of bromocriptine.
Resting hemodynamic values between
vascular and mixed responders were similar (table
1). The D2 receptor
agonist, bromocriptine (0.1 mg/kg, i.v.), elicited a biphasic arterial
pressure response; a brief pressor response within 30 to 90 sec after
injection (fig. 2) followed by a small
depressor response (table 2). The pressor response was caused by an increase in cardiac output in mixed responders (P = .02) and by an increase in systemic vascular
resistance in vascular responders (P = .045, table 2; fig. 2).
Five minutes later, arterial pressure was lower in vascular responders
only due to a decrease in systemic vascular resistance while cardiac output returned to pre-drug levels (table 2, time 0 in fig.
3). Heart rate and stroke volume were not
significantly affected by this dose of bromocriptine. A larger dose of
bromocriptine (1 mg/kg) elicited variable changes in arterial pressure
and heart rate in six rats instrumented with arterial and venous
cannulas only (table 3). An analysis of
variance revealed a significant increase in arterial pressure for both
doses.
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Fig. 2.
Cardiovascular effects of 0.1 mg/kg bromocriptine
(Brc), 1 mg/kg desipramine (Des), 0.1 to 0.5 mg/kg diazepam (Dzp), 0.3 mg/kg buprenorphine (Bup) and 50 µg/kg MK-801 (MK8) are shown at the time of the peak pressor response. Asterisks denote significant changes
(P < .05) from control values as determined by a two-way ANOVA
(bromocriptine, desipramine and diazepam) and by a Students' paired
t test (buprenorphine and MK-801). Other abbreviations are described in figure 1.
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Fig. 3.
Responses to cocaine (5 mg/kg, i.v.)
before and after pretreatment (5 min before) with bromocriptine (Brc)
in vascular (n = 6) and mixed responders
(n = 6). Control values are shown in table 1. As
denoted by asterisks at time zero, arterial pressure was reduced in
vascular responders and systemic vascular resistance was reduced in all
rats five minutes after bromocriptine administration (table 2). Data
were analyzed with a two-way ANOVA at the time of the peak pressor
response and with a three-way ANOVA during the sustained response (1, 3 and 5 min after cocaine administration). Asterisks denote differences
due to the drug (bromocriptine) pretreatment. In addition, vascular
responders had a smaller decrease in cardiac output at one minute and
smaller increases in systemic vascular resistance at 1, 3 and 5 min
whereas mixed responders had a smaller increase in systemic vascular
resistance only at 5 min after cocaine administration. Abbreviations
are described in figure 1.
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Bromocriptine pretreatment reduced the pressor response elicited by
cocaine primarily by reducing the increase in systemic vascular
resistance (fig. 3) although, in individual groups, this decrease was
only significant in vascular responders. These changes were due, in
part, to reduced baseline values (table 2). There was a significant
reduction in the decrease in cardiac output in vascular responders at
the 1 min time point. Bradycardic responses to cocaine were also
reduced by bromocriptine pretreatment (fig. 3) but stroke volume was
unaffected (data not shown). A greater dose of bromocriptine (1 mg/kg)
also reduced the peak pressor response to cocaine (table 3).
Responses recorded at the time of the peak change in cardiac output
were also measured (fig. 4). Again the
pressor response was reduced due to a decrease in the cocaine-induced
increase in systemic vascular resistance. The bradycardia was reduced
in vascular responders and there was a significant difference between heart rate responses in the two groups (fig. 4). After bromocriptine, there was no longer a difference between the cardiac output responses in vascular and mixed responders (figs. 3 and 4).
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Fig. 4.
Arterial pressure and cardiac output responses to
cocaine at the time of the peak change in cardiac output (0.5-3 min
after cocaine). Responses to cocaine alone (5 mg/kg, i.v., Coc) are depicted for all control values combined. In addition, responses to
cocaine after pretreatment with bromocriptine (0.1 mg/kg, Brc), desipramine (1 mg/kg, Des), GBR 12909 (1 mg/kg, GBR), diazepam (0.1 and
0.5 mg/kg, Dzp), buprenorphine (0.3 mg/kg, Bup) and MK-801 (0.05 mg/kg,
MK) are shown. Data were analyzed by one- (buprenorphine and MK-801) or
two-way (all other drugs) ANOVA. There was a significant interaction
for the maximum cardiac output response noted after GBR 12909 pretreatment because the mixed responders had a negative change and the
vascular responders had a positive change. Asterisks denote a
significant change (P < .05) in comparison to cocaine alone for
control values obtained in each experiment. The control values for
cocaine administration are a mean obtained from each animal used and
are not necessarily represented by the combined control value shown for
cocaine alone. Significant differences between vascular and mixed
responders are designated with a #. Other abbreviations are described
in figure 1.
