FUENTE:
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3157933/
The present
paper proposes that four neuromodulator systems underpin highly generalized
behavioral sets, but each targets either dorsomedial or ventrolateral cortical
systems, where it produces its effects in either a proactive or reactive
orientation to the environment. This way systems are discriminated that control
reactive approach (dopaminergic), reactive avoidance (cholinergic), proactive
behavior (noradrenergic), and withdrawal (serotonergic). This model is compared
with models of temperament, affect, personality, and so-called two-system
models from psychology. Although the present model converges with previous
models that point to a basic scheme underlying temperamental and affective
space, at the same time it suggest that specific additional discriminations are
necessary to improve descriptive fit to data and solve inconsistencies and
confusions. We demonstrate how proactive and reactive actions and controls can
be confused, and that this has many potential implications for psychology and
neurobiology. We uncover conceptual problems regarding constructs such as
effortful control, positive affect, approach-avoidance, extraversion,
impulsivity, impulse-control, and goal-directedness of behavior. By delineating
those problems, our approach also opens up ways to tackle them.
Keywords:
dopamine, noradrenalin, acetylcholine, serotonin, motivation, predictability,
temperament, self-regulation
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Introduction
The present
paper proposes that four neuromodulator systems underpin highly generalized
behavioral sets, but each targets either dorsomedial or ventrolateral cortical
systems, where it produces its effects in either a proactive or reactive
orientation to the environment. This way systems are discriminated that control
reactive approach (dopaminergic), reactive avoidance (cholinergic), proactive
behavior (noradrenergic), and withdrawal (serotonergic). This model is compared
with models of temperament, affect, personality, and so-called two-system
models from psychology. Although the present model converges with previous
models that point to a basic scheme underlying temperamental and affective
space, at the same time it suggest that specific additional discriminations are
necessary to improve descriptive fit to data and solve inconsistencies and
confusions. We intend the model as a step toward a comprehensive scheme to make
sense of multiple cognitive, motivational, and neural processes that must work
together and also be distinguishable. The comprehensive scope of the model
makes it useful for condensing the highly elaborative and often conflicting
findings concerning motivational sets, cognitive controls, personality
patterns, and their neuroanatomical and chemical substrates. In the discussion
we demonstrate how proactive and reactive actions and controls can be confused,
and that this has many potential implications for psychology and neurobiology.
In Section
“The Proactive and Reactive Behavioral/Physiological Programs” we will start by
describing separate brain systems for proactive and reactive modes of behavior
control. Next, in Section “Motivational Aspects of Neuromodulator Systems”, we
outline the neuromodulator systems that are, based for a large part on research
with animals, hypothesized to be involved in motivation and behavior such as
approach (the catecholamines, dopamine, and noradrenalin), avoidance
(acetylcholine and noradrenalin), and withdrawal (serotonin). After that, in
Section “Neuromodulation of Proactive and Reactive Behavioral Programs”, the
different motivations and behaviors related to the neuromodulator systems will
be united into a single framework with the distinction between proactive and
reactive behavior control, and this framework or model will be compared to
models of temperament and self-regulation. Finally, in Section “Conceptual
Issues Raised by the Model” we will discuss important conceptual issues that
are raised by the model.
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The
Proactive and Reactive Behavioral/Physiological Programs
Traditional
hypotheses described ascending neuromodulatory systems as “state-setting” or
“gating” systems, to regulate arousal or the readiness for cortical information
processing (e.g., Pribram and McGuinness, 1975). Such descriptions have proven
to be incomplete, and recent experiments indicate that in addition to the relatively
slow, or tonic, changes in the activity of neuromodulator systems (over
minutes), faster, transient, or phasic, components of activity are evoked by
defined cognitive and behavioral activities. Therefore, in addition to the more
global regulation of arousal, neuromodulators appear to influence and perhaps
even initiate the processing of highly specific cognitive operations (Briand et
al., 2007). We think both aspects of neuromodulator function are covered by a
biologically plausible hypothesis that neuromodulators are involved in the
activation of “behavioral programs” that orchestrate different aspects of
behavioral and physiological control systems into a unified program adapted to
a particular set of contexts and conditions. These aspects of control systems
include arousal, information processing biases, action control, specific
cognitive operations, and importantly, specific motivation (Tucker and
Williamson, 1984).
In Section “Proactive and Reactive Behavioral Programs for
Different Environmental Conditions” we will describe brain systems for reactive
and proactive modes of behavior control. Because the distinction between dorsal
proactive and ventral reactive systems is based for a large part on animal
learning or memory research, we will discuss the relationship with memory
systems in Section “The Proactive and Reactive Behavioral Programs and Memory”,
and we will discuss the consequences for cognition in Section “The Proactive
and Reactive Behavioral Programs and Cognition.” Building on the distinction
between proactive and reactive systems, we will propose separate behavioral
programs for proactive approach and avoidance (noradrenergic), reactive
approach (dopaminergic), reactive avoidance (cholinergic), and withdrawal
(serotonergic) in Section “Motivational Aspects of Neuromodulator Systems.”
Proactive and reactive behavioral programs for different
environmental conditions
A prominent example of behavioral programs can be found in
animal temperament research, where proactive and reactive temperaments are
found across different vertebrate species and related to differences in
neuromodulator and stress response systems. These temperaments seem to play a
role in the population ecology of the species, proactive temperament being more
adaptive in stable, high-predictability environments while reactive
temperaments are more adaptive in changing, low-predictability environments
(Koolhaas et al., 1999, 2007). High predictability environments are those
wherein models can be constructed that predict which actions will be effective
in a given context. Only in a predictable environment can behavior be guided by
a context model; in a low-predictable environment behavior should be guided
reactively by environmental feedback-control (Daw et al., 2005). Tucker and colleagues
developed a theory of brain systems that control the proactive and reactive
programs. Inspired by the work of Pribram and McGuinness (1975) and McGuinness
and Pribram (1980), they first related the proactive or extraverted temperament
to systems preferably modulated by noradrenalin and serotonin, and the reactive
or neurotic temperament to systems preferably modulated by dopamine and
acetylcholine (Tucker and Williamson, 1984).
Based on neurophysiological and animal learning research
Tucker, Luu, and colleagues subsequently developed their theory further to
incorporate dorsal and ventral limbic–thalamic–cortical control paths (Tucker
et al., 1995; Tucker and Luu, 2007). In the mammalian brain, two separate
control paths are routed from limbic networks through the frontal lobe to motor
cortex (see Figure Figure1).1). A ventrolateral pathway proceeds from
olfactory cortex through the orbital frontal lobe to lateral frontal cortex
before reaching the ventral premotor and motor cortices (Goldberg, 1985;
Passingham, 1987). This ventral pathway appears to provide greater external
constraint (i.e., reactivity) to motor control, in which external cues set
criteria for ongoing evaluation of the action progress. A mediodorsal pathway
proceeds from the cingulate gyrus through medial frontal cortex to dorsolateral
frontal cortex to the premotor and motor areas on the lateral convexity of the
hemisphere (Goldberg, 1985; Passingham, 1987). This dorsal pathway appears to
provide a projectional (i.e., proactive) mode of behavior control, in which
context models and predictions guide the action toward a goal.
