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The Journal of Neuroscience, June 1, 2001, 21(11):4074-4080
Progressive Enhancement of Delayed Hyperalgesia Induced by
Repeated Heroin Administration: A Sensitization Process
Evelyne
Célèrier,
Jean-Paul
Laulin,
Jean-Benoît
Corcuff,
Michel
Le Moal, and
Guy
Simonnet
Institut National de la Santé et de la Recherche
Médicale U 259, Psychobiologie des Comportements Adaptatifs,
Université Victor Ségalen Bordeaux 2, 33077 Bordeaux,
France
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ABSTRACT |
It is difficult to conceive that tolerance and sensitization
processes, two apparently opposite phenomena, can concomitantly modify
one given biological process, i.e., the processing of pain. We have
shown recently that opiates produce not only analgesia but also
long-lasting hyperalgesia in rats. This suggests that tolerance to the
analgesic effect of an opiate, especially heroin, could be in part the
result of an actual sensitization of pronociceptive systems. Here, we
show that both magnitude and duration of heroin-induced delayed
hyperalgesia increase with intermittent heroin administrations, leading
to an apparent decrease in the analgesic effectiveness of a given
heroin dose. Our observation that a small dose of heroin which is
ineffective for triggering a delayed hyperalgesia in non-heroin-treated
rats induced an enhancement in pain sensitivity for several days after
a series of heroin administrations is in agreement with the
sensitization hypothesis. The effectiveness of the opioid receptor
antagonist naloxone to precipitate hyperalgesia in rats that had
recovered their pre-drug nociceptive value after single or repeated
heroin administrations indicates that heroin-deprived rats were in a
new biological state associated with a high level balance between
opioid-dependent analgesic systems and pronociceptive systems. Because
the NMDA receptor antagonist dizocilpine maleate (MK-801) prevented
both heroin-induced long-lasting enhancement in pain sensitivity and
naloxone-precipitated hyperalgesia, these findings further suggest that
tolerance, sensitization, and one withdrawal symptom, hyperalgesia, are
issued from a neuroadaptive process in which NMDA systems play a
critical role.
Key words:
heroin; delayed hyperalgesia; pain sensitization; NMDA
receptors; opiate tolerance; rats
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INTRODUCTION |
From a pharmacological viewpoint,
sensitization refers to the "increased response to a drug that
follows its repeated intermittent administration" (Post, 1980 ;
Robinson and Becker, 1986; Antelman et al., 1987). This phenomenon has
also been described as "reverse tolerance," because tolerance is
usually defined as a decreased response to a drug with repeated
administrations (Jaffe, 1990). Tolerance and sensitization processes
are two effective strategies developed by living organisms for
maintaining adaptive responses to repeated changes in the internal or
external environment. As stated by Stewart and Badiani regarding
tolerance (1993), it is misleading to say that sensitization develops
with respect to a drug. Sensitization develops to one particular effect
of a drug and not to another. Although tolerance and sensitization are
considered as two opposite processes, they might be concomitantly
observed with some various effects of opiates: tolerance develops to
the analgesic and sedative effects, while at the same time
sensitization develops toward activating effects such as locomotor
hyperactivity (Jaffe, 1990; Stewart and Badiani, 1993).
Although it is difficult to conceive that one drug may induce two
opposite effects on the same biological process, a growing body of
evidence suggests that opiates produce not only analgesia but also
hyperalgesia in animals (Yaksh and Harty, 1988; Laulin et al., 1998,
1999; Célèrier et al., 2000) and humans (Ali, 1986; Arner
et al., 1988; De Conno et al., 1991; Devulder, 1997). It is now
believed that pain modulation results from a balance between the
activity of antinociceptive and pronociceptive systems (Rothman, 1992;
Fields and Basbaum, 1994; McNally, 1999). We proposed that opiates
concomitantly activate antinociceptive systems and a NMDA-dependent
pronociceptive system, leading to long-lasting hyperalgesia (Larcher et
al., 1998; Laulin et al., 1998; Célèrier et al., 1999,
2000). We also observed in rats that once-daily heroin administrations
induce a persistent increase of basal pain sensitivity that
progressively masks a sustained heroin analgesic action, the sum of
both effects giving the impression of less analgesia, i.e.,. apparent
tolerance (Laulin et al., 1999). Interestingly, the noncompetitive NMDA
receptor antagonist MK-801, which prevents the gradual lowering of the
nociceptive threshold, also prevents the apparent decrease in the
effectiveness of heroin (Mao et al., 1994; Laulin et al., 1998). This
suggests that repeated opiate administrations could induce an actual
sensitization of pronociceptive systems, leading to a more sustained
decrease of nociceptive threshold, which if not taken into account
gives the impression of less analgesia.
