Introduction

Adolescence is the phase of life between late childhood and adulthood. It is a time not only of physical maturation, but also of mental and emotional development into an independent, responsible adult. The major developmental tasks of adolescence include the establishment and nurturing of intimate relationships and the development of identity, future perspectives, independence, self-confidence, self-control, and social skills (1).

Heightened risk-taking behavior

Many adolescents and young adults are prone to take risks and enjoy having extreme emotions (2, 3). This is reflected in statistics showing that risky behavior in adolescence is linked with an elevated risk to health (4). In Germany, for example, 62% of all deaths among persons aged 15 to 20 are due to traumatic injuries. The most common causes of death are motor vehicle accidents, other accidents, violence, and self-injury (5). The high mortality is attributable to drunk driving, driving without a seatbelt, carrying weapons, substance abuse, and unprotected sexual intercourse (4).

Boys and girls in comparison

As can be seen in the Table, boys and girls engage in risky behavior at similar frequencies. In recent years, for example, the prevalence of smoking among boys and girls has become nearly equal, although some qualitative differences remain: Boys smoke more cigarettes, and they also more commonly smoke “harder” tobacco products such as cigars, black tobacco, and unfiltered cigarettes. Boys and girls also drink different alcoholic beverages: Boys tend to drink beer and hard liquor, while girls tend to drink wine, sparkling wine, etc. Boys drink alcohol more frequently and in larger amounts. They also consume illegal drugs more commonly than girls. Boys are more prone to accidents, and they take more risks when driving. Girls, on the other hand, are more likely to engage in health-endangering behavior in the area of nutrition (e.g., dieting, eating disorders).

Table

Risky behavior among German adolescents, in percent

Open in a separate window^*1Lampert and Thamm 2007 (e9);^*2Ravens-Sieberer et al. 2007 (e11);^*3Schlack and Hölling 2007 (e10);^*4BZgA 2006 (e12);^*5Shell Deutschland Holding (e13);^*6Lampert et al. 2007 (e14);^*7Lampert et al. 2007 (e15);^*8Kurth and Schaffrath Rosario 2007 (e16). KiGGS, German Health Interview and Examination Survey for Children and Adolescents; BELLA, BELLA Study (mental health module within KiGGS), BZgA, German Federal Centre for Health Education. From (39) Bühler A: Risikoverhalten in der Jugend. In: Uhlhaas PJ. Konrad K (eds): Strukturelle Hirnentwicklung in der Adoleszenz. Stuttgart: Kohlhammer 2011; 189–205. Reprinted with the kind permission of Kohlhammer, Stuttgart

Method

This review concerns new neurobiological insights into typical adolescent behavior and their implications for the best ways to deal with adolescents. We studied these issues with a selective search for relevant publications in German library catalogues, in the PubMed database using the search terms “adolescence/puberty,” “brain/neural,” and “development.” Cited publications were also considered. Special attention was paid to human neuro-imaging studies.

Background

Until just a few years ago, there was a general assumption in developmental psychology and neuroscience that major changes in the architecture and functioning of the brain were limited to the prenatal period and the first five or six years of life. (For a historical overview, see [6].) In the meantime, however, new scientific discoveries have compelled a revision of this assumption.

Large-scale longitudinal studies have shown that a basic reorganization of the brain occurs during adolescence (7). Many synapses are eliminated (8) while, at the same time, there is an increase in white matter (9, 10), and there are changes in neurotransmitter systems as well (11, e1, e2). Thus, the anatomical and physiological maturation processes that take place in adolescence are much more dynamic than originally thought. It can be concluded that a reorganization of cortical circuits takes place in adolescence and is reflected in the changes in cognitive functioning and affect regulation that are typical of this period of life (12).Interestingly, this pattern of human brain development differs from that of nonhuman primates. Although, for example, rhesus monkeys and chimpanzees (like human beings) are born with immature brains, all cortical brain areas in macaques mature at the same rate (13). In man, autopsy studies have shown that synaptogenesis reaches a maximum in the visual and auditory cortices a few months after birth, while synapses are formed much more slowly in the prefrontal cortex. Thus, over the course of human evolution, there was a switch from a synchronous to a heterochronous pattern of cortical development (8). This protracted developmental process presumably facilitates the development of specifically human skills, especially those acquired through embedding in a highly stimulating sociocultural environment, e.g., by schooling, music, verbal communication, and social interaction (14) (Figure 1).

