Position Paper: Antidepressants in Adolescents: How it is Beneficial and Why We Should be Wary

Zac LaRocca-Stravalle, Biology Major, Class of 2021

This is a position paper regarding the use of antidepressant for adolescence. This paper claims that the use of antidepressants for adolescents with depressive symptoms ought to be considered, but with careful evaluation. The reason I decided to research this topic is because depression is becoming a big issue in the world, particularly in the US, and those affected by depression include adolescents. I was curious about the effects that antidepressant use had on adolescents, considering that it is a time of critical brain development.

Antidepressants in Adolescents: How it is Beneficial and Why We Should be Wary  

Depression is a global health concern and is considered one of the leading causes of mental disability worldwide, which is expected to rise. Depressive symptoms are most prevalent in the adolescent and young adult population, as are the risk for many other affective disorders, such as anxiety disorders. Among adolescents with depression, moderate to severe depression account for one third of all depressive symptoms. In the United States, where rates of depression are the highest of any other developed nation, 2.8 million adolescents aged 12-17 presented major depression in 2014, around 11% in that age group (Center for Behavioral Health Statistics and Quality, 2015). Major depression is a risk factor for suicidality, and associated with social and academic impairments, anxiety disorders, substance abuse and physical health problems. About 20% of adolescents with moderate to severe depression show recurrent depressive symptoms throughout life, and it is most prevalent in those with major depression (Rushtonm, et al., 2002).

Although adolescents that develop moderate or severe depression are at risk for recurrent depressive episodes later in life, there is little research that characterizes the course of depression from adolescence to adulthood with regard to the development of recurrent and chronic depression. This is key to understanding the extent that antidepressants affect the development of adolescent depression, let alone ameliorate depressive symptoms. This essay evaluates the role of antidepressants, with particular focus on selective serotonin reuptake inhibitors (SSRIs), in the context of adolescent development, with the argument that the use of antidepressants for adolescents with depressive symptoms is indicated, but not without careful evaluation.

Adolescence is a time of great neurodevelopment. Cortical grey matter volume peaks at around 12 years, taking an inverted U-shape, and white matter follows a linear increase across ages 4 to 20 (Lenroot & Giedd, 2006; Giedd, et al., 1999). Maturation of many brain structures also occur through adolescent years. In combination with these structural and connectivity developments, neurotransmitter pathways also change. The dopamine pathway, for example, has been shown to change substantially, with dopamine levels peaking in adolescence. The increase in dopamine parallels the increases in dopamine receptor dendrites, innervation density and axonal length (Cousins & Goodyer, 2015). Serotonin pathways, too, are important in adolescent development and facilitate synaptic growth in childhood. These changes in neurotransmitter pathways play a central role in heightened reward sensitivity seen throughout adolescence, and are associated with changes in adolescent behavior, such as risk taking and mood alterations.

Despite this overall development, there is evidence that neurodevelopment is altered in adolescents with affective disorders. The differences between adolescents with and without depressive symptoms is important in the functioning of antidepressants. Those with depression generally have decreased brain volume compared to controls, and adolescents aged 12 to 16 at high risk of depression have reduced hippocampal and putamen growth, as well as a sex differential in amygdalar volume (Whittle, et al., 2014). As a comorbid condition with anxiety disorders, depression is associated with HPA dysregulation. Reasonably, these findings suggest that adolescents with depression, or an onset of depression, have altered neurodevelopment, but it remains difficult to distinguish the effects depression alone has on this development. Evidence suggests that the onset of depression itself is due to childhood conditions and maltreatment. In the extreme cases where there is emotional and physical abuse or neglect in early childhood, the onset of depressive symptoms occurs earlier, develops more severely, and reoccurs more often into adulthood (Cousins & Goodyer, 2015).

