Abstract
Recent advances in the developmental epidemiology, neurobiology, and treatment of pediatric anxiety disorders have increased our understanding of these conditions and herald improved outcomes for affected children and adolescents. This article reviews the current epidemiology, longitudinal trajectory, and neurobiology of anxiety disorders in youth. Additionally, we summarize the current evidence for both psychotherapeutic and psychopharmacologic treatments of fear-based anxiety disorders (e.g., generalized, social, and separation anxiety disorders) in children and adolescents. Current data suggest that these disorders begin in childhood and adolescence, exhibit homotypic continuity, and increase the risk of secondary anxiety and mood disorders. Psychopharmacologic trials involving selective serotonin reuptake inhibitors (SSRIs) and selective serotonin norepinephrine reuptake inhibitors (SSNRIs) are effective in pediatric patients with anxiety disorders and have generally demonstrated moderate effect sizes. Additionally, current data support cognitive behavioral therapy (CBT) for the treatment of these conditions in youth and suggest that the combination of psychotherapy + an SSRI may be associated with greater improvement than would be expected with either treatment as monotherapy.
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Introduction
Affecting between 15 and 20 % of youth, anxiety disorders are among the most prevalent psychiatric conditions in children and adolescents [1, 2]. Moreover, from a public health standpoint, these disorders, when present in youth, increase the risk of suicide attempts [3, 4] and are associated with significant morbidity and mortality. Additionally, longitudinal data suggest that anxiety disorders in youth predict a range of psychiatric disorders later in life, including other anxiety disorders, substance use disorders, and depression [5, 6].
To date, most treatment studies of pediatric anxiety disorders have largely focused on anxiety symptoms as a homogenous entities, and as such, many psychopharmacologic treatment investigations have included individuals with “pediatric anxiety disorder triad” (i.e., generalized anxiety disorder [GAD], social phobia [SoP]/social anxiety disorder, and separation anxiety disorder [SAD]). It is further noteworthy that accumulating clinical, phenomenologic, epidemiologic data support this classification. Specifically, the “triad anxiety disorders” frequently cooccur [7] exhibit very similar trajectories [8], share neurophysiology [9, 10], and respond similarly to both psychotherapeutic and psychopharmacologic treatments (e.g., selective serotonin reuptake inhibitors [SSRIs]) and cognitive behavioral psychotherapy [11].
Herein, we will review the developmental epidemiology, neurobiology, assessment, and treatment (both psychotherapeutic and psychopharmacologic) of youth with anxiety disorders as well as recent, long-term treatment data and emerging data concerning predictors of treatment response. Ultimately, to achieve the optimal outcome in any individual child or adolescent, a personalized approach is necessary, based on as much knowledge as possible of the developmental epidemiology, the personal and family history, signs and symptoms, pathophysiology, clinical phenotype, comorbidities, as well as the family, home, and school environment. Frequently, these data will result in a multipronged approach to treatment—which may include one or more psychopharmacologic or psychotherapeutic interventions.
Developmental Epidemiology and Course of Pediatric Anxiety Disorders
Accumulating data—from both retrospective and prospective studies—suggest that anxiety disorders are both the most frequent psychiatric disorders in children and adolescents and represent the “earliest of all forms of psychopathology” [12]. Mostly due to the frequent, early emerging specific phobias, the onset of the first or any anxiety disorder is usually in childhood, and thus considerably earlier than the onset of depressive or substance use disorders (Fig. 1a). However, there is considerable heterogeneity in the onset of the specific anxiety disorders with GAD, agoraphobia, panic disorder, and obsessive-compulsive disorder (OCD) mostly emerging in adolescence (Fig. 1b). Overall, anxiety disorders are more prevalent in girls compared to boys, although it is noteworthy that sex differences are accentuated by development, with prevalence ratios reaching 2–3:1 by adolescence [2, 6, 13, 14•].