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Effects of desipramine.
Desipramine was studied in 14 rats
(table 1). The monoamine uptake inhibitor, desipramine (1 mg/kg, i.v.),
increased arterial pressure in all rats (fig. 2) within 1 to 2 min
after administration. As seen with bromocriptine, the pressor response
was caused by an increase in cardiac output in mixed responders and
with an increase in systemic vascular resistance in vascular responders (fig. 2). Furthermore, heart rate fell in vascular responders only.
Stroke volume was not altered in either group. A larger dose of
desipramine (10 mg/kg, i.v.) elicited an equivalent peak increase in
arterial pressure in five conscious rats without cardiac output
instrumentation (table 3). Ten minutes later, arterial pressure
remained elevated in all rats but vascular responders had a
significantly higher resting arterial pressure than mixed responders.
The increase in arterial pressure was due to an increase in systemic
vascular resistance (table 2, time 0 in fig.
5) because heart rate and cardiac output
remained depressed in vascular responders only (table 2).
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Fig. 5.
Responses to cocaine (5 mg/kg, i.v.)
before and after pretreatment with desipramine (Des, 1 mg/kg,
i.v.) in vascular (n = 6) and mixed
responders (n = 7). Control values are shown in
table 1. As denoted by asterisks at time zero, crease in cardiac output and increase in systemic vascular resistance.
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Desipramine pretreatment (1 mg/kg) did not alter the peak pressor
responses to cocaine despite higher baseline values (fig. 5) but did
produce several changes at the 1-min time period. These included a
significant reduction in the cocaine-induced bradycardia in mixed
responders and a smaller decrease in cardiac output and increase in
systemic vascular resistance in vascular responders. When measured at
the time of the peak change in cardiac output, desipramine pretreatment
selectively prevented the cocaine-induced decrease in cardiac output
and heart rate in vascular responders without affecting significantly
the responses in mixed responders (fig. 4). Stroke volume was not
altered by desipramine (data not shown). At a higher dose of
desipramine (10 mg/kg), the pressor responses to cocaine were
significantly reduced (table 3).
Effects of GBR 12909.
The effects of administration of the
vehicle for GBR 12909 (3 mg/ml tartaric acid) were examined in 10 conscious rats. Vehicle injections elicited increases in arterial
pressure and heart rate that were not unlike those elicited by low
doses of GBR 12909 (table 3; fig. 6).
There were no differences in hemodynamic parameters 5 min after vehicle
injection (fig. 6).
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Fig. 6.
Responses to GBR 12909 (0.5-5 mg/kg, i.v.)
compared to vehicle (Veh) responses in vascular and mixed responders. A
dose-response relationship was noted for all parameters shown using a
three-way ANOVA for data at 1, 3 and 5 min after GBR 12909 administration. Peak arterial pressure responses were related to dose
also (two-way ANOVA). No differences were noted between the effects of
GBR 12909 on vascular responders compared to mixed responders so the
combined data are presented. Other abbreviations are described in
figure 1.
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The resting values of arterial pressure, heart rate and ascending
aortic flow were not different between rats (table 1). GBR 12909 (0.5-10 mg/kg, i.v.) evoked smaller hemodynamic responses compared to cocaine (figs. 1 and 6). Lower doses (0.5-1 mg/kg) produced small pressor responses and tachycardia that were not different from vehicle-induced effects. Lower doses produced decreases in systemic vascular resistance and increases in cardiac output whereas
higher doses (5 and 10 mg/kg) elicited biphasic cardiovascular changes
(fig. 6, responses to 10 mg/kg are not shown). There was a significant
dose-response relationship for arterial pressure, heart rate, cardiac
output and systemic vascular resistance (fig. 6) but not for stroke
volume (data not shown). There were no differences in the hemodynamic
effects noted in vascular and mixed responders except that the initial
peak pressor response was significantly greater in mixed responders
compared to vascular responders at the 1- and 5-mg/kg doses of GBR
12909 (data not shown). Arterial pressure and cardiac output were
elevated 5 min after GBR 12909 (1 mg/kg, i.v.)
administration (7.5 ± 1.7 mmHg and 4.2 ± 1.9%, respectively) although the increase in cardiac output was noted only in
mixed responders (table 2).
