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[RuII(η⁵-C₅H₅)(bipy)(PPh₃)]⁺, a promising large spectrum antitumor agent: cytotoxic activity and interaction with human serum albumin.
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The Persistent Challenge of Developing
Addiction Pharmacotherapies
Sarah E. Swinford-Jackson,1 Charles P. O’Brien,2 Paul J. Kenny,3 Louk J.M.J. Vanderschuren,4
Ellen M. Unterwald,5 and R. Christopher Pierce1
1
Department of Psychiatry, Brain Health Institute, Rutgers University, Piscataway, New Jersey 08854, USA
2
Department of Psychiatry, Perelman School of Medicine, University of Pennsylvania, Philadelphia,
Pennsylvania 19104, USA
3
Department of Neuroscience, Icahn School of Medicine at Mount Sinai, New York, New York 10029, USA
4
Department of Animals in Science and Society, Division of Behavioural Neuroscience, Faculty of Veterinary
Medicine, Utrecht University, 3584 CM, Utrecht, The Netherlands
5
Center for Substance Abuse Research and Department of Pharmacology, Lewis Katz School of Medicine,
Temple University, Philadelphia, Pennsylvania 19140, USA
www.perspectivesinmedicine.org
Correspondence: chris.pierce@rutgers.edu
There are currently effective Food and Drug Administration (FDA)-approved therapies for
alcohol, nicotine, and opioid use disorders. This article will review the development of
eight compounds used in the treatment of drug addiction with an emphasis on pharmacological mechanisms and the utility of preclinical animal models of addiction in therapeutic
development. In contrast to these successes, animal research has identified a number of
promising medications for the treatment of psychostimulant use disorder, none of which
have proven to be clinically effective. A specific example of an apparently promising pharmacotherapeutic for cocaine that failed clinically will be examined to determine whether this
truly represents a challenge to the predictive validity of current models of cocaine addiction.
In addition, the development of promising cocaine use disorder therapeutics derived from
animal research will be reviewed, with some discussion regarding how preclinical studies
might be modified to better inform clinical outcomes.
T
here are currently effective U.S. Food and
Drug Administration (FDA)-approved therapies for alcohol, nicotine, and opioid use disorders.6 In some cases, these therapeutics were
rationally designed and tested using a combination of various animal models of addiction. In
many cases, however, effective drug therapies for
substance use disorders were derived from the
testing of compounds developed for other central nervous system (CNS) disorders (e.g., analgesics and antidepressants), which were tested
clinically in the absence of prior animal research
using addiction models. This article will review
the development of eight compounds that are
6
This is an update to a previous article published in Cold Spring Harbor Perspectives in Medicine [Pierce et al. (2012). Cold Spring Harb
Perspect Med 2: a12880. doi: 10.1101/cshperspect.a012880].
Editors: R. Christopher Pierce, Ellen M. Unterwald, and Paul J. Kenny
Additional Perspectives on Addiction available at www.perspectivesinmedicine.org
Copyright © 2020 Cold Spring Harbor Laboratory Press; all rights reserved
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currently most effective in the treatment of alcohol, opioid, and nicotine use disorders with an
emphasis on pharmacological mechanisms as
well as the utility of animal models of addiction
in the development of these therapeutics. In
contrast to these successes, animal research has
identified a number of promising medications
for the treatment of psychostimulant use disorders, none of which have proven to be effective
clinically. This raises questions about the validity of current animal models of psychostimulant
addiction. A specific example of an apparently
promising pharmacotherapeutic for cocaine use
disorder (the D1 dopamine receptor antagonist
ecopipam) that failed clinically will be examined
to determine whether this truly represents a
challenge to the predictive validity of current
models of cocaine addiction. In addition, the
development of promising cocaine use disorder
therapeutics derived from animal research will
be reviewed.