The present experiments were designed to determine whether heroin
induces an actual sensitization to nociceptive inputs (Robinson and
Becker, 1986; Antelman et al., 1987). We first studied duration and
magnitude of both analgesia and hyperalgesia induced by intermittent or
once-daily administrations of the same dose of heroin. Second, we
tested the ability of a small heroin dose to induce delayed hyperalgesia and the ability of naloxone to precipitate hyperalgesia in
rats treated previously with higher heroin doses. Third, the consequences of NMDA receptor blockade on these phenomena were also examined.
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MATERIALS AND METHODS |
Animals. Experiments were performed on adult male
Sprague Dawley rats (IFFA-CREDO, L'Arbresle, France), weighing
350-400 gm, housed in groups of five per cage under a 12 hr light/dark
cycle (lights on at 8:00 A.M.) in a constant room temperature of
22 ± 2°C. The animals had ad libitum access to food
and water. Pharmacological tests and care of the animals were performed
in accordance with the National Institutes of Health Guide for
the Care and Use of Laboratory Animals.
Drugs. Diacetyl morphine hydrochloride (heroin) was
purchased from Francopia (Gentilly, France), naloxone hydrochloride was from Sigma (Saint-Quentin Fallavier, France), and MK-801
(dizocilpine maleate) was from Research Biochemicals International
(Natick, MA). All drugs were dissolved in normal saline (0.9%) and
administered subcutaneously (100 µl/100 gm body weight). Control
animals received equivolumic saline injections.
Nociceptive tests. Nociceptive thresholds were evaluated by
using a modification of the Randall-Selitto method (Kayser et al.,
1990), the paw-pressure vocalization test, in which a constantly increasing pressure is applied to the hindpaw until the rat squeaks. The Basile analgesimeter (Apelex, Massy, France; tip diameter of the
stylus: 1 mm) was used. A 600 gm cutoff value was set to prevent tissue damage.
General procedure. After arrival in the laboratory, animals
were allowed 5 d to become accustomed to the colony room. To avoid stress from the experimental conditions, which might affect measurement of the nociceptive threshold by producing stress-induced analgesia (Amir and Amit, 1978), the experiments were performed by the same experimenter in quiet conditions in a test room close to the colony room. For 2 weeks before the start of the experiments, the animals were
weighed daily, handled gently for 5 min, and placed in the test room
for 2 hr to become accustomed to the nociceptive apparatus. To ensure
basal value stability, a nociceptive threshold measurement was also
performed on the day preceding the scheduled experimental day. All
experiments began at 11:00 A.M. and were performed on groups of five to
nine animals during the light part of the cycle.
Experimental protocols. Because we observed previously that
the early analgesic effect of opiates was followed by a delayed hyperalgesic effect for several days (Laulin et al., 1998;
Célèrier et al., 2000), we examined both the short-term
(2-4 hr) and long-term (1-8 d) changes in nociceptive threshold
induced by repeated heroin administrations. Two kinds of heroin
administration protocols (intermittent or once daily) were used in this
study. In the first protocol (protocol 1), five heroin administrations
were performed according to an intermittent procedure: each heroin
administration (1.25 mg/kg) was performed only when the delayed
hyperalgesia induced by the preceding heroin administration had ended.