Figure 1
Figure 1
Left: primary direction of corticolimbic traffic for
organizing output from limbic integration toward specific action modules in the
motor cortex. Two separate control paths are routed from limbic networks
through the frontal lobe to motor cortex. A ventrolateral ...
The proactive and reactive behavioral programs and memory
Drawing from Gabriel's (1990) analysis of the roles of the
major limbic–thalamic–frontal circuits in animal learning, Tucker and
colleagues theorized that the proactive mode of action regulation is linked
closely to the operation of the mediodorsal corticolimbic pathway in the
maintenance of the context for action and expectations based on these actions.
Gabriel cites evidence that the dorsal pathway, with important control from the
hippocampus, posterior cingulate, and dorsolateral cortex, maintains a
cognitive representation of the context for action. This context model can be
adjusted only gradually, through a process that may be described as
context-updating (Tucker, 2001; Luu and Tucker, 2003a,b; Luu et al., 2004). By
contrast, when events are discrepant with expectancies, either from
stimulus-associations or context model, a more rapid, focused form of learning
is engaged, in which previous associations are disrupted and a new set of
contingencies may be attended effectively. Gabriel's (1990) research has
suggested that this new learning in response to context violation requires the
ventral circuit that involves the amygdala, ventral striatum, anterior
cingulate cortex (ACC), mediodorsal nucleus of the thalamus, anterior temporal,
insula, and the orbitofrontal and ventrolateral prefrontal cortices (Price,
1999; Bussey et al., 2001; Phillips et al., 2003a; Saleem et al., 2008). See
Table Table11 for an overview of central characteristics of the ventral and
dorsal systems and their associated behavioral programs.
Table 1
Table 1
Characteristics of the ventrolateral and mediodorsal
systems.
This model of learning bears resemblance to the model of
memory systems proposed by O'Keefe and Nadel (1978) and Nadel (1992). According
to those authors, several factors distinguish hippocampal based (“locale”)
learning from non-hippocampally based (“taxon”) learning. Importantly, locale
learning is assumed to be quite different from taxon learning with regard to
the underlying systems of motivation that drive it. O'Keefe and Nadel argued
that there is a fundamental connection between locale learning and exploration.
The drive to acquire information, in the first instance about one's
environment, is taken as the force underlying locale learning, just as it has
to be in the proactive system to enable the construction of context models. The
drives of reactive systems, such as hunger and thirst, are not considered to be
important in this system, though information about location of food, water,
mates, and safety might well be part of what is acquired. Taxon learning, on
the other hand, is assumed to be motivated by the traditional drives (e.g., to
exploit) emphasized by Hull (1943), and therefore to be dependent on the
standard application of reinforcements. The locale system is the basis for
providing the context within which context-free information from the taxon
systems could be situated. In contrast with those similarities between
respectively locale and taxon systems on the one hand, and proactive and
reactive systems on the other hand, quite opposite to the model of Tucker and
colleagues, O'Keefe and Nadel assume locale learning to be fast and all or
none, while taxon is assumed to be slow and incremental. However, O'Keefe and
Nadel acknowledge that there are examples of taxon learning that are very fast
and can occur with but a single pairing. We think this seeming contradiction
may be explained by the focus in the research of O'Keefe and Nadel on
hippocampal function, which reflects only one part of the proactive system, and
mediates only aspects of proactive learning function, such as perhaps an
episodic buffer. O'Keefe and Nadel compared only one part of one system, the
hippocampus, with everything that is non-hippocampal (Keren and Schul, 2009).
The association of the dorsal pathway with gradual learning
and context model-guided action control suggests that this pathway may be
relatively more efficient in retrieval compared to encoding. By contrast, the
association of the ventral pathway with rapid learning and action control by
external constraint suggests that this pathway may be relatively more efficient
in encoding compared to retrieval. Indeed, recent fMRI studies support this.
For instance, left ventrolateral prefrontal cortex was associated more with
successful encoding, whereas left dorsolateral prefrontal cortex was associated
more with successful retrieval (Prince et al., 2005; Kim et al., 2010). In a
meta-analysis of five different fMRI studies of episodic memory, Daselaar et
al. (2009); also Binder et al. (2010) and Kim et al. (2010) found that
successful retrieval was associated with increased activity in posterior
cingulate and precuneus, and posterior lateral parietal cortex, whereas
successful encoding was associated with decreased activity in these regions.
Encoding success and novelty detection overlapped in a ventrolateral anterior
insula/inferior frontal gyrus (IFG) area (Kim et al., 2010).
The proactive and reactive behavioral programs and cognition
The posterior cingulate and Papez circuits of the dorsal
networks support a positive memory bias that forms the context representation
and expectancy for approach and reward (see Deakin, 2003). The fundamental
motive tone for this control system leads actions to be initiated through
proactive (i.e., context-predicted) control (Tucker et al., 1995). With
preferential neuromodulation of the dorsal limbic and neocortical networks by
noradrenalin (Foote and Morrison, 1987), the habituation bias integral to
noradrenergic modulation (Tucker and Williamson, 1984) may be a mechanism
through which global attention, configural working memory, and gradual learning
are incorporated within the context model with minimal disruption of the
representation (Luu and Tucker, 2003a,b). Noradrenalin is distributed through
the dorsal pathways (Morrison and Foote, 1986), and regulated by those pathways
(Arnsten and Goldman-Rakic, 1984). Indeed, noradrenergic and serotonergic
antidepressants increase positive biases in the processing of emotional
material (e.g., Harmer et al., 2004; Serra et al., 2006; Norbury et al., 2007)
and appear to shift activity from ventral to dorsal networks (see Tucker and
Luu, 2007; Carver et al., 2008; Tops et al., 2009).
By contrast, the recognition of discrepancy or threat,
mediated by the ACC and IFG with inputs from reactive ventral limbic networks
(Corbetta and Shulman, 2002; Sridharan et al., 2008), leads to a suppression of
the context model, an engagement of focused attention, focus on and awareness
of the present moment, and the capacity for rapid reorganization of behavioral
contingencies. Neuromodulators of the ventral system provide a redundancy bias
to working memory (Tucker and Williamson, 1984), focusing attention on
potential discrepancies, threats, and rewards, and mediating the frustration
that may guide further learning and adaptive control. This redundancy bias in
working memory also supports perseverative cognition (Brosschot, 2010) such as
apprehensive worry and rumination. In humans, in the more subtle actions of
this regulatory influence, the vigilance for discrepant events leads to a
focused, analytic mode of cognition that is congruent with highly constrained,
feedback control of ongoing cognition and action.
In summary, focusing on the contrast between noradrenergic
and dopaminergic modulation (Tucker and Williamson, 1984), the dorsal or
noradrenalin system supports perceptual orienting, yet this system achieves its
major attentional control through increasing habituation. The system
responsible for augmenting neural activity in response to perceptual input thus
simultaneously decrements further response to input to facilitate proactive and
context model-guided control. The ventral or dopaminergic system, which
increments brain activity to support motor output and readiness, also
facilitates a tight momentary control of behavior by a continuous stream of
external or internal stimuli, or inhibition of behavior during redundant
processing of aspects of stimuli.
