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Prefrontal cortex activation under stress as a function of borderline personality disorder in female adolescents engaging in non-suicidal self-injury

Published online by Cambridge University Press:  08 August 2024

Saskia Höper Open the ORCID record for Saskia Höper [Opens in a new window] ,
Felix Kröller ,
Anna-Lena Heinze ,
Kay Franziska Bardtke ,
Michael Kaess Open the ORCID record for Michael Kaess [Opens in a new window]  and
Julian Koenig
Saskia Höper
Affiliation:
Department of Child and Adolescent Psychiatry, Centre for Psychosocial Medicine, Heidelberg University, Germany
Felix Kröller
Affiliation:
Department of Child and Adolescent Psychiatry, Centre for Psychosocial Medicine, Heidelberg University, Germany
Anna-Lena Heinze
Affiliation:
Department of Child and Adolescent Psychiatry, Centre for Psychosocial Medicine, Heidelberg University, Germany
Kay Franziska Bardtke
Affiliation:
Department of Child and Adolescent Psychiatry, Centre for Psychosocial Medicine, Heidelberg University, Germany
Michael Kaess
Affiliation:
Department of Child and Adolescent Psychiatry, Centre for Psychosocial Medicine, Heidelberg University, Germany; and University Hospital of Child and Adolescent Psychiatry and Psychotherapy, University of Bern, Switzerland
Julian Koenig*
Affiliation:
University Hospital of Child and Adolescent Psychiatry and Psychotherapy, University of Bern, Switzerland; Faculty of Medicine, University of Cologne, Germany; and Department of Child and Adolescent Psychiatry, Psychosomatics and Psychotherapy, University Hospital Cologne, Germany
*
Correspondence: Julian Koenig. Email: [email protected]
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Abstract

Background

Neuroimaging studies suggest alterations in prefrontal cortex (PFC) activity in healthy adults under stress. Adolescents with non-suicidal self-injury (NSSI) report difficulties in stress and emotion regulation, which may be dependent on their level of borderline personality disorder (BPD).

Aims

The aim was to examine alterations in the PFC in adolescents with NSSI during stress.

Method

Adolescents (13–17 years) engaging in non-suicidal self-injury (n = 30) and matched healthy controls (n = 29) performed a task with low cognitive demand and the Trier Social Stress Test (TSST). Mean PFC oxygenation across the PFC was measured with an eight-channel near-infrared spectroscopy system. Alongside self-reports on affect, dissociation and stress, BPD pathology was assessed via clinical interviews.

Results

Mixed linear-effect models revealed a significant effect of time on PFC oxygenation and a significant time×group interaction, indicating increased PFC activity in patients engaging in NSSI at the beginning of the TSST compared with healthy controls. Greater BPD symptoms overall were associated with an increase in PFC oxygenation during stress. In exploratory analyses, mixed models addressing changes in PFC connectivity over time as a function of BPD symptoms were significant only for the left PFC.

Conclusions

Results indicate differences in the neural stress response in adolescents with NSSI in line with classic neuroimaging findings in adults with BPD. The link between PFC oxygenation and measures of BPD symptoms emphasises the need to further investigate adolescent risk-taking and self-harm across the spectrum of BPD, and maybe overall personality pathology, and could aid in the development of tailored therapeutic interventions.

Keywords

Stressnon-suicidal self-injuryborderline personality disorderfunctional near-infrared spectroscopyprefrontal cortex
Type
Paper
Information
BJPsych Open , Volume 10 , Issue 5 , September 2024 , e142
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Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2024. Published by Cambridge University Press on behalf of Royal College of Psychiatrists