Administration of cocaine (5 mg/kg, i.v.) resulted in peak
pressor responses that were significantly greater in mixed responders compared to vascular responders (fig. 7).
GBR 12909 pretreatment did not alter this difference. GBR 12909 had
little effect on the time course of cocaine-induced responses in
vascular responders but, at the 1-min time point, the increase in
systemic vascular resistance was greater in mixed responders and the
increase in cardiac output was changed to a decrease despite the
elevated baseline value (fig. 7). Cocaine elicited an increase in
stroke volume in mixed responders that was blocked by GBR 12909 (data not shown).
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Fig. 7.
Responses at several time points to administration
of cocaine (5 mg/kg, i.v.) alone (squares) and 5 min
after administration of GBR 12909 (1 mg/kg, i.v.,
circles) in conscious, freely-moving rats (n = 15).
Control values are shown in table 1. Asterisks at time zero denote the
increase in arterial pressure and cardiac output elicited by GBR 12909 alone. At 1-min after cocaine administration, cardiac output and stroke
volume were significantly reduced and systemic vascular resistance was
elevated in mixed responders only. Data were analyzed and displayed as
described in figure 3.
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At the time of the maximum change in cardiac output, GBR 12909 reduced
the pressor response to cocaine in mixed responders by reducing cardiac
output responses (fig. 4). After GBR 12909 pretreatment, cardiac output
responses in mixed responders were similar to those in vascular
responders (fig. 4).
Effects of diazepam.
There was a difference in pretreatment
baseline values for heart rate between mixed and vascular responders in
rats studied using diazepam (table 1). Two doses of diazepam (0.1 and
0.5 mg/kg) were administered to rats instrumented for cardiac output determination (n = 12 and 6, respectively).
Dose-related differences in arterial pressure, heart rate and cardiac
output baseline values or cocaine-induced responses were not observed
using analysis of variance. Therefore, these data were combined in
figures 2, 4 and 8. Diazepam pretreatment
elicited an initial increase in arterial pressure in all rats within 60 to 90 sec due to an increase in cardiac output (fig. 2). Mixed
responders, but not vascular responders, demonstrated an increase in
heart rate also (fig. 2). After 10 min, arterial pressure was
significantly lower compared to baseline values in all rats although
the differences were only significant in vascular responders (table 2).
No apparent sedative effects were noted but rats were relatively
quiescent before and after all drugs administered except cocaine. In
contrast, a higher dose of diazepam (1 mg/kg, i.v.) elicited an initial
behavioral excitation in some rats (as noted by increased motor
activity) followed by an apparent lethargy (lying on cage bottom for
several minutes) in all six rats tested. These responses were
associated with an initial increase in arterial pressure (table 3) that was no longer apparent 10 min later. Heart rate was elevated for the
entire 10-min period before cocaine administration.
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Fig. 8.
Responses to cocaine (5 mg/kg, i.v.)
before and after pretreatment with diazepam (Dzp, 0.1 or 0.5 mg/kg,
i.v.) in vascular (n = 13) and mixed
responders (n = 5). Control values are shown in
table 1. An ANOVA on the dose-response relationship demonstrated no
differences in cocaine-induced effects so responses to the two doses
were combined. Arterial pressure was lower 10 min after treatment with
diazepam (designated by asterisks at time zero). Data are presented and
analyzed as described in figure 3.
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Most cardiovascular responses to subsequent administration of cocaine
were not altered by diazepam pretreatment (0.1 and 0.5 mg/kg) with the
exception of an enhanced tachycardia and reduced systemic
vasoconstriction at the time of the initial peak pressor response (fig.
8). Vascular responders had a significant decrease in the peak pressor
response due to a decrease in the cocaine-induced increase in systemic
vascular resistance. Stroke volume was unchanged (data not shown). At
the time of the peak change in cardiac output, arterial pressure and
heart rate responses to cocaine alone differed in vascular and mixed
responders (data not shown) but after diazepam pretreatment no
differences were observed (fig. 4). Administration of cocaine after
pretreatment with 1 mg/kg diazepam elicited similar arterial pressure
and heart rate responses. There was a small but significant reduction
in the pressor response after the lowest dose of diazepam (0.1 mg/kg)
only (table 3).
