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C H A P TE R 15

The executive brain

CONTENTS

Anatomical and functional divisions of the prefrontal cortex 387
Executive functions in practice 390
The organization of executive functions 398
The role of the anterior cingulate in executive functions 411
Summary and key points of the chapter 413
Example essay questions 414
Recommended further reading 414

The executive functions of the brain can be defined as the complex processes
by which an individual optimizes his or her performance in a situation that
requires the operation of a number of cognitive processes (Baddeley, 1996).
A rather more poetic metaphor is that the executive functions are the brain’s
conductor, which instructs other regions to perform, or be silenced, and
generally coordinates their synchronized activity (Goldberg, 2001). As such,
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executive functions are not tied to one particular domain (memory, language,
perception and so on) but take on a role that is meta-cognitive, supervisory
or controlling. Executive functions have traditionally been equated with the
frontal lobes, and difficulties with executive functioning have been termed as
“frontal lobe syndrome.” More accurately, executive functions are associated
with the prefrontal cortex (PFC) of the frontal lobes, and it is an empirically
open question as to whether all aspects of executive function can be localized
to this region. Primates, relative to other mammals, have disproportionately
more gray matter in their frontal lobes (Bush & Allman, 2004) and humans,
relative to other primates, have further disproportionately enlarged this region
of their brain (Donahue et al., 2018). This is shown in Figure 15.1.
The concept of executive functions is closely related to another distinction
with a long history in cognitive science—namely, that between automatic
and controlled behavior (e.g., Schneider & Shiffrin, 1977). This distinction

DOI: 10.4324/9781351035187-15

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 386 THE STUDENT’S GUIDE TO COGNITIVE NEUROSCIENCE

KEY TERM has already been encountered in another context, namely the production of
actions. When driving a car, one may accelerate, change gear and so on, in an
Executive functions apparently “autopilot” mode. But if the traffic is diverted through an unfamiliar
Control processes that
route, then one would need to override the automatic behavior and exert
enable an individual to
optimize performance in online control. This is often assumed to require the use of executive functions
situations requiring the (Norman & Shallice, 1986). The same logic may also apply in situations that
operation and coordina- lack motor output, i.e., in the online control of thoughts and ideas. This
tion of several more ba- provides humans (and possibly other species) with a remarkable opportunity;
sic cognitive processes. namely, to mentally simulate scenarios and think through problems “in the
mind” without necessarily acting them out. It is hardly surprising, therefore,
that some theories of executive function are effectively synonymous with
aspects of working memory (Baddeley, 1996; Goldman-Rakic, 1996).
Two other general points are in need of mention in this preamble. First,
the extent to which behavior is “automatic” (i.e., not requiring executive
function) versus “controlled” (i.e., requiring executive function) may be a
matter of degree rather than all or nothing. Even when generating words in
fluent conversation, some degree of executive control may be exerted. For
example, one may need to select whether to say the word “dog,” “doggy,”
“Fido” or “Labrador” depending on pragmatic context, rather than
relying on, say, the most frequent word to be selected. Second, one must
be cautious about falling into the trap of thinking that controlled behavior
requires an autonomous controller. This is the so-called homunculus
problem: think of a little man inside your head making your decisions, and
then imagine another little man in his head making his decisions, and so
on. Control may be an outcome of multiple competing biases rather than
the presence of a controller. Decisions may arise out of an interaction of
environmental influences (bottom-up processes) and influences related to
the motivation and goals of the person (top-down processes). The sight
of a cream cake may trigger an “eat me” response, but whether one does
eat it may depend on whether one is hungry or dieting. This basic idea

FIGURE 15.1: Enlargement
of frontal cortex shows an
evolutionary progression
(the brains are not drawn to
scale). In humans, this region
occupies almost a third of the
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cortical volume.
Adapted from Fuster, 1989.

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 THE EXECUTIVE BRAIN 387

has already been introduced from the perspective of attention (Chapter 9)
and action (Chapter 10), and will be explored here from the perspective of
performing tasks with novel or complex configurations.
This chapter first considers the major anatomical divisions within the
prefrontal cortex. The subsequent section outlines the main types of cognitive
tests that are believed to depend critically on the functioning of the prefrontal
cortex. The chapter then considers different possible functional organizations of
the prefrontal cortex: for instance, different functional roles for the lateral versus
orbital surfaces; different functional roles for posterior versus anterior portions
of the lateral surface; and hemispheric differences. Before discussing executive
functions, it is worthwhile to review the anatomy of the prefrontal cortex.

