Chapter 4 - Anatomy Nervous System.pdf

Transcript

Module 1.1
1.2

The Cells of the Nervous System

N o doubt you think of yourself as an individual. You don’t
think of your mental experience as being composed of
pieces... but it is. Your experiences depend on the activity of
Cerebral cortex:
16 billion neurons
a huge number of separate but interconnected cells. To under-
Rest of the brain:
stand the nervous system, the place to begin is to examine the
Less than 1 billion
cells that compose it.
Cerebellum:
69 billion neurons
Neurons and Glia
The nervous system consists of two kinds of cells, neurons
and glia. Neurons receive information and transmit it to other
cells. Glia serve many functions that are difficult to summa- Spinal cord:
rize, and we shall defer that discussion until later in this mod- 1 billion neurons
ule. The adult human brain contains approximately 86 billion
neurons, on average (Herculano-Houzel, Catania, Manger, &
Kaas, 2015; see Figure 1.1). The exact number varies from per-
son to person.
We now take it for granted that the brain is composed of
individual cells, but the idea was in doubt as recently as the
early 1900s. Until then, the best microscopic views revealed
little detail about the brain. Observers noted long, thin fi-
bers between one cell body and another, but they could not
see whether a fiber merged into the next cell or stopped
before it. In the late 1800s, Santiago Ramón y Cajal used
newly developed staining techniques to show that a small
gap separates the tip of a neuron’s fiber from the surface of
the next neuron. The brain, like the rest of the body, consists
Figure 1.1 Estimated numbers of neurons in humans
of individual cells. The numbers differ from one person to another.
(Source: Herculano-Houzel et al., 2015)
Santiago Ramón y Cajal, a Pioneer
of Neuroscience Santiago Ramón y Cajal
(1852–1934)
Two scientists of the late 1800s and early 1900s are widely
How many interesting facts fail to be con-
recognized as the main founders of neuroscience—Charles
verted into fertile discoveries because their
Sherrington, whom we shall discuss in Chapter 2, and the
Bettmann/Getty Images

first observers regard them as natural and
Spanish investigator Santiago Ramón y Cajal (1852–1934). ordinary things!... It is strange to see how
Cajal’s early education did not progress smoothly. At one the populace, which nourishes its imagina-
point, he was imprisoned in a solitary cell, limited to one tion with tales of witches or saints, mysteri-
meal a day, and taken out daily for public floggings—at the ous events and extraordinary occurrences,
age of 10—for the crime of not paying attention during his disdains the world around it as commonplace, monotonous and
Latin class (Cajal, 1901–1917/1937). (And you complained prosaic, without suspecting that at bottom it is all secret, mystery,
about your teachers!) and marvel. (Cajal, 1937, pp. 46–47)

18  

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 1.1 The Cells of the Nervous System   19

Cajal wanted to become an artist, but his father insisted membrane permit a controlled flow of water, oxygen, sodium,
that he study medicine as a safer way to make a living. He potassium, calcium, chloride, and other important chemicals.
managed to combine the two fields, becoming an outstanding Except for mammalian red blood cells, all animal cells
anatomical researcher and illustrator. His detailed drawings of have a nucleus, the structure that contains the chromosomes.
the nervous system are still considered definitive today. A mitochondrion (plural: mitochondria) is the structure that
Before the late 1800s, microscopy revealed few details performs metabolic activities, providing the energy that the cell
about the nervous system. Then the Italian investigator Camillo uses for all activities. Mitochondria have genes separate from
Golgi found a way to stain nerve cells with silver salts. This those in the nucleus of a cell, and mitochondria differ from one
method, which completely stains some cells without affecting another genetically. People with overactive mitochondria tend
others at all, enabled researchers to examine the structure of to burn their fuel rapidly and overheat, even in a cool environ-
a single cell. Cajal used Golgi’s methods but applied them to ment. People whose mitochondria are less active than normal
infant brains, in which the cells are smaller and therefore easier are predisposed to depression and pains. Mutated mitochon-
to examine on a single slide. Cajal’s research demonstrated that drial genes are a possible cause of autism (Aoki & Cortese, 2016).
nerve cells remain separate instead of merging into one another. Ribosomes are the sites within a cell that synthesize new
(Oddly, when Cajal and Golgi shared the 1906 Nobel Prize for protein molecules. Proteins provide building materials for
Physiology or Medicine, they used their acceptance lectures the cell and facilitate chemical reactions. Some ribosomes
to defend contradictory positions. In spite of Cajal’s evidence, float freely within the cell, but others are attached to the
which had persuaded almost everyone else, Golgi clung to the endoplasmic reticulum, a network of thin tubes that trans-
theory that all nerve cells merge directly into one another.) port newly synthesized proteins to other locations.
Philosophically, we see the appeal of the old idea that
neurons merge. We describe our experience as undivided, not The Structure of a Neuron
the sum of separate parts, so it seemed right that all the cells
in the brain might be joined together as one unit. How the The most distinctive feature of neurons is their shape, which
separate cells combine their influences is a complex and still varies enormously from one neuron to another (see Figure 1.3).
mysterious process. Unlike most other body cells, neurons have long branching ex-
tensions. All neurons include a soma (cell body), and most also
have dendrites, an axon, and presynaptic terminals. The tini-
The Structures of an Animal Cell est neurons lack axons, and some lack well-defined dendrites.
Figure 1.2 illustrates a neuron from the cerebellum of a mouse Contrast the motor neuron in Figure 1.4 and the sensory neu-
(magnified enormously, of course). Neurons have much in com- ron in Figure 1.5. A motor neuron, with its soma in the spinal
mon with the rest of the body’s cells. The surface of a cell is its cord, receives excitation through its dendrites and conducts
membrane (or plasma membrane), a structure that separates impulses along its axon to a muscle. A sensory neuron is spe-
the inside of the cell from the outside environment. Most chem- cialized at one end to be highly sensitive to a particular type
icals cannot cross the membrane, but protein channels in the of stimulation, such as light, sound, or touch. The sensory