According to this protocol, nociceptive threshold was measured every 30 min after each heroin injection until the end of the pharmacological effect on the heroin injection day. The nociceptive threshold was also
measured once daily until recovery of the pre-drug value. In the second
protocol (protocol 2), 12 once-daily administrations of heroin (0.3 or
2.5 mg/kg) were performed. According to this protocol, nociceptive
threshold was measured every 30 min after the 1st and 12th heroin
injection until the end of the pharmacological effect on the heroin
injection day. The nociceptive threshold was also measured once daily
between the 1st and 12th heroin injections and after the cessation of
heroin injection until recovery of the pre-drug value. In the two
protocols, basal nociceptive threshold measurement was performed just
before every heroin administration.
At the end of these two protocols, when all animals had recovered their
pretreatment nociceptive threshold value, two types of tests (separate
groups) were performed: (1) a heroin test that consisted of comparing
the effectiveness of a low heroin dose (0.2 or 0.3 mg/kg) for inducing
early analgesia and delayed hyperalgesia in saline- and heroin-treated
rats and (2) a naloxone test to assess the magnitude of
naloxone-precipitated hyperalgesia in saline- and heroin-treated rats
by evaluating the decrease of the nociceptive threshold 5 min after
administration (1 mg/kg, s.c.).
Statistical analysis. One-way and two-way ANOVAs were used
for assessing time effects of drugs and individual group comparisons. When significant effect was observed, post hoc analyses were
performed using Dunnett's test. Student's t tests were
used for assessing paired comparison between basal nociceptive
threshold values and area under the curves (AUCs), or for evaluating
changes in nociceptive threshold induced by naloxone. AUCs for
analgesic effects were calculated using the trapezoidal method as
performed previously (Célèrier et al., 2000). Statistical
significance criterion was p < 0.05.
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RESULTS |
Changes in pain sensitivity associated with intermittent
heroin administrations
As shown in Figure
1A, no change in the
analgesic effect of 1.25 mg/kg heroin was observed when using the
intermittent heroin injection according to protocol 1 (AUC comparison;
F(4,56) = 0.80, NS). Further
statistical analysis of the time course (0-4 hr) of the changes in
nociceptive threshold showed that the analgesic effect of the fifth
heroin administration on day 25 is similar to the analgesic effect of
the first heroin administration on day 1 (F(9,252) = 1.13, NS). Moreover, no
difference in the analgesic effect of 0.30 mg/kg heroin was observed in
saline- and heroin-treated rats when the opiate was injected at the end
of protocol 1 on day 37 (Fig. 1A) (AUC comparison;
Student's t test, NS).
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Figure 1.
Effects of five intermittent heroin (1.25 mg/kg,
s.c.) or saline administrations (black arrows) on
nociceptive threshold in rats (n = 10-15 rats per
group). A, Histograms represent the analgesic index
(AUC) of each heroin administration evaluated on days 1, 4, 9, 17, and
25 and the analgesic effect of a low heroin dose (0.3 mg/kg, s.c.;
white arrow) on day 37 in both the saline- and
heroin-treated groups. B, Changes in basal nociceptive
threshold determined by once-daily measurement of the nociceptive
threshold. Mean pressure values for triggering vocalization (±SEM)
were expressed in grams. *p < 0.05 and
**p < 0.01 with Dunnett's test as compared with
saline group. C, Effects of naloxone (1 mg/kg, s.c.;
white arrow) on basal nociceptive threshold in saline-
or heroin-treated rats. Naloxone was injected when animals had
recovered their initial nociceptive threshold value after the first or
fifth heroin administrations (days 4 and 33, respectively). The
nociceptive threshold was measured 5 min after naloxone
injection. Separate experiments were conducted for each naloxone test.
Mean pressure values (±SEM) were expressed as a percentage of basal
value. **p < 0.01 with Student's t
test as compared with pre-naloxone basal nociceptive value on day 4 or
day 33.
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Conversely, the intermittent heroin administrations induced a
progressive enhancement in both amplitude and duration of the heroin-induced delayed hyperalgesia (Fig. 1B).
