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REVIEW article

Front. Psychiatry, 24 August 2021
Sec. Psychological Therapy and Psychosomatics
This article is part of the Research Topic Insights in Psychosomatic Medicine: 2021 View all 9 articles

Spider Phobia: Neural Networks Informing Diagnosis and (Virtual/Augmented Reality-Based) Cognitive Behavioral Psychotherapy—A Narrative Review

\nJonas Hinze,Jonas Hinze1,2Anne Rder,Anne Röder1,2Nicole MenzieNicole Menzie1Ulf MüllerUlf Müller1Katharina Domschke,Katharina Domschke3,4Matthias Riemenschneider,Matthias Riemenschneider1,2Michael Noll-Hussong
Michael Noll-Hussong2*
  • 1Department of Psychiatry and Psychotherapy, Saarland University Medical Center, Homburg, Germany
  • 2Psychosomatic Medicine and Psychotherapy, Saarland University Medical Center, Homburg, Germany
  • 3Department of Psychiatry and Psychotherapy, Medical Center – University of Freiburg, Faculty of Medicine, University of Freiburg, Freiburg, Germany
  • 4Center for Basics in NeuroModulation, Faculty of Medicine, University of Freiburg, Freiburg, Germany

Recent fMRI studies on specific animal phobias, particularly spider phobia (arachnophobia), have identified a large variety of specific brain regions involved in normal and disturbed fear processing. Both functional and structural brain abnormalities have been identified among phobic patients. Current research suggests that both conscious and subconscious fear processing play a crucial role in phobic disorders. Cognitive behavioral therapy has been identified as an effective treatment for specific phobias and has been associated with neuroplastic effects which can be evaluated using current neuroimaging techniques. Recent research suggests that new approaches using virtual (VR) or augmented reality (AR) tend to be similarly effective as traditional “in vivo” therapy methods and could expand treatment options for different medical or individual scenarios. This narrative review elaborates on neural structures and particularities of arachnophobia. Current treatment options are discussed and future research questions are highlighted.

Introduction

Animal phobia is a type of specific phobia, which is classified under the Anxiety Disorders section of the DSM-5 (1). To meet the DSM-5 criteria for specific phobia, individuals have to show a marked and disproportionate fear or anxiety reaction when exposed to the phobic stimuli (i.e., animals like spiders). This fear or anxiety reaction may result in a full or limited panic attack. Due to fear or anxiety, individuals with specific phobia take significant steps to avoid the feared stimulus. Additionally, the fear and anxiety of a specific stimulus causes clinically significant distress or impairment in social, occupational, and in other relevant areas of function. Symptoms should last for at least 6 months. Individuals with specific phobias, who present without other comorbid diagnoses, are often seen in non-medical mental health settings. However, in medical-clinical settings, specific phobias are rarely seen without comorbid psychopathology, as they are frequently associated with other mental disorders, especially anxiety and depressive disorders (1). In fact, the median lifetime prevalence of specific phobia was estimated to be 7.2% with substantial variation between countries and sites (2). Most studies provide evidence for a higher risk to develop a specific phobia in females. Among the specific phobias, the prevalence of animal phobia is ranging among the most prevalent subtypes (with fear of heights). In this focused narrative review, we first elaborate on the neural structures involved in phobia before mentioning mental and neural processes, as well as structural and physiological changes. We continue by reviewing subconscious fear processing and cognitive behavioral therapy for arachnophobia, followed by a section of VR-AR based treatment options.

Neural Structures Involved in Phobia

Early neuroimaging studies of fear conditioning, as well as more recent experiments, have found evidence of an activation of the amygdala, the anterior cingulate cortex, and the insula—when healthy participants are confronted with conditioned fear-evoking stimuli independent of the task design (3). These structures are commonly referred to as the “fear network,” which is activated during the acquisition phase of fear-conditioning or corresponding paradigms, and shows stronger activation during extinction learning (4). The amygdala, an important structure for reward learning (5), processing of socially and emotionally relevant stimuli (6, 7), and fear acquisition (8), shows stronger activation to conditioned vs. unconditioned fear-evoking stimuli in healthy controls [e.g., (9)]. However, a more general approach assumes a state value-determining function of the amygdala (5, 10). According to this approach, the amygdala calculates and holds a continuously updated representation of value (5). Additionally, studies suggest that the amygdala is also involved in extinction learning in conjunction with the prefrontal cortex (PFC) (11). Apart from the amygdala, the anterior cingulate cortex and the insula are activated during fear conditioning. The insula, responsible for sensorimotor processing, socio-emotional processing, as well as higher cognitive functions, also holds representations of aversive body states (especially the left insular cortex) (12, 13). The anterior insula receives input from the amygdala and projects to the amygdala in turn. The main function of the anterior insula is thought to be the integration of internal states, whereas the posterior insula is responsible somato-visceral integration (14). Thus, the insula might integrate the somato-visceral sensations from anxiety inducing stimuli with the aversive stimuli in the environment (15). A comprehensive overview of the brain regions involved in the fear network can be seen in Figure 1.