(nuclear (ribosomes)
envelope)
(nucleolus)
Endoplasmic reticulum
(isolation, modification, transport
Nucleus of proteins and other substances)
(membrane-enclosed region
containing DNA; hereditary control)

Figure 1.2 An electron micro-
graph of parts of a neuron from
the cerebellum of a mouse
The nucleus, membrane, and other
structures are characteristic of most
animal cells. The plasma membrane
is the border of the neuron. Magnifi-
Plasma membrane
cation approximately x 20,000.
(control of material Mitochondrion (Source: Courtesy of Dr. Dennis M. D. Landis)
exchanges, mediation of cell- (aerobic energy
environment interactions) metabolism)

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20 CHAPTER 1 Nerve Cells and Nerve Impulses

neuron shown in Figure 1.5 conducts touch information from
the skin to the spinal cord. Tiny branches lead directly from
the receptors into the axon, and the cell’s soma is located on a
little stalk off the main trunk.
Dendrites are branching fibers that get narrower near
their ends. (The term dendrite comes from a Greek root word
meaning “tree.” A dendrite branches like a tree.) The den-
drite’s surface is lined with specialized synaptic receptors, at
which the dendrite receives information from other neurons.
(Chapter 2 concerns synapses.) The greater the surface area
of a dendrite, the more information it can receive. Many den-
drites contain dendritic spines, short outgrowths that in-
crease the surface area available for synapses (see Figure 1.6).
The cell body, or soma (Greek for “body”; plural: so-
mata), contains the nucleus, ribosomes, and mitochondria.
Most of a neuron’s metabolic work occurs here. Cell bodies
of neurons range in diameter from 0.005 millimeter (mm) to
0.1 mm in mammals and up to a millimeter in certain inverte-
brates. In many neurons, the cell body is like the dendrites—
covered with synapses on its surface.
The axon is a thin fiber of constant diameter. (The term
axon comes from a Greek word meaning “axis.”) The axon con-
veys an impulse toward other neurons, an organ, or a muscle.
Axons can be more than a meter in length, as in the case of ax-
Figure 1.3 Neurons, stained to appear dark ons from your spinal cord to your feet. The length of an axon
Note the small fuzzy-looking spines on the dendrites.
is enormous in comparison to its width, and in comparison
(Source: Photo courtesy of Bob Jacobs, Colorado College)

Dendrite

Nucleus
Myelin sheath
Presynaptic
Figure 1.4 The components Axon terminals
of a vertebrate motor neuron
The cell body of a motor neuron Axon hillock
is located in the spinal cord. The
parts are not drawn to scale. In Muscle
reality, an axon is much longer in Dendritic fiber
proportion to the soma. Soma spines

Cross section
of skin

Sensory
Axon endings
Nucleus Skin
Soma
surface

Figure 1.5 A vertebrate sensory neuron
Note that the soma is located on a stalk off the main trunk of the axon. As in Figure 1.4, the structures are not drawn to scale.