A N AT O M I C AL AND FUNCTIONAL DIVISIONS OF
T H E P R E F RO N TAL C O R T EX
The most basic anatomical division within the prefrontal cortex is that
between the three different cortical surfaces (Figure 15.2). The lateral surface
of the prefrontal cortex lies anterior to the premotor areas (Brodmann’s area
6) and the frontal eye fields (in Brodmann’s area 8). This surface lies closest
to the skull. The medial surface of the prefrontal cortex lies between the two
hemispheres and to the front of the corpus callosum and the anterior cingulate
cortex. In terms of anatomy, the anterior cingulate is not strictly part of the
prefrontal cortex, but it does have an important role to play in executive
functions and, as such, will be considered in this chapter. The orbital surface
of the prefrontal cortex lies above the orbits of the eyes and the nasal cavity.
The orbitofrontal cortex is functionally, as well as anatomically, related to the
ventral part of the medial surface (termed ventromedial prefrontal cortex)
(Öngür & Price, 2000). The terms orbito- and ventromedial PFC are sometimes
used interchangeably when finer anatomical divisions are not necessary.
The prefrontal cortex has extensive connections with virtually all
sensory systems, the cortical and subcortical motor system and structures
involved in affect and memory (Yeterian et al., 2012). There are also extensive
connections between different regions of the prefrontal cortex. These
extensive connections enable the coordination of a wide variety of brain
processes. The lateral prefrontal cortex is more closely associated with sensory
inputs than the orbitofrontal cortex. It receives visual, somatosensory and
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auditory information, as well as receiving inputs from multimodal regions
that integrate across senses. In contrast, the medial and orbital prefrontal
cortex is more closely connected with medial temporal lobe structures critical
for long-term memory and processing of emotion.
Aside from these gross anatomical divisions, a number of researchers have
developed ways of dividing different regions into separate areas of functional
specialization. These correspond approximately, although not exactly, with
different Brodmann areas (e.g., Fletcher & Henson, 2001; Petrides, 2000;
Stuss et al., 2002). These include areas shown on Figure 15.2 as ventrolateral
(including Brodmann’s areas 44, 45 and 47), dorsolateral (including Brodmann’s
areas 46 and 9), the anterior prefrontal cortex (Brodmann’s area 10) and the
anterior cingulate. These terms are sufficient to capture most of the functional
distinctions discussed in this chapter, but it is to be noted that not all researchers
regard the prefrontal cortex as containing functionally different subregions.

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 388 THE STUDENT’S GUIDE TO COGNITIVE NEUROSCIENCE

Anterior cingulate cortex
Lateral PFC
Pre-SMA

9
9 24
46 32
10
45 44 10

47
25
11 14
11

10 10
12 47 11 11 47 12
Orbital PFC 13 13
14

Brodmann’s Other names Possible functions Possible functions
areas (left hemisphere) (right hemisphere)

44, 45, 47 Ventro-lateral Retrieval and maintenance Retrieval and maintenance
prefrontal cortex of semantic and/or linguistic of visual and/or spatial
(VLPFC) information information
(Areas 44 + 45 on left also
called Broca’s area)
9, 46 Dorso-lateral Selecting a possible range Monitoring and checking
prefrontal cortex of responses, and suppressing of information held in
(DLPFC) inappropriate ones; mind, particularly in
manipulating the contents conditions of uncertainty;
of working memory vigilance and sustained
attention

10 Anterior prefrontal Multi-tasking; maintaining future intentions / goals whilst
cortex; frontal pole; currently performing other tasks or sub-goals. (The medial
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rostral prefrontal portion has been implicated in “theory of mind” – see
cortex Chapter 16)

24 (dorsal) Anterior cingulate Monitoring in situations of response conflict and error
32 (dorsal cortex (dorsal) detection
Pre-SMA

11, 12, 13, Orbito-frontal Executive processing of emotional stimuli (e.g. evaluating
14 cortex rewards and risks)

FIGURE 15.2: The prefrontal cortex has three different surfaces: the lateral surface (top left), the medial surface (top right)
and the orbitofrontal surface (bottom). The numbers refer to Brodmann areas that are discussed in the text.