Non-suicidal self-injury (NSSI) is defined as the intentional, self-directed damage of one's own body tissue without suicidal intent and for purposes not culturally or socially sanctioned.1 Given that NSSI is commonly associated with high psychological strain and a large range of comorbid mental disorders,Reference Ghinea, Edinger, Parzer, Koenig, Resch and Kaess2 it is regarded as a transdiagnostic marker of risk, particularly for the presence of disorders that are related to severe emotion dysregulation, such as depression or borderline personality disorder (BPD). The diagnosis of BPD is widely accepted as reliable and valid for adolescents,Reference Chanen, Sharp and Hoffman3 with prevalence rates ranging from 0.9 to 3.2% among adolescents and young adults in the USA.Reference Johnson, Cohen, Kasen, Skodol and Oldham4 Compared with other patient groups, patients with BPD commonly report high levels of psychopathological distress and lower health-related quality of life and psychosocial functioning.Reference Kaess, von Ceumern-Lindenstjerna, Parzer, Chanen, Mundt and Resch5,Reference Kaess, Fischer-Waldschmidt, Resch and Koenig6 BPD is associated with altered emotion regulation and increased stress vulnerability.Reference Daros and Williams7,Reference Thomas, Gurvich, Hudaib, Gavrilidis and Kulkarni8 Research suggests altered stress reactivity in patients with NSSI and/or BPD. Adult patients with BPD often report a higher stress burden and greater emotional reactivity to daily stressors compared with healthy controls and compared with patients with psychotic disorders.Reference Glaser, Os, Mengelers and Myin-Germeys9 Altered stress reactivity in adult patients with BPD is characterised by increased negative emotions after stress,Reference Deckers, Lobbestael, van Wingen, Kessels, Arntz and Egger10 as well as an attenuated cortisol response.Reference Drews, Fertuck, Koenig, Kaess and Arntz11 The stress-reducing effect of self-injury in adult BPD is described by a decrease in amygdala activation after self-injury.Reference Reitz, Kluetsch, Niedtfeld, Knorz, Lis and Paret12

Neuroimaging in non-suicidal self-injury

Former classical neuroimaging studies in NSSI showed task-specific alterations of neural activity in patients compared with controls. During a social exclusion paradigm, young patients engaging in NSSI showed increased prefrontal cortex (PFC) activationReference Groschwitz, Plener, Groen, Bonenberger and Abler13 as well as an aberrant activation in the amygdala at rest and during emotion recognition.Reference Westlund Schreiner, Klimes-Dougan, Mueller, Eberly, Reigstad and Carstedt14 Research on the neurobiological stress response in adolescent patients with BPD is sparse. For example, adolescent patients with BPD showed an attenuated heart rate response during a dual-task under stress.Reference Kaess, Parzer, Koenig, Resch and Brunner15 In addition, an attenuated cortisol response to stress was also found in adolescents with NSSI.Reference Klimes-Dougan, Begnel, Almy, Thai, Schreiner and Cullen16 Concerning neuroimaging, findings in healthy samples from functional magnetic resonance imaging (fMRI), electroencephalography and functional near-infrared spectroscopy (fNIRS) studies suggest alterations in prefrontal brain activation in response to stress. In healthy participants, stress affects the dorsolateral and ventral right PFC,Reference Dedovic, Duchesne, Andrews, Engert and Pruessner17Reference Wang, Rao, Wetmore, Furlan, Korczykowski and Dinges19 and the orbitofrontal cortex.Reference Dedovic, Duchesne, Andrews, Engert and Pruessner17,Reference Schaal, Heppe, Schweda, Wolf and Krampe18 To our knowledge, there are no existing studies examining neural responses to acute stress in adolescents with NSSI or BPD in a real-world setting. Stress paradigms that are suitable to be conducted in the MRI (such as the Montreal Imaging Stress Test) suggest alterations in functional connectivity in adolescent patients engaging in NSSI compared with controls.Reference Otto, Jarvers, Kandsperger, Reichl, Ando and Koenig20