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 1.1 The Cells of the Nervous System   21

B
Afferent
A (to B)

Efferent
Shaft (from A)
1mm Spine

Figure 1.7 Cell structures and axons
It all depends on the point of view. An axon from A to B is an efferent axon
from A and an afferent axon to B, just as a train from Washington to New
York is exiting Washington and approaching New York.

STOP & CHECK
1. What are the widely branching structures of a neuron called?
And what is the long, thin structure that carries information
Figure 1.6 Dendritic spines to another cell called?
Many dendrites are lined with spines, short outgrowths that receive
2. Which animal species would have the longest axons?
incoming information.
(Source: From K. M. Harris and J. K. Stevens, Society for Neuroscience, “Dendritic 3. Compared to other neurons, would an interneuron’s axon be
Spines of CA1 Pyramidal Cells in the Rat Hippocampus: Serial Electron Microscopy relatively long, short, or about the same?
with Reference to Their Biophysical Characteristics.” Journal of Neuroscience, 9 (1989),
2982–2997. Copyright © 1989 Society for Neuroscience. Reprinted by permission.) ANSWERS axon is short.
ron is contained entirely within one part of the brain, its
the feet, nearly 2 meters away. 3. Because an interneu-
elephants have axons that extend from the spinal cord to
to the length of dendrites. Giorgio Ascoli (2015) offers the occur in the largest animals. For example, giraffes and
analogy that if you could expand the dendrite of a reasonably tion to another cell is called an axon. 2. The longest axons
typical neuron to the height of a tree, the cell’s axon and its dendrites, and the long thin structure that carries informa-
branches would extend for more than 25 city blocks. 1. The widely branching structures of a neuron are called
Many vertebrate axons are covered with an insulating
material called a myelin sheath with interruptions known as
nodes of Ranvier (RAHN-vee-ay). Invertebrate axons do not
have myelin sheaths. Although a neuron can have many dendrites, Variations among Neurons
it can have only one axon, but the axon may have branches. The Neurons vary enormously in size, shape, and function. The
end of each branch has a swelling, called a presynaptic terminal, shape of a neuron determines its connections with other cells
also known as an end bulb or bouton (French for “button”). At and thereby determines its function (see Figure 1.8). For ex-
that point the axon releases chemicals that cross through the ample, the widely branching dendrites of the Purkinje cell in
junction between that neuron and another cell. the cerebellum (see Figure 1.8a) enable it to receive input from
Other terms associated with neurons are afferent, effer- up to 200,000 other neurons. By contrast, bipolar neurons in
ent, and intrinsic. An afferent axon brings information into the retina (see Figure 1.8d) have only short branches, and
a structure; an efferent axon carries information away from a some receive input from as few as two other cells.
structure. Every sensory neuron is an afferent to the rest of the
nervous system, and every motor neuron is an efferent from
the nervous system. Within the nervous system, a given neu-
Glia
ron is an efferent from one structure and an afferent to another Glia (or neuroglia), the other components of the nervous
(see Figure 1.7). You can remember that efferent starts with e system, perform many functions (see Figure 1.9). The term
as in exit; afferent starts with a as in admit. If a cell’s dendrites glia, derived from a Greek word meaning “glue,” reflects early
and axon are entirely contained within a single structure, the investigators’ idea that glia were like glue that held the neu-
cell is an interneuron or intrinsic neuron of that structure. rons together. Although that concept is obsolete, the term
For example, an intrinsic neuron of the thalamus has its axon remains. Glia outnumber neurons in the cerebral cortex,
and all its dendrites within the thalamus. but neurons outnumber glia in several other brain areas,

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22 CHAPTER 1 Nerve Cells and Nerve Impulses

Apical
dendrite

Dendrites
Basilar
dendrites
Axon
(a)

Axon

(c)

10 mm

(b) (d)

(e)

Figure 1.8 The diverse shapes of neurons
(a) Purkinje cell, a cell type found only in the cerebellum; (b) sensory neurons from skin to spinal cord; (c) pyramidal cell of the motor area of the cerebral
cortex; (d) bipolar cell of retina of the eye; (e) Kenyon cell, from a honeybee.
(Source: Part e courtesy of R. G. Goss)

