Medication-Enhanced Psychotherapy for Posttraumatic Stress Disorder: Recent Findings on Oxytocin’s Involvement in the Neurobiology and Treatment of Posttraumatic Stress Disorder


Scientific Update and Overview

Medication-Enhanced Psychotherapy for Posttraumatic 
Stress Disorder: Recent Findings on Oxytocin’s 
Involvement in the Neurobiology and Treatment of 
Posttraumatic Stress Disorder

Katrin Preckel 1 , Sebastian Trautmann 2 , Philipp Kanske 1,3

[1] Max Planck Institute for Human Cognitive and Brain Sciences, Leipzig, Germany. [2] Institute of Clinical Psychology 
and Psychotherapy, Department of Psychology, Medical School Hamburg, Hamburg, Germany. [3] Clinical Psychology 
and Behavioral Neuroscience, Faculty of Psychology, Technische Universität Dresden, Dresden, Germany. 

Clinical Psychology in Europe, 2021, Vol. 3(4), Article e3645, https://doi.org/10.32872/cpe.3645

Received: 2020-04-30 • Accepted: 2021-08-25 • Published (VoR): 2021-12-23

Handling Editor: Winfried Rief, Philipps-University of Marburg, Marburg, Germany

Corresponding Author: Katrin Preckel, Max Planck Institute for Human Cognitive and Brain Sciences, 
Stephanstraße 1A, 04103 Leipzig, Germany. Phone: +49 341 9940-2653. E-mail: preckel@cbs.mpg.de

Abstract
Background: Traumatic experiences may result in Posttraumatic Stress Disorder (PTSD), which is 
characterized as an exaggerated fear response that cannot be extinguished over time or in safe 
environments. What are beneficial psychotherapeutic treatment options for PTSD patients? Can 
oxytocin (OXT), which is involved in the stress response, and safety learning, ameliorate PTSD 
symptomatology and enhance psychotherapeutic effects? Here, we will review recent studies 
regarding OXT’s potential to enhance psychotherapeutic therapies for PTSD treatment.
Method: We conducted a literature review on the neurobiological underpinnings of PTSD 
especially focusing on OXT’s involvement in the biology and memory formation of PTSD. 
Furthermore, we researched successful psychotherapeutic treatments for PTSD patients and 
discuss how OXT may facilitate observed psychotherapeutic effects.
Results: For a relevant proportion of PTSD patients, existing psychotherapies are not beneficial. 
OXT may be a promising candidate to enhance psychotherapeutic effects, because it dampens 
responses to stressful events and allows for a faster recovery after stress. On a neural basis, OXT 
modulates processes that are involved in stress, arousal and memory. OXT effectively counteracts 
memory impairments caused by stress and facilitates social support seeking which is a key 
resilience factor for PTSD and which is beneficial in psychotherapeutic settings.

This is an open access article distributed under the terms of the Creative Commons 
Attribution 4.0 International License, CC BY 4.0, which permits unrestricted use, 
distribution, and reproduction, provided the original work is properly cited.

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Conclusion: OXT has many characteristics that are promising to positively influence 
psychotherapy for PTSD patients. It potentially reduces intrusions, but preserves memory of the 
event itself. Introducing OXT into psychotherapeutic settings may result in better treatment 
outcomes for PTSD patients. Future research should directly investigate OXT’s effects on PTSD, 
especially in psychotherapeutic settings.

Keywords
PTSD, oxytocin, treatment, medication-enhanced therapy, stress

Highlights
• Lower endogenous OXT levels after traumatic experiences are associated with 

developing PTSD.
• OXT administration around the time of the traumatic event may result in fewer 

intrusive memories.
• Abnormal signaling of the hippocampus and the vmPFC to the amygdala result in 

hyperactivation of the amygdala in PTSD.
• OXT facilitates social support seeking and safety learning while reducing personal 

distress.
• OXT’s characteristics are promising to enhance psychotherapeutic treatment for 

PTSD patients.