Figure 1

The development of the prefrontal cortex is protracted in man compared to other primates. The Figure shows the synaptic density per 100 µm² in the prefrontal cortex as a function of age in man (red), chimpanzees (blue), and rhesus macaques (olive green) (error bar = 95% confidence interval). From (40) Lui et al.: Extension of cortical synaptic development distinguishes humans from chimpanzees and macaques. Genome Research 2012; 22: 611–22. Reprinted with the kind permission of Cold Spring Harbor Laboratory Press, New York

The current understanding of brain development in adolescence

Brain structure

The brain is fully grown relatively soon after birth, in the sense that the cerebral cortex soon reaches its maximal volume. Nonetheless, important structural maturation processes continue to occur in adolescence, as structural imaging studies have shown (15, e3– e5). In the brain, the gray matter matures from back to front, so to speak: The maximum density of gray matter is reached first in the primary sensorimotor cortex and last in higher association areas such as the dorsolateral prefrontal cortex, the inferior parietal gyrus, and the superior temporal gyrus. This means that, in particular, brain areas such as the prefrontal cortex—which subserves higher cognitive functions such as behavioral control, planning, and assessing the risk of decisions—mature later than the cortical areas associated with sensory and motor tasks (16) (Figure 2).

Figure 2

Development of the white matter and gray matter of the frontal cortex over a human lifetime; separate curves for each sex. From (7) Giedd JN, et al.: Brain development during childhood and adolescence: a longitudinal MRI study. Nature Neuroscience 1999; 2: 861–3. Reprinted with the kind permission of Nature Publishing Group, LondonAutopsy findings suggest that these gray matter changes are due to synaptic pruning (17). Many synapses are formed in childhood that are later removed in adolescence. This occurs in an experience-dependent way, i.e., the synapses that survive are the ones that are more often “in use.” There are also other cellular mechanisms that might account for gray matter changes in this phase of life, e.g., a reduction in the number of glial cells and an increase of myelination (18).

As the gray matter decreases in volume, the white matter increases in volume. The white matter is composed of myelinated axons that conduct neural information rapidly. The volume of white matter increases continually from childhood into early adulthood (19). This expansion is presumed to be due, in large part, to the progressive myelination of axons by oligodendrocytes (10). Myelination tends to proceed from inferior to superior brain areas, and from posterior to anterior.

Brain function

The anatomical reorganization processes of the adolescent brain that are described above are associated with profound emotional and cognitive changes. In particular, there is progressive development of executive functions, i.e., cognitive processes that control thought and behavior and thereby allow the individual to adapt flexibly to new, complex situational tasks (20). In adolescence, at the same time that these basic cognitive skills are developing, there are also changes in social-affective abilities such as face recognition, the so-called theory of mind (i.e., the ability to put oneself mentally in another’s place), and empathy (21).

At the neural level, functional imaging studies of brain development have shown that children and adolescents often have a broader, less focal activation pattern than adults, and that the effective recruitment of neural resources increases with age, so that neural activity decreases in brain regions other than those that are relevant to the task at hand (22). It is not yet clear to what extent this pattern of neural development is due to experience-dependent or biologically determined influences. Imaging studies have also shown that adolescents have heightened activity in limbic areas in emotional situations: For example, Galvan et al. (23) found that the anticipation of a reward is associated with a more marked activation in the nucleus accumbens in adolescents than in children and adults. Interestingly, these researchers also found a positive correlation between activation in the nucleus accumbens and the adolescents’ individual risk-taking tendency (24).

Moreover, both structural and functional imaging studies have shown that the prefrontal cortex becomes more strongly linked to sensory and subcortical structures during adolescence (25, 26, e6). This implies a greater influence of frontal brain regions on cognitive and affective processes. The development of cognitive and affective neural circuits should not be regarded as the sole determinant of structural neurobiological maturation; rather, there appears to be a strong interaction of genetic factors with environmental demands. For example, affect regulation and the brain structures subserving it are influenced by the parent-child interaction (27).

Further findings showing that a profound reorganization of neural circuitry takes place in adolescence are derived from electrophysiological studies, including electroencephalographic (EEG) studies of changes in high-frequency and synchronous brain waves (28). Brain development in adolescence is associated with a decline of oscillatory activity at rest in the delta (0–3 Hz) and theta (4–7 Hz) bands, and an increase in the alpha (8–12 Hz) and beta bands (13–30 Hz). With task-dependent oscillations, the precision of synchronization of oscillatory activity in the theta, alpha, and beta bands increases. The late development of synchronized oscillations in adolescence is closely linked to structural (anatomical) maturation processes as well as to fundamental changes in neurotransmitter systems, which have been intensively researched in the past few years.

A neurobiological explanatory model for typical adolescent behavior

One of the more influential neurobiological models to explain typical adolescent behavior was developed by the group of Casey in New York (29, e7) (Figure 3).