especially the cerebellum (Herculano-Houzel et al., 2015; the message to the next neuron (Ben Achour & Pascual, 2012).
Khakh & Sofroniew, 2015). Overall, the numbers are almost This process is a possible contributor to learning and memory
equal. (De Pitta, Brunel, & Volterra, 2016). In some brain areas, as-
The brain has several types of glia. The star-shaped trocytes also respond to hormones and thereby influence neu-
astrocytes wrap around the synapses of functionally related rons (Kim et al., 2014). In short, astrocytes are active partners
axons, as shown in Figure 1.10. By surrounding a connection of neurons in many ways.
between neurons, an astrocyte shields it from chemicals cir- Tiny cells called microglia act as part of the immune
culating in the surround (Nedergaard & Verkhatsky, 2012). system, removing viruses and fungi from the brain. They
Also, by taking up the ions and transmitters released by axons proliferate after brain damage, removing dead or damaged
and then releasing them back, an astrocyte helps synchronize neurons (Brown & Neher, 2014). They also contribute to
closely related neurons, enabling their axons to send mes- learning by removing the weakest synapses (Zhan et al.,
sages in waves (Martín, Bajo-Grañeras, Moratalla, Perea, & 2014). Oligodendrocytes (OL-i-go-DEN-druh-sites) in
Araque, 2015). Astrocytes are therefore important for gener- the brain and spinal cord and Schwann cells in the periph-
ating rhythms, such as your rhythm of breathing (Morquette ery of the body build the myelin sheaths that surround and
et al., 2015). insulate certain vertebrate axons. They also supply an axon
Astrocytes dilate the blood vessels to bring more nutri- with nutrients necessary for proper functioning (Y. Lee et al.,
ents into brain areas that have heightened activity (Filosa et al., 2012). Radial glia guide the migration of neurons and
2006; Takano et al., 2006). A possible role in information pro- their axons and dendrites during embryonic development.
cessing is also likely but less certain. According to a popular When embryological development finishes, most radial
hypothesis known as the tripartite synapse, the tip of an axon glia differentiate into neurons, and a smaller number dif-
releases chemicals that cause the neighboring astrocyte to ferentiate into astrocytes and oligodendrocytes (Pinto &
release chemicals of its own, thus magnifying or modifying Götz, 2007).

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 1.1 The Cells of the Nervous System   23

Nancy Kedersha/UCLA/Science Source
Axon

Schwann
cell

Astrocyte
Capillary
(small blood vessel)

Astrocyte Schwann cell

Radial glia

Oligodendrocyte
Myelin sheath

Nancy Kedersha/UCLA/Science Source
Axon

Migrating neuron
Microglia

Microglia

Figure 1.9 Shapes of some glia cells
Oligodendrocytes produce myelin sheaths that insulate certain vertebrate axons in the central nervous system; Schwann cells have a similar function in
the periphery. The oligodendrocyte is shown here forming a segment of myelin sheath for two axons; in fact, each oligodendrocyte forms such segments
for 30 to 50 axons. Astrocytes pass chemicals back and forth between neurons and blood and among neighboring neurons. Microglia proliferate in areas of
brain damage and remove toxic materials. Radial glia (not shown here) guide the migration of neurons during embryological development. Glia have other
functions as well.

STOP & CHECK
4. What are the four major structures that compose a neuron?
5. Which kind of glia cell wraps around the synaptic terminals
of axons?

ANSWERS
terminal. 5. Astrocytes.
4. Dendrites, soma (cell body), axon, and presynaptic

The Blood–Brain Barrier
Neuron Although the brain, like any other organ, needs to receive
Astrocyte nutrients from the blood, many chemicals cannot cross from
the blood to the brain (Hagenbuch, Gao, & Meier, 2002). The
Synapse enveloped
by astrocyte mechanism that excludes most chemicals from the vertebrate
brain is known as the blood–brain barrier. Before we exam-
Figure 1.10 How an astrocyte synchronizes associated axons ine how it works, let’s consider why we need it.
Branches of the astrocyte (in the center) surround the presynaptic ter-
minals of related axons. If a few of them are active at once, the astrocyte
absorbs some of the chemicals they release. It then temporarily inhibits all
Why We Need a Blood–Brain Barrier
the axons to which it is connected. When the inhibition ceases, all of the When a virus invades a cell, mechanisms within the cell ex-
axons are primed to respond again in synchrony.
trude virus particles through the membrane so that the im-
(Source: Based on Antanitus, 1998)
mune system can find them. When the immune system cells