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 THE EXECUTIVE BRAIN 389

THE EXTRAORDINARY CASE OF PHINEAS GAGE

One of the most famous cases in the neuropsychological
literature is that of Phineas Gage (Harlow, 1993; Macmillan,
1986; Figure 15.3). On September 13, 1848, Gage was
working on the Rutland and Burlington railroad. He was using
a large metal rod (a tamping iron) to pack explosive charges
into the ground when the charge accidentally exploded, push-
ing the tamping iron up through the top of his skull; it landed
about 30 m behind him. The contemporary account noted
that Gage was momentarily knocked over but that he then
walked over to an ox-cart, made an entry in his time book and
went back to his hotel to wait for a doctor. He sat and waited
half an hour for the doctor and greeted him with, “Doctor,
here is business enough for you!” (Macmillan, 1986).
Not only was Gage conscious after the accident, he was
able to walk and talk. Although this is striking in its own right,
it is the cognitive consequences of the injury that have led
to Gage’s notoriety. Before the injury, Gage held a position
of responsibility as a foreman and was described as shrewd
and smart. After the injury, he was considered unemployable
by his previous company; he was “no longer Gage” (Harlow,
1993). Gage was described as

irreverent, indulging at times in grossest profanity …
manifesting but little deference for his fellows, impatient
of restraint or advice when it conflicts with his desires
… devising many plans of future operation, which are
no sooner arranged than they are abandoned in turn for
others.
(Harlow, 1993)

After various temporary jobs, including a stint in Barnum’s
Museum, he died of epilepsy (a secondary consequence of
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his injury) in San Francisco, some 12 years after his accident.
FIGURE 15.3: The skull of Phineas Gage,
Where was Phineas Gage’s brain lesion? This question with tamping iron in situ and a recently
was answered by an MRI reconstruction of Gage’s skull, discovered photograph of Gage. Modern
which found damage restricted to the frontal lobes, partic- reconstructions suggest that his brain
lesion may have been specific to the
ularly the left orbitofrontal/ventromedial region and the left
medial and orbital surfaces of the
anterior region (Damasio et al., 1994). Research suggests prefrontal cortex, sparing the lateral
that this region is crucial for certain aspects of decision mak- surfaces.
ing, planning, and social regulation of behavior, all of which Damasio et al., 1994. From the collection of
Jack and Beverly Wilgus.
appeared to have been disrupted in Gage. Other areas of the
lateral prefrontal cortex are likely to have been spared.

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 390 THE STUDENT’S GUIDE TO COGNITIVE NEUROSCIENCE

The prefrontal cortex is the starting and ending point of various circuits
that pass through the basal ganglia and thalamus (Alexander & Crutcher,
1990). These circuits modify activity in prefrontal cortex (both upwards and
downwards) such that it ultimately affects the probability of behavior. In
motor behavior, these circuits might influence the likelihood of an action and
how vigorous it is (see Chapter 10). In executive functions, it is proposed
that the corresponding prefrontal loop through the basal ganglia acts as
a gatekeeper by, for instance, making the information stored in working
memory less stable so that it can be updated (O’Reilly & Frank, 2006). The
basal ganglia loop to prefrontal cortex is believed to be crucial for learning of
novel tasks and, hence, important for making the transition from controlled
behavior to automatic behavior (O’Reilly & Frank, 2006). This is important
for procedural learning as exemplified by complex tasks such as driving a
car that, eventually, appear effortless. However, note that the basal ganglia
are not normally considered to be responsible for directly determining the
content of ongoing tasks. This depends on interactions between prefrontal
cortex and posterior regions involved in, say, language, perception or
emotion. Instead, the basal ganglia circuits are primarily concerned with task
efficiency and task learning.

EXEC U T I V E FUNCTIONS IN PRACTICE
This section considers some concrete situations in which executive functions
are needed. Evidence will be presented that the prefrontal cortex (or
subregions within it) are important for implementing this kind of behavior.