Figure 3

Nonlinear maturation processes of subcortical and prefrontal brain areas lead to an imbalance of neural networks in adolescence. Modified from (12) Casey BJ, Jones RM, Hare TA: The adolescent brain. Annals of the New York Academy of Sciences 2008; 1124: 111–26. Reprinted with the kind permission of John Wiley and Sons.

The main premise of this model, based on neuroanatomical findings and data from functional imaging studies (23, 24, 30, 31), is that adolescence is a period of neural imbalance caused by the relatively early maturation of subcortical brain areas and the relatively delayed maturation of prefrontal control areas (Figure 3), with the result that, in emotional situations, the more mature limbic and reward systems gain the upper hand, so to speak, over the still relatively immature prefrontal control system. This should not be taken to imply that adolescents are by nature unable to make rational decisions. Rather, in situations that are particularly emotionally laden (e.g., in the presence of other adolescents or when there is the prospect of a reward), the probability rises that rewards and emotions will affect behavior more strongly than rational decision-making processes (23, 24, 32). This model has been tested in a series of experimental studies (Box).

The influence of peers on risky behavior

Researchers recruited persons in three age groups (13 to 16 years, 18 to 22 years, and over 24 years) to study whether the influence of contemporaries (peers) on risky decisions depended on the age of the probands. Participants were put in a type of driving simulator in which they had to drive as far as possible until a traffic light turned redand a wall appeared. If the car was not stopped soon enough, it crashed into the wall, and the driver lost points. The participants were either alone or in groups of three persons in the simulator. The 13- to 16-year-olds were found to be more likely to make risky decisions than the participants in the other age groups, but only in the presence of their peers. Adult driving behavior was independent of the presence or absence of peers (33).

It has been found, for example, that adolescents can assess the risk of certain behaviors just as well as adults can when asked about them in a questionnaire. On the other hand, ecologically valid behavioral tests clearly show that adolescents make more risky decisions in groups than they do when alone (33). The reason is presumably that, at this age, the benefit of risky behavior—the social approbation of peers—is rated much more highly than the risk itself. This may be associated with the nonlinear maturation pattern of the prefrontal and limbic brain areas. In accordance with this model, research on preventive programs has shown that programs based on imparting knowledge about risks are less effective than those focusing on individual benefits and on the training of social competence and resistance (34).

It is intriguing to ask what functional benefit, if any, might accrue to the individual from this temporary imbalance between cortical and subcortical brain structures. From the evolutionary perspective, adolescence is the developmental period in which a young person acquires independence. This process is not unique to the human species; increased novelty-seeking and increased social interactions with other individuals of the same age can be observed in many other species as well (35). Risky behavior among adolescents can be seen as the product of a biological dysequilibrium between the search for diversion and new experiences (“sensation seeking”) on the one hand, and as yet immature self-regulatory capabilities on the other (2); its purpose may be to enable adolescents to break away from the familial security zone, so that they can, for example, find a partner outside their primary family. Immaturity of the prefrontal cortex seems to favor certain types of learning and flexibility (1).

In fact, over the lifetime of an individual, there are probably multiple developmental windows in which the brain is particularly well prepared for certain types of learning experience. From the evolutionary perspective, the cognitive style typical of adolescence, which is especially sensitive to social-affective stimuli and flexible in the assignment of goal priorities, may be optimally suited to the social developmental tasks facing the adolescent. This also implies that the adult brain cannot be considered the optimal functional system in an absolute sense, and that adolescence should not be considered a state of deficient brain performance.

The influence of pubertal hormones on adolescent brain development

The maturation of the reproductive system during puberty is associated with rising concentrations of the gonadal steroid hormones. The brain has a high density of steroid receptors, and it is thus plausible that the sex hormones exert an effect on neural networks in adolescence. Sisk and Foster (36, e8) have proposed that a second wave of cerebral restructuring occurs in adolescence, building on an earlier, perinatal phase of sexual differentiation. According to this model, the hormones of puberty affect the further structuring of the adolescent brain, so that a permanent reorganization of the brain results, with the effect that neural networks are sensitized to activating hormonal effects. The rising concentrations of pubertal hormones have different effects on the developing hypothalamic-pituitary-adrenal (HPA) axis in boys and girls: The rise in androgens in boys apparently inhibits the hypothalamic secretion of corticotropin-releasing hormone (CRH), while estrogens in girls regulate the HPA axis upward. Estrogens may make girls more susceptible to stress, while androgens make boys more resilient to it (37).