Effects of buprenorphine.
Buprenorphine (0.3 mg/kg) alone
produced a delayed (6-7 min) increase in arterial pressure due to
increases in heart rate, cardiac output and systemic vascular
resistance in seven vascular responders (fig. 2, mixed responders were
not tested) without affecting stroke volume. Ten minutes after
administration of buprenorphine, arterial pressure, heart rate and
cardiac output were still significantly elevated (table 2 and time 0 in
fig. 9). The effects of cocaine alone and
of buprenorphine plus cocaine were similar except that the increase in
systemic vascular resistance was enhanced by buprenorphine pretreatment
1 minute after cocaine (fig. 9). Responses at the time of the maximum
cocaine-induced decrease in cardiac output were not changed
significantly by buprenorphine pretreatment (fig. 4).
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Fig. 9.
Responses to cocaine (5 mg/kg, i.v.)
before and after pretreatment with buprenorphine (0.1 mg/kg,
i.v.) in vascular responders (n = 7). Control values are shown in table 1. Arterial pressure, heart rate
and cardiac output were significantly elevated 10 min after
administration of buprenorphine (denoted by asterisks at time zero).
Data were analyzed by a one-way ANOVA (peak values) and by two-way
ANOVA (1, 3 and 5 min). Abbreviations are described in figure 1.
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Effects of MK-801 (dizocilpine).
Administration of MK-801 (50 µg/kg) evoked an increase in arterial pressure mediated by increases
in systemic vascular resistance, heart rate, and cardiac output in nine
vascular responders (mixed responders were not tested) that reached
peak values approximately 7 to 9 min after administration (fig. 2).
These values remained elevated 10 min after administration when cocaine
was injected. The arterial pressure and heart rate responses to cocaine
administration were greater (fig. 10)
due to higher baseline values (table 2). The pressor response appeared
to be due to an increase in baseline cardiac output possibly due to
inhibition of the bradycardia. At the time of the peak cardiac output
response, the cardiovascular responses were unaltered (fig. 4). Stroke
volume responses were not altered (data not shown).
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Fig. 10.
Responses to cocaine (5 mg/kg,
i.v.) before and after pretreatment with MK-801
(dizocilpine, 0.05 mg/kg, i.v.) in vascular responders
(n = 9). Control values are shown in table 1. As
denoted by asterisks at time zero, arterial pressure, heart rate,
cardiac output and systemic vascular resistance were elevated 10 minutes after administration of MK-801 (table 2). Data were analyzed as
described in figure 9 and are presented as described in figure 1.
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Discussion |
These data provide the first detailed description of cardiac
output and systemic vascular resistance responses to a variety of
agents proposed for the treatment of cocaine addiction and/or toxicity.
The responses to proposed treatments and to the combination of the
treatments and cocaine were described in two subsets of a population.
Our laboratory has reported that the cardiac output responsiveness to
cocaine is highly variable and is correlated with their predisposition
to the development of cocaine-induced hypertension and cardiomyopathies
(Branch and Knuepfer, 1994a; Knuepfer et al., 1993a). We
divided rats into vascular responders (with a decrease in cardiac
output) and mixed responders (no change or an increase in cardiac
output) to facilitate analysis of the differences in responsivity. In
our study, resting ascending aortic flow values were significantly
higher in vascular responders compared to mixed responders. It may be
argued that this difference may predispose these rats to a decrease in
cardiac output in response to cocaine. This is unlikely because we have
published several reports using relatively large numbers of rats
classified in this manner (Branch and Knuepfer, 1993, 1994a; Knuepfer
et al., 1993a, b). We have not noted such differences in
these studies. Therefore, this difference may contribute to the
differential responsiveness but is not likely to be the sole cause.