Working memory
The prefrontal cortex within the frontal lobes is widely recognized as playing
a crucial role in working memory. Most models tend to assume that the
main storage site of information is not within the frontal lobes themselves
but in the posterior cortex, and that the function of the prefrontal cortex
is to keep this information active and/or manipulate the active information
according to current goals.
In Baddeley’s (1986) model, for instance, the notion of the central
executive is effectively synonymous with models of prefrontal functioning.
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Goldman-Rakic’s (1996) account also regards the prefrontal cortex as
implementing a working memory system and draws primarily on animal
lesion studies and single-cell recordings. Lesions to the lateral prefrontal
cortex can impair the ability to hold a stimulus/response in mind over a
short delay (Butters & Pandya, 1969). In one delayed response task, monkeys
were presented with a box in a particular location on the screen. The box
then disappeared and the monkey was required to hold the location “in
mind.” After a delay, they were then required to look at where the target
was previously displayed (Figure 15.4). Single-cell recordings from monkeys
show that some dorsolateral prefrontal neurons respond selectively during
the delay period, suggesting that this is the neural mechanism for holding
locations in mind (Funahashi et al., 1989).

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 THE EXECUTIVE BRAIN 391

FIGURE 15.4: Single-cell recordings in the dorsolateral prefrontal cortex show that different
neurons respond to (a) studying in a target location, (b) holding it “in mind” during a delay,
and (c) responding to the removal of a cue by moving the eyes to that location.
From Goldman-Rakic, 1992. Reprinted with permission of Patricia J. Wynne. www.patriciawynne.com.

Goldman-Rakic (1996) argued that there is a division between the
content of information processed in dorsolateral and ventrolateral regions,
but that the same types of process are used for both. Specifically, she suggests
that ventral regions support working memory for objects and dorsal regions
support spatial working memory (that is, the dorsal and ventral visual
stream is manifested at the level of executive functions). Other evidence is
inconsistent with this view. Rao et al. (1997) report that individual neurons
can change their responsiveness from being object based to being location
based as the demands of the task change, irrespective of whether they are
located in dorsolateral or ventrolateral regions.
Petrides (2000) offers an alternative
account of working memory to that of
Goldman-Rakic. He argues that the
dorsolateral and ventrolateral prefrontal
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regions should be distinguished by the fact
that they are engaged in different types of
process and not that they are specialized for
different types of material (e.g., spatial versus
object based). This is a hierarchical model
of working memory (Figure 15.5). In this
model, the ventrolateral prefrontal cortex
is responsible for activating, retrieving and
maintaining information held in the posterior
cortex. The dorsolateral prefrontal region is
FIGURE 15.5: A hierarchical model of working memory in which
responsible when the information held within ventrolateral prefrontal cortex (VLPFC) activates and maintains
this system requires active manipulation (e.g., information, and the dorsolateral prefrontal cortex (DLPFC)
ordering of information). Petrides and Milner manipulates that information.

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 392 THE STUDENT’S GUIDE TO COGNITIVE NEUROSCIENCE

KEY TERM (1982) found that patients with prefrontal lesions were impaired on a test
of working memory termed the self-ordered pointing task. The patients
Self-ordered pointing
were presented with an array of eight words or pictures and, on the first
task
A task in which partic-
trial, required to pick anyone. On the second trial, they were asked to pick a
ipants must point to different one from the first; on the third trial, they must pick a different one
a new object on each again and so on. As such, they must maintain and update an online record
trial and thus maintain a of chosen items. This is shown in Figure 15.6. Similar studies on monkeys
working memory for previ- suggest the critical region to be the dorsolateral prefrontal cortex (Petrides,
ously selected items. 1995). In a human functional imaging study, Owen et al. (1996) found that
maintaining and updating a record of which locations had been marked was
linked to dorsolateral PFC activity whereas short-term retention of spatial
locations was associated with ventrolateral activity.