Although ventral and dorsal systems will usually work in
parallel and in interaction for many tasks, stable, and dynamic biases toward
one or the other system may explain temperamental and state variation,
respectively, in tendencies toward reactive or proactive programs. This claim
is supported by a recent fMRI study, in which subjects were scanned while they
adopted either a reflective, extended self-reference linking experiences across
time in memory (which may involve the dorsal system) or a momentary
experiential self-reference centered on the present moment (ventral reactive).
The experiential focus yielded reduced activity in dorsal system areas such as
medial prefrontal cortex, posterior cingulate cortex and hippocampus, and
increased engagement of ventral areas such as in the insula, secondary
somatosensory cortex, ventrolateral prefrontal cortex and inferior parietal
lobule. These effects were largest in subjects that were trained to develop
focused attention on the present. Functional connectivity analyses further
demonstrated a strong coupling between the insula and the ventromedial
prefrontal cortex in untrained subjects that was uncoupled in the trained group
(Farb et al., 2007). This decoupling may reflect increased ability in trained
subjects to avoid rumination by disengaging attentional processes of
self-referential elaboration (Farb et al., 2007). These results suggest a
fundamental neural dissociation between two distinct forms of self-awareness
consistent with the dorsal and ventral programs, which are habitually
integrated but can nevertheless vary within and between individuals in relative
activation. For a review of neuroimaging studies showing the role of the
insula/IFG area in awareness of the moment and emotional intensity, see Craig
(2009); for a review of neuroimaging studies of the relations between dorsal
areas and reflective, planfull behavior vs. ventral areas and reactive
behavior, see Carver et al. (2008).
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Motivational Aspects of Neuromodulator Systems
The classic neuromodulator systems that project from the
brainstem and basal forebrain, the noradrenergic, serotonergic, cholinergic,
and dopaminergic systems, are very complex and each has been related to a
multitude of functions at various levels (e.g., physiological, behavioral
levels) that often seem unrelated. On the other hand, functions at different
levels that seem unrelated at first sight may be part of a common behavioral and
physiological program. For behavioral scientists who want to constrain their
behavioral models with knowledge of brain function, characterization of
behavioral programs in terms of associated motivational aspects seems to be
most important. Although functions, modules and other units may be grouped into
physiological and even behavioral programs without aspects of motivation being
involved, the phylogenetically old brainstem neuromodulator systems seem
plausible candidates in the search of basic motivated programs. Indeed, despite
above complexities, for each of the neuromodulators there are reviews that
suggest a function in aspects of motivation.
Considering elementary control functions that have been
conserved through evolution as part of behavioral programs, we propose each of
the brainstem neuromodulators to have neuromodulatory function that can best be
conceptualized as a phylogenetically conserved drive, “functioning in a
higher-order capacity to integrate a variety of behavioral functions” (Lucki,
1998). Each of the neuromodulator systems cover a large area of influence from
a central point of origin, which is suitable for a general regulatory system
(Clark, 1979). The projections of those systems apply a neurophysiological
modulatory influence, and this has very general, vectoral drive properties,
meaning that behavior is oriented in a certain direction. A general
phylogenetically conserved drive or behavioral program theory of neuromodulator
function in behavior can help to account for why each neuromodulator appears to
influence so many behaviors, but also is an unlikely neurotransmitter to be the
principle or sole mediator of any of these behaviors (Lucki, 1998).
The catecholamines dopamine and noradrenalin: different
drives to approach
Activity in midbrain dopamine neurons has been shown to be
related to signaling the rewarding value of events and actions (Schultz, 2002).
Most midbrain dopamine neurons exhibit burst activity following delivery of
primary rewards. They respond to both rewards (with activation) and
punishments/reward omission (mostly with depression; Ungless et al., 2004).
This dopaminergic activity, however, appears to depend on the predictability of
the reward, such that unpredicted rewards elicit dopaminergic activation and an
unpredicted non-reward induces a depression in dopamine activity, while fully
predicted rewards do not elicit dopamine activity (Schultz, 2002). The
dopaminergic response has been associated with the “wanting” or “drive” aspect
of reward processing that facilitates approach, or frustration when attractive
stimuli are out of reach, and not so much with the “liking” aspect (Berridge,
2007). For instance, in an fMRI study of cocaine-dependent subjects
drug-induced “high” feeling was found to correlate negatively with activity in
regions including the ventral striatum (nucleus accumbens), ACC and IFG while
craving correlated positively with activity in these regions (Risinger et al.,
2005).
The noradrenalin-driven locus coeruleus is believed to be
aroused in active coping efforts to maintain or gain control (Henry, 1993) and
in response to unexpected uncertainty (Yu and Dayan, 2005). High noradrenergic
activity has been related to aggression and assertiveness (Haller et al., 1998;
Tse and Bond, 2006), possibly because aggression is often involved in the
(re)gaining of control and proactive coping (Henry, 1993). McClelland et al.
(1980) proposed that brain noradrenalin mediates a power drive, i.e., a drive
to gain control. The locus coeruleus modulates vigilance and the initiation and
energizing of adaptive behavioral responses (Aston-Jones et al., 1994).
Because many readers will associate noradrenalin with
stress-responding and anxiety, it is important to discuss the differences
between the (pro)active avoidance behaviors that appear to be modulated by
noradrenergic systems, and passive, inhibitory and reactive avoidance and
withdrawal that will be discussed in the next two sections. In the present
framework the association of noradrenergic function with active coping is
explained by the guidance of avoidance behaviors by context models. The
encoding of adaptive active coping behaviors in context models and the
associated positive expectancy bias that these behaviors will be successful,
facilitates adaptive, context-dependent proactive coping responses guided by
those context models (Tucker et al., 1995; Koolhaas et al., 1999). This is
associated with high arousal and alertness, but at the same time not directly
controlled by environmental stimuli without involving the context model, and
feedback from the stimulus environment should not interfere with the proactive
control of motor responding; attention is modulated by the context model
instead of exclusively focused on the threat stimulus. In these aspects the noradrenergic
proactive avoidance responding is different from the reactive avoidance we will
discus in Section “Acetylcholine: The Drive to Avoid.”
The proactive and reactive programs appear to have evolved
because they are adaptive in stable, predictable, and in low predictability,
changing environments, respectively (Koolhaas et al., 1999). The behaviors that
are adaptive in stable vs. changing environments have also been characterized
as “exploration” (essential in constructing context models to serve the
proactive program) vs. “exploitation” (reactive appetitive), respectively
(Cohen et al., 2007). Evidence suggests that dopaminergic systems mediate
exploitation (Daw et al., 2006) while noradrenalin neurons in the locus
coeruleus have been suggested to mediate shifts between exploration and
exploitation (Usher et al., 1999). Alternatively, if noradrenalin in the locus
coeruleus is involved in a proactive program, then it may apply network reset
and modulate switching between goal-directed and exploratory behaviors, which
is necessary for switching between proactive goal-behavior repertoires, so as
to permit rapid behavioral adaptation to changing environmental imperatives and
context switches. It may be that unexpected changes in the world – within the
context of a proactive behavioral program – activate a noradrenergic interrupt
signal in order to search for alternative behavioral repertoire within the
proactive program (Usher et al., 1999; Yu and Dayan, 2005). On the other hand,
locus coeruleus noradrenalin may be involved in switching between the proactive
control phases of deliberation and post-decision implementation (Einhauser et
al., 2010).