Traumatic experiences may result in Posttraumatic Stress Disorder (PTSD), which is 
characterized as an exaggerated fear response that cannot be extinguished over time 
or in safe environments. The lifetime prevalence of developing PTSD lies at about 
4% (Koenen et al., 2017). This number is relatively low considering that 80% of the 
general population experience traumatic events during their lifetime. Critical factors 
that determine if someone develops PTSD after experiencing or witnessing traumatic 
events include female gender, history of mental disorder (Tortella-Feliu et al., 2019), 
childhood adversities (McLaughlin et al., 2017), but also individual emotional contagion 
and empathy (Trautmann et al., 2018). In particular, for witnessed trauma, the ability to 
distinguish own feelings from that of others is crucial to avoid excessive personal distress 
and anxiety (Preckel, Kanske, & Singer, 2018). Also, emotion regulation abilities may 
be indicative of PTSD development after a traumatic experience, as prospective studies 
on emotion regulation and trauma symptoms show (Bardeen, Kumpula, & Orcutt, 2013; 
Ehring & Ehlers, 2014).

Treatment approaches for PTSD are not yet sufficiently successful, this is shown by 
patient drop-out rates, for instance, which are highly variable with rates between 16% to 
53.1% (Hatchett & Park, 2003; Lewis, Roberts, Gibson, & Bisson, 2020), depending on how 
the drop-out rates were defined. Importantly, although trauma‐focused cognitive behav­
ior therapy is the best‐validated treatment for PTSD, it has failed to develop over the 

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past few decades. Importantly, only two‐thirds of PTSD patients respond effectively to 
this therapy. Besides, the majority of PTSD patients does not take part in evidence‐based 
treatment, this applies predominately to low‐ and middle‐income countries (Bryant, 
2019). This underlines the need for better therapeutic approaches and ongoing research 
on this topic. Behavioral and medication treatment approaches for PTSD have different 
strengths and weaknesses (Flanagan & Mitchell, 2019), which makes a combination, of 
a medication-enhanced psychotherapy approach very promising. Regarding the common 
symptoms of PTSD such as intrusive memories and flashbacks, avoidance behavior, 
(negative) changes in cognition and in arousal (American Psychiatric Association, 2013), 
as well as deficits in social cognition (e.g. empathy, compassion and Theory of Mind) 
(Couette, Mouchabac, Bourla, Nuss, & Ferreri, 2020; Palgi, Klein, & Shamay-Tsoory, 
2016), the neuropeptide and hormone Oxytocin (OXT) may bear relevance for the 
treatment of PTSD (Palgi, Klein, & Shamay-Tsoory, 2016). OXT may be a relevant 
treatment enhancer, because it has been found to influence memory (Lee et al., 2015), 
approach-avoidance behavior (Preckel, Scheele, Kendrick, Maier, & Hurlemann, 2014), 
social cognition (e.g. emotion recognition) (Schwaiger, Heinrichs, & Kumsta, 2019) and 
arousal (Rash & Campbell, 2014). Due to OXT’s broad influence on human well-being, 
it has been introduced as a promising treatment agent for various disorders including 
PTSD (Koch et al., 2014; Misrani, Tabassum, & Long, 2017; Preckel, Kanske, Singer, 
Paulus, & Krach, 2016). Furthermore, OXT attenuates the development of PTSD symp­
toms after trauma exposure in patients with high acute symptomatology (van Zuiden 
et al., 2017) and is useful as an early preventive intervention (Frijling, 2017). Another 
study found that OXT was able to reduce PTSD symptoms which were triggered by 
trauma-script exposure (Sack et al., 2017).

In this update article, we review the latest literature on the relationship of biological 
underpinnings of PTSD, memory formation and OXT. We investigate the question: What 
role can/ does OXT play in PTSD symptom development and how might it improve 
PTSD symptoms?