FIGURE 1
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Figure 1. Neural structures involved in fear processing. Arrows indicate the direction of the activation.

Resting state fMRI paradigms suggest that the anterior cingulate cortex (ACC), as well as limbic- and hypothalamus- related areas, is functionally connected to areas responsible for affective processing (16). Although not all anxiety-related disorders (e.g., PTSD) show an increased activation of the subgenual ACC or the anterior middle cingulate cortex (17), e.g., patients suffering from social-anxiety disorder or specific phobias demonstrate an increased activity of the pregenual ACC and middle cingulate cortex in comparison to healthy controls (12, 17). In their meta-analysis, Etkin and Wagner (17) report hypoactivation in the insula and amygdala for PTSD patients, but no deactivations could be observed in specific phobia. Similarly, no hypoactivation in specific phobia was observed in the rostral anterior cingulate cortex, the ventromedial prefrontal cortex, the dorsal anterior cingulate cortex, or the thalamus. However, a more recent review reports evidence for hypoactivity in phobic patients in ventral, dorsomedial and dorsolateral prefrontal areas compared to healthy controls (15). These prefrontal areas are functionally connected to the amygdala. The dorsal system comprising the dorsolateral prefrontal cortex (DLPFC) and dorsomedial prefrontal cortex (DMPFC) might be related to the regulation of affective states, whereby a stronger activation is coupled with limbic inhibition (1820). Altogether, these findings suggest a deficient regulatory mechanism of affective states in individuals suffering from specific phobia in comparison to healthy controls.

In general, current fMRI research studies indicate that a large array of brain regions are involved in both normal and phobic fear processing; however, the activation in phobic states has been found to be stronger (21). The stronger activation in phobic patients includes increased neural, electrodermal, pupillary, and subjective reactions, as well as stronger activated neural structures, compared to non-phobic individuals. For instance, when confronted with the feared stimulus, individuals with spider phobia show increased activation of different brain regions, particularly in areas related to visuo-attentional processing (occipital and parietal regions; ventral visual pathway), emotional processing (amygdala, pulvinar nucleus of the thalamus), representations of aversive body states (ACC, insula, specifically left insular cortex), and flight behavior processing (premotor areas) (2224).

Interestingly, individuals suffering from spider phobia compared to non-phobic individuals show an increased fear response pattern in the mid-insula, dorsal anterior cingulate, and the ventrolateral PFC that grows linearly with perceived danger. Thus, these brain regions seem to hold a quantitative representation of the exaggerated fear response (25). While most of the regions mentioned above are involved in normal fear processing, the activation of the supplementary motor area (SMA) seems to be unique in specific phobias (26).

As mentioned above, a predominantly known key structure in fear processing is the amygdala, which usually shows hyperactivity in individuals with phobia (23). Increased activity of the amygdala is due to an exaggerated input from a fast subcortical pathway and can be reduced by glucocorticoid administration (27). An extrageniculostriate pathway has been suggested as the main pathway responsible for fear processing, which connects the thalamus and the amygdala (23). In contrast to common fear theories, which postulate that the activation of the amygdala is independent from attention when perceiving threatening stimuli, recent research shows that amygdala activation in response to very briefly presented cues is not independent from attention processes in patients with phobia (28). However, the amygdala response to phobic stimuli among individuals with phobia is a stronger but briefer one as compared to healthy controls, suggesting that it might be responsible for the rapid onset of phobic disorders (29). Additionally, the increased activity in the amygdala in patients with phobia does not only occur when they are confronted with phobic stimuli, but also as a response to generally repulsive and threatening stimuli (26). This suggests that increased activity in the amygdala may occur as a result of detection of motivationally relevant stimuli in general, whereas the activation of the insula and supplementary motor area seem to be superficially connected to the processing of phobic stimuli (26, 30). The attenuating effect of glucocorticoid administration on the fear response of the amygdala among individuals with phobia might be due to the fact that high glucocorticoid levels weaken traumatic and fearful memory traces, which are assumed to play a crucial role in phobic disorders and therefore facilitate the extinction of phobic fear (31). It has been recently shown that cortisol administration was able to alter the activity of the salience network to a level that was comparable to that found in healthy controls (32). In addition, high endogenous cortisol levels, which physiologically peak in the morning, strengthen the effect of exposure therapy in spider phobia compared to lower cortisol levels in the afternoon (33).