Twenty-four hours after the first 1.25 mg/kg heroin administration, a
marked decrease in the nociceptive threshold was observed for 2 d
in the heroin group as compared with the saline group threshold
(F(1,23) = 8.60; p < 0.01; Dunnett's test, p < 0.05). The second, third,
fourth, and fifth heroin administrations produced more and more
hyperalgesia because significant decreases in nociceptive threshold
were observed for 3, 6, 5, and 6 d, respectively
(F(1,23) = 5.77, p < 0.05; F(1,23) = 13.53, p < 0,01; F(1,23) = 6.34, p < 0.05;
F(1,23) = 9.29, p < 0.01, respectively; for the first, second, third, fourth, and fifth
administration, Dunnett's test, p < 0.05). In
contrast, the five intermittent saline administrations produced no
change in the basal nociceptive threshold
(F(3,27) = 0.95, F(5,45) = 0.47, F(8,72) = 0.39, F(8,72) = 0.56, and
F(8,72) = 0.79, respectively, for the
first, second, third, fourth, and fifth administration; NS). To further
evaluate sensitization of heroin-induced delayed hyperalgesia, we
injected a low heroin dose (0.30 mg/kg) in both saline- and
heroin-treated rats on day 37 (when heroin-treated rats had recovered
their pre-drug nociceptive threshold value). In saline-treated rats the
administration of the low heroin dose was ineffective for inducing a
delayed hyperalgesia (Fig. 1B) (F(5,45) = 0.24, NS). In contrast, 0.3 mg/kg heroin provoked a large decrease of the nociceptive threshold 24 hr after the opiate injection in heroin-treated rats (Fig.
1B) (F(4,56) = 10.25, p < 0.0001; Dunnett's test as compared with
saline group, p < 0.05).
Naloxone-precipitated hyperalgesia was also studied in both saline- and
heroin-treated rats. When animals had recovered their pre-drug
nociceptive threshold after the first or fifth 1.25 mg/kg heroin
administrations (days 4 and 33, respectively), injection of naloxone
produced an immediate lowering of the nociceptive threshold below the
basal value ( 32 and 46%, respectively) (Fig. 1C)
(Student's t test, p < 0.05). In contrast,
no significant effect of naloxone was observed when it was administered
in saline-treated groups (Student's t test, NS).
Changes in pain sensitivity associated with once-daily
administration of heroin
Although no significant change in the basal nociceptive threshold
was observed 24 hr after a first exposure to 0.3 mg/kg heroin (Dunnett's test, NS), the 12 repeated once-daily administrations (protocol 2) induced a gradual lowering of the basal nociceptive threshold (hyperalgesia), which peaked at 30% after the 12th heroin
injection (Fig. 2A)
(F(22,396) = 5.74 as compared with saline group, p < 0.0001; Dunnett's test,
p < 0.01). As shown in Figure 2A,
the basal nociceptive threshold value returned to the saline group
value on day 20, i.e., 8 d after cessation of heroin treatment
(Dunnett's test, NS). On the contrary, the basal nociceptive threshold
was not altered by 12 repeated once-daily saline administrations (Fig.
2A) (F(22,198) = 0.30, NS).
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Figure 2.
A, Delayed effects of 12 once-daily
heroin (0.3 mg/kg, s.c.) or saline administrations on basal nociceptive
threshold in rats (n = 10 rats per group). Basal
nociceptive threshold was determined daily before each heroin or saline
administration and after the heroin treatment was stopped. Mean
pressure values for triggering vocalization (±SEM) were expressed in
grams. **p < 0.01 with Dunnett's test as compared
with saline group. B, Effects of naloxone (1 mg/kg,
s.c.; white arrow) on basal nociceptive threshold in
saline- or heroin-treated rats. Naloxone was injected on day 25 when
animals had recovered their pre-drug nociceptive threshold after the
heroin treatment. The nociceptive threshold was measured 5 min after
naloxone injection. Mean pressure values for triggering vocalization
(±SEM) were expressed as a percentage of basal value.
**p < 0.01 with Student's t test
as compared with pre-naloxone basal nociceptive value.
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Twelve repeated once-daily administrations of a higher dose of heroin
(2.5 mg/kg) induced a more marked decrease in the nociceptive threshold
below the saline group value (Fig.