Amphetamine administration (1 mg/kg), ethanol administration (0.475 or
0.95 mg/kg) or a brief air jet stress evoke differential cardiovascular
responsiveness that is directly related to the differential hemodynamic
responses elicited by cocaine in vascular and mixed responders (Branch
and Knuepfer, 1994a; Gan and Knuepfer, 1994; Knuepfer et
al., 1993b). In our study, bromocriptine (0.1 mg/kg, i.v.) or
desipramine (1 mg/kg, i.v.) evoked an acute increase in arterial
pressure in all rats. The pressor response was a result of increasing
cardiac output in mixed responders and of increasing systemic vascular
resistance in vascular responders. These data suggest that rats exhibit
differential hemodynamic responses to dopamine
(D2 receptor) agonists or reuptake blockers in
addition to acute stress, ethanol and amphetamine. These data provide
further support for a differential sensitivity to a range of drug
treatments whether these are agents that mimic cocaine's pharmacologic
effects (e.g., desipramine, bromocriptine) or not. We
propose that individual rats are predisposed to specific hemodynamic
response patterns evoked by behavioral stress that, in most examples
cited here, occurs after administration of psychoactive agents.
Bromocriptine.
Dopamine agonists, such as bromocriptine, are
the most common class of agents used to treat cocaine addiction and
toxicity (Halikas et al., 1993). Bromocriptine has been
shown to reduce cocaine craving in humans (Dackis and Gold, 1985), and
self-administration behavior and motor responses in rats (Campbell
et al., 1989; Hubner and Koob, 1990) presumably by
desensitizing dopamine receptors responsible for cocaine-induced
euphoria. With regard to the autonomic nervous system, bromocriptine
alone increased heart rate and pupillary diameter but lowered arterial
pressure in human subjects (Preston et al., 1992). We noted
a biphasic response (increase followed by a decrease) in arterial
pressure after bromocriptine administration (0.1 and 1 mg/kg, i.v.) in
conscious rats (fig. 2; table 2).
After bromocriptine pretreatment, pressor responses to cocaine were
reduced but heart rate responses were enhanced in humans (Kumor
et al., 1989; Preston et al., 1992). Our results
in conscious rats also suggest that pressor responses are reduced and
heart rate responses are greater. Furthermore, we noted that cardiac output and systemic vascular resistance responses in both groups were
smaller (figs. 3 and 4) thereby eliminating differences in cocaine-induced cardiovascular reactivity between vascular and mixed
responders. This may be due, in part, to a difference in baseline
values because reductions in arterial pressure and systemic vascular
resistance were noted 5 min after bromocriptine administration (table
2). Alternatively, if cocaine alters hemodynamic responses by enhancing
dopamine receptor activation, bromocriptine might reduce the response
by desensitizing the receptors. Although others have suggested that the
combination of bromocriptine and cocaine does not appear to enhance
potential cardiovascular toxicity (Kumor et al., 1989;
Preston et al., 1992), our data suggest that the combined
effects of these two agents may ameliorate cardiotoxicity.
Desipramine.
Tricyclic antidepressants have been shown to be
effective in treating craving for cocaine (Tennant and Rawson, 1983)
and cocaine toxicity (Antelman et al., 1981). For example,
desipramine is widely used for treatment of addiction to cocaine
(Halikas et al., 1993). Desipramine may reduce the stimulant
properties of cocaine in some patients and enhance it in others
(Fischman et al., 1990) suggesting that individual
differences may alter the effectiveness of desipramine in treating
cocaine addiction. The autonomic responses to both agents may also vary
because both cocaine and desipramine produce an initial brief
excitation of sympathetic activity in some conscious animals followed
by a sustained inhibition of sympathetic activity in all subjects
(Branch and Knuepfer, 1994b; Dorward et al., 1991; Knuepfer
and Branch, 1992). As noted with cocaine, arterial pressure was
elevated for at least 10 min after desipramine administration (1 or 10 mg/kg) despite the reported sympathoinhibition caused by both agents.
Others have not observed a change in arterial pressure with desipramine administration in conscious rats (Tella et al., 1993),
rabbits (Dorward et al., 1991) and humans (Kosten et
al., 1992) although Fischman et al. (1990) reported an
increase in arterial pressure in human subjects after chronic
desipramine maintenance therapy. Therefore, the decrease in central
sympathetic drive may not offset the enhanced catecholamine levels due
to reuptake blockade.