Mental and Neural Processes Involved in Fear Processing

While structures of the network mentioned above are involved in fear processing in general, their specific roles seem to be more complex. The temporo-spatial activation of different brain areas in spider phobia can especially be linked to different emotion regulation deficiencies. While automatic emotion regulation deficiencies seem to be reflected by increased activity in the insula and reduced activity in the ventromedial PFC, effortful emotion regulation deficits are reflected in an enhanced activity in medial PFC areas (34). Different neural processes have also been found for phasic fear in comparison to sustained anxiety (35). Phasic fear is defined as an apprehensive state that accumulates rapidly and diminishes if the threatening stimulus is removed (36). While phasic fear was found to be associated with amygdala activity, sustained anxiety was identified to be related to activity in the bed nucleus of stria terminalis (BNST), the ACC, and the insula among spider phobic patients compared to healthy controls (35). When comparing brain activation patterns in different types of phobias, several studies show very similar immediate responses but differences in the sustained response, which reflects the cross-linked mental processes behind anxiety disorders (12, 22). These findings correspond to fMRI studies on anticipatory fear of phobic stimuli. Straube et al. (37) showed that patients with phobia showed increased activity in the ACC, insula, thalamus, visual areas (i.e., fusiform gyrus), and BNST in comparison to healthy controls. This suggests that ACC regions and the anterior medial PFC seem to be related to the severity of the phobic disorder (37). These findings support the idea of the amygdala being related to automatic fear processing, while the insula, ACC, and dorsomedial PFC seem to be related to direct fear processing which requires attentional processes (37). In sum, these data highlight the dynamic relationship underlying neural processes involved in fear reactions, which is consistent with the finding that both visual and linguistic stimuli (phobia related words) are able to activate the aforementioned fear-related brain regions, supporting the idea of integrating neural networks for the processing of threatening stimuli (38).

Structural and Physiological Changes

Both functional and structural abnormalities like thinning of the right ACC can be found in patients with spider phobia (39). The size of the amygdala is negatively correlated to severity of symptoms among phobic patients (40). However, it remains unclear whether the structural changes are a causal or a consequence of the symptoms.

Phobias can not only be associated to neural abnormalities but also associated with physiological changes. When exposed to a phobic stimulus, patients with phobia show somatic response patterns or “markers” which differ from healthy controls, such as greater heart rate amplitudes and hypervigilance, as well as increased pupillary dilatation, electrodermal response, and self-reported affect (21, 41). Although some of these markers do not reflect a general tendency for anxiety, they are stimuli-dependent when comparing different types of phobias in fMRI studies (41).

The evidence for sex differences in activation patterns as a response to phobic stimuli is still not entirely clear. There is some evidence that phobic activation patterns may differ between males and females. These differences might be due to different attention styles and self-control strategies (42) as well as more pronounced and repetitive negative thoughts in females compared to males (43). Further support is based on epidemiological studies showing a higher frequency of phobic disorders in young female patients (44).

Biopsychosocial Theories of Phobias

Past research has relied on Seligman's theory of prepared learning (45, 46) to explain the nature of fear and the rise of phobias. However, more recent research shows again that the underlying mechanisms might be more differentiated. For instance, animal phobias (i.e., spider phobia) have been found to be more robust and less susceptible to social influence compared to social fears (47). Hence, in order to explain phobic disorders, a bio-psycho-social theory combining particularly genetic and cultural factors seems be more useful. For example, the heritability in animal fear is estimated to be 45% (48).

Studies on the biological origin of fear and phobic reactions have highlighted the role of structural differences in anxiety sensitivity, such as the inclination to interpret physical symptoms as potentially threatening. Anxiety sensitivity is found to be correlated to right anterior insular cortex size (volume and thickness) in patients with spider phobia (49). Other structural regions that are involved in emotional and attentional processing are also involved in the detection of body states and motor behavior (2224).