The dopaminergic and noradrenergic systems are different
systems with different drive functions, which we characterize, following the
discussion in the previous section, as “reactive approach” and “proactive
approach and avoidance”, respectively. However, they seem similar in the way
they oppose, and are opposed by, the serotonergic and cholinergic systems, and
energize behavior (e.g., Mawson, 1999). We think these similarities together
with other factors are the cause of conceptual confusion we return to in
Sections “Neuromodulation of Proactive and Reactive Behavioral Programs” and
“Conceptual Issues Raised by the Model.”
Acetylcholine: the drive to avoid
Especially in reactive systems, the drive to approach seems
in natural opposition to a drive to avoid. Acetylcholine seems to be implicated
in a drive to avoid, i.e., in anxiety. Brainstem cholinergic projections induce
a rapid, transient elevation of vigilance level by their phasic response to
novel, unfamiliar stimuli (Kayama and Koyama, 2003). Basal forebrain cortical
cholinergic activity may foster the attentional processing of threat-related
stimuli and associations, and thereby contribute to cortical/cognitive aspects
of anxiety (Berntson et al., 2003). In healthy male volunteers the behavioral
and cardiovascular sensitivity to a centrally active cholinergic stimulant
correlated significantly with “irritability” and “emotional lability” as well
as with habitually passive strategies in stress coping (Fritze et al., 1995).
Acetylcholine has been proposed to signal expected uncertainty, coming from
known unreliability of predictive cues within a context (Yu and Dayan, 2005)
and hence may, like dopamine, bias behavior toward ventral system control that
is adaptive in changing, low predictable environments.
Although the striatum has been strongly implicated in
dopaminergic reward processing, it should be noted that evidence indicates that
cholinergic and dopaminergic systems work together to produce the coordinated
functioning of the striatum (Zhou et al., 2003). Especially in the striatum,
the dense mingling of dopaminergic and cholinergic constituents enables potent
interactions. Moreover, acetylcholine-mediated mechanisms might be of crucial
importance in processing the cortical inputs to the striatum (Calabresi et al.,
2000). A recent study found that cholinergic but not dopaminergic projections
to the basal ganglia carry reward omission information (Joshua et al., 2008). A
role of a cholinergic activation system in facilitating detection of stimuli
associated with punishment, failure, or reward omission has been suggested
previously (Gray, 1989; Boksem et al., 2006). Similarly, Sarter et al. (2006)
review evidence indicating that increases in the activity of cortical
cholinergic inputs represent a major component of the neuronal circuitry
mediating increases in what they call “attentional effort.” These cortical
cholinergic inputs mediate effortful cognitive control that is engaged when
negative or aversive events and response outcomes signal that goals are not
being achieved, making effort necessary. Such negative events may encompass
aversive outcomes such as error detection, reward loss, and punishment (Sarter
et al., 2006).
In light of the wide-spread cholinergic projections to the
cortex and its involvement in many aspects of cognition, it is important to
stress that a label such as “avoidance” may not do justice to the complexity of
cholinergic functions. We only use labels such as approach and avoidance to
stress motivational aspects and to position the programs in relation to papers
in which these labels are often mentioned. We envision that cholinergic systems
have a general function, perhaps comparable to noradrenalin, but complementary
to it in the sense that it is associated with reactive control. The contrast
between central noradrenergic and cholinergic function may be similar to their
peripheral functions in the sympathetic and parasympathetic autonomic nervous
system, respectively. The sympathetic system provides a global, feed-forward,
proactive response to challenge, while the parasympathetic system fine-tunes
the response, more tightly guided by detailed environmental feedback control
(Porges et al., 1996). The reactive avoidance behavioral program is a program
for low-predictable environments or circumstances, in which threats are judged
to outweigh opportunities. This situation, and associated kind of control, may
have been dominant in many species, environments, and periods in evolution, and
this behavioral program may have developed into a very general and versatile
program that is nevertheless biased toward reactive avoidance. Moreover, the
more recent cognitive control elaborations of the ventral systems provide
essential capabilities to present day humans.
In our model, reactive avoidance stands out from the other
motivations in terms of motivational and affective biases: reactive avoidance
is associated with negative affective biases (Tucker et al., 1995), while
approach and (pro)active avoidance are facilitated by positive biases (Carver
et al., 2000). Indeed, noradrenergic and dopaminergic neuromodulation seem to
be characterized by high levels of subjective energy and social activity,
positive emotional biases or defenses, and reward orientation and impulsivity;
also serotonin has been related to positive emotional biases, positive social
engagement, social potency, and aspects of dominance (see Nutt et al., 2007;
Carver et al., 2008; Tops et al., 2009; Sections “The Catecholamines Dopamine
and Noradrenalin: Different Drives to Approach” and “Serotonin: The Drive to
Withdraw”). These biases are opposite to, or contrast as very different from,
reactive avoidance or neuroticism. By contrast, while antidepressants are used
that stimulate noradrenalin, serotonin or dopamine, recently anticholinergic
antidepressants are developed (Howland, 2009). The cholinergic–adrenergic
hypothesis of mood disorders states that depression would be the clinical
manifestation of a state of cholinergic dominance, whereas mania would reflect
noradrenergic dominance (Fritze et al., 1995; Howland, 2009). In conclusion, of
the neuromodulators considered, only acetylcholine seems to fit the profile of
a neuromodulator of a reactive avoidance program. However, in future work the
distinction between proactive and reactive avoidance should be worked out
further, so as to determine whether noradrenergic systems cannot account for
(aspects of) reactive avoidance as well.
Serotonin: the drive to withdraw
We have proposed that serotonin functions as a
neuromodulator of a drive to withdraw: a phylogenetically conserved motive to
reduce the present or anticipated environmental stimulation mentally or
behaviorally, such as by moving into an environment of lower stimulation levels
(Tops et al., 2009; see also Lowry et al., 2009). Serotonin exerts an
inhibitory influence on behavior (see Lucki, 1998) and decreases responsiveness
to motivational stimuli, increasing restraint by allowing for responding to
cues of longer-term outcomes and delay of gratification (Depue, 1995; Carver
and Miller, 2006). Functional roles of serotonergic projections from the dorsal
raphe nucleus to upper brain structures have been investigated by recording
neural activity in this nucleus, and by observing effects of stimulation of
this nucleus (Kayama and Koyama, 2003). According to these authors, action on
upper brain is inhibitory in spite of waking-specific activity of the neurons.1
The serotonergic systems serves to dampen and oppose the actions of the
dopaminergic, noradrenergic, and cholinergic systems, for example by promoting
behavioral inhibition and cortical de-arousal (Robbins, 1997). Thus, serotonin
promotes satiety, sleep, quiet non-aroused waking, parasympathetic activation,
and the anti-stress relaxation response. Low serotonin and (hypothetically)
frustration of the drive to withdraw will increase irritability (Tops et al.,
2009).
