Abnormal Psychology

Understanding Psychological Disorders: The Neuropsychosocial Approach 39

The Axon

Theaxon is the part of the neu-

ron that sends signals when a

neuron fi res. The axon is a long,

threadlike structure covered by a

layer of fatty material, known as

the myelin sheath, that insulates

it electrically. Though a neuron

has only a single axon, it often

branches extensively, allowing

signals to be sent simultane-

ously to many other neurons

(Shepherd, 1999). When a neu-

ron has been stimulated to the

point that it fires, a wave of

chemical activity moves from

the cell body down the axon

very quickly. This wave is called

anaction potential. When the

action potential reaches the end of

the axon, it typically causes chemi-

cals to be released. These chemicals are stored in structures called terminal buttons,

and they affect other neurons, muscles, or glands.

If stimulation does not cause a neuron to fi re when it should, the circuit of

which it is a part will not function correctly—and psychopathology may result. Let’s

consider why a neuron might not fi re when stimulated appropriately.

The Dendrites

Neurons fi re when they are appropriately stimulated. But how are they stimulated?

Two ways: First, through dendrites,which receive signals from other neurons. These

dendrites are highly branched, so a single neuron can receive many different signals

at the same time. Received signals move along the dendrites to the cell body (Kandel,

Schwartz, & Jessell, 2007). Second, in some cases, neurons receive inputs directly on

their cell bodies. Such inputs are produced not only by other neurons, but also by

glial cells. Glial cells are involved in the “care and feeding” of neurons, and act as

a kind of support system (in fact, glialmeans “glue” in Greek; Lambert & Kinsley,

2005). The brain has about ten times as many glial cells as neurons, which implies

that glial cells are important. In fact, researchers have learned that glial cells do much

more than provide support services; they can directly stimulate neurons, and play a

role in modulating input from other neurons (Parpura & Haydon, 2000).

Given the roles of neurons and glial cells in brain function, it is not surprising

that researchers have found that at least some patients with psychological disorders

(specifi cally, the sorts of mood disorders we consider in Chapter 6) have lost both

types of cells. One possible reason for such defi cits may be that stress early in child-

hood (and even to the mother, prior to a child’s birth) can disrupt the development

of both neurons and glial cells (Zorumski, 2005).

Chemical Signals

The way neurons communicate is crucial for understanding psychopathology. In

many cases, psychological disorders involve faulty signaling among neurons, and ef-

fective medications operate by altering the ways in which signals are produced or

processed (Kelsey, Newport, & Nemeroff, 2006). Subsequent chapters of this book

will describe how particular signaling problems contribute to some psychological dis-

orders and how certain medications compensate for such problems. To understand

these problems with chemical signaling, we now need to consider the following: what

Action potential

The wave of chemical activity that moves

from the cell body down the axon when a

neuron fi res.

2.4 • The Neuron

Figure 2.4

f 24 h

g4

Nucleus

Dendrites

Myelin

sheath

Terminal buttons

Cell

body

Axon

Neuralim

puls

e