BUPRENORPHINE AND METHADONE FOR
OPIOID USE DISORDER
The earliest references to animal models of addiction in the literature all referred to work on
opioids, mainly morphine. Research using animal models prior to 1960 used the term addiction loosely given that the drug of abuse was
experimenter delivered. For example, Plant
and Pierce (1928) administered very high doses
of morphine to dogs daily for 2–3 months. Indeed, the doses chosen were toxic in some cases
as the authors reported that “two of our animals
died in convulsions on doses of 190 and 220 mg
per kg” (Plant and Pierce 1928). At that time,
the severity of the withdrawal syndrome was
thought to be the primary factor contributing
to relapse among opioid-dependent humans.
Therefore, Plant and Pierce sought to examine
and characterize opioid withdrawal in animals.
Following cessation of morphine treatment,
they noted that “five of our dogs showed marked
changes in temperament during the first week of
withdrawal, in that they became very cross” and
“one animal died in convulsions on the third day
of withdrawal” (Plant and Pierce 1928). These
authors summed up their observations as fol2
lows: “The period of addiction in dogs has given
a picture that follows closely the description of
addiction in man [including vomiting, constipation, hypersensitiveness, scratching, irritability,
and decrease in narcotic action of the drug].”
Note that Pierce and Plant defined addiction
as opioid withdrawal and tolerance (Plant and
Pierce 1928).
The first valid animal model of addiction
was developed in the early 1960s. As a first
step toward developing a model in which animals self-administer drugs of abuse, two waterdeprived rhesus monkeys were trained to press a
lever to receive intravenous infusions of saline
(Clark et al. 1961). The authors also showed that
saline self-administration could be extinguished
and brought under stimulus control (i.e., the
monkeys would lever press for light cues previously paired with the saline infusions) (Clark
et al. 1961). Subsequently, it was demonstrated
that rats (Weeks 1962) and monkeys (Thompson and Schuster 1964) would self-administer
morphine intravenously.
Although results from the self-administration paradigm have contributed significantly to
the development of more recent addiction pharmacotherapies, the first successes came from
drugs that were developed for other purposes.
For example, methadone, the first truly successful substance use disorder therapeutic, was originally developed at Hoechst in the 1930s as an
analgesic. Methadone was tested for analgesic
efficacy by scientists at Eli Lilly and Company
and Burroughs Wellcome & Company in the
1940s (Scott and Chen 1947; Thorp et al.
1947). In early papers, methadone was sometimes spelled methadon and also was called dolophine. As an aside, it has been erroneously
reported that methadone, which was developed
in Germany, was originally named after Adolf
Hitler (i.e., adolophine). Then, as now, a major
goal of opioid research was to identify effective
analgesics that lacked an addiction liability.
Therefore, methadone was tested by a group of
prominent behavioral pharmacologists whose
findings were summed up as follows: “we believe
that unless the manufacture and use of methadon are controlled addiction to it will become
a serious public health problem” (Isbell et al.
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Developing Addiction Pharmacotherapies
1947). This conclusion was based in part on reports from their recovering opioid-dependent
patients such as: “That is great stuff. I wouldn’t
have believed it possible for a synthetic drug to
be so like morphine. Can you get it outside? Will
it be put under the narcotic laws? I wish I could
get it to kick my next habit.” The authors also
noted that “methadon prevented the appearance
of signs of physical dependence in 12 men who
had been proved to be addicted to morphine”
(Isbell et al. 1947). These observations suggested
that methadone might be used to treat opioid
use disorder. This idea was not tested until the
1960s, with the publication of the landmark
study by Dole and Nyswander (1965), which
demonstrated that methadone relieved “narcotic
hunger” and produced tolerance such that the
euphoric effect of heroin was substantially
blunted (Dole and Nyswander 1965).
Although methadone and morphine are
both full µ-opioid receptor agonists with substantial addiction liabilities, methadone is a
preferable opioid use disorder therapeutic because of a substantially longer half-life and higher oral bioavailability. Methadone distribution is
restricted to clinics to ensure that the drug is
taken orally, which obviates withdrawal and
maintains tolerance in the absence of euphoria.