Overview

Until now, research on early childhood has received the most attention from the scientific community and the media. Recent findings show, however, that the continuing psychological and biological changes of adolescence exert a powerful influence on cerebral structure and function. The brain of the adolescent goes through a new phase of plasticity in which environmental factors can have major, lasting effects on cortical circuitry. This opens up new opportunities for education. For example, for the very reason that adolescents are so readily influenced by emotions, they stand to profit from learning experiences taking place in a positive emotional context that are intentionally designed to train emotional regulation. Given that risky behavior in adolescence has a neurobiological basis, attempts to suppress such behavior completely seem bound to fail. It would be more reasonable to enable adolescents to have emotional experiences in a safe environment, and to increase the social rewards associated with non-risky behaviors through regulatory legislation (e.g., prohibition of certain kinds of advertising) and the provision of emotionally positive models. For instance, the teenage lead character in a television soap opera might decide to opt out of a hard-drinking contest organized by friends.

Moreover, the protracted period of neural plasticity in adolescence also makes adolescents more vulnerable to harmful environmental influences, e.g., drugs. The findings of animal experiments and human studies suggest, for example, that the use of cannabis in adolescence can cause permanent cognitive changes and structural changes in the brain that are more extensive than those seen in adult cannabis users (38). Future research on brain development should, therefore, address the important matter of environmental influences on the function and organization of the brain.

Until now, cognitive neuroscience has not adequately analyzed the influence of social and cultural context on cognitive and affective processes and their development. Thus, our current understanding that adolescence is a decisive phase in brain maturation, and that brain maturation processes may be operative up to the age of twenty, or even beyond, also has important implications for educational and social policy. Any decisions affecting the development of children and adolescents should take the neurobiological facts into account. Major current issues of this type include the question of legalizing cannabis consumption and the applicability of juvenile delinquency law in adolescence.

​Key Messages

• In adolescence, a fundamental reorganization of the brain takes place that continues into the beginning of the third decade of life.

• Adolescent brain development is characterized by an imbalance between the limbic and reward systems, which mature earlier, and the not yet fully mature prefrontal control system. This imbalance may be the neural substrate for the typical emotional reactive style of adolescence, and it may promote risky behavior.

• Typical adolescent behavior is the basis for the development of autonomy in adolescents and promotes their emancipation from the primary family.

• The hormones of puberty affect the further sex-specific restructuring of the adolescent brain.

• The reorganization of the adolescent brain renders it particularly susceptible to environmental influences, both positive and negative.

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Adolescent Brain Development: A Period of Neural Reorganization and Vulnerability

Introduction

Adolescence marks a pivotal phase in human development, characterized by significant physical, cognitive, and emotional transformations. Recent neurobiological insights have shed light on the profound brain reorganization that occurs during this period, influencing adolescent behavior and shaping their future selves.

Brain Structure and Function

During adolescence, the brain undergoes a process of synaptic pruning, where excess synapses are eliminated, while white matter volume increases. This reorganization occurs heterochronously, with the prefrontal cortex, responsible for higher cognitive functions, maturing later than sensory and motor areas.

Functional imaging studies reveal that adolescents exhibit broader and less focal brain activation patterns than adults. As they age, neural activity becomes more localized and efficient. Additionally, the prefrontal cortex strengthens its connections with subcortical structures, allowing for greater cognitive and emotional regulation.

Neurobiological Model of Adolescent Behavior

A prominent neurobiological model suggests that adolescence is a period of neural imbalance. The early maturation of subcortical areas, including the limbic and reward systems, combined with the delayed development of the prefrontal cortex, results in an increased sensitivity to emotional stimuli and a heightened propensity for risk-taking.

Influence of Pubertal Hormones

The onset of puberty brings about a surge in gonadal steroid hormones, which play a role in further shaping the adolescent brain. These hormones differentially affect the hypothalamic-pituitary-adrenal axis in boys and girls, potentially contributing to gender differences in stress responses.

Environmental Influences and Vulnerability

The protracted period of neural plasticity in adolescence makes the brain particularly susceptible to environmental influences. Positive experiences, such as emotionally engaging learning opportunities, can have lasting beneficial effects. Conversely, negative influences, such as substance abuse, can lead to detrimental consequences, including cognitive impairment and structural brain changes.

Implications for Education and Social Policy

Understanding the neurobiological underpinnings of adolescent brain development has significant implications for education and social policy. Educational interventions that foster emotional regulation and provide positive role models can support healthy adolescent development. Additionally, policies that consider the unique vulnerabilities of adolescents, such as the potential consequences of cannabis legalization and the applicability of juvenile delinquency law, are crucial for promoting their well-being.

