ChapTER 5 Body Rhythms and Mental States 177and modulates the activity of other neurotransmit-
ters, just a couple of drinks can affect percep-
tion, response time, coordination, and balance,
despite the drinker’s own impression of unchanged
or even improved performance. As one research
team noted, “Alcohol increases mind wandering
while simultaneously reducing the likelihood of
noticing one’s mind wandering” (Sayette, Reichle,
& Schooler, 2009). Alcohol also affects memory:
Information stored before a drinking session
remains intact during the session but is retrieved
more slowly (Haut et al., 1989). Consuming small
amounts does not seem to affect sober mental
performance, but binge drinking—usually defined
as five or more drinks on a single occasion—can
impair later cognitive functioning (Parada et al.,
2012). In other words, a Saturday night binge is
potentially more dangerous than a daily drink.
As for other recreational drugs, there is little
evidence that light or moderate use can damage the
human brain enough to affect cognitive function-
ing, but nearly all researchers agree that heavy or
very frequent use is another matter. In one study,
heavy users of methamphetamine had damage to
dopamine cells and performed more poorly than
other people on tests of memory, attention, and
movement, even though they had not used the
drug for at least 11 months (Volkow et al., 2001).
Under some conditions, the repeated use of
some psychoactive drugs, such as heroin and
tranquilizers, can lead to tolerance: Over time,
more and more of the drug is needed to get the
same effect. When habitual heavy users stop tak-
ing a drug, they may suffer severe withdrawaltolerance Increased
resistance to a drug’s
effects accompanying
continued use.report reactions ranging from mild euphoria to
relaxation or even sleepiness.
Some researchers believe that heavy smoking
of marijuana (which is high in tar) may increase
the risk of lung damage (Barsky et al., 1998; Zhu
et al., 2000). In moderate doses, the drug can inter-
fere with the transfer of information to long-term
memory and impair coordination and reaction
times, characteristics it shares with alcohol. In
large doses, it can cause hallucinations and a sense
of unreality. However, a meta-analysis found only a
small impairment in memory and learning among
long-term users versus nonusers, less than what
typically occurs in long-term users of alcohol and
other drugs (Grant et al., 2003). And there have
been zero deaths reported from marijuana use.
Cannabis has been used therapeutically for
nearly 3,000 years and is one of the fundamental
herbs of traditional Chinese medicine. Its ben-
efits have been affirmed in contemporary medi-
cine as well. It reduces the nausea and vomiting
that often accompany chemotherapy treatment
for cancer and AIDS treatments; it reduces the
physical tremors, loss of appetite, and other symp-
toms caused by multiple sclerosis; it reduces pain;
it helps reduce the frequency of seizures in some
patients with epilepsy; it helps clear arteries; and
it alleviates the retinal swelling caused by glau-
coma (Aggarwal et al., 2009; Ben Amar, 2006;
Grinspoon & Bakalar, 1993; Steffens et al., 2005).
The Physiology of Drug Effects
LO 5.12
Psychoactive drugs produce their effects by acting
on brain neurotransmitters, the chemical sub-
stances that carry messages from one nerve cell
to another. A drug may increase or decrease the
release of neurotransmitters at the synapse; pre-
vent the reuptake (reabsorption) of excess neu-
rotransmitter molecules by the cells that have
released them; or interfere with the receptors
that a neurotransmitter normally binds to (see
Chapter 4). Figure 5.4 shows how one drug,
cocaine, increases the amount of norepinephrine
and dopamine in the brain by blocking the reup-
take of these substances following their release.
Cocaine also increases the availability of serotonin
(Rocha et al., 1998).
Watch the Video What’s In It For Me?: Your Brain
on Drugs at MyPsychLab
The biochemical changes associated with drug
use affect cognitive and emotional functioning. For
example, alcohol activates the receptor for GABA,
the inhibitory neurotransmitter found in virtually
all parts of the brain. Because GABA is so prevalent
Dopamine receptors Postsynaptic neuronPresynaptic
neuronCocaine
molecule
blocking
dopamine
Dopamine reuptake
reuptakeFIguRE 5.4 Cocaine’s Effect on the Brain
Cocaine blocks the brain’s reuptake of dopamine and
norepinephrine, so synaptic levels of these neurotrans-
mitters rise. The result is overstimulation of certain brain
receptors and a brief euphoric high. Then, when the
drug wears off, a depletion of dopamine may cause the
user to crash and become sleepy and depressed.