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24 CHAPTER 1 Nerve Cells and Nerve Impulses

discover a virus, they kill it and the cell that contains it. In ef-
Brain tissue
fect, a cell exposing a virus through its membrane says, “Look,
immune system, I’m infected with this virus. Kill me and save Fat-
solu
ble
the others.” mol
ecu
This plan works fine if the virus-infected cell is, for exam- le
ple, a skin cell or a blood cell, which the body replaces easily.
Gluc
However, with few exceptions, the vertebrate brain does not ose
tran
replace damaged neurons. If you had to sacrifice brain cells spor
t
whenever you had a viral infection, you would not do well! To
minimize the risk of irreparable brain damage, the body lines Ami
no-a
the brain’s blood vessels with tightly packed cells that keep out cid
tran
most viruses, bacteria, and harmful chemicals. spor
t
However, certain viruses do cross the blood–brain bar-
rier (Kristensson, 2011). What happens then? When the ra-
bies virus evades the blood–brain barrier, it infects the brain
and leads to death. The spirochete responsible for syphilis also Charged
penetrates the blood–brain barrier, producing long-lasting molecules
and potentially fatal consequences. The microglia are more –
CO2 +
effective against several other viruses that enter the brain, Cell wall tight
mounting an inflammatory response that fights the virus with- junction
out killing the neuron (Ousman & Kubes, 2012). However,
CO2
this response may control the virus without eliminating it.
When the chicken pox virus enters spinal cord cells, virus Endothelial cell
particles remain there long after they have been exterminated O2
from the rest of the body. The virus may emerge from the spi- Large O2
nal cord decades later, causing a painful condition called shin- molecule
gles. Similarly, the virus responsible for genital herpes hides in
the nervous system, producing little harm there but periodi-
cally emerging to cause new genital infections.
Blood vessel Brain tissue

How the Blood–Brain Barrier Works Figure 1.11 The blood–brain barrier
The blood–brain barrier (see Figure 1.11) depends on Most large molecules and electrically charged molecules cannot cross
from the blood to the brain. A few small, uncharged molecules such as O2
the endothelial cells that form the walls of the capillaries
and CO2 cross easily, as can certain fat-soluble molecules. Active transport
(Bundgaard, 1986; Rapoport & Robinson, 1986). Outside the systems pump glucose and amino acids across the membrane.
brain, such cells are separated by small gaps, but in the brain,
they are joined so tightly that they block viruses, bacteria, and
other harmful chemicals from passage.
“If the blood–brain barrier is such a good defense,” you Ottersen, 2003). For certain other chemicals, the brain uses
might ask, “why don’t we have similar walls around all our active transport, a protein-mediated process that expends
other organs?” The answer is that the barrier keeps out useful energy to pump chemicals from the blood into the brain.
chemicals as well as harmful ones. Those useful chemicals in- Chemicals that are actively transported into the brain include
clude all fuels and amino acids, the building blocks for proteins. glucose (the brain’s main fuel), amino acids (the building
For these chemicals to cross the blood–brain barrier, the brain blocks of proteins), purines, choline, a few vitamins, and
needs special mechanisms not found in the rest of the body. iron (Abbott, Rönnback, & Hansson, 2006; Jones & Shusta,
No special mechanism is required for small, uncharged 2007). Insulin and probably certain other hormones also
molecules such as oxygen and carbon dioxide that cross cross the blood–brain barrier, at least in small amounts,
through cell walls freely. Also, molecules that dissolve in the although the mechanism is not yet known (Gray, Meijer, &
fats of the membrane cross easily. Examples include vitamins Barrett, 2014; McNay, 2014).
A and D and all the drugs that affect the brain—from antide- The blood–brain barrier is essential to health. In people
pressants and other psychiatric drugs to illegal drugs such as with Alzheimer’s disease or similar conditions, the endothe-
heroin. How fast a drug takes effect depends largely on how lial cells lining the brain’s blood vessels shrink, and harmful
readily it dissolves in fats and therefore crosses the blood– chemicals enter the brain (Zipser et al., 2007). However, the
brain barrier. barrier poses a difficulty for treating brain cancers, because
Water crosses through special protein channels in nearly all the drugs used for chemotherapy fail to cross the
the wall of the endothelial cells (Amiry-Moghaddam & blood–brain barrier.