Ellison (1979) showed that the low-serotonin animal can be
thought of as being in a state of central functioning appropriate for any
animal out in the environment, foraging for food: it is hyper-aroused,
sensitive to stimulation and vigilant. Furthermore, Ellison suggested two
antagonistic types of positive affect (drives): one which pulls the animal out
of hiding into the environment by positively rewarding it when it engages in
appetitive consummatory responses (catecholaminergic), and another which pulls
it back into the security of the nest by satisfying a reciprocal set of needs
(serotonergic). The positive affects that Ellison associated with serotonergic
function were security and relaxation, which are proposed to serve functions of
energy conservation and recuperation.
Another function of serotonin may lay in its relative
promotion of dorsal systems and proactive behavior. It has been suggested that
serotonin facilitates motor output, partly by suppressing ongoing processing of
sensory input that might disrupt motor output, thereby effectively facilitating
proactive action control (Jacobs and Fornal, 1995). We proposed that serotonin
facilitates a mode of proactive function that guides behavior that is best
performed without interference from high levels of unpredictable environmental
stimulation (Tops et al., 2009). Most activities reflecting attachment behavior
are most successfully maintained when the organism is relatively relaxed and
free from challenge by the need for self-preservation. Serotonergic sanguinity
and comfort may be important to the facilitation of social interactions by
reducing the associated anxiety and inhibition. We proposed that serotonin is
involved in the type of social interactions, in which immediate reward value is
traded for delayed rewards. To do so, serotonin decreases both aversive and
appetitive reactivity. The drive for these low-arousal social behaviors may
have been derived from a serotonergic drive to withdraw into a safe place or
comfort. We speculate that the development of phylogenetically more recent
social and cognitive functions may have led to the increasing complexity and
number of serotonergic system receptor sub-types and some co-selection of both
ventral and dorsal elements in most recent sub-systems.
Other motivational functions of serotonin have been
suggested in the literature. Serotonin has been suggested to be implicated in
harm avoidance and anxiety (e.g., Deakin, 2003). However, in that literature
the drive to avoid is not discriminated from the drive to withdraw. We argue
elsewhere that serotonergic function is more likely to relate to a drive to
withdraw than to a drive to avoid (Tops et al., 2009, also for references to
other authors arguing against direct involvement of serotonin in a drive to
avoid or anxiety). Another hypothesis, that serotonin decreases immediate
stimulus reactivity and increases future orientation, which may promote
behaviors that could be described as proactive avoidance (Carver et al., 2008,
2009), we think is compatible with the present one. However, we think a role in
future orientation is derived from a phylogenetically more basic function in
withdrawal: perceptions of environmental resource availability and feeding
state motivate organisms to withdraw in order to conserve energy and recover,
while in more recent evolutionary history additionally future oriented
behaviors and cognitions may be facilitated (Russo et al., 2009; Tops et al.,
2009).
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Neuromodulation of Proactive and Reactive Behavioral
Programs
We now turn to models of temperament and self-regulation. We
do this because we believe that combining (a) the four behavioral programs
related to the neuromodulators with (b) the division into proactive and
reactive behavioral programs, produces a model that is very similar to a model
that has recently been proposed to integrate literature on temperament and
self-regulation systems, serotonin function, psychopathology, and neuroimaging
(Carver et al., 2008, 2009). However, we think our behavioral programs approach
has additional strengths compared to theirs. Specifically, we think our model
uncovers important conceptual problems and also opens up ways to address those
problems. Tackling conceptual issues will also help in comparing our approach
to other research that suggested related distinctions between dorsal and
ventral networks associated with top-down/goal-directed vs. stimulus-driven
attention, executive control vs. salience-detection, attention vs. emotion,
aspects of emotion perception, resting state connectivity, visceromotor vs.
viscerosensory function and psychopathology, although it is beyond the space
limits of this paper to address all those comparisons directly (Price, 1999;
Corbetta and Shulman, 2002; Yamasaki et al., 2002; Phillips et al., 2003a,b;
Fox et al., 2006; Seeley et al., 2007).
Figure Figure22 is a depiction of the two reactive
motivational systems, i.e., the dopamine-linked reactive approach system and
the acetylcholine-linked reactive avoidance system, and of the noradrenalin-
and serotonin-linked proactive approach and avoidance system. Inspection of
this figure may raise the question why it depicts separate reactive approach
and reactive avoidance systems, but not separate proactive approach and
proactive avoidance systems. One explanation for the lack of evidence for
separate proactive approach and proactive avoidance systems may be that the
involvement of the ventral systems in acute external reactivity and reactive
responding to threat may induce time constraints that are best met by separate
systems for the fundamentally different behaviors. By contrast, proactive
approach and proactive avoidance may be guided by the same context models. Relatedly,
proactive approach and avoidance may not be opposites as much as their reactive
counterparts are: proactive avoidance of threat involves active
problem-solving, a coping style that has even been termed “approach coping”
(Roth and Cohen, 1986). Indeed, individuals who score high on measures of
adaptive optimism that most likely reflect a bias toward proactive behavioral
programs (see below) have been shown to confront both pleasant and unpleasant
emotions and threat stimuli to serve active problem solving (Aspinwall et al.,
2001). Finally, reactive approach and reactive avoidance behavioral programs
may have evolved because they represent two alternative adaptive strategies in
low-predictability environments. In such environments, reactive harm avoidance
may evolutionary have been more adaptive for women who care for vulnerable
children and family, whereas in such environments reactive approach may be more
adaptive for men who hunt and compete for physical and social resources (Del
Giudice, 2009), which may explain higher prevalence of internalization
disorders and reactive avoidance temperament in women, and externalization
disorders and reactive approach temperament in men (e.g., Oldehinkel et al.,
2007).
Figure 2
Figure 2
Three temperamental influences (and associated
neuromodulators) on behavior that reflect different behavioral programs. A
reactive system for approaching rewards and a reactive system for avoiding
threats or punishment both interact, collaborate and compete ...
Interestingly, although Figure Figure22 shows the reactive
behavioral programs and their interaction by a context-model-guided proactive
program, this figure is actually adapted from a figure in Carver et al. (2008,
2009); compared to that figure, we added “proactive approach and avoidance” to
describe the box that originally only said “(deliberative) effortful control.”
Carver and colleagues presented this model to explain aspects of serotonin
function and psychopathology. They based their perspective on a set of theories
from cognitive, social, personality, motivational, and developmental psychology
that are often called two-system or two-mode models. Such models converge on
the idea that there exist two modes of processing information and regulating action,
which operate simultaneously and in competition with each other: a lower-order
system that responds quickly to associative cues of the moment and a
higher-order system that responds more reflectively and planfully. However, for
the terms they used in their figure (see Figure Figure2)2) they chose a
particular temperament model of self-regulation from developmental psychology
(Derryberry and Rothbart, 1997; Posner and Rothbart, 2007). Additionally, they
discuss evidence that those systems involve ventral, respectively dorsal
cortical areas. And similar to what we proposed, they suggest that serotonin
shifts activity from ventral to dorsal systems, i.e., that low serotonin is
linked to relative dominance of the reactive systems (Tucker and Luu, 2007; Tops
et al., 2009). They also suggest, as we did, that the kind of behavior
manifested when serotonin is low, depends on biases toward either reactive
approach or reactive avoidance systems (also Prange et al., 1974). Starting
from a different literature than we do, they arrive at a similar explanation
for different forms of psychopathology that seem associated to low serotonin
(Tops et al., 2009).