Not surprisingly, a crucial part in the neurobiological understanding of phobic disorders is the involvement of the amygdala. While common fear theories postulate that its activation is independent from attentional processes (23), others postulate that the amygdala's activation is influenced by distractors (28), suggesting that attention is needed for its activation. The strong and brief activation of the amygdala when confronted with distressing stimuli is hypothesized to be responsible for the rapid onset of phobic disorders (29), suggesting that minimal exposure with phobic objects is sufficient for the onset of the disorder. Other research proposes a more general overactivation of the area, which does not seem to be connected to specific stimuli, but rather to generally motivational relevant stimuli (26). Altogether, the amygdala has been identified as a key region of interest when trying to understand phobic disorders; however, the exact mechanisms remain to be understood.

Subconscious Fear Processing

Phobic stimuli are assumed to have greater affective salience in patients with phobia and therefore gain a more rapid access to awareness. Schmack et al. (50) demonstrated that the activation in orbitofrontal and ventral visual areas (higher-level cortical areas) as a response to the presence of phobic stimuli could be crucial for the affective salience of subjective invisible object stimuli (suppressed from view). Further research has shown that presentation of subliminal stimulus activates fear regions in spider phobia (right amygdala) while deactivating conscious fear processing, suggesting that the threat is computed even before the stimulus is processed consciously (5153). While some studies suggest that amygdala activation in spider phobia is robust to distraction tasks requiring the participant's attention (54), other studies have found that amygdala activation appears to decrease in healthy controls when performing distraction tasks (5456). Overall, there is some evidence that phobic reactions can occur outside an individual's awareness, however, the role of distraction in this process is not clear.

Phobic Cognition Biases

The covariation bias is a common bias that occurs among individuals with phobias. There is evidence suggesting that individuals with phobias tend to overestimate the association between the feared stimulus and aversive consequences (57). Recent research suggests that the covariation bias may be enhanced by simultaneous activity in senso-motoric and visual cortices, while the right PFC has been found to reduce the bias (57). In addition to the covariation bias, patients with phobia tend to show an encounter expectancy bias which means that they overestimate the likelihood that they will encounter a feared object (58). Recent fMRI studies suggest that the encounter expectancy bias appears to be related to deficits in cognitive control and contextual integration (lateral PFC, precuneus, and visual cortex) (58). Furthermore, a dysfunctional circuit of greater rostral ACC activation in response to phobic related stimuli compared to neutral stimuli was found in subjects with animal phobia, but not in healthy controls, suggesting attention abnormalities (59). Other studies indicate that amygdala activation depends on attention allocation when the stimuli are briefly presented (28), which might contribute to the behaviorally observable attention bias in anxious individuals (60).

Treatment of Spider Phobia: Effects of Cognitive Behavioral Therapy

Although a variety of treatment options for specific phobia exist, this review focuses on CBT and new approaches based on CBT-techniques, as they are regarded to be clinically the most promising evidence-based therapeutic procedures so far (61). However, a variety of other treatment options exist, including (but are not limited to) psychopharmacotherapy (e.g., SSRI or benzodiazepine medication), hypnotherapy, cognitive therapy, psychodynamic psychotherapy, imaginal or virtual reality exposure, augmented or in vivo-exposure.

Ongoing research on various modalities of psychological treatments for mental health disorders strongly suggests that problem-oriented psychotherapy can reliably modulate the neurophysiological and neurochemical processes in brain regions responsible for perception, movement, pain, and emotion processing (62, 63). Functional MRI-resting state studies among individuals with spider phobia show that cerebral blood flow in fear-related brain regions is reduced after cognitive behavioral interventions (64). This effect was not only found for the anticipatory fear, but also for fear processing after the presentation of spider pictures in the scanner (64). Some fMRI studies have shown a significant pre to post decrease in amygdala, insula, and ACC hyperactivity among individuals with phobia after an intensive one-session exposure therapy was provided (23). In addition, the dorsolateral PFC and the parahippocampal gyrus have been found to be hyperactive among individuals with spider phobia prior to receiving therapy, which might reflect deficiencies in metacognitive strategies when confronted with a spider on the one hand and fear memory on the other; however, these effects disappeared after successful therapy (63). Eye-tracking studies show that patients use maladaptive coping skills (i.e., visual avoidance) when faced with phobic stimuli whilst their fear circuit is activated and experiencing a threat (65). In comparison, healthy controls show more effective coping skills when paying visual attention to potentially dangerous stimuli, such as looking at them for a longer period of time; this might help to downregulate cognitive evaluations of risk (65). This might also be the case among successfully treated individuals who learned to effectively cope with perceived threats by reducing avoidance. Furthermore, fMRI studies have revealed that the long-term positive effects of CBT may be due to increased activation of the orbitofrontal cortex (OFC), which is involved both in emotional-related learning and neural inhibition (66).