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 1.1 The Cells of the Nervous System   25

STOP & CHECK sperm also rely overwhelmingly on glucose.) Because metab-
olizing glucose requires oxygen, neurons need a steady supply
6. Identify one major advantage and one disadvantage of having of oxygen. Although the human brain constitutes only about
a blood–brain barrier. 2 percent of the body’s weight, it uses about 20 percent of its
7. Which chemicals cross the blood–brain barrier passively? oxygen and 25 percent of its glucose (Bélanger, Allaman, &
8. Which chemicals cross the blood–brain barrier by active Magistretti, 2011).
transport? Why do neurons depend so heavily on glucose? They can
and sometimes do use ketones (a kind of fat) and lactate for
ANSWERS fuel. However, glucose is the only nutrient that crosses the
certain vitamins, and iron.
membrane. 8. Glucose, amino acids, purines, choline,
passively. So do chemicals that dissolve in the fats of the blood–brain barrier in large quantities.
carbon dioxide, and water cross the blood–brain barrier Although neurons require glucose, glucose shortage is
tage). 7. Small, uncharged molecules such as oxygen, rarely a problem, except during starvation. The liver makes
tage) and also keeps out most nutrients (a disadvan-
glucose from many kinds of carbohydrates and amino acids, as
well as from glycerol, a breakdown product from fats. A more
6. The blood–brain barrier keeps out viruses (an advan-

likely problem is an inability to use glucose. To use glucose,
the body needs vitamin B1, thiamine. Prolonged thiamine
deficiency, common in chronic alcoholism, leads to death of
Nourishment of Vertebrate Neurons neurons and a condition called Korsakoff ’s syndrome, marked
Most cells use a variety of carbohydrates and fats for nu- by severe memory impairments.
trition, but vertebrate neurons depend almost entirely on
glucose, a sugar. (Cancer cells and the testis cells that make

Module 1.1 In Closing

Neurons

What does the study of individual neurons tell us about behav- or axons that cannot find each other. In short, the locations,
ior? Everything the brain does depends on the detailed anat- structures, and activities of your neurons are the basis for
omy of its neurons and glia. In a later chapter we consider the everything you experience, learn, or do.
physiology of learning, where one slogan is that “cells that fire However, nothing in your experience or behavior follows
together, wire together.” That is, neurons active at the same from the properties of any one neuron. The nervous system is
time become connected. However, that is true only if the more than the sum of its individual cells, just as water is more
neurons active at the same time are also in approximately the than the sum of oxygen and hydrogen. Our behavior emerges
same place (Ascoli, 2015). The brain cannot connect dendrites from the communication among neurons.

Summary
1. Neurons receive information and convey it to other cells. 5. Because of the blood–brain barrier, many molecules
The nervous system also contains glia, cells that enhance cannot enter the brain. The barrier protects the nervous
and modify the activity of neurons in many ways. 18 system from viruses and many dangerous chemicals. 23
2. In the late 1800s, Santiago Ramón y Cajal used newly 6. The blood–brain barrier consists of an unbroken wall of
discovered staining techniques to establish that the ner- cells that surround the blood vessels of the brain and spi-
vous system is composed of separate cells, now known as nal cord. A few small, uncharged molecules such as water,
neurons. 18 oxygen, and carbon dioxide cross the barrier freely. So do
3. Neurons contain the same internal structures as other molecules that dissolve in fats. Active transport proteins
animal cells. 19 pump glucose, amino acids, and a few other chemicals
4. Neurons have these major parts: a cell body (or soma), into the brain and spinal cord. Certain hormones, includ-
dendrites, an axon with branches, and presynaptic ing insulin, also cross the blood–brain barrier. 24
terminals. Neurons’ shapes vary greatly depending 7. Neurons rely heavily on glucose, the only nutrient that
on their functions and their connections with other crosses the blood–brain barrier in large quantities. They
cells. 19 need thiamine (vitamin B1) to use glucose. 25

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 Module 3.1

Structure of the Vertebrate
Nervous System

Y our nervous system includes a
huge number of neurons, and
an even huger number of synapses.
Central Nervous System (brown)

Brain
How do all the parts work together
to make one behaving unit? Does Spinal cord
each neuron have a unique func-
tion? Or does the brain operate as
an undifferentiated whole?
The answer is something
between those extremes. Consider
an analogy to human society: Each
individual has a specialty, such as
teacher, farmer, or nurse, but no one
performs any function without the
cooperation of many other people.
Similarly, brain areas and neurons
have specialized functions, but they
perform those roles by means of
connections with other areas.

Terminology to
Describe the Nervous
System
For vertebrates, we distin- Peripheral Nervous System
guish the central nervous sys-
Somatic (blue):
tem from the peripheral nervous Controls voluntary muscles and conveys
system (see Figure 3.1). The sensory information to the central nervous system
central nervous system (CNS) is
Autonomic (red): Controls involuntary muscles
the brain and the spinal cord. The Sympathetic: Expends energy
peripheral nervous system (PNS) Parasympathetic: Conserves energy
connects the brain and spinal

Figure 3.1 The human nervous
system
The central nervous system consists of the
brain and spinal cord. The peripheral ner-
vous system is the nerves outside the brain
and spinal cord.