3A)
(F(26,442) = 8.37, p < 0.0001; Dunnett's test, p < 0.01). Such a decrease
is already observed 24 hr after the first 2.5 mg/kg heroin injection, and it peaked at 54% after the 12th heroin injection (Dunnett's test, p < 0.01). As observed previously, the basal
nociceptive threshold is not altered by 12 repeated once-daily saline
administrations (Fig. 3A)
(F(27,243) = 0.54, NS). In a separate
experiment, we also compared the analgesic effect of 0.2 mg/kg heroin
before and after 12 once-daily administrations of 2.5 mg/kg heroin. As shown in Figure 4 and as described
previously (Laulin et al., 1999), we observed no change in both time
course and AUC relating to the analgesic effect of heroin despite the
large shift in the basal nociceptive threshold (group effect:
F(1,16) = 40.96, p < 0.0001; time effect: F(4,64) = 45.21, p < 0.0001; no interaction: F(4,64) = 0.68, NS; Dunnett's test,
p < 0.01). After the cessation of 12 once-daily 2.5 mg/kg heroin administrations, the basal nociceptive threshold value
returned to the saline group value on day 21 (Fig. 3A)
(Dunnett's test, NS).
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Figure 3.
A, Delayed effects of 12 once-daily
heroin (2.5 mg/kg, s.c.) or saline administrations on basal nociceptive
threshold in rats (black arrows; n = 9-10 rats per group). The basal nociceptive threshold was determined
daily before each heroin or saline administration and after the heroin
treatment was stopped. Delayed effects of a low heroin dose (0.2 mg/kg,
s.c.; white arrow) on days 33 when animals had recovered
their pre-drug nociceptive threshold after the heroin treatment. Mean
pressure values for triggering vocalization (±SEM) were expressed in
grams. **p < 0.01 with Dunnett's test as compared
with basal nociceptive value on day 1. B, Effects of
naloxone (1 mg/kg, s.c.; white arrow) on basal
nociceptive threshold in saline- or heroin-treated rats. Naloxone was
injected on day 29 when animals had recovered their pre-drug
nociceptive threshold value after the heroin treatment. The nociceptive
threshold was measured 5 min after naloxone injection. Mean pressure
values for triggering vocalization (±SEM) were expressed as a
percentage of basal value. **p < 0.01 with
Student's t test as compared with pre-naloxone basal
nociceptive value. C, D, Results obtained
in experiment similar to A and B,
respectively, in rats receiving 12 coadministrations of MK-801 (0.15 mg/kg, s.c.) and heroin (or saline). MK-801 was administered 30 min
before each 2.5 mg/kg heroin administration.
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Figure 4.
Changes of the nociceptive threshold induced by
0.2 mg/kg heroin on days 1 and 13 before and after 12 once-daily 2.5 mg/kg heroin administrations (n = 9-15 rats per
group). Mean pressure values (±SEM) were expressed in grams.
Inset indicates comparison of areas under the curve.
**p < 0.01 with Dunnett's test as compared with
saline group.
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When injected in animals that had recovered their pre-drug nociceptive
threshold after 12 once-daily 2.5 mg/kg heroin administrations (day
33), a small heroin dose (0.2 mg/kg) produced a marked decrease of the
nociceptive threshold 24 hr after the opiate injection (Fig.
3A). Such a decrease lasted 3 d
(F(11,84) = 19.22, p < 0.0001; Dunnett's test as compared with saline group value,
p < 0.01). This low heroin dose was ineffective in
producing a delayed hyperalgesia in saline-treated rats
(F(7,63) = 0.65, NS).
When once-daily heroin-treated animals had recovered their pre-drug
nociceptive thresholds (days 25 and 29 for 0.3 and 2.5 mg/kg heroin
injections, respectively), naloxone induced a significant decrease of
26 and 41% in the nociceptive threshold below the basal value (Figs.