It has been suggested that desipramine attenuates the tachycardic
responses to cocaine (Kosten et al., 1992). Some
investigators have suggested that the potential for toxicity after
desipramine may be greater (Fischman et al., 1990; Misra
et al., 1986). This has been suggested to be a result of the
ability of acute desipramine administration to enhance plasma levels of
cocaine (Misra et al., 1986; Tella and Goldberg, 1993)
although others have not noted a change in cocaine levels during
desipramine maintenance therapy (Kosten et al., 1992). In
our study, acute desipramine treatment prevented the decrease in
cardiac output in vascular responders. Although the smaller cardiac
output responses may be a result of lower baseline values of cardiac
output (table 2), attenuating the decrease in cardiac output (fig. 5)
suggests a beneficial effect of desipramine. Although these changes
were small, the results with 10 mg/kg desipramine (table 3) demonstrate
that the peak pressor response to cocaine, at least, would be
attenuated at higher doses. In fact, Tella and coworkers (1993) did not
observe significant changes in arterial pressure or heart rate 5 min
after a similar dose of desipramine in conscious rats. The possible significance regarding reuptake blockade will be discussed below.
GBR 12909.
GBR 12909 is more selective and more potent in its
ability to bind to the dopamine transporter compared to cocaine
(Andersen, 1989; Izenwasser et al., 1990; Rothman et
al., 1989) and inhibits cocaine-induced increases in extracellular
dopamine (Rothman et al., 1991). It has been shown to
produce similar behavioral responses to those elicited by cocaine in
animal studies (Cunningham and Callahan, 1991; Heikkila and Manzino,
1984; Howell and Byrd, 1991). GBR 12909 substitutes for cocaine at
least in some animals in drug discrimination studies (Johanson and
Barrett, 1993). Because of its selectivity for the dopamine transporter
and the known involvement of dopamine in eliciting cocaine-induced
euphoria, GBR 12909 has been proposed as a treatment for cocaine
addiction (Rothman and Glowa, 1995; Rothman et al., 1989,
1991).
The cardiovascular responses to GBR 12909 were, in general, smaller
than those elicited by equivalent doses of cocaine but were otherwise
similar. We noted increases in cardiac output and heart rate after
lower doses of cocaine that changed to decreases at higher doses
(Branch and Knuepfer, 1993; 1994a) as noted with GBR 12909. Because GBR
12909 is more selective than cocaine in inhibiting dopamine uptake
(Andersen, 1989), the responses to GBR 12909 more specifically reflect
the contribution of dopamine in mediating the autonomic responses to
cocaine. These data do not differentiate between possible actions in
the CNS and/or in the peripheral tissue. These data suggest that GBR
12909 evokes hemodynamic responses that are qualitatively similar to
those elicited by cocaine. Therefore, it is likely that the mechanisms these two agents have in common may be responsible for the hemodynamic responses.
Pretreatment with GBR 12909 had some effects on the hemodynamic
responses to cocaine (fig. 7). Specifically, mixed responders had a
relatively selective conversion of an increase in cardiac output to a
decrease such that they were no longer different from vascular
responders. Some agents (e.g., propranolol, physostigmine, ethanol) appear to shift the cardiac output responses of both groups of
rats in a negative direction whereas others (e.g., methyl atropine) shift the cardiac output responses to more positive values
(Branch and Knuepfer, 1994a; Gan and Knuepfer, 1993; Knuepfer et
al., 1995; Mueller et al., 1995). Tella and Goldberg
(1993) reported that GBR 12909 pretreatment produced a substantial
increase in cocaine levels 30 sec after cocaine administration
suggesting toxicity might be enhanced. This is unlikely to explain the
selective effects on mixed responders because earlier dose-response
studies do not suggest that higher doses produce a decrease in cardiac output in mixed responders unless seizure activity ensues (Branch and
Knuepfer, 1993, 1994a). The effects of higher doses of GBR 12909 (5-10
mg/kg) on cardiovascular responses are more profound and apparently
long-lasting. This suggests that there is a greater chance of possible
toxicity with cocaine although we did not investigate this. It is not
known at present whether these effects are mediated by actions on
central or peripheral monoamine uptake systems but the selectivity of
GBR 12909 for the dopamine transporter and the high density of these
transporters in the CNS suggests these effects may be centrally
mediated. It is apparent, at least, that GBR 12909 alone (0.5-5 mg/kg)
is not likely to produce untoward cardiovascular effects.
Dopamine hypothesis.