Methadone is not prescribed for home use because of the legitimate fear that, in the absence of
monitoring, the drug will be solubilized and administered intravenously, thereby producing a
high roughly equivalent to morphine or heroin
administered by the same route. In the case of
methadone, the clinical trial came before animal
studies. Over the years, a number of animal studies have confirmed that methadone prevents
opioid withdrawal and blunts relapse in animal
models of craving (Goode 1971; Jones and Prada
1977; Negus 2006).
Although there is no question that methadone has proven to be effective in the treatment
of opioid use disorder, there are several problems with the methadone clinic model. Primarily, the distance to the closest clinic may render
daily clinic visits unfeasible. For some patients
living in close proximity to a clinic, the stigma
associated with daily visits to a methadone clinic
reduces compliance. A clever pharmacological
strategy was developed to produce a therapeutic
for opioid use disorder that could be taken at the
convenience of the patient. It was noted that
opioid receptor agonists have good oral bioavailability, whereas the opioid receptor antagonist
naloxone does not. Thus, if a pill contains both
compounds and is taken orally, the opioid receptor agonist effect predominates. In contrast,
if the therapeutic is administered intravenously,
the antagonist would block the agonist effect.
This strategy led to the development of Suboxone, which is a combination of buprenorphine
and naloxone. Buprenorphine, which was developed by Reckitt and Colman in the 1970s as an
analgesic, was chosen over methadone because
it is a partial µ-opioid receptor agonist, which, in
contrast to methadone, has a low instance of
death associated with overdose (Mendelson
and Jones 2003). Suboxone was approved by
the FDA for the treatment of opioid use disorder
in 2002 following the passage of DATA 2000 by
the U.S. Congress, which allowed individual
physicians to be certified to prescribe opioidbased therapeutics for the treatment of opioid
use disorder. Although Suboxone rapidly became the first-line prescription treatment for
opioid use disorder (Department of Veterans
Affairs and Department of Defense 2015), limits
on the number of opioid-dependent patients
each physician is allowed to treat have constrained the even wider use of this effective medication. Accessible and effective pharmacotherapeutic treatments for opioid use disorder, like
Suboxone, are particularly important given the
emergence of the opioid epidemic, declared a
public health emergency by the U.S. Department of Health and Human Services in 2017.
NALTREXONE FOR OPIOID USE DISORDER
AND ALCOHOL USE DISORDER
In the early 1970s, receptor-binding assays were
used to show that “narcotic antagonists” such as
naloxone bind to specific receptors in the brain.
Opioid receptor antagonists including naltrexone and naloxone were subsequently tested as
pharmacotherapies for opioid addiction (Martin et al. 1973). The discovery of endogenous
opioids and their receptors prompted research
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S.E. Swinford-Jackson et al.
into the potential role of opioid peptides in the
effects of many drugs including alcohol. Initial
reports suggested that naltrexone and naloxone
reduced alcohol preference in hamsters and rats
(Ross et al. 1976) and attenuated alcohol reinforcement in rhesus monkeys (Altshuler et al.
1980). Based on these and similar findings, a
placebo-controlled, double-blind clinical trial
examining the effect of naltrexone on alcohol
relapse was performed. Results indicated that
naloxone cut the relapse rate approximately in
half compared to controls (Volpicelli et al.
1992). These results were rapidly replicated,
with the highest rates of abstinence observed
in patients who received both naltrexone and
supportive therapy (O’Malley et al. 1992). Numerous trials subsequently showed that naltrexone is effective in the treatment of alcohol use
disorder.
A single-nucleotide polymorphism at
A118G (Asn40Asp) in exon I of the µ-opioid
receptor was identified and shown to triple the
potency of β-endorphin at these receptors (Bond
et al. 1998). This polymorphism was shown to be
associated with alcohol addiction (Bart et al.
2005) and individuals with one or two copies
of the Asp40 allele treated with naltrexone had
significantly lower rates of relapse than patients
homozygous for the Asn40 allele (Oslin et al.