Task-setting and problem-solving
Problem-solving is synonymous with many lay notions of what it is to
exhibit intelligent behavior and it is not surprising that executive functions,
and the prefrontal cortex, have been linked to intelligence both within and
across species. For instance, performance on tests of executive function tends
to correlate with each other and also correlates with certain standardized
measures of intelligence (Duncan et al., 1997). In the lab, problem-solving is
often tested by giving an endpoint (a goal) and, optionally, a starting point (a
set of objects) and participants must generate a solution of their own. This
kind of open-ended solution is also referred to as task-setting.
Patients with lesions to the prefrontal cortex often show clinical
symptoms of poor task-setting and problem-solving. To test this formally,
a number of tests have been devised. Shallice (1982) reports a test called the
“Tower of London,” in which patients must move beads from one stake to

FIGURE 15.6: A self-ordered
pointing task based on
Petrides and Milner (1982).
Participants are required
to point to a new object on
each trial and, as such, must
keep an online record of
previous selections.
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 THE EXECUTIVE BRAIN 393

KEY TERMS
FAS Test
A test of verbal fluency in
which participants must
generate words beginning
with a letter (e.g., “F”) in
a limited amount of time.
Stroop Test
FIGURE 15.7: The “Tower of London” task requires beads to be moved from an initial Response interference
position to a specified endpoint. Performance can be measured in terms of time to from naming the ink color
complete task or number of moves taken (relative to the optimal number of moves). of a written color name
From Shallice, 1982. Royal Society of London. (e.g., the word BLUE is
printed in red ink and
participants are asked
another to reach a specified endpoint (Figure 15.7). Patients with damage to
to say the ink color, i.e.,
the left prefrontal cortex take significantly more moves. This implies that they “red”).
perform by trial-and-error rather than planning their moves (see also Morris
Go/No-Go Test
et al., 1997). Functional imaging studies of healthy participants suggest that
A test of response inhibi-
activity within the dorsolateral prefrontal cortex increases with the number tion in which participants
of moves needed to reach the endpoint (Rowe et al., 2001). must respond to a fre-
A number of verbal tests also involve finding solutions to problems in quent stimulus (go trials)
which there is no readily available answer. In the Cognitive Estimates Test but withhold a response
(Shallice & Evans, 1978), patients with damage to the prefrontal cortex are to another stimulus (no-
impaired at producing estimates for questions in which an exact answer go trials).
is unlikely to be known (“How many camels are in Holland?”) but can be
inferred from other relevant knowledge (e.g., camels are only likely to reside
in a small number of zoos). In the FAS Test (Miller, 1984), participants must
generate a sequence of words (not proper names) beginning with a specified
letter (“F,” “A” or “S”) in a 1-minute period. This test is not as easy as it
sounds (have a try) and involves generating novel strategies, selecting between
alternatives and avoiding repeating previous responses. Patients with left
lateral prefrontal lesions are particularly impaired (Stuss et al., 1998).

Overcoming potent or habitual responses
The classic example of overcoming a habitual response is provided
by the Stroop Test (Stroop, 1935). In this task, participants must name
the color of the ink and ignore reading
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the word (which also happens to be a
color name), as shown in Figure 15.8.
The standard explanation is that reading
of words occurs automatically and this
generates a salient incorrect response that
competes with the less-automatic task of
naming colors (MacLeod & MacDonald,
2000). Performance on the Stroop Test has
long been linked with the integrity of the
prefrontal cortex (Perret, 1974).
Go/No-Go Tests involve the participant
making a set of responses to some stimuli FIGURE 15.8: The Stroop Test involves naming the color of the
(“go” trials) but withholding responses to a ink and ignoring the written color name (i.e., “red, green, yellow,
subset of stimuli (“no-go” or “stop” trials). blue, yellow, white”).