2B, 3B) (Student's t test,
p < 0.01). On the contrary, no significant effect of
naloxone was observed in once-daily saline-treated rats (Student's
t test, NS). Strikingly, naloxone still precipitated
hyperalgesia in 2.5 mg/kg heroin-treated rats on day 70, i.e., 2 months
after cessation of the heroin treatment (Table
1) (Student's t test,
p < 0.05).
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Table 1.
Changes in basal nociceptive threshold induced by naloxone
on day 70, i.e., 58 d after cessation of the 12 once-daily heroin
or saline administrations (n = 8-9 rats per group)
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Preventive effect of MK-801 on both heroin-induced delayed
hyperalgesia and naloxone-precipitated hyperalgesia
When injected 30 min before each 12 once-daily administrations of
2.5 mg/kg heroin, the noncompetitive NMDA receptor antagonist MK-801
(0.15 mg/kg) totally prevented the progressive decrease in the
nociceptive threshold (Fig. 3C)
(F(27,216) = 1.05, NS). In a control
experiment, MK-801 treatment induced no change in the basal nociceptive
threshold value when it was performed on the saline-treated group (Fig.
3C) (F(27,243) = 0.48, NS).
In the MK-801-heroin coadministration schedule, a low heroin dose (0.2 mg/kg) was ineffective in inducing delayed hyperalgesia when injected
on day 33, i.e., 21 d after the heroin treatment had ceased (Fig.
3C) (F(7,56) = 0.56 and
F(7,63) = 0.73 in MK-801-heroin- and
MK-801-saline-treated groups, respectively; NS).
Moreover, naloxone was also unable to precipitate hyperalgesia when it
was injected on day 29 in rats that have received 12 once-daily
MK801-heroin coadministrations (Fig. 3D) (Student's t test, NS). No naloxone effect was observed in the
MK-801-saline-treated group (Fig. 3D) (Student's
t test, NS).
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DISCUSSION |
The first result of this study is that intermittent
administrations of the same dose of heroin induced not only an
analgesic effect but also a long-lasting enhancement in pain
sensitivity (hyperalgesia), as observed with the progressive emergence
of a delayed decrease of the nociceptive threshold for several days. This hyperalgesia cannot be explained by an excess of nociceptive inputs induced by behavioral testing associated with heroin
administration because we reported previously that long-lasting
hyperalgesia is also observed in opiate-treated rats unexposed to
repeated nociceptive stimuli on the day of opiate administration
(Laulin et al., 1998; Célèrier et al., 2000). This
phenomenon appears an actual sensitization of pronociceptive systems
because both magnitude and duration of hyperalgesia increased as a
function of heroin administrations. Indeed, we observed that the first 1.25 mg/kg heroin administration induced moderate hyperalgesia for
2 d, whereas the fifth injection of the same heroin dose was followed by a larger hyperalgesia for 6 d. Our study also shows that repeated 12 once-daily subcutaneous heroin injections induced a
gradual lowering of the nociceptive threshold that progressively disappeared after the cessation of the heroin treatment. Thermal hyperalgesia has also been reported 48 hr after cessation of a series
of 8 once-daily intrathecal injections of morphine (Mao et al., 1994).
Our observation that the administration of a small heroin dose (0.2 or
0.3 mg/kg), which was ineffective in inducing a delayed hyperalgesia
after the first exposure in rats, triggered substantial delayed
hyperalgesia after a series of intermittent or once-daily heroin
administrations is in agreement with the sensitization hypothesis.
Considered as a whole, these results clearly indicate that a repeated
heroin administration schedule induced a sensitization to
heroin-induced delayed hyperalgesia.
The second result of this study is that pain hypersensitivity
progressively disappeared in heroin-treated rats after the cessation of
heroin administrations, as demonstrated by the slow return of the
nociceptive threshold to the pre-drug value. Interestingly, the larger
the decrease of the nociceptive threshold, the larger was the delay to
return to basal pain sensitivity. Two types of processes might account
for this phenomenon. The first one would be a progressive deactivation
of pronociceptive systems according to a mere homeostatic process. The
second one would be a sustained and prolonged activity of the
pronociceptive systems progressively opposed by an active and opposite
counteradaptation that is isodirectional to the first effect of the
opiate (Poulos and Cappell, 1991; Ramsay and Woods, 1997), i.e., pain
inhibition by endogenous analgesic systems (Fig.