The actions of bromocriptine, desipramine
and GBR 12909 give insight into the causes of hemodynamic responses to
cocaine. Both bromocriptine and desipramine will enhance dopamine
receptor activation by different mechanisms. Because these agents
selectively reduce the decrease in cardiac output elicited by cocaine,
it is possible that dopamine receptor activation alleviates the
cardiodepression noted in some rats. Interestingly, GBR 12909 would be
expected to have similar results but did not. It is possible that the
dose of GBR 12909 was insufficient to attenuate the responses to
cocaine, but, due to the prolonged effects of GBR 12909 higher doses
were not used. Schindler et al. (1991) reported that the
cocaine-induced pressor response was not antagonized by D1 or D2
receptor antagonists or mimicked by a D2 agonist in conscious squirrel
monkeys. In our study, the agonists or uptake inhibitors could mimic
the effects of cocaine to some extent (figs. 2 and 6) but only
bromocriptine was effective in reducing the pressor response to
cocaine. In contrast, all three agents were capable of preventing
differential cardiac output and systemic vascular resistance responses
in the two groups of animals. These data suggest that dopamine
receptors may be responsible for the differences in hemodynamic
response patterns noted in vascular and mixed responders.
It is unclear at this time whether the hemodynamic responses are
dependent on the direct actions of dopamine or whether the affective
component of the psychoactive agents, mediated in part by dopamine,
indirectly triggers the cardiovascular responses. In this regard, the
data are consistent because bromocriptine and desipramine both elicited
differential cardiac output responses and attenuated the
cocaine-induced decrease in cardiac output. In contrast, GBR 12909 did
not elicit differential responsiveness alone at the 1-mg/kg dose and
did not prevent the decrease in cardiac output. Again, it is possible
that a higher dose of GBR 12909 would have such effects.
Diazepam.
Diazepam is effective in ameliorating stress-induced
hormonal and neurochemical responses (Lahti and Barsuhn, 1975) that are similar to effects observed after cocaine administration (Levy et
al., 1992; Moldow and Fischman, 1987; Rivier and Vale, 1987). Larger doses of diazepam are reported to reduce cocaine toxicity (Catravas and Waters, 1981; Derlet and Albertson, 1989; Guinn et
al., 1980) although others have reported no significant protection (Trouvé and Nahas, 1990). The effectiveness of diazepam in
reducing toxicity may only be manifest at greater doses (>1 mg/kg)
when anticonvulsant effects are manifest whereas lower doses, such as
those used in our study, may not be effective in protecting rats from
lethal doses of cocaine (Smith et al., 1991). Diazepam is
effective for treating toxicity in patients experiencing
cocaine-induced seizures (Jonsson et al., 1983; Resnick and
Resnick, 1984). In humans, sedative and antianxiety effects are noted
at doses of 30 to 300 µg/kg (Rall, 1990). Although doses in humans
cannot be directly compared to those in rats, the substantial
difference (100-fold) between doses in rats and those in humans
suggests that greater sedation is necessary to prevent toxicity in
rats. Diazepam (0.1 or 0.5 mg/kg) produced biphasic arterial pressure responses (fig. 2; table 2). A small depressor response remaining noted
only in vascular responders was not likely to substantially alter
responses to cocaine administration. Therefore, these data suggest that
diazepam may not alter cocaine-induced cardiovascular toxicity.
Buprenorphine.
Buprenorphine is a mixed agonist/antagonist at
the mu opioid receptor with potent analgesic effects and
little or no potential for dependence (Cowan et al., 1977;
Mello et al., 1989). Buprenorphine has been suggested as a
treatment for cocaine addiction because it suppresses cocaine-induced
responding in self-administration studies (Mello et al.,
1989; Mendelson et al., 1990; Winger et al.,
1992) and blocks cocaine-induced place preference (Suzuki et
al., 1992). Little is known concerning the possible cardiovascular interactions between buprenorphine and cocaine. It was reported that
arterial pressure and heart rate responses to cocaine and plasma
cocaine levels were not altered by buprenorphine maintenance therapy in
human subjects (Teoh et al., 1993). Buprenorphine, even at a
low dose (0.3 mg/kg), reduced toxicity to lethal injections of cocaine
in mice (Shukla et al., 1991; Witkin et al.,
1991). At this dose, we noted net increases in arterial pressure, heart rate and cardiac output in vascular responders that were still present
after 10 min (fig. 2; table 2). Despite these changes in hemodynamic
variables, buprenorphine had little effect on the cardiovascular
responses to cocaine with the exception of a possible increase in the
systemic vascular resistance response. If the shift in baseline is not
considered, buprenorphine pretreatment would blunt the initial pressor
response and enhance both the decrease in cardiac output and heart rate
(data not shown). Therefore, if buprenorphine-induced cardiovascular
effects were allowed to resolve, it is possible that cocaine-induced
cardiodepression might be greater.