We start our article by describing the stress physiology and the roles that OXT 
and cortisol play in it, we then continue by discussing the influence of OXT on the 
neural circuits of fear conditioning, PTSD and memory and, before summarizing our 
thoughts, we discuss the potential benefits of OXT as a treatment enhancer for PTSD 
psychotherapy.

S t r e s s  P h y s i o l o g y  a n d  t h e  R o l e s  o f  O x y t o c i n 
a n d  C o r t i s o l

The stress response involves multiple levels, which include cognitive, behavioral and 
physiological processes. On the physiological level, highly stressful or traumatic experi­
ences, activate the hypothalamic-pituitary-adrenal (HPA) axis as well as the oxytociner­

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gic system (Donadon, Martin-Santos, & Osório, 2018). Activity of the HPA axis and 
its end-product cortisol facilitate adaption to the faced stressor (e.g. de Kloet, Joëls, & 
Holsboer, 2005). A typical physiological stressful response involves the following steps: 
The hypothalamus releases the cortiocotropin-releasing-hormone (CRH) to the pituitary 
gland, which in turn releases the adrenocorticotropic hormone (ACTH) into systemic 
circulation. ACTH prompts the adrenal gland to release glucocorticoids such as cortisol. 
When cortisol levels in the blood increase, this is perceived by brain regions (e.g. hypo­
thalamus) and the release of CRH is stopped to return to homeostasis (Smith & Vale, 
2006).

In PTSD patients, the reinstating of homeostasis fails (Yehuda, 2002), resulting in 
an indiscriminately heightened physiological stress responses (e.g. McFarlane, Atchison, 
Rafalowicz, & Papay, 1994). Hypocortisolism is often reported in PTSD patients, which 
might at first sight be counterintuitive. Yet, the downregulation of available cortisol 
could be an attempt of the body to compensate for exaggerated stress responses (Thaller, 
Vrkljan, Hotujac, & Thakore, 1999). This compensatory attempt, however, results in 
a sensitization to the glucocorticoid system (Rohleder, Wolf, & Wolf, 2010), meaning 
that low concentrations of cortisol are sufficient to induce a fear or stress response. 
Furthermore, the observed hypocortisolism may be dependent on the type of cortisol 
measure, because in the cerebrospinal fluid of patients with PTSD, a sustained increase of 
the corticotropin-releasing hormone was observed (Sherin & Nemeroff, 2011). While hair 
cortisol levels are commonly reported to be lower in PTSD patients when compared to 
those of healthy controls (Steudte-Schmiedgen, Kirschbaum, Alexander, & Stalder, 2016; 
Steudte-Schmiedgen et al., 2015; van Zuiden et al., 2019), but there are contradictory 
findings (van den Heuvel et al., 2020).

Exogenously administered OXT promotes a faster recovery after the stress response 
(Heinrichs, Baumgartner, Kirschbaum, & Ehlert, 2003; Kubzansky, Mendes, Appleton, 
Block, & Adler, 2012), and it attenuates salivary cortisol elevations after a physical stres­
sor (Cardoso, Ellenbogen, Orlando, Bacon, & Joober, 2013). Endogenous OXT levels are 
frequently measured in the periphery and lower endogenous OXT levels after traumatic 
experiences are associated with developing PTSD (Donadon, Martin-Santos, & Osório, 
2018), even though endogenous OXT levels of individuals who suffer from PTSD and 
those of healthy controls did not differ (Engel et al., 2019). Interestingly, OXT and cortisol 
levels are positively correlated when participants were able to anticipate a stressor 
(Brown, Cardoso, & Ellenbogen, 2016). Anticipation and predictability seem to strongly 
influence OXT’s action, because also exogenously administered OXT has ambiguous 
effects on threatening responses which is partly due to the predictability or unpredicta­
bility of threatening cues. This means that OXT administration results in anxiogenic 
effects when threat cues are unpredictable, because defensive responses to unpredictable 
shocks were significantly increased by OXT (as compared to placebo and vasopression 
administration), while predictable shocks were not influenced by OXT administration 