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 394 THE STUDENT’S GUIDE TO COGNITIVE NEUROSCIENCE

KEY TERMS The no-go trials are often infrequent, so the participant gets into the habit
of making a response. No-go rules can be defined in terms of simple rules
Impulsivity (e.g., “respond to all stimuli except the letter B”) or more complex rules (e.g.,
A behavioral tendency
“respond to all stimuli except the letter B when it follows another letter B”).
to make immediate
responses or seek imme- Brain activity during successful no-go trials is normally taken as indexing
diate rewards. response inhibition, and the proportion of errors on no-go trials is taken as a
Wisconsin Card Sorting behavioral marker of impulsivity (Perry & Carrol, 2008).
Test Both the Stroop Test and the Go/No-Go Test are related by virtue of the
A test of executive fact that they are typically explained with respect to the concept of inhibition.
functions involving rule Inhibition, in terms of neural activity, has a very specific definition (reduced
induction and rule use. spiking rate) with a well-characterized mechanism at the synaptic level
(more negative post-synaptic membrane potential). Behavioral or cognitive
inhibition simply means reducing the likelihood of a particular thought/
action and the mechanism behind it, at the neuronal level, is not clear. Some
contemporary models of executive function do not rely on the concept of
inhibition at all and rely solely on biasing activation signals, also termed
ONLINE RESOURCES “gain” (Stuss & Alexander, 2007). Certainly, tasks such as the Stroop and
Go/No-Go are likely to involve a variety of functions such as task-setting
To test yourself on the
Stroop Test and on and monitoring ongoing performance, in addition to biasing of competing
task-switching, visit responses (either via gain or inhibition).
the demo test library Contemporary research has suggested that performance on these tasks
(www.testable.org/ is related to particular brain regions rather than the “prefrontal cortex” in
ward). general. A meta-analysis of functional imaging studies of the Go/No-Go task
suggests that a region of the medial prefrontal cortex (specifically the pre-
SMA, pre-supplementary motor area) was common across tasks for No-Go
stimuli with right lateral prefrontal cortex also implicated in more complex
No-Go rules (Simmonds et al., 2008). Studies of patients with damage to
the prefrontal cortex confirm that the pre-SMA region and the right lateral
prefrontal cortex are important for this task (Picton et al., 2007). With regards
to the Stroop Test, a similar picture emerges that highlights the importance of
the anterior cingulate cortex and the nearby
Reference cards pre-SMA region (Alexander et al., 2007).
The specific roles of the anterior cingulate
and pre-SMA are returned to later.

Task-switching
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Color Number Form Random choice In the Wisconsin Card Sorting Test, a
or complex rule series of cards must be matched against
reference cards (Milner, 1963; Nelson,
1976). The cards can be matched according
to one of three dimensions, namely color,
Response cards number and shape (see Figure 15.9). For
example, in the color condition a blue
card must be grouped with blue cards
and red cards grouped with red cards
FIGURE 15.9: In the Wisconsin Card Sorting Test, patients are given (ignoring number and shape). After each
a card that can be sorted by a number of rules (matching shape, trial, participants are told whether they are
number or color). Sometimes the rule unexpectedly changes and the correct or not. Eventually, they are told
patients must adjust their responses to the new rule. that they are incorrect and they must then

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 THE EXECUTIVE BRAIN 395

spontaneously switch task, i.e., start sorting according to number or shape. KEY TERMS
Many patients with damage to the prefrontal cortex fail to make this shift
and continue to incorrectly sort according to the previous rule, a behavior Perseveration
Failure to shift away from
termed perseveration.
a previous response.
The Wisconsin Card Sorting Test has a number of features that make
it demanding: the switches are unpredictable and, moreover, the relevant Task-switching
Discarding a previous
dimensions (color, shape, number) are not given but need to be inferred.
schema and establishing
This also makes it hard to know why, in cognitive terms, failure on the task a new one.
happens. Other task-switching paradigms have been developed that enable
Switch cost
more fine-grained analysis of the underlying mechanisms. These tend to be
A slowing of response
used in studies of non-brain-damaged participants using fMRI or TMS. time due to discarding
To give an example of a task that involves switches that occur predictably, a previous schema and
imagine that you are a participant looking at a square 2 × 2 grid such as that setting up a new one.
in Figure 15.10. A digit and/or number pair (e.g., L9) will appear in each
part of the grid, moving clockwise, and you must make a response to each
stimulus. When the stimulus is in the upper half of the grid, you must decide
if the letter is a consonant or vowel using a left-right button press. When the
stimulus is in the lower half, you must decide if the digit is odd or even (some
participants would get the complementary set of instructions). This produces
two types of trial—those in which the task switches and those in which it
does not. The reaction times for the switch trials are significantly slower, and
this difference remains even though the change is predictable and even if the
subject is given over a second to prepare before each stimulus is presented
(Rogers & Monsell, 1995). This difference in reaction time between switch
and non-switch trials is called the switch cost.
The switch cost could either reflect suppressing the old task or reflect setting
up the new task. This can be evaluated by considering switches between easy
and hard tasks. A greater switch cost from easy to hard would imply a difficulty
in setting up the new (harder) task, whereas a greater switch cost from hard to
easy would imply a difficulty in inhibiting the old (harder) task. The evidence
suggests it is the latter; i.e., the switch cost has more to do with inhibiting the old
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FIGURE 15.10: When the digit and/or letter pair is in the top half, the subject must decide whether the letter is a consonant
or vowel. When it is in the bottom half, the digit must be classified as odd or even. This generates two types of trial—those
in which the task switches and those in which it does not. Switch trials are significantly slower even though the switch is
predictable and even if participants are given over 1 sec to prepare before the stimulus is shown.
Reprinted from Monsell, 2003. © 2003, with permission from Elsevier.