68  

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 3.1 Structure of the Vertebrate Nervous System   69

Coronal plane Right

Sagittal
plane Dorsal
Left (for brain)

or
Horizontal

r

teri
rio
te
plane

Pos
An

Science Pictures Limited/Science Source
Ventral
(for brain)

Ventral Dorsal (for
(for brainstem brainstem
and spinal and spinal
cord) cord)
Medial Lateral

Dr. Dana Copeland
Dr. Dana Copeland

Dr. Dana Copeland

Horizontal plane Sagittal plane Coronal plane

Figure 3.2 Terms for anatomical directions in the nervous system
In four-legged animals, the dorsal and ventral axes for the head are parallel to those for the rest of the body. However, humans’ upright posture has tilted
the head, so the dorsal and ventral directions of the head are at right angles to those of the spinal cord.

cord to the rest of the body. Part of the PNS is the and the bottom of the brain is ventral (on the stomach side).
somatic nervous system, which consists of the axons con- The same would be true for you if you crawled on your hands
veying messages from the sense organs to the CNS and and knees. However, when humans evolved upright posture,
from the CNS to the muscles. Another part of the PNS, the the position of the head changed relative to the spinal cord.
autonomic nervous system, controls the heart, intestines, For convenience, we still apply the terms dorsal and ventral
and other organs. The autonomic nervous system has some to the same parts of the human brain as other vertebrate
of its cell bodies within the brain or spinal cord and some in brains. Consequently, the dorsal–ventral axis of the human
clusters along the sides of the spinal cord. brain is at a right angle to the dorsal–ventral axis of the spi-
To follow a map, you must understand north, south, east, nal cord. Figure 3.2 also illustrates the three ways of taking
and west. Because the nervous system is three-dimensional, a plane through the brain, known as horizontal, sagittal, and
we need more terms to describe it. As Figure 3.2 and coronal (or frontal).
Table 3.1 indicate, dorsal means toward the back and Table 3.2 introduces additional terms that are worth
ventral means toward the stomach. (A ventriloquist is liter- learning. Tables 3.1 and 3.2 require careful study and review.
ally a “stomach talker.”) In a four-legged animal, the top of After you think you have mastered the terms, check yourself
the brain is dorsal (on the same side as the animal’s back), with the following “Stop & Check” questions.

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70 CHAPTER 3 Anatomy and Research Methods

Table 3.1 Anatomical Terms Referring to Directions Table 3.2 Terms Referring to Parts of the Nervous System
Term Definition Term Definition
Dorsal Toward the back, away from the ventral Lamina A row or layer of cell bodies separated from
(stomach) side. The top of the human other cell bodies by a layer of axons and
brain is considered dorsal because it has dendrites
that position in four-legged animals. Column A set of cells perpendicular to the surface of
Ventral Toward the stomach, away from the dorsal the cortex, with similar properties
(back) side Tract A set of axons within the CNS, also known as
Anterior Toward the front end a projection. If axons extend from cell bodies
Posterior Toward the rear end in structure A to synapses onto B, we say that
the fibers “project” from A onto B.
Superior Above another part
Nerve A set of axons in the periphery, either from
Inferior Below another part the CNS to a muscle or gland or from a
Lateral Toward the side, away from the midline sensory organ to the CNS
Medial Toward the midline, away from the side Nucleus A cluster of neuron cell bodies within the
Proximal Located close (approximate) to the point CNS
of origin or attachment Ganglion A cluster of neuron cell bodies, usually
Distal Located more distant from the point of outside the CNS (as in the sympathetic
origin or attachment nervous system)
Ipsilateral On the same side of the body (e.g., two Gyrus (pl.: gyri) A protuberance on the surface of the brain
parts on the left or two on the right) Sulcus (pl.: sulci) A fold or groove that separates one gyrus
Contralateral On the opposite side of the body (one on from another
the left and one on the right) Fissure A long, deep sulcus
Coronal plane A plane that shows brain structures as
(or frontal plane) seen from the front
was that the entering dorsal roots (axon bundles) carry sensory
Sagittal plane A plane that shows brain structures as
seen from the side information, and the exiting ventral roots carry motor informa-
tion. The cell bodies of the sensory neurons are in clusters of
Horizontal plane A plane that shows brain structures as
neurons outside the spinal cord, called the dorsal root ganglia.
(or transverse plane) seen from above
(Ganglia is the plural of ganglion, a cluster of neurons. In most
cases, a neuron cluster outside the CNS is called a ganglion, and
a cluster inside the CNS is called a nucleus.) Cell bodies of the
STOP & CHECK motor neurons are inside the spinal cord.
In the cross section through the spinal cord shown in
1. What does ventral mean, and what is its opposite? Figures 3.4 and 3.5, the H-shaped gray matter in the center
2. What term means toward the midline, and what is its opposite?
3. If two structures are both on the left side of the body, they are
______ to each other. If one is on the left and the other is on Gray matter White matter Sensory nerve
the right, they are _____ to each other. Central canal
Dorsal root ganglion
4. The bulges in the cerebral cortex are called _______. The Dorsal
grooves between them are called ____.