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(Grillon et al., 2013). Furthermore, OXT’s effects on anxiety depend on the timing of 
OXT administration and threat content, because both anxiolytic and anxiogenic effects 
have been reported (Frijling, 2017; Neumann & Slattery, 2016). Importantly though, in 
people who experienced moderate emotional trauma, anxiolytic effects of OXT have 
been found (Donadon et al., 2018). While OXT’s effects on cortisol are diverse, a recent 
meta-analysis reported that OXT attenuated the cortisol response to a greater extend, 
when the HPA-axis was strongly activated and this effect was strongest among clini­
cal populations (patients with PTSD, Major Depressive Disorder and Bipolar Disorder) 
(Cardoso, Kingdon, & Ellenbogen, 2014). These ambiguous findings may be due to the 
cross-binding ability of OXT and vasopressin, (for more detail see: Preckel & Kanske, 
2018). Moreover, OXT enables rapid and flexible adaptation to fear signals in social 
contexts, which can be advantageous in preventing PTSD; but simultaneously it may 
elevate vulnerability for interpersonal trauma (Eckstein et al., 2016).

Thus, we assume that the dampening effect of OXT on the HPA axis (Neumann, 
Krömer, Toschi, & Ebner, 2000) may act on different levels and result in reduced stress 
responses, thereby eliciting the opposite effects of typical stress tasks such as the Trier 
Social Stress Test (TSST; Kirschbaum, Pirke, & Hellhammer, 1993). This assumption is 
grounded in the observation that OXT is associated with faster recovery of the endocrine 
and the autonomic system after stressful events (Engert et al., 2016), as well as on 
skin conductance findings which were measured directly after traumatic events and 
predicted subsequent chronic PTSD development (Hinrichs et al., 2019). Consequently, 
OXT’s dampening effect on the HPA axis activation may function as a stress-buffer for 
traumatic events and by buffering stress responses it may prevent the development of 
chronic PTSD after trauma exposure. The anxiolytic OXT effects may also result in fewer 
treatment dropouts.

Cortisol, like OXT, has time-sensitive effects on the HPA-axis activity. Activating the 
HPA-axis by exposing participants to a stress task, for instance the TSST, before they 
participate in a trauma analogue paradigm (trauma film), results in increased numbers of 
intrusive memories (in participants who biologically respond to the TSST) as compared 
to participants who perform a control task (placebo TSST) and are not stressed prior to 
the trauma film paradigm (Schultebraucks et al., 2019). In contrast, administering cortisol 
after a trauma results in fewer intrusions (De Quervain, 2006). Outcomes of post-trauma 
cortisol administration are, however, also somewhat inconclusive, because not all stud­
ies report fewer subsequent intrusions (Graebener, Michael, Holz, & Lass-Hennemann, 
2017; Ludäscher et al., 2015). Cortisol (here: hydrocortisone) as a treatment enhancer 
augmented psychological treatment successfully, meaning that prolonged exposure ther­
apy resulted in greater retention when participants received cortisol (Yehuda et al., 2015).

Thus, OXT as well as cortisol are promising agents for medication-tailored treatment 
for PTSD patients.

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O X T ’ s  I n f l u e n c e  o n  F e a r  C o n d i t i o n i n g ,  a n d  i t s 
R o l e  i n  P T S D  a n d  M e m o r y