2006). Thus, naltrexone treatment of alcohol
use disorder is one of the few examples of a
pharmacogenomic therapeutic. Naltrexone,
which is marketed as ReVia and Depade, has
been used in the treatment of opioid use disorder
since 1984 and alcohol use disorder since 1995.
In 2006, an extended-release injectable formulation of naltrexone (Vivitrol) was approved by
the U.S. FDA for the treatment of alcohol and
opioid use disorders. Naltrexone and acamprosate are each currently first-line pharmacotherapies for alcohol use disorder in the United
States.
ACAMPROSATE FOR ALCOHOL USE
DISORDER
Acamprosate, a homotaurine derivative, was developed in France in the 1980s. The rationale was
that since alcohol activates GABAA receptors
4
and homotaurine is a GABA receptor agonist,
perhaps homotaurine derivatives might serve as
alcohol replacement therapies (Boismare et al.
1984). Indeed, calcium bis acetylhomotaurine
(acamprosate) significantly reduced the voluntary intake of alcohol by rats (Boismare et al.
1984). Based on this result, acamprosate was
tested in a double-blind placebo-controlled clinical trial with the success criterion defined as
alcohol abstinence following 3 months of outpatient treatment. Results indicated that 20 of 33
patients receiving acamprosate remained alcohol-free compared to 12 of 37 subjects receiving
placebo (Lhuintre et al. 1985). The efficacy of
acamprosate as an effective therapeutic for alcohol use disorder has been repeatedly replicated
(Mason and Heyser 2010). Acamprosate has
been used for the treatment of alcohol use disorder in Europe since 1989. Surprisingly, the
precise mechanism of action of acamprosate remains unclear. Because of the ambiguity of the
drug’s mechanism of action, the U.S. FDA delayed approval of acamprosate (marketed as
Campral) until 2004.
Although acamprosate was targeted for the
treatment of alcohol use disorder because of presumed effects on GABA and taurine transmission, the therapeutic effects of this drug appear
to be due primarily to effects on glutamate systems. Although initial reports suggested that
acamprosate is an NMDA receptor antagonist,
subsequent work indicated that acamprosate
acts as a partial agonist at spermidine sites on
NMDA receptors (Dahchour and De Witte
2000) and also is an mGluR5 receptor antagonist
(De Witte et al. 2005). Alcohol withdrawal is
associated with a number of changes in neurotransmission including, notably, increased glutamate transmission in regions of the CNS
(Mason and Heyser 2010). A growing body of
evidence is consistent with the notion that acamprosate blunts alcohol craving and withdrawal
by normalizing glutamate transmission (Heilig
and Egli 2006).
Disulfiram also is used in the treatment of
alcohol use disorder. However, this drug does
not specifically target aspects of addiction or
withdrawal. Rather, disulfiram blocks aldehyde
dehydrogenase resulting in the accumulation of
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Developing Addiction Pharmacotherapies
acetaladehyde after alcohol ingestion, which
produces an array of aversive symptoms. Thus,
disulfiram acts as a punishing agent in the event
of relapse rather than a therapeutic. Although
disulfiram continues to be used in the treatment
of alcohol use disorder, there are concerns related both to the safety and effectiveness of this
compound (Heilig and Egli 2006).
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NICOTINE, VARENICLINE, AND BUPROPION
FOR NICOTINE USE DISORDER
The history of nicotine replacement therapies
dates to a letter Dr. Claes Lundgren, a physiology
professor at Lund University, sent to his friend
Ove Fernö at Aktiebolaget Leo pharmaceutical
company in 1967. Lundgren and his colleague,
Stephan Lichtneckert, suggested oral nicotine as
a substitute for tobacco based on the observation
that sailors sometimes switched from smoking
to chewing tobacco without difficultly when assigned to submarine duty. Fernö immediately
recognized the promise and commercial potential of nicotine replacement and embarked on a
research program to design a means to orally
administer nicotine with delayed absorption.