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 396 THE STUDENT’S GUIDE TO COGNITIVE NEUROSCIENCE

task than setting up the new one. For example, bilinguals are slower at switching
from their second to their first language than from their first to their second
language in picture naming (Meuter & Allport, 1999). With Stroop stimuli,
people are faster at switching from word naming to color naming (easy to hard)
than color naming to word naming (hard to easy) (Allport et al., 1994).
Functional imaging studies reveal a variety of prefrontal regions
together with the anterior cingulate cortex/pre-SMA to be involved in task-
switching, by comparing switch trials with no-switch trials (Ravizza & Carter,
2008) or contrasting the switch preparation time (before the stimulus) with
switch execution after the stimulus (Brass & von Cramon, 2002). However,
it is not always straightforward to link specific regions with specific cognitive
processes because there are often different types of switching mechanism.
Most task-switching experiments involve both a switching of response rules
and a switching of the stimulus selected. In the study described previously, for
example, the left hand switches from responding “consonant” to responding
“odd,” and the stimulus selected switches from letter to digit (i.e., multiple
aspects of the task are switched). Rushworth et al. (2002) attempted to control
for these differences in a combined fMRI and TMS study. They found that
the medial frontal lobes (the pre-SMA region) are important for reassignment
of stimulus–response pairings (e.g., which button to press), whereas lateral
frontal regions may be involved in selection of the current rule (e.g., whether
KEY TERM to respond to color or shape in their task).
Multi-tasking
Carrying out several
tasks in succession;
Multi-tasking
requires both task-switch- Multi-tasking experiments can be regarded as having an element of maintaining
ing and maintaining future goals while current goals are being dealt with (Figure 15.12). This is
future goals while current
related to, but an extension of, task-switching. In task-switching one goal is
goals are being dealt
with. substituted for another. In multi-tasking several goals are maintained at the
same time (but only one executed).

FIGURE 15.11: Bilingual
speakers are faster at
switching from their first to
their second language, than
from their second to their
Copyright © 2019. Taylor & Francis Group. All rights reserved.

first language. How can this
apparently paradoxical result
be explained?
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 THE EXECUTIVE BRAIN 397

Patients with lesions to the prefrontal
cortex may be particularly impaired at multi-
tasking, even though each task in isolation may
be successfully performed and even though they
perform normally on other tests of executive
function, including the Wisconsin Card Sorting
Test and FAS Test (Burgess et al., 2000; Shallice
& Burgess, 1991). This suggests a possible
fractionation of executive functions (assuming
it isn’t simply related to task difficulty)—an
idea returned to in the next section. In the Six
Element Test the participant is given six open-
ended tasks to perform within a 15-minute
period (e.g., arithmetic, writing out names FIGURE 15.12: How do we perform multi-tasking? Could the
anterior prefrontal region hold the key?
of pictures). Critically, they are instructed to
attempt each task. However, they will be unable to complete all of them in
the time allowed, and more points are awarded for earlier items. Constraints
are placed on some of the ordering of tests. Patients with prefrontal lesions
would often fail to switch tasks, spend too long planning (e.g., taking notes)
but never execute the plans and so on. The patients could easily perform
the isolated tasks, but their difficulties were only apparent when they had to
coordinate between them (Shallice & Burgess, 1991).