To investigate the mechanisms, which underlie PTSD, Pavlovian fear conditioning para­
digms are helpful models. In fear conditioning experiments, an aversive stimulus is used 
as an unconditioned stimulus (US) in order to establish fear as soon as the conditioned 
stimulus (CS) is presented. In PTSD, one traumatic event is sufficient to establish a CS. 
The main brain structures that are involved in fear conditioning and PTSD include the 
amygdala, the hippocampus and the ventromedial prefrontal cortex (vmPFC) (Careaga, 
Girardi, & Suchecki, 2016; Koenigs & Grafman, 2009). The amygdala is the core structure 
of fear conditioning (Duvarci & Pare, 2014; Ehrlich et al., 2009) and extinction (Maren, 
2011; Myers & Davis, 2002). The different nuclei of the amygdala have specialized 
roles in the fear learning and extinction processes. The lateral nucleus of the amygdala 
(LAn) provides the amygdala primarily with input and is important for mediating fear 
learning via neural plasticity, while the basolateral and basomedial nuclei converge 
sensory information of the conditioned stimulus and the unconditioned stimulus (Herry 
& Johansen, 2014). The hippocampus is important for encoding information, and for 
modulating appropriate emotional responses to potentially fearful stimuli (Acheson, 
Gresack, & Risbrough, 2012; Lissek & van Meurs, 2015). Furthermore, lower hippocampal 
activation has been linked to direct memory suppression in healthy participants (Benoit 
& Anderson, 2012), that can be interpreted as reduced voluntary recall. The vmPFC 
mediates the extinction of conditioned fear by inhibiting the amygdala (Koenigs et al., 
2008).

In PTSD patients, these brain regions differ on a structural and functional level in 
comparison to healthy controls. For example, reduced hippocampal volume is associated 
with PTSD development (Gilbertson et al., 2002; Logue et al., 2018; Pitman et al., 2006) as 
well as being a consequence of stressful experiences (Admon et al., 2013). On a functional 
level, abnormal hippocampus activation hindered extinction learning in safe contexts 
(Patel, Spreng, Shin, & Girard, 2012) and reduced top-down regulation to the amygdala 
which results in enhanced fear conditioning (Rauch, Shin, & Phelps, 2006). A reduction of 
functional and structural connectivity between the hippocampus and the vmPFC has also 
been reported (Admon et al., 2013).

The amygdala is also crucially involved in associative learning (LeDoux, 1996; 
McGaugh, 2000) and its dysfunction may be responsible for increased fear conditioning 
responses in PTSD patients, which in turn results in stronger memory formation of the 
traumatic event (= intrusive memories) (Careaga et al., 2016). Also, vmPFC activation 
is lower and results in decreased top-down regulation of the amygdala (Rauch, Shin, 
& Phelps, 2006). The hippocampus as well as the vmPFC project to the amygdala and 
their failure to adequately inhibit amygdala activation causes its hyperactivity which is 
frequently found in PTSD patients (Hayes, Hayes, & Mikedis, 2012; Liberzon & Abelson, 
2016; Patel, Spreng, Shin, & Girard, 2012; Pitman et al., 2012; Shin & Liberzon, 2010). 

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Amygdala hyperactivation is especially pronounced when compared to non-trauma ex­
posed controls, but not necessarily when compared to trauma-exposed controls (Patel 
et al., 2012), therefore it cannot be ruled out that this mechanism is related to trauma 
exposure rather than to PTSD (van Wingen, Geuze, Vermetten, & Fernandez, 2011). 
However, the evidence that amygdala hyperactivation might be causally related to PTSD 
development, could be shown by previous lesion studies in veterans with and without 
PTSD (Koenigs & Grafman, 2009). Another lesion study showed that elevated amygdala 
activation is related to dysfunctional vmPFC activity (Motzkin et al., 2015). Furthermore, 
PTSD patients (as compared to healthy controls) display an initially increased amygdala 
response when confronted with trauma-related negative (vs. non-trauma related nega­
tive) stimuli (Protopopescu et al., 2005). The elevated amygdala activation may explain 
the emotional memory quality in PTSD patients, especially, because this activation does 
not habituate over time (Protopopescu et al., 2005).