CBT has been found to effectively treat specific phobias in most, but not all cases. Recent research identified different neural mechanisms for automatic and elaborated responses to threat (51). For instance, hyperactivation in the right amygdala and fusiform gyrus were found to rise when subliminal phobic stimuli were shown, an effect which did not disappear after CBT, suggesting that CBT might only influence conscious fear responses. Moreover, Zilverstand et al. (67) found that neurofeedback facilitates anxiety regulation in spider phobia when comparing a neurofeedback-group to a group with no specific strategies via fMRI. The neurofeedback-participants showed significantly lower anxiety levels at the end of the neurofeedback training as well as a down-regulation of the insular region. Neurofeedback was provided in response to activation in the left dorsolateral PFC and right insula, which was used as a marker for successful regulation of the phobic fear (67). Similar effects were observed for the hyperactivity of the insula and ACC when confronted with phobic stimuli, as this hyperactivity disappeared after successful CBT (95).

Another crucial contributing factor to the outcomes of CBT treatment in phobia might be that fear-relevant emotions can modulate learning processes and change activity in frontostriatal and medial temporal lobes, which are associated with specific learning processes (68). In addition, research shows that the effects of CBT can be enhanced by the administration of D-cycloserine, which is known to enforce the activations in the fear relevant brain regions (69); this suggests that high levels of acute activation in the fear regions predict better therapy outcomes. For a comprehensive overview of the present state of literature on neural networks predicting psychotherapy response in anxiety disorders, see Lueken et al. (70). Considering the mentioned gender differences in fear processing, recent research also suggested that that progesterone could be a useful pharmacological adjunct to cognitive therapy (71).

New Approaches: Virtual and Augmented Reality in Phobia Treatment

Although in-vivo exposure provides an excellent treatment option, patients are often reluctant to leverage the treatment options. Therapists often avoid the logistic difficulties that come with in-vivo-exposure therapies (e.g., time-consuming therapy session, catching, and keeping the spiders). In addition, spider-phobic individuals can be reluctant to confront their fears in reality. Hence, treatment options using virtual or augmented realities might be an interesting alternative from different viewpoints. Augmented Reality (AR) is a new approach to treatment that allows enriching real-life environments with virtual elements and has been successfully applied in various settings including treatment of mental health disorders (72). Advantages of AR in the treatment of psychological disorders include the adaptability to individual needs, as well as its accessibility and ecological validity, such that it can be used in personally relevant, real life settings (72). Furthermore, rare scenarios (e.g., special spider moving behaviors) can be administered repeatedly and consequentially the threatening content of the simulated spider can be varied more easily. Early research on AR and its use to treat specific phobia (especially small animal phobia) provides an insight on the feasibility of this new approach (7377). Newer studies demonstrate equivalent treatment efficacy between augmented reality based and in-vivo exposure therapies (7880). Moreover, the safety and usability of augmented reality systems in clinical samples has been demonstrated [e.g., (81)].

Virtual Reality (VR), in contrast, describes completely simulated, artificial environments—an approach which has recently gained popularity to treat psychiatric diseases, in particular anxiety disorders (82). The success of VR therapy approaches is supported by various research reports showing good effects for adults and children (82, 83). Patients with specific phobias prefer a virtual treatment-option over in-vivo-exposure and have fewer reservations (84). Several trials have demonstrated efficacy of VR-based exposure treatment in spider phobia when compared to a control condition (85, 86). Furthermore, non-inferiority of virtual reality exposure therapy for small animal or spider phobia was demonstrated in comparison to an in-vivo exposure therapy, particularly after 3 (87, 88) and 12 months (88). Research using fMRI to examine brain activation while participants explore VR environments shows that identical anxiety-related brain regions are activated as with real life photographs (89). Some studies suggest a potentially beneficial augmentative effect of non-invasive brain stimulation such as intermittent Theta Burst Stimulation (iTBS) over the left prefrontal cortex on a VR challenge in spider phobia, supporting the relevance of the prefrontal network in phobia treatment [e.g., (86, 90)].

Discussion

While technically new approaches promise many advantages in the field of treating natural object phobias (such as spider phobia), one can question if unpredictable nature elements like a real threat can be completely replaced by artificial elements at this stage. More research has to be conducted to assess the similarity between simulated human behavior and real-life behavior. Concerns regarding addictive behavior in virtual reality have also been raised (83). Because a sense of immersion is important in virtual reality therapy, new approaches promise—besides further technical improvements—the integration of tactile simulation in conjunction to the simulated visual experience.