ANSWERS
sulk, meaning “to pout” (and therefore lie low).
4. gyri; sulci. To remember sulcus, think of the word
dorsal. 2. medial; lateral 3. ipsilateral; contralateral
1. Ventral means toward the stomach side. Its opposite is Motor nerve

The Spinal Cord
The spinal cord is the part of the CNS within the spinal column.
The spinal cord communicates with all the sense organs and Ventral
muscles except those of the head. It is a segmented structure,
and each segment has on both the left and right sides a sen- Figure 3.3 Diagram of a cross section through the spinal cord
The dorsal root on each side conveys sensory information to the spinal
sory nerve and a motor nerve, as Figure 3.3 shows. One of the
cord; the ventral root conveys motor commands to the muscles.
earliest discoveries about the functions of the nervous system

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 3.1 Structure of the Vertebrate Nervous System   71

and parasympathetic nervous systems (see Figure 3.6). The
sympathetic nervous system, a network of nerves that pre-
pare the organs for a burst of vigorous activity, consists of
chains of ganglia just to the left and right of the spinal cord’s
central regions (the thoracic and lumbar areas). These ganglia
have connections back and forth with the spinal cord. Sympa-
thetic axons prepare the organs for “fight or flight,” such as by
increasing breathing and heart rate and decreasing digestive
activity. Because the sympathetic ganglia are closely linked,
they often act as a single system “in sympathy” with one an-
other, although certain events activate some parts more than
others. The sweat glands, the adrenal glands, the muscles that
constrict blood vessels, and the muscles that erect the hairs of
the skin have sympathetic input but no parasympathetic input.
Figure 3.4 Photo of a cross section through the spinal cord The parasympathetic nervous system, sometimes called
The H-shaped structure in the center is gray matter, composed largely of
the “rest and digest” system, facilitates vegetative, nonemer-
cell bodies. The surrounding white matter consists of axons.
(Source: Dr. Keith Wheeler/Science Source)
gency responses. The term para means “beside” or “related to,”
and parasympathetic activities are related to, and generally the
opposite of, sympathetic activities. For example, the sympa-
of the cord is densely packed with cell bodies and dendrites. thetic nervous system increases heart rate, and the parasym-
Many neurons from the gray matter of the spinal cord send pathetic nervous system decreases it. The parasympathetic
axons to the brain or to other parts of the spinal cord through nervous system increases digestive activity, whereas the sym-
the white matter, containing myelinated axons. pathetic nervous system decreases it. The parasympathetic
Each segment of the spinal cord sends sensory informa- system also promotes sexual arousal, including erection in
tion to the brain and receives motor commands from the males. Although the sympathetic and parasympathetic systems
brain. All that information passes through tracts of axons in produce contrary effects, both are constantly active to varying
the spinal cord. If the spinal cord is cut at a given segment, the degrees, and many stimuli arouse parts of both systems.
brain loses sensation from that segment and below. The brain The parasympathetic nervous system is also known
also loses motor control over all parts of the body served by as the craniosacral system because it consists of the cranial
that segment and the lower ones. nerves and nerves from the sacral spinal cord (see Figure 3.6).
Unlike the ganglia in the sympathetic system, the parasym-
The Autonomic Nervous System pathetic ganglia are not arranged in a chain near the spinal
cord. Rather, long preganglionic axons extend from the spinal
The autonomic nervous system consists of neurons that re- cord to parasympathetic ganglia close to each internal organ.
ceive information from and send commands to the heart, in- Shorter postganglionic fibers then extend from the parasym-
testines, and other organs. Its two parts are the sympathetic pathetic ganglia into the organs themselves. Because the para-
sympathetic ganglia are not linked to one another, they act
more independently than the sympathetic ganglia do. Para-