Research in children and adolescents, some of which based on
the temperament questionnaires developed by Rothbart and colleagues, found
support for the model in Figure Figure2.2. For instance, there is significant
covariation between internalizing and externalizing behavior that is partly
explained by individual differences in emotional reactivity, although there is
also evidence that internalizing behavior is a protective factor against
externalizing behavior (Rhee et al., 2007). This is consistent with
internalizing and externalizing both being mediated by reactive systems and
dampened by the proactive system or effortful control, but at the same time
externalizing behavior is inhibited or opposed by the reactive avoidance system
if punishments are involved (see below and Figure Figure3).3). In a large
population sample (n = 2230) studied at preadolescence and again as adolescents
(Oldehinkel et al., 2004, 2007), fearful and shy temperaments were associated
with internalizing disorders, and frustration and high-intensity pleasure
temperaments were associated with externalizing disorders. In adolescents both
associations were attenuated by high levels of effortful control (Oldehinkel et
al., 2007). Additionally, high frustration or irritability tended to be
associated with both categories of disorders (Oldehinkel et al., 2004, 2007;
Baldwin and Dadds, 2008). This fits with the hypothesized association of both
categories of reactive temperament and disorders with low serotonin; low
serotonin is associated with increased emotional reactivity, the evidence
appearing strongest for irritability (Russo et al., 2009).
Figure 3
Figure 3
Different kinds of self-regulation after adding effortful
control to the temperamental influences. We introduced an “effortful control”
element to each program from Figure Figure2.2. Taking as example the
self-regulation of reactive ...
Go to:
Conceptual Issues Raised by the Model
Although there is a lot of conceptual confusion and
imprecision in the two-system model literature (see Keren and Schul, 2009, and
the discussion below), most of the evidence reviewed by Carver et al. (2008,
2009) seems to support our model as well. However, there are a few differences
in our models and approach. We claim that our model using behavioral programs
points at conceptual problems that may affect the model of Carver et al., as
well as other behavioral research. We will discuss a few examples below of
issues raised by our model.
Higher-order effortful control or both reactive and
proactive effortful control
Carver et al. (2008, 2009) conceptualize the proactive
system as being at a “higher order” than the reactive system. This is similar
to tendencies in two-system models and psychology in general to generate
contrasts based on dichotomies such as cognitive–emotional,
controlled–automatic, positive–negative, approach–avoidance, hot–cold etc.
(Keren and Schul, 2009). However, the behavioral/physiological programs
approach may trigger new insights because it suggests that elements that are
not intuitively similar, connected, or at a similar level of complexity
(perhaps even opposites in some ways) may nevertheless be associated with the
same system: they may be associated with the same system because they are
elements of the same program that is adaptive in a particular environment. In
other words, criteria for elements to be associated to the same psychologically
relevant system are derived from their role in an adaptive program instead of
from intuitions of what is similar, compatible, or comparable.
For instance, although the reactive programs in the model of
Tucker and colleagues include elements that appear more primitive (e.g.,
impulsive aspects of reactivity discussed below) and indeed may be of
phylogenetically older origin and develop to completion at a younger age
compared to the proactive system (Flechsig, 1901), Tucker and colleagues
actually argue that in humans, in the ventral reactive regulatory influence,
the working memory redundancy bias and vigilance for discrepant events leads to
a focused, analytic mode of cognition (Tucker and Williamson, 1984). Indeed,
absorption, which reflects reactive attention focused on the present and
intense emotion, is associated in healthy individuals with increased working
memory capacity and elaboration learning but relative performance deficiencies
in tasks of memory for associative, context-dependent verbal material,
visuospatial working memory, and executive control functions in terms of a
heightened perseveration tendency and false positive errors (de Ruiter et al.,
2006; Amrhein et al., 2008); we think this pattern fits with a relative bias
toward reactive and away from the proactive program. We think that each program
incorporated in its more recent elaborations elements of cognitive control. At
the neurophysiological level this may often involve prefrontal cortex
elaborations and different receptor subtypes (Durstewitz and Seamans, 2008).
That is why we think detail and explaining power can be added to the model in
Figure Figure22 by introducing an “effortful control” element to each program
(Figure (Figure33).
For comparison and consistency with Figure Figure22 and
other literature we stayed with the term “effortful control” (Derryberry and
Rothbart, 1997; Posner and Rothbart, 2007; Carver et al., 2008, 2009), although
we suggest that subjectively effort may be experienced differently under each
program. Sarter et al. (2006) review evidence indicating that increases in the
activity of cortical cholinergic inputs in response to negative events and
response outcomes represent a major component of the neuronal circuitry
mediating increases in “attentional effort” or effortful cognitive control.
Sense of effort and physical exertion relate negatively to extraversion and
positively to neuroticism, anxiety, depression (Morgan, 1994), and insula
activity (Williamson et al., 1999; de Graaf et al., 2004). These findings are
consistent with acute effort sense being related to momentary awareness and
affective intensity of the moment (Craig, 2009) in the reactive avoidance
system.
Failure to discriminate reactive positive affect from
proactive positive affect
In addition to suggesting that certain elements of programs
that seem opposites actually may belong together within the same program, the
present model also suggests the opposite: that other elements that are usually
not discriminated actually belong to different programs that may even be seen
as opposites in some regards. This may be true for two types of positive
affect. Evidence suggesting that there are two types of positive affect
associated with different programs comes from studies of the relationship
between positive affect and cognition. Intuitively researchers have linked
positive affect to reward processing and dopaminergic function (e.g., Watson et
al., 1999). Other researchers have discussed appetitive or pregoal positive
states and “wanting” as being different from consummatory or postgoal positive
states and “liking” and argued that dopamine function is only involved in the
former (e.g., Berridge, 2007). According to the present model, the reactive
approach positive affect (“wanting”) of the ventral system would be associated
with focused attention; however, there should be another kind of positive
affect related to proactive approach and global attention (Table (Table11 and
Section “The Proactive and Reactive Behavioral/Physiological Programs”).
Moreover, whereas there is a positive affective bias associated with the
proactive dorsal circuit, in moderate-temperament individuals in situations
without strong positive incentives there is a negative affective bias
associated with reactive ventral system function (Derryberry and Tucker, 1994).
This negative bias to reactive function is supported by studies of dynamics of
mood over the day, which show that while positive affect shows a tonic rhythm
of increase in the morning and decrease in the evening, negative affect only
shows reactivity to events (Watson et al., 1999). The circadian rhythm of
positive affect may be modulated by noradrenalin, as noradrenalin has been
associated with positive affect (Nutt et al., 2007), tonic activation (Kayama
and Koyama, 2003)1 and circadian arousal regulation (González and Aston-Jones,
2006).