Fig 1. Group-by-Time Interaction of Selected Brain Volumes in Participants in a Longitudinal Study of Brain Development and Depression Onset During Adolescence(Whittle, et al., 2014)

The understanding of adolescent brain development is important for evaluating treatments for depression. The use of antidepressants for adolescents have been of particular concern because of the potential vulnerabilities in adolescent neurocognitive development. Antidepressants themselves are known to alter brain function, and providing such medicine to a maturing brain raises concerns. The exact targets of antidepressants, particularly SSRIs, is not fully known, but extensive evidence has shown that SSRIs reactivate hippocampal neurogenesis that is substantially reduced in major depressed individuals (Boldrini, et al., 2012). SSRIs have also been shown to reduce the abrogated connections between the hippocampus and dorsal medial PFC -- strong connectivity between these regions are present in those with depression. SSRIs affect more than just the hippocampus, however. As mentioned, the amygdala is also implicated in depressive symptoms, and clinical studies have shown that SSRIs reduce amygdala response to negative bias in facial expressions (Harmer, et al., 2004).

The extent that SSRIs affect the adolescent brain is still under investigation. Studies focusing on the effects of SSRIs in adolescents have used animal models, and there is evidence for age-dependent effects. One concern in providing SSRIs to adolescents has to do with the interaction between increased serotonin levels and hippocampal development in juvenile and adolescent rats. The increase in serotonin reuptake by fluoxetine has been shown to reduced dendritic branching in the hippocampus, as well as alter protein expression in various hippocampal regions compared to adult rats with the same treatment (Norrholm & Ouimet, 2000). The chronic treatment of fluoxetine in juvenile and early adolescent rats increases serotonin transporter affinity into adulthood. This was not shown when the drug was given to rats later in adolescence and early adulthood. These findings suggest that SSRIs may affect neurodevelopment in adolescence when compared with their adult counterparts. However, there is little clinical research of antidepressant effects on adolescent brain development, and many animal studies used healthy, not depressed, subjects. The evidence that SSRIs exert age-related effects is nonetheless important in addressing possible acute and chronic detrimental effects in neurodevelopment.

https://www.psychiatrictimes.com/ssri-prescribing-rates-and-a
dolescent-suicide-black-box-hurting-or-helping/page/0/1

In 2004, the efficacy of SSRIs came under scrutiny by the US Food and Drug Administration (FDA) in response to research that suggested antidepressant drugs increased suicidality twofold in children. The FDA issued a black box warning and required antidepressant drug manufacturers to include warning labels on their product about the possible link between suicidal behavior in youth and antidepressant use (Singh, et al., 2009). Around the same time, a warning was issued in the United Kingdom for similar concerns. In both instances, the prescription of antidepressants for children rapidly decreased, with some studies indicating a 20% decrease in antidepressant prescriptions for children and adolescents. This reduction in antidepressant prescription, however, was associated with concurrent increases in suicides and sucide attempts in the same age group. Since 1997, when the Center for Disease Control and Prevention (CDC) started documenting suicidality in the US, 2004 marked the highest year-to-year change in suicide attempt rates. Whether or not the lack of antidepressant prescription after the FDA’s warning triggered increased suicidality is not concrete. However, there are similar examples in other countries, such as the Netherlands, where there was a 49% increase in youth suicides during a 22% decrease in SSRI prescriptions in children and adolescents between 2003 and 2005. Even so, no evidence was purported for this sucide-prescription link in the United Kingdom. Taken together, the concerns raised by the FDA and other health organizations may not have warranted statewide alarm, but use of antidepressants for children and adolescents should nonetheless be taken seriously and cautiously. As it stands now, however, opinions are divided.

In contrast to the warnings against the use of SSRIs in children in adolescence, there is clinical evidence that suggest antidepressants have beneficial outcomes in adolescents. Such studies showed that chronic administration of fluoxetine had significant symptomatic remission in youth with moderate to severe depression, and that the use of SSRIs has greater benefit then alternative therapies alone (March, et al., 2005; Goodyer, et al., 2007). In these studies, adolescent participants were divided into four different treatment groups: an antidepressant group, a placebo group, a cognitive-behavioral therapy (CBT) group, and an antidepressant group with CBT. Outcomes were measured byway of depression rating scores and questionnaires. The results in both studies suggested that those given fluoxetine, with or without CBT, improved the greatest, but the effectiveness of antidepressants alone compared to antidepressants with CBT were mixed. Suicidal ideation was reduced in all treatments in both studies and was shown to reduce the greatest in those treated with antidepressants.