Although anxiety disorders with onset in childhood or adolescence may spontaneously remit, the course of pediatric anxiety disorders is overall considered to be chronic and persistent. This is due to several decades of data suggesting that anxiety disorders in childhood or adolescence strongly predict the presence of the same condition (homotypic continuity) later in life [6, 15–18]. The individual course, however, is often “waxing and waning,” and “syndrome shifts” to other anxiety syndromes frequently occur [19]. The presence of “pure” anxiety disorders decreases with age in favor of patterns with multiple anxiety disorders, and by late adolescence or early adulthood, secondary psychopathology, such as depressive or substance use disorders, has frequently developed (heterotypic continuity) [6, 16, 20–23]. Thus, early anxiety manifestations are at the outset of a “cascade of psychopathology” suggesting the need for early recognition and treatment [24, 25]. In addition to adverse long-term psychopathological outcomes, child and adolescent anxiety disorders were linked with poor long-term functioning and general health as well as interpersonal, financial, and educational difficulties [17, 26] in addition to suicidality [17, 27].
Neurobiology of Pediatric Anxiety Disorders
Considerable advances have been made in the understanding of the neurobiology of pediatric anxiety disorders over the past decade (for reviews, see [9, 28]). In general, these studies implicate dysfunction in prefrontal-amygdala-based circuits, although a myriad of both functional and structural neuroimaging studies reveal dysfunction (or abnormalities) in default mode networks and posterior structures, including the posterior cingulate, precuneus, and cuneus (Fig. 2). Among the structures which are most frequently implicated in the pathophysiology of pediatric anxiety disorders, the amygdala—which is charged with the initiation of central fear responses—is frequently “overactivated” in functional magnetic resonance imaging (fMRI) studies of youth with fear-based anxiety disorders. However, the implication of the amygdala-based dysfunction extends beyond its activity and functional responsiveness to its connectivity. In this regard, intrinsic functional connectivity networks, including connectivity to the medial prefrontal cortex, anterior cingulate cortex, insula, and cerebellum have been described. In addition to the amygdala, the ventrolateral prefrontal cortex has been examined in numerous studies of youth with fear-based anxiety disorders. Importantly, this structure regulates amygdala activity and plays a pivotal role in extinction in the context of fear conditioning and responds in tandem with the amygdala to emotional probes. It is further noteworthy that this structure may serve a lynchpin function in pediatric anxiety disorders. As such, the VLPFC is not only hyperactivated in youth with anxiety disorders, but the degree of activation is inversely proportional to the severity of anxiety symptoms, consistent with the notion that the VLPFC plays compensatory role in youth with anxiety (for review, see [9]). Consistent with this notion, fluoxetine and cognitive behavioral therapy (CBT) are associated with increases in activity of this structure in adolescents with anxiety [29]. Finally, the cingulate cortex which girdles the limbic system and subserves motivation and cognitive control is hyperactivated in youth with anxiety disorders [30] and that glutamatergic tone within the anterior cingulate cortex directly correlates with the severity of anxiety in adolescents with GAD [31]. That normalized concentration of the excitatory neurotransmitter glutamate, within the anterior cingulate cortex, that correlate with the severity of anxiety in adolescents is of interest in that it suggests a neurochemical basis for anxiety symptoms and also raises the possibility that glutamate modulating medications may have utility in pediatric anxiety disorders.
Screening and Assessment
Current practice parameters from the American Academy of Child and Adolescent Psychiatry [32] recommend screening for anxiety symptoms, rating the severity of the anxiety symptoms and functional impairment in youth with anxiety disorders and carefully assessing for comorbid psychiatric conditions as well as for general medical conditions (e.g., hyperthyroidism) that may mimic anxiety symptoms. Moreover, the evaluation of the pediatric patient with suspected anxiety should allow anxiety disorders to be differentiated from developmentally appropriate worries, fears, and responses to stressors. Additionally, stressors or traumas should be considered to determine their contribution to the development or maintenance of anxiety symptoms. Finally, it is critical to consider that anxiety-related symptoms such as crying, irritability, or tantrums may be misinterpreted by adults as oppositionality or disobedience; these behaviors represent the child’s distress and efforts to avoid the anxiety-provoking stimulus.