5). Although a progressive deactivation
of pronociceptive systems after the cessation of heroin administrations
could not be excluded totally, our results strongly suggest a critical
role for the second process. This is supported by the effectiveness of
naloxone in precipitating hyperalgesia in rats that had recovered their
pre-drug nociceptive threshold value after stopping heroin administration. Although the effectiveness of naloxone in precipitating hyperalgesia was only slightly increased between the first and fifth
heroin injections (32 and 48% decrease of the nociceptive threshold,
respectively) in the intermittent heroin injection schedule, our
observation that the naloxone-precipitated hyperalgesia was maintained
for 2 months after a series of 12 daily heroin administrations had
ended (35% decrease of the nociceptive threshold) provides evidence
that compensatory mechanisms permitting maintenance of the pre-drug
nociceptive threshold value were sustained for a long time. Because an
opioid receptor antagonist, which was ineffective in control heroin
naive rats, induced a pharmacological effect such as hyperalgesia, this
means either that opioid receptors were stimulated by a compensatory
increase of endogenous opioid ligands or that signaling activity of
opioid receptors is enhanced. Indeed, it has been reported that opioid
agonist stimulation results in a gradual conversion of the µ opioid
receptor into a sensitized or constitutively active state (Wang et al.,
1994; Bilsky et al., 1996) and upregulation of the cAMP pathway
(Nestler, 1992). Although these three mechanisms may account for
the naloxone-precipitated hyperalgesia, the unmodified analgesic
effects of heroin in this model of discontinuous administration favors
the hypothesis of an increase of endogenous opioid ligands. Studies are
in progress in our laboratory to identify the nature of endogenous
opioids that could be involved in this adaptive process, permitting a return to basal nociceptive threshold. Taken together, these studies suggest that heroin-deprived animals were, for a very long-time, in a
new biological state associated with a high-level balance between
opioid-dependent analgesic systems and pronociceptive systems that mask
one another (Fig. 5). This is in agreement with the compensatory
response hypothesis (Wise, 1988; Schulteis and Koob, 1996; Robinson and
Berridge, 2000), especially the opponent process theory (Solomon,
1980).
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Figure 5.
Simplified schematic model illustrating the
putative neuroadaptative continuum model linking sensitization,
apparent tolerance, and hyperalgesic withdrawal symptom. Before the
first exposure to heroin, an initial equilibrium
(homeostasis) is associated with a low level balance
between opioid-dependent analgesic systems (a)
and NMDA-dependent pronociceptive systems (b) as
indicated by the naloxone ineffectiveness in precipitating
hyperalgesia. Dotted line represents the sum of the
systems activity of a and b. Functioning
levels of the latter are represented by the column height. Repeated
heroin administrations induces a gradual decrease in the nociceptive
threshold (Pronociceptive systems sensitization) leading
to hyperalgesic state. This progressively shifts the unchanged
analgesic response, giving the impression of less analgesia (apparent
tolerance). After heroin treatment is stopped (Withdrawal),
the return to pre-drug nociceptive threshold is not underlain by a
deactivation of pronociceptive systems but is supported by an
endogenous opioid system counteradaptation. The new equilibrium
(allostasis) is associated with a high-level balance
between opioid-dependent analgesic systems and NMDA-dependent
pronociceptive systems leading to a long-term pain vulnerability.
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The third result of our study is that, unlike sensitization of
heroin-induced hyperalgesia observed after repeated administration, a
change in heroin-induced analgesia was never observed. As reported earlier (Laulin et al., 1999), we observed that both time course and
AUC related to the analgesic effect of heroin were unchanged when the
opiate was injected during the hyperalgesic phase induced by heroin.