The result was nicotine gum. Years later, Fernö
reflected on his work as follows: “Putting nicotine into chewing gum is not an invention. Fixing the nicotine to an ion exchange resin and
putting that into a chewing gum to enable the
chewer to control the rate of release—that is an
invention” (Ferno 1994). Initial clinical trials
performed in Sweden (Ferno et al. 1973) and
London (Russell et al. 1976) in the 1970s indicated that nicotine gum was effective in reducing
nicotine withdrawal and maintaining smoking
abstinence. A landmark randomized doubleblind, placebo-controlled clinical trial published
in 1982 indicated that smoking abstinence was
47% in the nicotine gum group compared to a
21% success rate among controls (Jarvis et al.
1982). These results led to the approval of nicotine gum, which Aktiebolaget Leo (acquired as
McNeil by Johnson & Johnson) named Nicorette, by the U.S. FDA in 1984. Nicotine gum,
nicotine lozenges, patches, nasal sprays, and inhalers are all popular forms of nicotine replacement therapy and are effective in maintaining
abstinence from tobacco use (Polosa and Benowitz 2011). The combination of slow-release
forms like transdermal patches and acute nicotine replacement via lozenges or gum have been
shown to be particularly effective at maintaining
abstinence and reducing craving in meta-analyses of clinical trials (Shah et al. 2008; Lindson
et al. 2019). Electronic cigarettes (or e-cigarettes)
were initially considered as another form of nicotine replacement therapy. However, concerns
about lack of consistent regulations, unknown
long-term health consequences, and the possibility of their use as a “gateway” to smoking
cigarettes or cannabis, particularly among the
youth, all contribute to the failure of any e-cigarettes or similar vaping products to be approved by the FDA as nicotine use disorder
therapeutics (Sharpless 2019).
Animal studies are notably absent in the history of Nicorette. More recently, a rational strategy led to the development of the partial nicotinic receptor agonist varenicline for smoking
cessation. Nicotinic acetylcholine receptors
(nAChRs) are pentameric ligand-gated ions
channels composed of combinations of at least
17 different subunits (Pierce and Kumaresan
2006). A number of studies indicate that α4β2
nAChRs, which are the most widely expressed
subtypes in the brain, play a critical role in nicotine-induced dopamine release and reinforcement (Mineur and Picciotto 2008). The α4β2
nAChR partial agonist varenicline was developed
by Pfizer for smoking cessation. The rationale
was that varenicline might serve the dual purpose
of moderately increasing mesolimbic dopamine
levels, which are reduced during nicotine withdrawal, and also blunting nicotine-induced dopamine release in the event of relapse (Coe et al.
2005). Animal studies revealed that varenicline
reduced nicotine-induced dopamine release in
the nucleus accumbens (Coe et al. 2005) and inhibited nicotine self-administration as well as the
reinstatement of nicotine seeking (O’Connor
et al. 2010). A randomized double-blind clinical
trial demonstrated that the smoking abstinence
rate with varenicline was 44% compared with
nearly 18% for placebo (Gonzales et al. 2006;
Jorenby et al. 2006). Notably, measures of nicotine withdrawal and craving also were reduced by
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S.E. Swinford-Jackson et al.
varenicline (Gonzales et al. 2006). Based on these
results, the U.S. FDA fast-tracked approval for
varenicline (Chantix) as a smoking cessation
drug, which was granted in 2006.
The initial varenicline smoking cessation
clinical trials used bupropion as a positive control. The abstinence rate for bupropion was
nearly 30%, which is significantly greater than
placebo but substantially lower than varenicline
(Gonzales et al. 2006; Jorenby et al. 2006). Bupropion, which was developed by Burroughs
Wellcome & Company (now GlaxoSmithKline),
was approved for the treatment of depression by
the U.S. FDA in 1985. A sustained release formulation of bupropion, marketed as Wellbutrin
SR, remains a highly successful antidepressant.