Altogether, meta-analyses estimating the outcome and effectiveness of VR therapy state that VR-based psychological procedures appear to be equivalent to in-vivo exposure therapy, and superior to no treatment, and comes along with several advantages such as accessibility [e.g. (91, 92)]. However, there is currently no evidence that VR therapy could be superior to conventional face-to-face therapy methods with a real therapist. Additionally, more light has to be shed on both possible side effects like cybersickness (symptoms like vertigo, nausea, and headache) and methods to circumvent these have to be established (83, 93, 94). Future studies should also focus on improving the immersive experience for the user, e.g., by combining the simulated visual experience with tactile or auditory information. To the best of our knowledge, no study to date includes the auditory input in the simulated environment, e.g., when a particularly large spider moves over a surface. In addition, the therapy systems available to date require input from the therapist. In order to increase accessibility of exposure therapy interventions, a standalone therapy system is favorable. Last not least, a future challenge will be the smooth real time interaction between the simulated phobic object and the hands of the participants.

The aim of this focused review was to provide an overview and summarize recent findings in the field of specific phobic disorders, especially spider phobia. A particular emphasis was drawn on brain circuits and neural networks associated with spider phobia and treatment using cognitive behavioral therapy (“gold standard”) and emerging approaches including virtual or augmented reality.

Functional MRI has proven to be a strong research tool to investigate the neural basis for both normal and phobic fear. Accordingly, research over the past decade has been able to identify a large array of brain regions associated with fear processing: not only those involved in emotional and attentional processing, but also for the detection of body states and motor behavior. While the amygdala seems to be mainly involved in automatic fear processing, albeit not fully independent of attentional processes, other structures as the insula, ACC, and dorsomedial PFC appear to be directly related to fear processing requiring attentional resources (37). As a consequence, further research is mandatory for a better understanding of the underlying mechanisms and the neural bases of spider phobia for both predicting and potentially enhancing therapy outcome.

Cognitive behavioral therapy has been proven as a very effective clinical treatment and its effects can be observed even at a neural level (62). The newly emerging approaches such as virtual and augmented reality appear to show similar effects in comparison to in-vivo exposure therapy while increasing the accessibility and acceptance of treatment opportunities and supporting therapy-resistant patients (72, 83). Virtual and augmented reality-based therapy can thus already provide an excellent add-on option to the usual treatment. However, further research in VR/AR-based therapies is mandatory, in particular with a focus on improvement in feasibility and prevention and management of the immanent side effects of VR-based therapies.

Author Contributions

JH and AR substantially contributed to the conception of the work and drafting the first version of the document. UM, NM, KD, MR, and MN-H contributed to the analysis and critically revising the document as well as providing final approval of the version to be published.

Funding

This work was partly supported by the German Research Foundation (DFG), CRC-TRR58 “Fear, Anxiety, Anxiety Disorder” (project Z02 to KD). KD is a member of the Anxiety Disorders Research Network (ADRN) and European College of Neuropsychopharmacology (ECNP).

Conflict of Interest

KD is a member of Janssen Pharmaceuticals Steering Committee Neurosciences.

The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Publisher's Note

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Keywords: specific phobia, functional neuroimaging, augmented reality, virtual reality, psychotherapy, spider phobia, arachnophobia, neuroscience

Citation: Hinze J, Röder A, Menzie N, Müller U, Domschke K, Riemenschneider M and Noll-Hussong M (2021) Spider Phobia: Neural Networks Informing Diagnosis and (Virtual/Augmented Reality-Based) Cognitive Behavioral Psychotherapy—A Narrative Review. Front. Psychiatry 12:704174. doi: 10.3389/fpsyt.2021.704174

Received: 01 May 2021; Accepted: 26 July 2021;
Published: 24 August 2021.

Edited by:

Andreas Stengel, Charité – Universitätsmedizin Berlin, Germany

Reviewed by:

Marie-Eve Hoeppli, Cincinnati Children's Hospital Medical Center, United States
M. Carmen Juan, Universitat Politècnica de València, Spain
Thomas Gerhard Wolf, University of Bern, Switzerland

Copyright © 2021 Hinze, Röder, Menzie, Müller, Domschke, Riemenschneider and Noll-Hussong. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.

*Correspondence: Michael Noll-Hussong, bWlub2h1JiN4MDAwNDA7Z214Lm5ldA==

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