Because of its narrowness, in-scanner stress tasks pose considerable challenges to the research methodology. Some well-established stress paradigms cannot be performed in the scanner without compromising their validity. Other paradigms need extensive modification to be scanner-compatible. fNIRS represents a valuable alternative neuroimaging method to study neural responses during stress induction. fNIRS is highly correlated with blood-oxygenation-level dependent signals from fMRI, when focusing on the cortical surface.Reference Alderliesten, De Vis, Lemmers, van Bel, Benders and Hendrikse21 The main principle of fNIRS is the measurement of light in the near-infrared spectrum. Through light attenuation from absorption and scattering, it detects changes in the concentration of oxygenated haemoglobin (O2Hb) and deoxygenated haemoglobin (HbR) in surface areas of the brain in real time.Reference Quaresima and Ferrari22

The present study

Most research on participants engaging in NSSI focuses on adult patients with BPD. To account for developmental aspects and the interlink between NSSI and BPD in adolescents, studies on NSSI across the spectrum of BPD pathology in adolescent samples are needed. In the present study, we aimed to investigate the neural responses of adolescents with NSSI to an acute stressor, comparing patients with a healthy control group and investigating the stress response as a function of BPD severity. We hypothesised that adolescent patients engaging in NSSI would show an increased PFC activation in response to an acute stress task compared with matched healthy controls. We further expected that the severity of BPD pathology would be positively correlated with the increase in PFC activation in the NSSI group. In a former study, we found no group differences in connectivity across the PFC during resting state between patients engaging in NSSI and healthy controls, but found a descriptively stronger connectivity that was associated with greater BPD pathology.Reference Koenig, Höper, van der Venne, Mürner-Lavanchy, Resch and Kaess23 Hence in exploratory analyses, we aimed to examine PFC connectivity under stress and in association with BPD pathology.

Method

Participants

Patients were recruited from the specialised out-patient clinic for risk-taking and self-harming behaviour (AtR!Sk; Ambulanz für Risikoverhaltensweisen und Selbstschädigung Reference Kaess, Ghinea, Fischer-Waldschmidt and Resch24 at the Clinic for Child and Adolescent Psychiatry, Center for Psychosocial Medicine, University of Heidelberg, Germany). Healthy controls were recruited via public advertisement (e.g. recruitment at public places) and matched to the patient group by age. As self-harming behaviours differ between genders,Reference Andover, Primack, Gibb and Pepper25 only females were included to this analysis. Previous data from the study, focusing on behavioural and psychophysiological outcomes, were published earlier.Reference Koenig, Lischke, Bardtke, Heinze, Kröller and Pahnke26 The recruitment period lasted from July 2016 until May 2018. Inclusion criteria for the patient group were at least five incidents of NSSI during the past 12 months, age between 13 and 17 years, and female gender. Inclusion criteria for the healthy control group were age between 13 and 17 years and female gender. General exclusion criteria were deficient language skills or clinically relevant impairments in intelligence, glucocorticoid medication intake, pregnancy, any underlying neurological or endocrinological diseases, acute psychosis, acute suicidality, substance dependency and a body mass index (BMI) <17.5 kg/m2 or >30 kg/m2. An additional exclusion criterion for the patient group was current BPD drug treatment. A further exclusion criterion for participants of the control group was any current and former psychiatric disorder or lifetime NSSI. After completion of the study, every participant received an allowance of €40 for study participation.

For the NSSI group, 180 (100%) adolescents were screened and 37 (20.56%) were included in the study. Reasons for study exclusion are provided (see Supplementary Table 1 available at https://doi.org/10.1192/bjo.2024.728). During study participation, seven participants in the NSSI group dropped out of the study: one (0.56%) reported acute headaches, two (1.11%) showed dissociative symptoms that required interruption of experimental procedures, three (1.67%) did not show up for the second appointment and one (0.56%) dropped out because of further reasons not documented in detail. This resulted in a final sample of n = 30 (16.67%) for the NSSI group. A total of 66 (100%) female adolescents were screened as healthy controls for study participation. Of those, 31 (46.97%) were included in the study. One (1.52%) refused to participate in the stress task and hence dropped out of the study. Finally, one (1.52%) had to be excluded from NIRS analyses because of technical issues during the assessment. This resulted in a sample of n = 29 healthy controls (43.94%).