The use of antidepressants to treat adolescents with depressive symptoms is warranted, overall. However, it is obvious that the effects of antidepressants on children and adolescents is different from that of adults. Given that adolescence is a time of great neurodevelopment, it is appropriate to be wary of the neurological consequences of antidepressant use, both acutely and chronically. More longitudinal studies of antidepressants on adolescence is needed. As it stands, however, there is no major evidence that precludes the use of antidepressants for human adolescents, despite some of the concerns raised by animal studies. The positive outcomes of antidepressant use in adolescents adds to its efficacy, which may outweigh the benefits of CBT. Therefore, the use of antidepressants for adolescents with depressive symptoms ought to be indicated, but there must be careful evaluation where further research is needed.  

References

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3. Lenroot, R. K., & Giedd, J. N. (2006). Brain development in children and adolescents: Insights from anatomical magnetic resonance imaging. Neuroscience & Biobehavioral Reviews, 30(6), 718-729. doi:10.1016/j.neubiorev.2006.06.001
4. Giedd, J. N., Blumenthal, J., Jeffries, N. O., Castellanos, F. X., Liu, H., Zijdenbos, A., Rapoport, J. L., et al. (1999). Brain development during childhood and adolescence: A longitudinal MRI study. Nature Neuroscience, 2(10), 861-863. doi:10.1038/13158
5. Cousins, L., & Goodyer, I. M. (2015). Antidepressants and the adolescent brain. Journal of Psychopharmacology, 29(5), 545–555. doi:10.1177/0269881115573542
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Ben Dorfman

February 11th, 2019

Reading Response 2: Chapter 4 Neuroplasticity.

Psychotherapy triggers a shift in thinking that leads to reorganization of certain brain areas consistent with neuroplasticity.

Review Questions:

What is the difference between a critical period versus a sensitive period? Critical periods are abrupt/narrow periods during which a particular stimulus is expected for normal development to occur. Sensitive periods are more gradual periods that are associated with opportunities for certain types of learning to occur. Sensitive periods are wide periods that occur throughout the lifespan and during these periods it is easier to learn certain things.

Define neurogenesis and synaptogenesis? Neurogenesis is the process by which new neurons form. Synaptogenesis is the formation of new synapses between neurons.

Definitions:

Allostasis: The process by which the body undergoes in order to maintain homeostasis. A number of systems (endocrine, sympathetic, parasympathetic, hpa axis) may be involved in this process.

Glucocorticoids: glucocorticoids are a class of steroids that bind to the glucocorticoid receptor. Glucocorticoid receptors are found in almost every vertebrate animal cell. Glucocorticoids (esp. cortisol) plays an important role in the immune system as it is released in response to stress.

Long-Term depression: LTD is the decrease of strength of a synapse. Reduced use of synapse leads it to become weaker and weaker.  This may be important for removing superfluous information. This process ensures that energy expenditure continues to be allocated properly.

Reflection: The correlation between socioeconomic (SES) status and neurological well-being deeply surprised me. Language processing centers and executive function were the most impaired in people of lower socioeconomic status. Children in higher SES had much larger vocabularies by the age of three than kids in lower SES. The gaps in language may be due to lack of exposure to educators. How can we change the societal structure so that education can be more widespread so that neuro-development can be enhanced for everybody not only the rich? Hopefully in the future programs will be set up so that everybody can have equal access to these essential things that help us develop normally.

It seems that the hierarchical structure is intentionally decreasing access to education so that those with wealth and power can maintain their positions of power. If one were to give life to a program that gave access to quality education to the lower class than the lower class would be at odds and threaten to overtake the upper class.

In addition to the power of socioeconomic status and brain development, I found the power of psychotherapy to be quite mind boggling. It is incredible to me that one’s brain chemistry can alter so much just by talking about what the neural activity is creating(about one’s thoughts)! Tools like psychotherapy need to implemented and encouraged more in schools. I feel that psychotherapy is often stigmatized and that its therapeutic potential is often overshadowed by other forms of treatments mostly pharmacological treatments.

Discussion Question: Does Long Term Depression lead to pruning? Can learning be agonized even more if one were to add the amount of NMDA receptors in somebody’s brain?