Diminished structural connectivity between the amygdala and vmPFC has been 
found in PTSD patients (Koch et al., 2017). The functional connectivity between these 
regions, could be increased by OXT (in men with PTSD), thereby reducing amygdala 
hyperactivity (Koch et al., 2014).

Returning to fear conditioning experiments, administering intranasal OXT before fear 
conditioning results in faster fear conditioning, (Eckstein et al., 2016) while administra­
tion after fear-conditioning and before fear extinction results in better fear extinction and 
inhibited amygdala activation (Eckstein et al., 2015). Moreover, reduced skin conductance 
responses to electric shocks after OXT as opposed to placebo administration in human 
studies support the notion of OXT’s “anti-stress-properties” (Eckstein et al., 2016). Thus, 
exogenous OXT effects are time sensitive and remain currently inconclusive.

The amygdala is further suggested to mediate influences of medication on memory 
consolidation (McGaugh, 2000), therefore it may also mediate OXT effects on memory 
and potentially change the emotional content of memories in PTSD patients. A recent 
study showed that the severity of childhood trauma exposure (as reported from memory) 
was related to oxytocin-modulated amygdala responses in patients with PTSD while this 
was not the case in healthy controls (Flanagan et al., 2019). If OXT has the potential to 
change the content of memories to turn more positively, this may already result in less 
hyperactivity of the amygdala, which is strongly influenced by negative valence (Preckel 
et al., 2019). This is further supported by OXT’s inhibiting effects on the activation of 
(para-)limbic structures, its facilitating action on cognitive performance and its inhibiting 
effects on arousal (Lischke, Herpertz, Berger, Domes, & Gamer, 2017; Misrani et al., 2017; 
Solomon et al., 2018). Animal studies report that exogenous OXT has “anti-stress proper­
ties” on hippocampal plasticity and memory (Lee et al., 2015). The hippocampus plays an 
important role in the negative feedback loop of the HPA-axis (Joseph & Whirledge, 2017) 
and it is altered in PTSD patients (Schumacher et al., 2019).

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Regarding OXT’s effects on memory, earlier studies found that OXT impairs mem­
ory recall, the generation of associated target words, or explicit memory (Heinrichs, 
Meinlschmidt, Wippich, Ehlert, & Hellhammer, 2004). Recent findings, however, suggest 
that exogenous OXT may also have positive influences on memory. For example, OXT 
improves safety learning in healthy humans (Eckstein et al., 2019) and animal studies 
show that OXT effectively counteracts memory impairments caused by stress on a 
cellular level, thereby preventing memory impairments (Lee et al., 2015). Another animal 
study found changes in long-term synaptic plasticity in the amygdala (medial nucleus) 
due to OXT’s action. These oxytocin-induced synaptic changes are strongly related 
to social recognition memory (Rajamani, Wagner, Grinevich, & Harony-Nicolas, 2018). 
These findings indicate that OXT may have restoring functions on plasticity related to 
memory processes.

Furthermore, OXT improves memory performance which is accompanied by in­
creased connectivity between the dorsolateral (dl)PFC and the ACC in traumatized as 
compared to trauma exposed individuals without PTSD (Flanagan et al., 2018). This is 
an important finding, because decreased connectivity between the dlPFC and the ACC 
is described as a maladaptive neural process (= reduced neural processing efficiency) 
in demanding cognitive tasks. Furthermore, the decrease in connectivity between these 
brain regions is associated with the trait measure “worry” (as a dimension of anxiety) 
in healthy individuals (Barker et al., 2018). Regarding the association between worry 
and PTSD that has been found in previous studies (Blazer, Hughes, & George, 1987), it 
may be assumed that similar neural maladaptations take place in PTSD and which may 
be positively influenced by OXT administration. Increased ACC activation after OXT 
administration has also been reported elsewhere (Preckel, Scheele, Eckstein, Maier, & 
Hurlemann, 2015). To sum up, OXT positively influences memory on a cellular, neural 
activation and behavioral level.