Evaluation
By the mid-1990s there was a generally agreed-upon definition of what
the essential features of executive functions were: e.g., allowing flexible or
“intelligent” behavior, exerting control via a biasing influence. There was
also a general consensus that the prefrontal cortex had a critical role in
implementing this, and there were also a set of frequently used tasks that were
assumed to be a good indicator of prefrontal functioning (e.g., the Wisconsin
Card Sort, the Stroop Test). There was also agreement on the kind of model
that could account for this. One simple model of executive functions is the
original version of the SAS (Supervisory Attentional System) model—
introduced in Chapter 10. This consists of a set of tasks and behaviors (termed
schemas) and a biasing mechanism that activated/suppressed these schemas
according to the individual’s current goals (Norman & Shallice, 1986). The
Copyright © 2019. Taylor & Francis Group. All rights reserved.

activation of schemas was conceptualized as a balance between bottom-up
processes (cues in the environment, habits, etc.) and top-down processes (task
instructions, long-term plans, etc.). Disruption of this balance, for example,
by a prefrontal lesion would tend to result in recent or habitual responses
being inappropriately elicited (e.g., in the Stroop Test, or Wisconsin Card
Sort), poor planning and so on.
Although these core ideas and empirical results are as valid today as
they were in the 1990s, the contemporary intellectual landscape relating
to executive functions is far more detailed and complex. In the mid-1990s
there was already some evidence that was hard to accommodate by existing
theories. For instance, it was found that some patients with prefrontal lesions
could pass the standard tests of executive functions, but yet show significant
impairments in organizing their daily life and in their social interactions

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 398 THE STUDENT’S GUIDE TO COGNITIVE NEUROSCIENCE

EGAS MONIZ AND THE PREFRONTAL LOBOTOMY

The career of Egas Moniz was an eventful one. In politics, he served as Portuguese Ambassador
to Spain and was President of the Portuguese Delegation at the Paris Peace Conference in 1918,
following the First World War. However, it is his contribution to neurology and neurosurgery that
gained him fame and infamy. In the 1920s he developed cerebral angiography, enabling blood
vessels to be visualized with radioactive tracers. In 1935, he developed the prefrontal lobotomy/
leucotomy for the treatment of psychiatric illness. Between then and 1954, more than 50,000
patients would have the procedure in the USA (Swayze, 1995) and over 10,000 in the UK (Tooth &
Newton, 1961). This brought Moniz mixed fortunes. He was awarded the Nobel Prize for Medicine.
However, he had to attend the ceremony in a wheelchair because, some years previously, he had
been shot in the spine and partially paralyzed by one of his lobotomized patients.
Moniz’s operation was designed to sever the connections between the prefrontal cortex and
other areas, notably the limbic system (Moniz, 1937, 1954). This procedure was adapted by oth-
ers in frighteningly simple ways. For instance, an ice-pick-type implement was inserted through the
thin bony plate above the eyes and waggled from side to side.
At that point, there were no pharmacological treatments for psychiatric complaints. Lobotomy
was used for a variety of disorders, including obsessive-compulsive disorder, depression and
schizophrenia. The measurement of “improvement” in the patients was rather subjective, and the
fact that the lobotomized patients tended to be duller and more apathetic than before was not
sufficient to halt the appeal of the lobotomy. Formal assessments of cognitive function, if they had
been carried out, would undoubtedly have revealed impairments in executive function.
Moniz died in 1955. By then, his surgical innovation had been phased out and its success has
been left to history to judge.

(Eslinger & Damasio, 1985; Shallice & Burgess, 1991). This revealed a
potential flaw in the early accounts. However, these observations could still
be explained away: for instance, by pointing out that lab tests may not be fully
sensitive to deficits apparent in the “real world.” Brain imaging has made a
very significant contribution toward moving the debate forward.
This has enabled a more fine-grained analysis of the functions of
different regions of the prefrontal cortex (and their connectivity) both in
Copyright © 2019. Taylor & Francis Group. All rights reserved.

studying healthy participants (in fMRI) but also in identifying more precise
lesion locations in patients. The next section considers various ways in which
executive functions might be organized in the brain.

T H E O R G AN I Z ATION OF E XE CUTIVE FUNCTIONS
Although there are many different approaches to explaining executive
functions, it is important to emphasize that they typically agree on many
of the core principles outlined so far. Namely, that they require flexible
processing in order to override automatic behavior, switch flexibly between
tasks and carry out a current task while holding in mind other goals—and
that this is achieved via a biasing influence (they make certain behaviors more
or less likely) rather than dictating to the rest of the brain. As for differences

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 THE EXECUTIVE BRAIN 399

between models, one of the key distinctions is the extent to which different
models assume that executive function