Ben Dorfman

Position Paper

April 28th, 2019

The Benefits of Exercise on the Adolescent Mind

Adolescents make up about 13% of the United States population and worldwide there are about 1.2 billion adolescents (Sivagurunathan, 2015). Adolescence is a tumultuous time as it bridges the naive innocence of childhood with the responsibility and obligations of adulthood. The first symptoms and onset of many psychiatric disorders appear during this time period (Kessler, 2007). The prevalence of psychiatric disorders amongst adolescents has been increasing for the last 20-30 years. Recent estimates suggest that approximately 12% of adolescents struggle with a psychiatric disorder.  

The neurophysiological changes that occur during this time period (activation of neural pathways such as the HPA and HPG axis) contributes to increased stress. Compounded with the stress of physiological changes, adolescents face many environmental stressors such as the desire to fit in with peers and pressure to succeed academically and extracurricularly. With all the chaos that occurs during this time period researchers are finding new ways to help reduce the stress of this cohort so that most of us can grow into healthy adults who contribute to society.

One of the methods that is being researched is the effect of exercise on mental well-being. It is my belief that physical exercise (especially prolonged aerobic exercise) can be an effective treatment for several psychiatric disorders experienced during adolescence especially bipolar disorder and depression.

Physical exercise modulates genes that promote structural changes in the brain to enhance cognitive function and overall well-being (Mandolesi, 2018). Even acute exercise is proven to have positive effects on individuals. In one study conducted by A.W. Metcalfe and his team, bipolar adolescent subjects were subjected to a 27 minute interval session of aerobic exercise. The neurophysiology of diseases like bipolar disorder are still being understood but several researchers have begun to conclude that it may be due to a dysfunction of the ventral-striatal dopaminergic pathway (Cousins, 2009). After the patients were done with the exercise the researchers found normal levels of activation of the reward pathway compared with healthy control subjects. In conjunction with normal baseline activity of these neurological circuits came a reduction in the symptoms found in bipolar patients. It has long been known that the effects of exercise have improved the symptoms of bipolar patients.

The mechanisms responsible for these neurologic changes following exercise are the subject of much research. Some studies have shown that the increase of brain-derived neurotrophic factor (BDNF) in the striatum are responsible for the positive symptoms following exercise (Schuch, 2015) (Marais, 2009). BDNF is a gene that is involved in neural development, but has several other functions. BDNF enhances neural transmission and aids in learning and memory by promoting neurogenesis in the hippocampus (Liu, 2017). It is well established that exercise contributes to increased dopamine levels. Exercise is also closely associated with endorphins which are endogenous opiates that function as pain-reducers. The changes in endorphin levels that are seen post-exercise may contribute to the activation of the meso-limbic dopaminergic pathway (Spanegel, 1992).

Other biological effects of exercise are ATP/ADP ratio shifts, fluctuations of intracellular Calcium (Ca2+), and activation of other oxidation pathways (Vina, 2012). The psychoactive mechanisms of exercise are due to a variety of factors. The increased release B-Endorphin during physical exercise may lead to the euphoria experience. (Bortz, 1981). The response of several stress hormones such as ACTH and cortisol fluctuates during exercise (Harper, 1984). These stress hormones may lead to altered pain perception, but researchers are unsure what the differences in these hormone levels mean. In addition to the BDNF gene discussed earlier, exercise leads to an increase in glial cell derived neurotrophic (GDNF) factor and insulin growth factor (IGF). GDNF is another important chemical that helps promotes survival and IGF is involved in the proliferation and function in nearly every cell.

The World Health Organization recommends 60 minutes of moderate-vigorous physical activity a day for 11-17 year olds. According to the World Health Organization, 81 percent of 11-17 year olds did not meet this recommendation. In the United States, 3 out of 10 high school students participated in regular physical activity (CDC, 2017). The decline in physical activity usually occured between the ages 9-15 (Cairney). The decrease of physical exertion during these formative years has been linked to decreases in perceived parental support, self-efficacy, socialization and attention (Dishman, 2017). Routine physical exercise as an adolescent is more likely to lead to an increase in exercise as an adult (Sacker, 2006). Routine physical activity (aerobic exercise) reduces the risk for cardiovascular disease, type 2 diabetes, and even specific types of cancer (Ashcraft, 2016). Animal studies have shown that running increases neuronal cell proliferation, differentiation, and survival (Cotman, 2002).