Moreover, exogenous OXT was able to improve social behavioral deficits in autism 
spectrum disorder patients (ASD) via reinstating vmPFC activation, during a social-com­
munication task (Aoki et al., 2015). In male PTSD patients, OXT reinstated diminished 
connectivity between the amygdala and the vmPFC and in female patients it reestablish­
ed increased connectivity between the amygdala and the dorsal anterior cingulate cortex 
(dACC), accompanied by reduced subjective anxiety and nervousness (Koch et al., 2016b). 
A recent study showed that OXT dampened amygdala activation in PTSD patients, 
when they saw emotional faces (regardless of valence), while amygdala activation was 
increased in trauma-exposed control participants (Koch et al., 2016a). Assuming that 
OXT’s action in ASD patients is the same as in PTSD patients, as the common action on 
brain activity suggests, OXT may also improve social and affective functioning in PTSD 
by restoring vmPFC activation.

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O x y t o c i n ’ s  P o t e n t i a l  B e n e f i t  i n  P s y c h o t h e r a p y 
f o r  P T S D

Apart from different comorbidities such as depression, anxiety or alcohol abuse, social 
support is one of the strongest predictors for successful PTSD therapy (Dewar, Paradis, 
& Fortin, 2020), just like therapeutic alliance (Lantz, 2004). The willingness to share 
thoughts and emotions is clearly related to perceived social support (Kahn & Cantwell, 
2017). As mentioned previously, OXT increases social support seeking and the perception 
of received social support (Cardoso, Valkanas, Serravalle, & Ellenbogen, 2016) and it 
also increases the willingness to verbally share one’s emotions with someone else (Lane 
et al., 2013). This makes it specifically promising for medication-enhanced psychother­
apeutic interventions, because it might facilitate emotional disclosure. OXT increases 
social support seeking and the perception of received social support (Cardoso, Valkanas, 
Serravalle, & Ellenbogen, 2016) as well as safety learning (Eckstein et al., 2019) in healthy 
individuals. Assuming that OXT unfolds the same characteristics in PTSD patients, it 
is likely that OXT can ameliorate PTSD symptoms successfully. In a study on trauma 
disclosure, OXT alone did not increase the tendency to disclose trauma (Scheele et al., 
2019). This might be due to insufficient(ly perceived) social support, because it has 
also been suggested that the presence of social support might be necessary to elicit 
prosocial OXT effects (Cardoso et al., 2016), to mention one of many context-dependent 
OXT effects. Therefore, administering OXT in a psychotherapeutic setting, where social 
support is available, might result in increased disclosure. Concerning the therapeutic 
relationship which is important for successful therapy outcomes, increased sensitivity 
to social reward may result in increased social support seeking and may thus increase 
the likelihood of a positive psychotherapeutic relationship. Notably, it has been found 
that anterior insula activation was normalized, during social reward processing, in PTSD 
patients after OXT administration (Nawijn et al., 2017).

Psychotherapeutic interventions that have been successful in ameliorating PTSD 
symptoms include eye movement desensitization and reprocessing (Shapiro, 2014) pro­
longed exposure (Singh, 2019), imagery rescripting and reprocessing therapy (Grunert, 
Weis, Smucker, & Christianson, 2007), exposure therapy (Paunovic & Ost, 2001) as well 
as exposure-based cognitive-behavioral group therapy (CBGT) (Schwartze, Barkowski, 
Strauss, Knaevelsrud, & Rosendahl, 2019). Clinical trials which have investigated OXT’s 
enhancing effects on different treatment options, revealed that OXT could enhance expo­
sure-therapy in PTSD patients (Flanagan et al., 2019) and patients with arachnophobia 
(Acheson et al., 2015). A study, which focused on physiological responses to OXT, found 
one notable difference and that was a higher skin conductance baseline level in the OXT 
group (Pitman et al., 1993).

Here, we take CBGT as an example to explain how simultaneous OXT administration 
can enhance psychotherapy.