Conclusion

Adolescence is a transformative period marked by profound brain reorganization that continues into early adulthood. The interplay of biological and environmental factors shapes the adolescent brain, influencing behavior, emotional reactivity, and future outcomes. By understanding the neurobiological basis of adolescent development, we can create supportive environments and policies that foster their healthy growth and transition into adulthood.

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Adolescence: A Time of Brain Reorganization and Risk-Taking

Introduction

Adolescence is a unique period of development marked by significant physical, mental, and emotional changes. During this time, the brain undergoes a major reorganization that influences adolescent behavior and decision-making.

Brain Structure and Function

• The brain matures from back to front, with higher-level cognitive areas like the prefrontal cortex developing later than sensory and motor areas.

• During adolescence, there is a decrease in gray matter (due to synaptic pruning) and an increase in white matter (due to myelination).

• These changes lead to improved cognitive abilities, such as executive function and affect regulation.

Neurobiological Model of Adolescent Behavior

• The imbalance model suggests that the earlier maturation of limbic and reward systems compared to the prefrontal cortex can lead to heightened emotional reactivity and risk-taking in adolescents.

• In emotionally charged situations, the limbic system may override the still-developing prefrontal control system.

Influence of Peers

• Adolescents are more likely to engage in risky behavior in the presence of peers.

• The social approval of peers can outweigh the perceived risks of certain actions.

Hormonal Influences

• Pubertal hormones play a role in further restructuring the adolescent brain.

• Estrogens in girls may increase susceptibility to stress, while androgens in boys may enhance resilience.

Environmental Influences

• The adolescent brain is particularly susceptible to environmental influences, both positive and negative.

• Positive experiences can promote emotional regulation and healthy decision-making.

• Negative influences, such as drug use, can have lasting effects on brain structure and function.

Implications

• Understanding the neurobiological basis of adolescent behavior can inform educational and social policies.

• It is important to provide adolescents with safe environments to explore their emotions and develop non-risky coping mechanisms.

• Decisions affecting adolescents should take into account the ongoing brain maturation processes.

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The Teenage Brain: Why They Act the Way They Do

What's Happening to The Teen Brain?

The brain goes through a major change during your teenage years. It's like a construction zone, with lots of changes happening. These changes affect how you think, feel, and act.

Strong Emotions

One big change is that the parts of your brain that handle emotions and rewards are getting stronger. This means a teenager might feel things more intensely, like excitement, happiness, or sadness.

Impulse Control Is Still Under Construction

At the same time, the part of your brain that helps you control your impulses and make good decisions is still developing. It's like the control tower at an airport, but it's not quite finished yet.

The Imbalance

Because of these changes, you might see teenagers acting on their emotions more often than thinking things through. This can lead to some risky behavior, like trying new things or hanging out with friends who might not be the best influence.

It's All Normal

This is all part of growing up. This imbalance in your brain helps you become more independent and find your own way in the world. It's like your brain is giving you a little push to explore and learn.

Hormones and Your Brain

Another thing that's happening is that a teenager's hormones are going crazy. These hormones can also affect your brain and make you more sensitive to stress or emotions.

Your Brain Is a Sponge

The good news is that the brain is super flexible during this time. It's like a sponge, soaking up new experiences and information. This means teens can learn new things easily and shape their brains in positive ways.

Bad Influences Beware

But it also means that the brain is more sensitive to bad influences, like drugs or alcohol. These things can have a bad effect on your brain's development and cause problems later on.

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Your Brain in Your Teen Years

It Goes Through Important Changes

Did you know that your brain is still growing and changing a lot when you're a teenager? It changes a lot during this time. This process of changing lasts until you're in your early twenties.

The Emotional Rollercoaster

During this change, the parts of your brain that control your emotions and rewards get stronger. But the part that helps you think clearly and control your actions is still growing. This can make it feel like you're on an emotional rollercoaster sometimes. It's normal for a teenager to feel really excited or happy one minute, and then sad or angry the next.

Why Teens Take Risks

Because of this, teenagers often take more risks than adults. It's because the emotional parts of their brains are stronger than the thinking parts. So when they see something that looks fun or exciting, they might not think about the dangers as much.

Hormones and Your Brain

When you hit puberty, your body starts making more hormones. These hormones can also affect your brain and make you feel more emotional.

Your Brain is Like a Sponge

The good news is that your brain is like a sponge during your teen years. It can learn and change really easily. This means it's a great time to learn new things and develop good habits. But it also means that bad experiences can have a bigger impact on your brain.

Important Points

• A teenager's brain changes a lot

• This can make them feel emotional and take more risks.

• Hormones can also affect their emotions.

• It's a great time to learn new things.

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