Why does exercise have such a profound effect in adolescents. As mentioned earlier, adolescence is a formative period of development in which the brain is undergoing immense changes and thus is more sensitive to changes in the environment. The activation of the reward pathways during adolescents may serve as a reinforcer to the positive emotions felt following exercise.

There are four different psychosocial explanations for the effects of physical activity on mood. The first one posits that physical activity is a distraction and that is what contributes to the positive effects rather than any biochemical process. The second explanation states that the sense of achievement from exercise contributes to the increased mood. The third explanation hypothesizes that an increase in social opportunity is brought on by many forms of exercise leading to an increased mood. Lastly, the fourth theory states that exercise helps ‘body form’ which leads to an increase in self-esteem. While I think there may be truth in all of these explanations, I believe that the correlation between exercise and mood is not purely psychosocial and that there is also a neurobiological explanation. Many psychosocial factors do play a role in the prevalence of physical activity. For example, an individual in a lower SES may have to work many more hours than somebody in a high SES which would not allow that individual in the lower SES to have time to participate in regular physical activity. In addition, adolescents in lower SES often live in areas where crime is prevalent and access to recreational areas, such as parks and gyms is not feasible.

Depression is one of the most prevalent psychological disorders amongst adolescence. Prolonged exercise has been proven to mitigate the effects of depressive symptoms. In one study, participants aged 11-14 were recruited and then followed for two years. During this time and after two years the subjects filled out the Short Moods and Feelings Questionnaire. These researchers found an 8% decrease in depressive symptoms for each additional hour exercise undertook per week (Rothon, 2010). In another study adolescents and young adults (aged 12-25) who had depression were recruited. These individuals underwent periods of prolonged aerobic exercise several times a week for an eight week period. A reduction in overall depressive symptoms was found after the eight week period. In a study done by the Institute of Mental Health and the University of Ottawa, depressed adolescents who had not been using pharmacological treatment tried prolonged aerobic exercise to treat their symptoms. Three times a week for twelve weeks subjects participated in aerobic exercise for 45 minutes each time. Anxiety was measured after each session with Generalized Anxiety Disorder 7 Item Questionnaire. A decrease in depressive symptoms and anxiety was seen amongst subjects. This study was a landmark study as it is one of the firsts to treat depression with aerobic exercise (Jaworska, 2019).

Before the invention of agriculture humans had to constantly move locations in order to find the resources to survive. This active lifestyle of movement has been lost in modern times as we no longer need to constantly move in order to survive. The loss of an active lifestyle is a major consequence of the modern world that I believe has led to a decrease in overall life satisfaction for many individuals. How can we as a society promote an active lifestyle? The U.S. government lists physical exercise at the top of the public health agenda. But for many people, school, and jobs prevent them from finding time. I believe that increased education of the positive factors of exercise as well as increased time in schools that allow adolescents to play outside and move around could increase mental well-being significantly.

In my life, physical exercise has had a tremendous effect on my well being. As a high school freshman I attended a public school with over 1,000 kids in my class. Transferring from a small private school in another town I did not know a single kid. This experience brought about extreme anxiety and confusion. A couple months into my freshman year I was diagnosed with depression. My parents and I decided not to try pharmacological treatment over the fear of long term side effects. After a brutal freshman year, the fall of my sophomore year came about and I was still just as shy and scared as I was a year prior. To my dismay, my mother forced me to join the cross country team. Reluctantly and angrily I started going to cross country practice. Little did I know this was a defining moment in my life. I found the running to be difficult, but I enjoyed the challenge and it allowed me to finally connect with some of my peers. Flash forward four years later to today and I still continue to run religiously.  After a run I am more energized, productive, and sociable. I believe this to be a consequence of several of the factors that I discussed earlier.

In our society, the amount of psychiatric disorders is increasing along with the amount of psychiatric drugs. In my life, I would say that over half my peers take some sort of psychiatric drug daily. I find it very strange that so many people regularly take antidepressants, mood stabilizers, or stimulants. For many people, these medications are ineffective or have adverse side effects. I believe it would be beneficial to experiment with other types of therapy such as physical exercise to aid in these mental illnesses.

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