During the hyperalgesic period, the shift of the nociceptive threshold
is actually what produced the impression of less analgesia, i.e.,
apparent tolerance. Moreover, this study showed that the analgesic
effect of heroin was also unchanged when heroin is administered in
heroin-treated animals that recovered their pre-drug nociceptive threshold value after cessation of heroin administrations, and it is in
agreement with some studies showing that intermittent exposure may lead
to sensitization of a drug effect, whereas continuous exposure to a
drug may lead to tolerance of the same drug effect (Post, 1980). This
could explain why controlled clinical studies report that the dose of
opiates that is required in chronic pain patients to alleviate pain
(intermittent exposure) may remain constant for years on end (Twycross
and McQuay, 1989; Foley, 1991; Portenoy, 1996). Taken together, these
data indicate that the increases of the opiate doses that are sometimes
required to alleviate pain in suffering patients are caused either by
disease progression leading to aggravation of pain, as suggested
previously (Collin et al., 1993; Colpaert, 1996), or by an excessive
enhancement of pain sensitivity induced by repeated opiate
administration, as observed in this study. In this respect, apparent
tolerance to the opiate analgesic effect observed in intermittent
heroin-treated rats appears as a by-product resulting from a pain
sensitization process.
The relationships between apparent tolerance, pain sensitization, and
naloxone-precipitated hyperalgesia observed in intermittent heroin-treated rats lead to the assumption that if the sensitization process was prevented before the drug effect was initiated, apparent tolerance, pain sensitization, and naloxone-precipitated hyperalgesia could not be expressed. Numerous studies demonstrated that the NMDA
receptor antagonist may prevent the expression of sensitization processes (Stewart and Badiani, 1993), especially pain sensitization leading to hyperalgesia, allodynia, and spontaneous pain (Haley and
Wilcox, 1992; Mao et al., 1995; Coderre and Katz, 1997). Of note is the
observation that µ-opioid receptor stimulation triggers the
activation of NMDA receptors by reducing
Mg2+ blocking via intracellular protein
kinase C (PKC) activation (Chen and Huang, 1991, 1992). It has been
suggested that the subsequent increase of intracellular
Ca2+ concentration further stimulates PKC
activity leading to a lasting enhancement of glutamate synaptic
efficiency in a positive feedback (Mao et al., 1995; Coderre and Katz,
1997). The present study shows that the NMDA receptor antagonist
MK-801, when administered just before heroin, not only precluded
sustained heroin-induced delayed hyperalgesia as described previously
(Laulin et al., 1998, 1999) but also prevented the effectiveness of a
small heroin dose to induce a sustained hyperalgesia in heroin-deprived
rats, a critical criterion for sensitization. No apparent tolerance was observed. Moreover, MK-801 also prevented naloxone effectiveness in
precipitating hyperalgesia in heroin-deprived rats that had recovered
their pre-drug nociceptive threshold value. This indicates that
naloxone-precipitated hyperalgesia is the result of the sharp breakdown
of an equilibrium between opioid-dependent analgesic systems and
NMDA-dependent pronociceptive systems. Because NMDA receptor
antagonists can prevent the development of sensitization and long-term
potentiation (Kullmann and Siegelbaum, 1995; Hudspith, 1997), our
results lead to the hypothesis that pain sensitization and some signs
of withdrawal such as hyperalgesia are issued from a neuroadaptive
continuum triggered by opioid receptor stimulation in which
NMDA-dependent pronociceptive systems play a critical role.
| |
FOOTNOTES |
Received Jan. 16, 2001; revised March 9, 2001; accepted March 16, 2001.
This work was supported by Institut National de la Santé et de la
Recherche Médicale, Université Victor Ségalen
Bordeaux 2, Université Bordeaux 1, and Institut Union
Pharmacologique Scientifique Appliquée de la Douleur. E.C. is a
recipient of a doctoral fellowship from the Ministère de
l'Education Nationale, de l'Enseignement Supérieur et de la Recherche.
Correspondence should be addressed to Guy Simonnet, Institut National
de la Santé et de la Recherche Médicale U 259, rue Camille
Saint-Saëns, 33077 Bordeaux, France. E-mail:
gsimonnet{at}yahoo.com.
| |
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TOP
ABSTRACT
INTRODUCTION