MK-801.
It has been reported that MK-801 (dizocilpine) and
other NMDA receptor antagonists reduce toxicity to lethal doses of
cocaine (Derlet and Albertson, 1990; Rockhold et al., 1991;
Witkin and Tortella, 1991) although the precise mechanism by which this
occurs remains to be determined. MK-801 also reduces the untoward
proarrhythmic effects of cocaine on the myocardium (Hageman and Simor,
1993). Interestingly, MK-801 did not alter heart rate, arterial
pressure or sympathetic nerve activity substantially in
pentobarbital-anesthetized dogs (Hageman and Simor, 1993). In contrast,
we and others (Lewis et al., 1989) noted that this dose of
MK-801 elicited increases in arterial pressure and heart rate in
conscious rats (fig. 2; table 2). Because higher doses produce more
profound changes in cardiovascular parameters in conscious animals
making interpretation more difficult, these were not used in our study.
Although the changes evoked by MK-801 were reduced somewhat 10 min
after pretreatment (table 2), it is possible that the shift in baseline
heart rate may have contributed to the enhanced tachycardia followed by
a reduced bradycardia after cocaine administration. In addition, an
increase in aortic flow and in systemic vascular resistance was noted
10 min after MK-801 administration. Taking into account the higher
arterial pressure, heart rate and cardiac output, the cocaine-induced
responses were shifted upward in vascular responders. We suggest that
the difference in baseline may be largely responsible for changes in
hemodynamic responses to cocaine because no differences in the pressor
or cardiac output responses are noted if the baseline shift is not
taken into consideration (data not shown). It appears as though the
increase in the cocaine-induced pressor response is due entirely to an
increase in the cardiac output response with the likely contribution of
heart rate to this response. These data suggest that this dose of
MK-801 may exacerbate pressor and heart rate responses to cocaine
possibly due to the change in baseline. These data also demonstrate
that the pressor responses can be dissociated from the cardiac output
responses. Interestingly, propranolol has the opposite effect;
ameliorating the pressor response and enhancing the decrease in cardiac
output (Branch and Knuepfer, 1994a).
In conclusion, our data describe, for the first time in most cases,
detailed cardiovascular responses to cocaine after pretreatment with a
variety of proposed and currently used treatment regimens for cocaine
addiction and toxicity. Our previous studies suggest that arterial
pressure and heart rate responses alone are not sufficient to predict
potential cocaine-induced myocardial toxicity (Knuepfer et
al., 1993a). Although it is clear that humans also vary in their
susceptibility to cocaine-induced cardiotoxicity, related studies are
necessary to demonstrate whether or not hemodynamic variables can
predict those individuals at risk. These results also implicate
potential neurotransmitters that may mediate specific hemodynamic
responses to cocaine.
The authors acknowledge the technical assistance of Mr. David De
Ornellis and the editorial assistance of Dr. Patrick J. Mueller. We are
indebted to NOVO-Nordisk Pharmaceuticals and Drs. David N. Johnson and
James Terrill from the NIDA, Medications Development Division for
providing the GBR 12909. Portions of this work were presented in
abstract form (Gan, Q. and Knuepfer, M.M., FASEB J. 7: A473,
1993; Gan, Q. and Knuepfer, M.M., NIDA Monograph 141: 317, 1994).
ANOVA, analysis of variance;
Brc, bromocriptine;
Bup, buprenorphine;
COC, cocaine hydrochloride;
CHG, change;
CO, cardiac output;
Des, desipramine;
Dzp, diazepam;
GBR 12909 or GBR, 1-(2-(bis(4-fluorphenyl)-methoxy)-ethyl)-4-(3-phenyl-propyl)piperazine;
HR, heart rate;
INJ, injection;
MAP, mean arterial pressure;
MK-801 or
MK8, dizocilpine;
NMDA, N-methyl-D-aspartic acid;
SV, stroke volume;
SysVR, systemic vascular resistance.
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Abstract
Introduction