Several well-studied child self-report screening measures for anxiety exist and may be used in patients > 8 years of age. First, the Multidimensional Anxiety Scale for Children [33], the Screen for Child Anxiety and Related Emotional Disorders (SCARED) [34], and the Spence Children’s Anxiety Scale (SCAS) [35] were developed to be sensitive and specific for assessing anxiety in youth and are useful in clinical practice to monitor treatment progress [36]. The Preschool Anxiety Scale is a parent report adapted from the SCAS that was developed for screening for anxiety in young children (ages 2.5 to 6.5). The SCARED and SCAS are available online/free access. Second, the Pediatric Anxiety Rating Scale, which is frequently utilized as a primary or secondary outcome measure in psychopharmacologic trials of youth, is a clinician-rated measure used to assess the severity of anxiety symptoms and change over time [37]. Third, with regard to social phobia or social anxiety, the Social Anxiety Scale, the Social Worries Questionnaire, and the social phobia subscale of SCARED are brief screening measures for social phobia/social anxiety symptoms. Fourth, a set of novel dimensional anxiety scales was recently generated during the DSM revision process to support clinical decision-making and monitoring treatment progress (www.psychiatry.org/dsm5). These self-rated scales can be used for children aged 11 or older and comprise the core constructs of fear and anxiety together with cognitive, physical, and behavioral symptoms in a consistent and brief way, using a common template for each of the anxiety disorders [38].
Psychological Treatments
Cognitive Behavioral Therapy
Well-regarded as an effective evidence-based treatment for childhood anxiety disorders, CBT has several key components: psychoeducation of child and caregivers regarding the nature of anxiety; techniques for managing somatic reactions including relaxation training and diaphragmatic breathing; cognitive restructuring by identifying and challenging anxiety-provoking thoughts; practicing problem-solving for coping with anticipated challenges; systematic exposure to feared situations or stimuli, including imaginal, simulated, and in vivo methods, with special focus on desensitization to feared stimuli; and relapse prevention plans [36]. To date, a few studies have evaluated the efficacy of CBT either alone or in combination with psychopharmacologic treatment for childhood anxiety disorders [7, 39]. In a large, multisite study of youth with moderate to severe GAD, SoP, and SAD, the Child/Adolescent Anxiety Multimodal Study (CAMS), 488 children and adolescents (aged 7–17 years) were randomized to one of three treatment groups (sertraline monotherapy, CBT, or sertraline + CBT) for 12 weeks [7]. In terms of clinical improvement and symptom severity, all treatment groups were superior to placebo (24 %), and the combination therapy (sertraline + CBT) was significantly more efficacious (81 %) than either group treated with either medication (55 %) or CBT (60 %) alone. The 24- and 36-week follow-ups in CAMS revealed that over 80 % of acute responders maintained their positive response at both 24 and 36 weeks [40•]. During the follow-up period, participants continued in active treatment with sertraline, CBT booster sessions, or both. Finally, the naturalistic 6-year follow-up study of this sample (n = 288) revealed that these treatment effects were durable and sustained, with remission rates of 48.8, 51.9, and 45.8 % for combination therapy, sertraline only, and CBT only, respectively [41]. Alternatively, nearly half of the acute responders relapsed during the follow-up period. The authors argue that many youth with anxiety disorders require intensive or extended treatment to maintain acute treatment gains [41].
Beidel and colleagues [39] evaluated the efficacy of Social Effectiveness Therapy for Children (SET-C) versus fluoxetine or placebo in children and adolescents aged 7–17 with social phobia. SET-C was more effective than placebo on primary outcome measures and specific symptom measures. Additionally, SET-C was superior to fluoxetine in terms of rate of treatment response (79 vs 36.4 %, p < 0.001), lack of posttreatment diagnosis, and higher end-state functioning [39]. Finally, CBT has now been examined in very young children with anxiety disorders [42]. Sixty-four preschoolers, aged 4–7 years, were randomized to a parent-child CBT intervention or a monitoring-only control condition for a duration of 6 months. The response rate of children in the CBT group (defined as much or very much improved on the Clinical Global Impression (CGI)-Anxiety scale) was 69 %, compared to 32 % for children in the control group. Additionally, 59 % of children CBT-treated were free of all anxiety diagnoses following treatment (vs 18 % of controls) [42].