Studies generally support the model of Derryberry and Tucker
(1994), finding that whereas negative affective states are associated
relatively with increased local attention, positive affect is associated with
more global attention (see Förster et al., 2006). Importantly, studies that
specifically induced reactive approach-related positive affect (i.e.,
“wanting”, using pictures of desserts presented to hungry volunteers) found
reduced global or increased local processing (Gable and Harmon-Jones, 2008;
Harmon-Jones and Gable, 2009). The results specifically supports the present
model, as it is the first to discriminate reactive approach from proactive
approach, and it relates the former to focused attention and the latter to
global attention. However, related distinctions between different types of
positive affect have been made by others.
Drawing on the review by Derryberry and Tucker (1994), the
broaden-and-build theory of Fredrickson (2004) appears to describe proactive
system positive affect. According to this theory some positive emotions broaden
an individual's momentary thought-action repertoire: joy sparks the urge to
play, interest sparks the urge to explore, contentment sparks the urge to savor
and integrate, and love sparks a recurring cycle of each of these urges within
safe, close relationships. The broadened mindsets arising from these positive
emotions are contrasted to the narrowed mindsets sparked by emotions associated
with specific action tendencies, such as attack or flee (and reactive approach,
we argue; also Gable and Harmon-Jones, 2008). Panksepp (1998) similarly
discriminates a play positive affect system and a seeking emotive system
involved in reward obtainment. These theories have in common with each other
and the present model that they suggest that, in addition to reactive approach
positive affect, there are kinds of positive affect that are adaptive in
stable, predictable, or comfortable environments and allow for a broadening of
attention and cognition (Panksepp, 1998; Carver, 2003; Fredrickson, 2004; Gable
and Harmon-Jones, 2008). This broadening of attention in the proactive mode
functions to guide play and explorative behavior and integration to construct
context models, read contexts and to flexibly and optimally select and switch
between context models.
Factor analyses of self-rated mood suggest that affective
states can be described by a two-factor model (e.g., Watson et al., 1999). One
factor or dimension has been labeled alternatively as “arousal–dearousal” or
“engagement–disengagement”; the other dimension has been labeled
“pleasantness–unpleasantness.” Alternatively, other authors argue that these
factors are best rotated such that affective space is described by the
dimensions “positive activation” and “negative activation.” Positive
affectivity and negative affectivity are also found as traits that are related
to extraversion and neuroticism, respectively, and were suggested to represent
the subjective components of broader biobehavioral systems of approach and
withdrawal, respectively (Watson et al., 1999; Carver et al., 2000). We think
the engagement–disengagement dimension may reflect the balance, as modulated by
serotonin, between reactive and proactive systems in Figure Figure22 (i.e., it
may reflect the disengagement of reactive systems involved in the intense
experience of the moment, for instance due to increased suppression by
serotonin, effecting increased withdrawal), whereas the pleasantness–unpleasantness
dimension may reflect the balance between reactive approach and reactive
avoidance system activation. By contrast, the rotated solution of negative
activation and positive activation may contrast reactive avoidance system
activation with activations in reactive approach and/or proactive approach
systems that are not discriminated. We think that the present model is
consistent with this literature, given the limitations of the used measures and
analyses (Carver et al., 2000).
In another approach to the issue of basic dimensions of
affective dispositions, two models have been proposed, one by Tellegen (1985),
composed of positive emotionality, negative emotionality, and constraint, and
the other by Watson and Clark (1993), composed of positive temperament,
negative temperament, and disinhibition. These models seem to fit the model in
Figure Figure22 very well, assuming that constraint and inhibition reflect the
regulation of the reactive approach and avoidance systems by the proactive
system. However, in the next sections we will elaborate further on how our
model points at potential confusion between different types of impulse control
that may affect constructs such as constraint, impulsivity, and inhibition
(Figure (Figure33).
Failure to discriminate proactive and reactive approach,
proactive, and reactive extraversion
Because positive affectivity is an important aspect of
temperament and personality (Carver et al., 2000), if there are indeed
different types of positive affect that belong to different temperament
systems, then failure to discriminate them may impair models of temperament. It
is thought that positive affect is an important aspect of temperament because
it is functionally involved in approach motivation (Carver et al., 2000).
Hence, the implications described above of failing to discriminate between
reactive and proactive types of positive affect, translate in the realm of
temperament and personality research to consequences of failing to discriminate
between reactive approach and proactive approach, respectively. This
distinction is usually not made in psychology (but see Braver et al., 2009).
But there are reasons to believe that this is potentially an important
distinction, and that recognition of this distinction may facilitate progress
in behavioral- and neurosciences.
Remember that proactive and reactive temperament seems to
characterize two basic behavioral programs that are recognizable across
vertebrate species (Koolhaas et al., 1999). In humans the Big 2 of personality
or temperament research are extraversion (positive affectivity) and neuroticism
(negative affectivity). It would make sense to expect, as Tucker and colleagues
suggested, that extraversion and neuroticism would reflect the proactive and
reactive behavioral programs, respectively (Tucker and Williamson, 1984).
However, in addition to indications that extraversion and its associated
optimistic bias are indeed related to proactive approach and adaptive context
model-guided behavior and lower risk of psychopathology, they are also linked
to reactive approach and externalizing behavior (e.g., Taylor et al., 2003).
Similarly, optimism may reflect optimism that context models remain efficient
in guiding successful behavior, i.e., optimism about predictability, a form of
optimism that is necessary for a bias toward proactive behavior; or reflect
optimism that the individual has enough resources to control his environment
(even when unpredictable) in a reactive, opportunistic way, a form of optimism
and positive bias that characterizes narcissistic and the other disorders of
the externalizing category. In terms of Figure Figure22 it appears that
reactive avoidance may be contrasted with reactive approach, or at other times
with proactive approach, or with a combination of proactive and reactive
approach. In other words, it seems that similarities to the human observer
between reactive and proactive approach have led to failure of measures of
temperament to discriminate them. An observation that could discriminate
reactive from proactive extraversion is that neurotic (i.e., reactive)
extraverts but not low-neurotic (proactive?) extraverts showed response
facilitation when rewards could be obtained (Reed and Derryberry, 1995).
Proactive approach and reactive approach may be hard to
discriminate from each other, both by questionnaire measures and observational
techniques, because the phenotypical differences between both may often be more
subtle compared to the similarities. Like the similarities between
noradrenergic and dopaminergic neuromodulation (Nutt et al., 2007), both seem
to be characterized by high levels of subjective energy and social activity,
positive emotional biases or defenses, and reward orientation and impulsivity;
also serotonin has been related to positive emotional biases, positive social
engagement, social potency and aspects of dominance (see Carver et al., 2008;
Tops et al., 2009; and Section “Serotonin: The Drive to Withdraw”). Both are
opposite to, or contrast as very different from, reactive avoidance or
neuroticism.
Confusion between proactive and reactive impulsivity, between
proactive and reactive impulse control
Impulsivity is a behavioral aspect that may be importantly
implicated in the conceptual confusion we proposed above. Though widely used in
research on personality, the impulsivity construct is far from being well defined.