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OXT improves various aspects of social cognition, for example trust (Kosfeld, 
Heinrichs, Zak, Fischbacher, & Fehr, 2005). Trust is an essential component of psycho­
therapy that needs to be established first, before the actual therapy can begin (Wampold, 
2015). Therefore, if OXT facilitates trust, by decreasing amygdala and dorsal striatum 
activation as neuroimaging studies were also able to show (Baumgartner, Heinrichs, 
Vonlanthen, Fischbacher, & Fehr, 2008), it may have beneficial effects on psychothera­
peutic outcomes. A recent study on food intake reported that OXT enhances brain 
activation in areas that govern cognitive control, including the vmPFC (Spetter et al., 
2018). Should OXT have the same effects on the vmPFC in PTSD patients, OXT might 
be particularly beneficial for PTSD patients who take part CBGT. There is a growing 
literature body which investigates OXT’s potential on psychotherapies for PTSD patients 
(e.g. Engel et al., 2021; Koch et al., 2014; Koch et al., 2019). Though OXT appears to be a 
promising candidate to ameliorate PTSD symptoms, especially when combined with psy­
chotherapies, further studies are required to disentangle the exact mechanism of OXT. 
It is also crucial to find out which PTSD patients can benefit most from OXT-enhanced 
psychotherapy, because OXT has many person-specific characteristics, ranging from 
a person’s attachment style to oxytocin receptor gene variations which differentially 
influence OXT’s action in individuals (Bartz, Zaki, Bolger, & Ochsner, 2011; Olff et al., 
2013). Thus, studies with precise designs which combine behavioral, biological, imaging 
and clinical aspects are required to further address these questions (Giovanna et al., 
2020).

C o n c l u s i o n  a n d  O u t l o o k
In this update paper, we described the mechanisms underlying PTSD by discussing 
the most recent studies on structural and functional brain changes associated with 
PTSD, including findings on structural and functional connectivity. We have discussed 
potential OXT mechanisms of action from the healthy population and ASD patients and 
related these to mechanisms that are malfunctioning in PTSD patients, thereby building 
direct implications for OXT’s potential action mechanism. Most importantly, we like to 
emphasize OXT’s promising characteristics as a psychotherapeutic enhancer. However, 
there are still uncertainties, which need further investigation. These include the critical 
aspects of pharmacodynamics and the ideal dosage. It became clear that therapeutic 
approaches are not yet sufficiently successful in treating PTSD patients, because patients 
drop out of therapy frequently and some symptoms remain after treatment. OXT remains 
a promising candidate for medication-tailored PTSD therapy and research on this topic 
should be continued.

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Funding: KP is supported by German Federal Ministry of Education and Research within the ASD-Net (BMBF FKZ 

01EE1409A). ST is supported by the German Research Foundation (DFG R 1489/1-1) and the Federal Ministry of 

Defense (E/U2AD/HD008/CF550) PK is supported by German Federal Ministry of Education and Research within the 

ASD-Net (BMBF FKZ 01EE1409A), the German Research Foundation (DFG KA 4412/2-1; KA 4412/4-1; KA 4412/5-1) 

and Die Junge Akademie at the Berlin-Brandenburg Academy of Sciences and Humanities and the German National 

Academy of Sciences Leopoldina.

Acknowledgments: The authors have no support to report.

Competing Interests: The authors declare no conflicts of interest.

Twitter Accounts: @katrin_preckel, @pkanske

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	Oxytocin’s Role in the Neurobiology and Treatment of PTSD
	(Introduction)
	Stress Physiology and the Roles of Oxytocin and Cortisol
	OXT’s Influence on Fear Conditioning, and its Role in PTSD and Memory
	Oxytocin’s Potential Benefit in Psychotherapy for PTSD
	Conclusion and Outlook
	(Additional Information)
	Funding
	Acknowledgments
	Competing Interests
	Twitter Accounts

	References