Mindfulness-Based Psychotherapies
Mindfulness, “the intentional, accepting, and nonjudgmental focus of one’s attention on the emotions, thoughts, and sensations occurring in the present moment” [43], has been utilized as the basis for a myriad of treatments over the last several decades to promote health and well-being in both adults and youth with anxiety disorders. Two approaches in particular have been used to increase psychological health: mindfulness-based stress reduction (MBSR) and mindfulness-based cognitive behavioral therapy (MBCT) [44]. Both MBCT and MBSR use regular mindfulness meditation practices to develop mindfulness skills. Moreover, these psychotherapeutic interventions show promise for the treatment of anxiety disorders. In this regard, randomized, controlled trials in anxious adults have shown statistically significant improvement in symptoms of GAD [45–47], social anxiety [48–50], specific phobia [51], and panic disorder [45]. Mindfulness-based interventions have also shown effective in studies looking at a heterogeneous group of anxiety disorders [52, 53]. At least one study has shown mindfulness to be as effective as CBT for social anxiety disorder [54].
In children and adolescents, studies of mindfulness-based interventions have been more limited. Catani et al. [55] found meditation-based relaxation to be as effective as trauma-focused CBT in the treatment of children with PTSD from war and tsunami in Sri Lanka. Lierh and Diaz [56] found a mindfulness intervention to be effective in decreasing symptoms of anxiety and depression in a group of minority children. Other studies have shown effectiveness of mindfulness-based treatments in a variety of mental health problems in children [44], and open-label studies suggest that group-based MCBT may be effective for the treatment of adolescents with generalized, social, or separation anxiety disorders who are at risk for developing bipolar disorder. Given the acceptability and tolerability of mindfulness-based interventions, as well as their demonstrated effectiveness thus far, such treatments for anxiety in children is an exciting area that warrants further investigation.
Psychodynamic Psychotherapy
Psychodynamic psychotherapy has been evaluated in youth with anxiety disorders and recently subjected controlled trials. In one trial of 4–10-year-old children with anxiety disorders [57], using a quasi-experimental wait-list children (N = 30) which were treated with 20–25 sessions of manualized, short-term Psychoanalytic Child Therapy (PaCT). In this study, 67 % of patients no longer met criteria for any anxiety disorder compared to 0 children in the wait-list group. In parallel, internalizing and total problems significantly declined during treatment and gains were maintained at 6 months posttreatment [57]. Fonagy and Target [58] examined the effect of intensity of psychodynamic psychotherapy. In this sample of 763 patients at the Anna Freud Center, several disorders were associated with differential responses with regard to the intensity of psychotherapy. Specifically, overanxious disorder—the DSM-III forerunner of GAD—responded better to high-intensity psychotherapy, but similar differences in effect were not observed for simple phobias or separation anxiety disorder.
Psychopharmacologic Interventions
The aggressive evaluation of serotonergic antidepressants in youth with anxiety disorders is consistent with the evidence that these medications dampen fear responses in preclinical models of anxiety [59] and is likely driven by evidence supporting their use in adults with anxiety disorders as well as by their evidence for related psychiatric syndromes in youth, including major depressive disorder, with which anxiety disorders often cooccur.
