398 CHAPTER 9
lingers there, which causes the receiving neuron to fi re even when relatively
little dopamine has been released by the sending neuron (Koob & Bloom,
1988; Koob, Sanna, & Bloom, 1998). Thus, relatively little stimulation can
produce pleasurable sensations.
A similar mechanism is at work when someone takes methamphet-
amine. Again, the drug binds to the molecules that transport excess do-
pamine back to the terminal buttons and prevents them from operating
effectively—thereby leaving more dopamine in the synapse, which in turn
activates the dopamine reward system. Long-term use of methamphet-
amine disrupts the functioning of these transporter molecules. Moreover,
as shown in Figure 9.7, not all of the damage infl icted on the brain by long-
term methamphetamine abuse is reversible. The images in the fi gure show
the distribution of dopamine transporters in the brain of a person who
abused methamphetamine. As is evident, even 2 years after the person stopped using
methamphetamine, the neurological effects of chronic abuse are not totally reversed.
Brain Systems and Neural Communication II: Beyond Dopamine
In this book we have emphasized that brain areas work together in systems, and
often more than one system is involved in producing a particular behavior. This is
true of stimulant abuse in particular, and substance abuse in general. Although the
dopamine reward system plays a crucial role in leading people to abuse drugs, it is
not the whole story. Many other neurotransmitters and their related brain systems
have been implicated in drug abuse, but three are particularly important: gamma-
aminobutyric acid (GABA), glutamate, and serotonin.
The GABAnergic system—the term used for the system of neurons that rely on
the neurotransmitter GABA—appears to play a particular role in the shift from rec-
reational use to abuse and dependence (Brady, 2005; Kalivas & Volkow, 2005). The
GABAnergic system includes part of the frontal lobe—in particular, the prefrontal
cortex—that is involved in motivated behavior (that is, behavior oriented toward a
goal) and thus in drug-seeking behavior (Kalivas & Volkow, 2005).
The glutamate system—which consists of neurons that rely on the neurotrans-
mitter glutamate—also plays a role in the shift from drug use to abuse and depen-
dence. Glutamate receptors abound throughout the cortical and limbic regions that
play a role in drug abuse, and researchers have shown that such receptors help
to produce the reinforcing effects of drugs—which lead some people to become
abusers—and also the negative effects experienced during withdrawal (Kenny &
Markou, 2004). In fact, drugs that block glutamate receptors have been used to
treat cocaine dependence and nicotine dependence (Ait-Daoud et al., 2006).
Finally, the serotonin system—which consists of neurons that rely on the neu-
rotransmitter serotonin—plays a role in the abuse of stimulants. This is not surpris-
ing, given that this system is critical for the regulation of many basic biological
functions, such as eating, drinking water, sexual behavior, and response to pain
(Pihl & Peterson, 1995). Serotonin has been shown, for example, to play a role in
producing the desire for cocaine (Aronson et al., 1995).
However, it’s important to remember that the different neurotransmitters and
brain systems work together and that their effects emerge from their interactions. As
we have described, stimulants lead to increased dopamine production in the nucleus
accumbens (and other dopamine-producing areas), and the higher level of dopamine
not only has direct effects on the reward value of drugs but also indirectly modulates
the activity of the GABAnergic, glutamate, and serotonin systems. These systems
can cause the drug to have rewarding effects and make other rewards (such as a
good meal, an interesting conversation, or a paycheck) feel less valuable (Kalivas &
Volkow, 2005).
Thus, although stimulants in general engage the dopamine reward system, this
effect is not the only reason why some people come to abuse such drugs. Some
stimulants also have more specifi c effects on the brain. For example, MDMA not
only causes dopamine to be released, but also binds to serotonin transporters and
9.7 • Methamphetamine Abuse:
Reversible and Irreversible
Brain Damage (a) This scan shows
the distribution of dopamine transporters
in a normal brain. (b) This scan shows
the brain of a person who had used
methamphetamine over a period of
years; as is evident, even 1 month after
this person stopped using the drug, the
dopamine transporters are still in short
supply. (c) This scan shows the brain of
the same abuser more than a year after
stopping the use of methamphetamine;
although there is some recovery of
function, the effects of chronic abuse are
not completely reversed.
Source: Nora D. Volkow et al., The Journal of
Neuroscience, December 1, 2001, 21 (23):9414–9418.
Figure 9.7
bd
(a)No history of (b) (c)
methamphet-
amine use
1 month after
abuse stops
1 year after
abuse stops