Antidepressants were tested as smoking cessation agents because cigarette smokers have higher rates of depression that may be exacerbated by
nicotine withdrawal (Glassman et al. 1990).
Double-blind placebo-controlled clinical trials
revealed that a sustained-release formulation
of bupropion significantly increased the rate of
smoking cessation (Hurt et al. 1997). Bupropion
was approved for the treatment of nicotine addiction in 1997 and is marketed as Zyban. Similar to other antidepressants, bupropion is a
dopamine and norepinephrine reuptake inhibitor. Interestingly, bupropion also is an nAChR
antagonist at various subtypes including α4β2
(Slemmer et al. 2000), which may account for
the effectiveness of bupropion as a smoking cessation agent relative to other antidepressants.
PSYCHOSTIMULANTS
Despite decades of focused research efforts,
there are no effective pharmacotherapies for
psychostimulant use disorders. Indeed, a broad
range of drugs targeting multiple CNS transmitter systems have been tested as treatments for
psychostimulant dependence without success
(Kampman et al. 2005). Drugs that modulate
dopaminergic transmission were among the first
assessed for the treatment of psychostimulant
addiction both in animal studies and clinical
trials. Dopamine receptors are classified as either D1-like or D2-like. There was substantial
interest in D1-like dopamine receptor antago6
nists as psychostimulant use disorders therapeutics as they lack the sometimes serious extrapyramidal side effects associated with D2-like
dopamine receptor antagonists (Haney and
Spealman 2008). Animal and human laboratory
studies revealed that acute administration of
D1-like dopamine receptor antagonists attenuated the reinforcing effects of cocaine (Romach
et al. 1999; Platt et al. 2002). However, clinical
use of a D1-like dopamine receptor antagonist
requires repeated administrations. Unfortunately, when humans were maintained on
the D1-like dopamine receptor antagonist, ecopipam, cocaine self-administration actually
increased (Haney et al. 2001). This finding is
consistent with results from rhesus monkeys utilizing continuous drug administration (Kleven
and Woolverton 1990) and is likely due to antagonist-induced increases in D1 dopamine receptor
density in the brain (Haney and Spealman 2008).
It is important to emphasize that in the case of
ecopipam, the animal and human data paralleled
one another both when the drug was administered acutely and repeatedly.
Fortunately, there are other examples of rationally developed therapeutics for psychostimulant use disorders that appear promising.
N-acetylcysteine (NAC), which is used to treat
acetaminophen overdose, has been shown to
normalize decreased nucleus accumbens glutamate levels following cocaine self-administration as well as the reinstatement of cocaine-seeking behavior in rats (Baker et al. 2002, 2003).
Clinical trials demonstrate that NAC attenuated
cocaine use and decreased desire to use cocaine
(LaRowe et al. 2007; Mardikian et al. 2007). Recent clinical trials also support the ability of
NAC to reduce incentive salience for cocaine
cues (Levi et al. 2017) and delay relapse in cocaine-abstinent subjects (LaRowe et al. 2013),
suggesting that NAC may be therapeutically
beneficial in maintaining abstinence and/or preventing relapse. Another interesting strategy is
the development of cocaine vaccines. Active immunization with a cocaine vaccine attenuated
cocaine self-administration as well as the reinstatement of cocaine seeking in rats (Kantak
et al. 2000). Clinical data indicate that the cocaine vaccine, TA-CD, produced selective anti-
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Developing Addiction Pharmacotherapies
cocaine antibodies, which blunted the intoxicating effects of cocaine (Haney et al. 2010). In
these studies, insufficient immune responses to
vaccines is a persistent issue, which has led to the
development of novel vaccines designed to generate consistently high antibody titers (Wee et al.
2012). An adenovirus-based cocaine vaccine reduced motivation for cocaine and reinstatement
of cocaine seeking in rats (Wee et al. 2012) and
delayed reacquisition of cocaine self-administration in nonhuman primates (Evans et al.