Fluoxetine
Fluoxetine reduces anxiety in youth with triad anxiety disorders (mean age: 11.8 ± 3 years, N = 74) over the course of 12 weeks of treatment [60]. In this trial, fluoxetine was initiated at 10 mg/day and titrated to a maximum fixed dosage of 20 mg/day following the first week of treatment. Fluoxetine demonstrated significant improvement in anxiety symptoms and was generally well-tolerated. Adverse effects reported include nausea, abdominal pain, drowsiness, and headaches. Additionally, Beidel and colleagues [39] examined the efficacy of fluoxetine and SET-C in a 12-week, placebo-controlled study in youth (mean age: 11.6 ± 2.6 years, N = 122) with SoP (primary diagnosis). Patients were treated with fluoxetine (n = 33), SET-C (n = 57), or placebo (n = 32), and fluoxetine was initiated at 10 mg/day (2 weeks), then titrated, sequentially, to 40 mg daily. Fluoxetine was superior to placebo, and SET-C was statically superior to both fluoxetine and placebo. In terms of side effects in this trial of social phobia patients, only nausea occurred more frequently in patients receiving fluoxetine.
Fluvoxamine
Fluvoxamine has been examined in children and adolescents (aged 6–17 years, N = 128) with mixed anxiety disorders (GAD, SoP, and/or SAD) in an 8-week double-blind, placebo-controlled study [61]. Fluvoxamine-treated patients exhibited a statistically significant improvement in PARS score compared to youth receiving placebo. Fluvoxamine was well-tolerated, and there were no statistically significant differences in adverse events between placebo-treated patients and those receiving fluvoxamine.
Paroxetine
Wagner and colleagues [62] treated children with SoP, aged 8–17 years, with flexibly dosed paroxetine over the course of a 16-week, multicenter, parallel group study. Paroxetine was initiated at 10 mg/day and then flexibly dosed to a maximum of 50 mg/day. Patients receiving paroxetine exhibited a greater response rate (CGI–I: 77.6 % of the paroxetine-treated vs 33.8 % of placebo-treated patients, p < 0.001), and in this sample, paroxetine was well-tolerated. However, decreased appetite, vomiting, and insomnia were observed, and four paroxetine-treated patients (and 0 placebo-treated patients) experienced emotional lability and suicidal ideation.
Sertraline
One 9-week, double-blind, placebo-controlled study of children and adolescents with GAD, aged 5–17 years examined the efficacy of fixed-dose treatment with sertraline [63]. In this trial, sertraline was initiated at 25 mg/day for 1 week and then increased to 50 mg/day for the subsequent 8 weeks. Sertraline treatment was associated with statistically significant improvements in anxiety symptoms (Hamilton Anxiety Scale Score (HAM-A)), lower symptom severity (i.e., lower CGI-S scores) as well as greater improvement (i.e., higher CGI-I scores). In this study, there were no significant differences in adverse events between sertraline- and placebo-treated patients. Walkup and colleagues examined the efficacy of sertraline in the CAMS [7], which involved a sample of 488 children and adolescent, aged 7–17 years, with GAD, SoP, or SAD or a combination of these disorders, who received sertraline (n = 133), CBT (n = 139), a combination of the sertraline and CBT (n = 140), or placebo (n = 76) over the course of 12 weeks. Sertraline + CBT (81 %) was statistically superior to sertraline monotherapy (55 %) and CBT monotherapy (60 %) in terms of clinical improvement (i.e., CGI-I score) and symptom severity (i.e., PARS score). Additionally, sertraline and CBT monotherapy were superior to placebo (24 %). Recently, the long-term extension study of CAMS was published—Child/Adolescent Anxiety Multimodal Extended Long-term Study (CAMELS) [41], in which 288 of the original 488 CAMS participants were followed longitudinally. Patients who responded to acute treatment were more likely to be in remission and to have lower PARS scores. Also, of clinical importance, 50 % of responders to acute treatment—regardless of type—achieved remission over the follow-up interval.