Different ways of measuring and operationalizing this construct have led to
contradictory empirical results. Nor is it clear where impulsivity belongs in
multidimensional personality models. Originally included by Eysenck in
extraversion but later moved to his psychoticism construct, it is a facet of
neuroticism in the NEO five-factor model, and correlates to both extraversion
and neuroticism (see Estrella Romero et al., 2006; also Carver et al., 2000).
Additionally, in the five-factor model conscientiousness or constraint is
supposed to reflect impulse control. Impulsivity is part of reactive behavior
controlled by the ventral systems. Although ventral effortful control and
reactive harm avoidance can produce constrained, feedback control of ongoing
cognition and action (Tucker and Williamson, 1984), the direct control of
behavior by emotional stimuli of the moment produces emotional reactive,
impulsive behavior. This emotionally reactive kind of impulsivity is seen in
internalizing and externalizing disorders (see also Reed and Derryberry, 1995).
However, aspects of proactive behavior can also be described as impulsive. The
lack of feedback control of ongoing cognition and action in the proactive mode,
and also its opposition of reactive avoidance and inhibition, can be
experienced and labeled as impulsive. In fact, Tucker and colleagues used to
stress this kind of impulsivity related to proactive, feedforward function in
previous writings (Tucker et al., 1995).
Figure Figure33 suggests that reactive approach or
impulsive reward responding can be regulated in at least three different ways:
(1) by inhibition or regulation from the proactive system (proactive
inhibition); (2) by inhibition or opposition from the reactive avoidance system
if punishments are involved (reactive inhibition); (3) by effortful control or
constraint within the reactive approach system itself. Additionally, proactive
approach and impulsivity can be inhibited by reactive inhibition and possibly
be regulated by effortful control. Research until now did not simultaneously
take those different forms of inhibition of approach into account, but usually
focused on dichotomies.
Proactive and reactive goal-directed behavior
A final issue of conceptual confusion we would like to
address within our framework is the relationship of behavioral programs with
“goal-directedness.” In two-system models the cognitive control-type system is
often described as supporting goal-directed behavior, while in the
reactive-type system the reactivity is interpreted as being opposite to
internal goal-directed. However, in our approach, drives and motivation are
central to all four behavioral programs. The difference is how they are
expressed, e.g., in proactive or reactive behavior. In a proactive mode, context
models can assist in directing behavior toward goals. In a reactive mode, goals
and motivational stimuli can be held active by the redundancy bias and actually
lead to perseveration or obsessional behavior (Tucker and Williamson, 1984).
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Summary
The present model suggests a reorganization of conceptual
space in psychology. It suggests that certain behavioral characteristics that
are usually contrasted with each other may actually belong to the same
behavioral control system. At the same time, it suggests that some other
characteristics belonging to different control systems are typically not
discriminated. We think confusion in psychological conceptualizations arose
because of two features of brain organization that cause (1) relationships
between characteristics to not confirm to intuition and (2) difficulty in
discriminating between characteristics that share psychologically salient
features. Such problems can only be solved when conceptualization is
constrained by a model that takes such features of brain organization into
account. We discussed several aspects in which our model differs from, or is
similar to other models. However, instead of attempting to define the
definitive, ultimate model, our main point is that there are two aspects of brain
organization that we think may help developing models of behavioral control
that may overcome limitations of previous models.
The first feature of brain organization we think is
important is the organization into behavioral/physiological programs. The behavioral/physiological
programs approach may trigger new insights because it suggests that elements
that are not intuitively similar, connected or at a similar level of
complexity, or even seem opposites in some ways, may nevertheless be associated
with the same system. They may be associated with the same system because they
are elements of the same program that is adaptive in a particular environment.
In other words, criteria for elements to be associated to the same
psychologically relevant system are derived from their role in an adaptive
program instead of from intuitions of what is similar or comparable. As an
example, we discussed the tendency in psychology to group elements together
that appear to reflect higher levels of complexity, sophistication and
cognitive control, and contrast these with elements that appear to reflect
lower levels of complexity, sophistication and cognitive control. However, the
behavioral programs approach suggests that each program is likely to
incorporate elements from the higher and lower levels, even when those elements
seem opposites in some regards. For instance, reactive systems, that may at
first thinking appear more primitive and not reflexive, may nevertheless be
associated to high cognitive controls such as focused attention and a
redundancy bias in working memory; at the same time, proactive systems as well
may be associated with types of behavioral impulsivity and higher cognition.
The second feature of brain organization is the organization
into dorsomedial systems that control behavior in a proactive way guided by
context models, and ventrolateral systems that control behavior in a reactive
way guided by environmental feedback. Without a model stressing the importance
of this distinction, this distinction may be less salient and obvious in
observed behavior and psychological experience, compared to other features that
proactive and reactive programs may have in common. We discussed the example of
proactive and reactive forms of positive affect that are typically not
discriminated. Because positive and negative affectivity are core aspects of
other constructs such as temperament, extraversion, approach-avoidance, and
impulsivity, failure to discriminate between reactive and proactive affect
affects those domains as well. In the discussion we did not elaborate on the
distinction between proactive and reactive forms of avoidance, although we
think this is important as well, and should be addressed in future work.
We do not advocate simply reorganizing psychological models
around terms such as “proactive” and “reactive.” These terms are just as
vulnerable to spurious associations and intuitions as other psychological
terms. Rather, we advocate thinking in terms of brain systems controlling
behavior guided by context models and other systems controlling behavior in an
active, vigilant momentary attentional mode closely tied to motor readiness.
Next, further elaboration on this basic distinction between underlying
mechanisms is needed, in terms of their interactions, dynamics, and
incorporation into more specialized behavioral programs and asymmetric
hemispherical functions (Tucker et al., 1995; Tops and Boksem, 2010). For
determining the characteristics of each behavioral program it will be important
to delineate the specific environments and circumstances for which they
evolved, and to go back-and-forth between psychological and brain models and
evidence.
For the present model to be tested optimally, new measures
should be developed that address the conceptual problems we discussed and
specifically target the systems described. For this, careful thinking is
necessary about how to catch often subtle differences at the behavioral level
and how to catch the essence of systems. However, if the central points of this
paper prove right, than this endeavor would likely improve progress and
consistency of results in many important areas of psychology and
psychopathology research.
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Conflict of Interest Statement
The research was conducted in the absence of any commercial
or financial relationships that could be construed as a potential conflict of
interest.
Go to:
Acknowledgments
This research was supported by a Veni grant of the
Netherlands Organization for Scientific Research (NWO) (451-07-013).
Go to:
Footnotes
1The study by Kayama and Koyama (2003) also investigated
noradrenergic projections originating in the locus coeruleus and cholinergic
projections from neurons gathering in the laterodorsal tegmental nucleus and
scattering in the pedunculopontine tegmental nucleus. They conclude that the
noradrenergic projection is a rather tonic activating system, but it also
elevates vigilance levels transiently with phasic sensory responses. The
cholinergic projections induce a rapid, transient elevation of vigilance level
by their phasic response to novel, unfamiliar stimuli. This seems consistent
with proactive and reactive control modes modulated by noradrenalin and
acetylcholine, respectively. Additionally, a group of cholinergic neurons
constitutes a system to induce and maintain paradoxical sleep.
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