2016); this cocaine vaccine dAd5GNE is currently under investigation in a phase I clinical
trial. An obvious issue with vaccines is their
specificity. That is, a cocaine vaccine will not
be effective against amphetamine or its derivatives, which might be substituted for cocaine
during a bout of drug craving. Cocaine antibodies also could be whelmed with a sufficiently
high dose of the drug.
In terms of the validity of animal models of
psychostimulant addiction, we note that the preclinical and clinical data are consistent when the
animal model is drug self-administration (Haney and Spealman 2008). Moreover, two of the
more promising cocaine use disorder therapeutics (NAC and cocaine vaccines) were tested
primarily with self-administration models of
addiction and relapse.
SUMMARY AND CONCLUSIONS
We have reviewed the development of the eight
main compounds currently used in the treatment of substance use disorders. As outlined
in Table 1, two of these drugs are antagonists,
one is a transporter inhibitor, two are full agonists, and three are partial agonists. Clearly, the
most successful treatments for addiction involve
receptor stimulation, with the primary goal of
obviating drug withdrawal. Agonist therapeutics
also reproduce some of the positive aspects of
the drug of abuse (e.g., mood elevation), which
enhances compliance. Partial agonists are particularly appealing as they blunt the psychoactive effects of the drug of abuse in the event of
relapse. Moreover, the risk of overdose is substantially diminished with partial relative to full
agonists.
Table 1 Therapeutics used in the treatment of substance use disorders and their mechanism of action
Therapeutic
Acamprosate
Buprenorphine
Bupropion
Methadone
Naloxone
Naltrexone
Nicotine
Varenicline
Drug of
abuse
Mechanism of
action
Alcohol
Opioids
Nicotine
Opioids
Opioids
Alcohol,
opioids
Nicotine
Nicotine
Partial agonist
Partial agonist
Indirect agonist
Agonist
Antagonist
Antagonist
Agonist
Partial agonist
The fact that partial agonists are particularly
effective addiction therapeutics raises the question of partial dopamine agonist treatments for
psychostimulant use disorders (Platt et al. 2002;
Keck et al. 2015). Surprisingly, there is very little
clinical research in this area. Indeed, the only
compound tested clinically is the D2-like dopamine receptor partial agonist aripiprazole,
which is approved for the treatment of schizophrenia, depression, and bipolar disorder. Aripiprazole reduced cocaine reinstatement in rats
(Feltenstein et al. 2007) and decreased the discriminative stimulus properties of amphetamine in a human laboratory study (Lile et al.
2005). Initial clinical trial results have been
mixed with one study reporting that aripiprazole reduced cocaine craving and use (Meini
et al. 2011). In contrast, another clinical trial
showed that aripiprazole increased the self-administration of smoked cocaine, apparently to
compensate for decreased subjective effects of
cocaine (Haney et al. 2011). These experiments
highlight both the promise of partial agonists in
the treatment of psychostimulant use disorders
and the persistent frustration in developing
clearly effective therapeutics for stimulant craving and addiction.
Overall, it is clear that a disconnect exists
between even well-designed preclinical studies
that identify potential addiction pharmacotherapies and clinical outcomes in patients with substance use disorders. One important factor may
be sex differences in the responsiveness to any
given treatment. In 2016, the National Institutes
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S.E. Swinford-Jackson et al.
of Health instituted a requirement that all research studies account for sex as a biological
variable. Increased preclinical focus on sex
may clarify whether the effects of potential pharmacotherapies are dependent on sex, expanding
upon previous studies that may have been predominantly performed in males. Personalized
medicine strategies could also unlock new treatments for substance use disorders. Pharmacogenomic approaches that tailor treatment to
individuals based on single-nucleotide polymorphisms, illustrated above by improved outcomes of naltrexone treatment for alcohol use
disorder in patients with the Asp40 allele (Oslin
et al. 2006), are excellent examples of how individual differences can be leveraged for better
pharmacotherapeutic development and implementation.
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The Persistent Challenge of Developing Addiction Pharmacotherapies
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