Venlafaxine
Venlafaxine ER was evaluated in youth with GAD and SoP. In an 8-week, multicenter, randomized, double-blind, placebo-controlled study of patients, aged 6–17 years with GAD (N = 320) [64]. Over the course of treatment, GAD symptoms significantly improved relative to placebo, and side effects were consistent with the known side effect profile of venlafaxine and included anorexia and somnolence, increases in heart rate and blood pressure, as well as weight loss. Also, two patients who received venlafaxine (compared to 0 patients receiving placebo) reported suicidal ideation/suicide attempt. March and colleagues [65] examined venlafaxine ER in children and adolescents with SoP. This double-blind, placebo-controlled trial studied a 16-week course of venlafaxine in children and adolescents (aged 8–17 years, mean age: 13.6 ± 3.0 years, N = 293,). Venlafaxine was initiated at 37.5 mg/day and titrated according to body weight to an average of 2.6–3.0 mg/kg (maximum dose: 225 mg/day for patients ≥ 50 kg). Efficacy measures included the Social Anxiety Scale, child or adolescent version (SAS-CA), and CGI-I. Venlafaxine-treated patients exhibited significant improvements in SoP symptoms compared to placebo-treated patients. Adverse effects of venlafaxine included weight loss (secondary to anorexia), nausea, and dizziness. Further, three venlafaxine-treated patients (compared to 0 placebo-treated patients) developed suicidal ideation, although no suicides or suicide attempts occurred.
Duloxetine
Strawn and colleagues [66•] evaluated the efficacy of duloxetine in a double-blind, placebo-controlled trial of children and adolescents with GAD, aged 7–17 years (N = 272) over the course of 10 weeks. In this study, PARS severity for GAD scores as well as total PARS score, CGAS, CGI-I, and CGI-S scores all improved over the course of treatment and this medication was recently approved by the United States Food and Drug Administration for the treatment of GAD in youth aged 7–17 years. Significant side effects included nausea, vomiting, decreased appetite, dizziness, cough, oropharyngeal pain, and palpitations.
Recently, all randomized, double-blind, placebo-controlled trials of SSRI/SSNRIs in pediatric patients with fear-based anxiety disorders, were subjected to a meta-analysis [67•] to provide a meta-analytic estimates of effect size and tolerability measures. This meta-analytic evaluation suggests a modest effect size (Cohen’s d = 0.62) and importantly suggests that SSRIs may not be associated with a statistically significant risk of suicidality in pediatric patients with anxiety disorders. Moreover, in this meta-analysis of 1673 patients, antidepressant treatment did not appear to be associated with an increase in all cause discontinuation (p = 0.132). Nonetheless, treatment-emergent activation was more commonly associated with antidepressants (compared to placebo), although this only trended toward statistical significance (p = 0.05) [67•].
Tricyclic Antidepressants
Prior the availability of newer antidepressant medications, tricyclic antidepressants (TCAs) were frequently utilized for pediatric anxiety disorders; however, their role has subsequently been supplanted by the SSRIs and SSNRIs. Moreover, controlled trials of TCAs for youth with anxiety disorders have yielded conflicting results (Table 1). Specifically, clomipramine, which is efficacious in randomized, controlled trials of pediatric patients with OCD, only one randomized controlled trial exists for pediatric anxiety disorders. Moreover, the anticholinergic side effects, need for frequent cardiac monitoring, lethality in overdose, have limited their use clinically in pediatric populations.
Benzodiazepines
Benzodiazepines bind to the GABAA receptor and in doing so potentiate the effects of the endogenous, inhibitory neurotransmitter, gamma-aminobutyric acid (GABA). Thus, it is not surprising that for nearly two decades, benzodiazepines have been used to treat anxiety symptoms in youth. However, to date, the evidence for or against the use of benzodiazepines in pediatric patients with anxiety disorders has been limited to randomized, controlled studies in surprisingly few patients.
The efficacy of benzodiazepines in anxious youth has been evaluated in two randomized clinical trials. In youth with GAD, aged 8–17 years (mean age: 12.6 years, N = 30), who were treated with alprazolam (or placebo), no statistically significant differences were observed in anxiety symptoms or in clinical global improvement between alprazolam-treated and placebo-treated youth [68]. However, alprazolam was associated with fatigue and dry mouth. Additionally, Graae and colleagues [69] assessed the efficacy of clonazepam in pediatric patients with SoP and/or GAD (aged: 7–13 years, N = 15). Clonazepam reduced anxiety symptoms to comparable levels as placebo, and no differences were detected in CGI-I scores between benzodiazepine- and placebo-treated youth. Finally, side effects, including irritability, drowsiness, and “oppositional behavior,” were common.
Other Medications
The 5-HT1A agonist buspirone has been evaluated in a large, unpublished, study of pediatric patients with GAD who were aged 6–17 years (N = 559). In this 6-week, randomized, placebo-controlled trial (Bristol-Meyers Squibb 2010), patients were treated with buspirone 15–60 mg/day (divided BID) and no statistically significant differences between buspirone and placebo were observed. However, buspirone was well tolerated, and no serious adverse effects were more frequently reported in buspirone-treated patients compared to the placebo-treated patients.
Atomoxetine has been evaluated in youth with ADHD and a cooccurring anxiety disorders (SAD, GAD, and/or SoP; PARS score ≥15) in a 12-week, multicenter, double-blind, placebo-controlled study [70]. Patients (aged 8–17 years, mean age: 12.0 ± 3.0 years, N = 176) were treated with atomoxetine which was titrated to 1.8 mg/kg/day (mean dose: 1.3 mg/kg/day). Reductions in both anxiety and ADHD symptoms were observed with atomoxetine treatment, and this SNRI was well-tolerated, although decreased appetite was more frequently observed in atomoxetine-treated patients.
Finally, one double-blind, placebo-controlled trial of extended release guanfacine N placebo = 21; N guanfacine ER = 62) in pediatric patients with GAD/SoP/SAD has recently been completed (NCT01470469, www.clinicaltrials.gov). This trial involved 12 weeks of treatment with extended release guanfacine (1–6 mg/day) or placebo. While the full results have not been published, some data are available on clinicaltrials.gov which suggest that extended-release guanfacine is safe and well tolerated in youth with anxiety disorders. However, “efficacy end points were exploratory, [and] no statistical testing was performed because the study was not powered.”
Predictors of Treatment Response
Accumulating evidence suggests a constellation of “predictors” of treatment response in children and adolescents with anxiety disorders. These predictors include demographic characteristics, clinical characteristics, and family system factors. In one study of youth aged 7–17 years with triad anxiety disorders who were treated with fluoxetine (or placebo), having a first-degree relative with an anxiety disorder was associated with poorer functional outcomes at end point (OR = 3.3) [60]. In the CAMS, increased caregiver strain, a measure of the effect of caring for a child with emotional problems on the primary caregiver (e.g., increased time demands, financial strain, disruption of family relationships), predicted higher end point PARS score. Additionally, Ginsburg and colleagues [71] noted that older age predicted a decreased likelihood of remission in CAMS (OR = 0.92, 95 %, p = 0.01), which was defined as the absence of all study entry diagnoses. Additionally, being Caucasian predicted an increased likelihood to enter remission (OR = 2.07, p = 0.003). Finally, the long-term, follow-up study of CAMS participants suggests that males as well as participants with better family functioning are more likely to be in remission approximately 6 years postrandomization [41].
Regarding baseline anxiety symptom severity, in fluoxetine-treated patients, more severe anxiety at baseline (Clinical Global Impression Severity Scale [CGI-S] > 4) was significantly associated with a poorer functional outcome [60], while in other samples of SSRI-treated youth, baseline anxiety symptom severity predicts SSRI nonresponse (OR = 7.34) [72]. Further, more severe anxiety at baseline, as reported by both independent evaluators and parents, predicted higher PARS scores at week 12 in CAMS (p < 0.01 and p = 0.02, respectively) [73•]. Additionally, the type of specific anxiety disorders appears to influence treatment response. Treatment response to fluoxetine in pediatric anxiety disorders is moderated by SoP diagnosis, at least with regard to clinical and functional response [60]. Moreover, in CAMS, having a principal diagnosis of SAD eliminated any advantage of sertraline (and CBT), relative to placebo, with regard to PARS score, although superiority of combined treatment (sertraline + CBT) compared to placebo was preserved [73•]. Finally, in CAMS, a principal diagnosis of SoP was associated with a statistically equivalent decrease in PARS score in patients treated with sertraline ± CBT, but not in patients receiving CBT monotherapy (compared to placebo) [73•], suggesting that for a primary diagnosis of SoP, medication may be a requisite treatment element. Finally, Masi and colleagues [72] observed, in a sample of youth 7–18 years (N = 140) who were treated with fluoxetine, sertraline, or fluvoxamine for 12 weeks, two comorbidity-predicted treatment nonresponse: conduct disorder (OR = 6.39, 95 % CI: 1.402–14.36, p = 0.011) and bipolar disorder (OR = 3.85, 95 % CI: 1.00–9.90, p = 0.050), while in CAMS, a diagnosis of a comorbid internalizing disorder attenuated the probability of achieving remission at end point [71].
Future Directions
While there has been a dramatic increase in the number of neuroimaging, genetic, as well as psychopharmacologic and psychotherapeutic studies involving anxiety disorders in children and adolescents, much work remains. In this regard, while current data suggest a basic neurocircuitry of anxiety disorders in youth, the relationship between dysfunction within these amygdala-prefrontal networks and risk, progression, and treatment remains largely unknown. Moreover, while both psychopharmacologic and psychotherapeutic studies have established the efficacy for a number of treatments, data regarding predictors (either clinical, neurobiological, or psychopharmacologic) of treatment response are brutally lacking. Relatedly, few studies have examined optimal “dosing” of either psychotherapeutic or psychopharmacologic treatments, and little is known regarding next-step interventions for youth with anxiety disorders, who do not respond to initial evidence-based strategies. Finally, the optimal duration of treatment for pediatric patients with anxiety disorders is generally unknown, with both psychopharmacologic and psychotherapeutic studies being frequently focused on short-term, acute effects.
Conclusions
Anxiety disorders are both highly prevalent in youth and are associated with substantial morbidity and an increased risk of suicide attempts and self-injurious behavior. Moreover, these disorders are associated with dysfunction within a myriad of amygdala-based networks throughout the prefrontal cortex (for recent reviews, see [9, 28]). Over the past several decades, screening and assessment tools have been developed to assist clinicians in identifying anxiety symptoms early and accurately establishing anxiety disorder diagnoses. Importantly, these disorders are amenable to treatment, both psychopharmacologic and psychotherapeutic, and there has been a recent surge in evidence for exposure-based CBT and SSRIs/SSNRIs in the treatment of childhood anxiety disorders. Specifically, psychopharmacologic trial data in pediatric patients with non-OCD anxiety disorders suggest that SSRIs and SSNRIs are efficacious and well-tolerated. However, placebo-controlled studies do not support the efficacy of benzodiazepines or buspirone in the treatment of youth with anxiety disorders. Moreover, we are beginning to appreciate that certain clinical and demographic variables may ultimately predict successful treatment outcome, including a family history, baseline anxiety severity, and comorbidity.
Abbreviations
- SSRI:
-
Selective serotonin reuptake inhibitor
- SAD:
-
Separation anxiety disorder
- SoP:
-
Social phobia
- GAD:
-
Generalized anxiety disorder
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Katja Beesdo-Baum and Meghann M. Hennelly declare that they have no conflict of interest.
Anna M. Wehry has received a grant from the American Academy of Child and Adolescent Psychiatry.
Sucheta D. Connolly has received a grant from the National Institute of Mental Health, 1R01MH086517, (01 Jul. 2010–31 Mar. 2015) (Phan and Monk, co-PIs) Brain Markers of Anxiety Disorders and SSRI Treatment in Children and Adolescents. Role: coinvestigator.
Jeffrey R. Strawn has received research support from Edgemont, Eli Lilly, Shire, Forest Research Institute and the National Institute of Mental Health (NIMH).
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Wehry, A.M., Beesdo-Baum, K., Hennelly, M.M. et al. Assessment and Treatment of Anxiety Disorders in Children and Adolescents. Curr Psychiatry Rep 17, 52 (2015). https://doi.org/10.1007/s11920-015-0591-z
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DOI: https://doi.org/10.1007/s11920-015-0591-z