The study comprised two appointments. The first appointment included an extensive clinical characterisation of participants via interviews and self-reports. Appointment two comprised the actual stress induction experiment. Written informed consent was provided by participants and their caregivers before inclusion in the study. The authors assert that all procedures contributing to this work comply with the ethical standards of the relevant national and institutional committees on human experimentation and with the Helsinki Declaration of 1975, as revised in 2008. All procedures involving human patients were approved by the ethical committee of the University of Heidelberg (study identifier: S-685/2015).

Procedures

At the first appointment, patients completed a diagnostic interview and answered self-report questionnaires. Diagnostic tools that are relevant for the present manuscript are presented here. Further instruments are reported elsewhere.Reference Koenig, Lischke, Bardtke, Heinze, Kröller and Pahnke26 For all diagnostic tools, a validated German translation was used. During the interview, demographic data (e.g. school form, age, height, weight) were queried. Suicidality and NSSI behaviour were assessed with the Self-Injurious Thoughts and Behaviors Interview (SITBI-G),Reference Fischer, Ameis, Parzer, Plener, Groschwitz and Vonderlin27 BPD criteria were assessed with the Structured Clinical Interview for the DSM-IV (SCID-II).Reference Wittchen, Zaudig and Fydrich28 The semi-structured Mini-International Neuropsychiatric Interview for children and adolescents (M.I.N.I.-Kid)Reference Sheehan, Lecrubier, Sheehan, Amorim, Janavs and Weiller29 was conducted with all participants to check for common Axis 1 disorders. In self-report questionnaires, dimensional characteristics of BPD criteria were determined with the Borderline Symptom List Short Form (BSL-23).Reference Bohus, Kleindienst, Limberger, Stieglitz, Domsalla and Chapman30 Moreover, traumatic childhood experiences were determined with the Childhood Trauma Questionnaire (CTQ).Reference Klinitzke, Romppel, Häuser, Brähler and Glaesmer31 In addition to the diagnostic interview, possible influencing factors of the physiological stress reaction were assessed. Therefore, somatisation, depression and anxiety were assessed with the Brief Symptom Inventory (BSI-18).Reference Spitzer, Freyberger, Stieglitz, Carlson, Kuhn and Magdeburg32 Healthy controls also underwent a diagnostic interview and questionnaires, which included a demographic assessment, the SITBI-G, BSL-23, BSI-18 and CTQ. To make sure that healthy control participants did not fulfil criteria for any psychiatric disorder, the SCID-II Non-Patient (SCID-N/P)Reference First, Spitzer, Gibbon and Williams33 was conducted. All interviews and questionnaires were digitised with LimeSurvey for Windows (LimeSurvey GmbH, Hamburg, Germany; www.limesurvey.org/).

The second appointment comprised the actual experiment, including the stress induction paradigm. The detailed procedures are described elsewhere.Reference Koenig, Lischke, Bardtke, Heinze, Kröller and Pahnke26 The Trier Social Stress Test (TSST) for stress induction in children and adolescents was used as the stress task.Reference Kirschbaum, Pirke and Hellhammer34 The rationale for using the TSST over other paradigms is that the TSST is one of the best validated stress paradigms to reliably induce interpersonal stress in adolescents.Reference Seddon, Rodriguez, Provencher, Raftery-Helmer, Hersh and Labelle35 The aim was not to specifically induce academic stress. The respective cover-story has been suggested for adolescents and has previously been widely used. As adolescents with NSSI or BPD are known to show difficulties in handling interpersonal stress, examining stress during real-world interpersonal interaction is important in this patient group. Thus, it was intended to present the participants with a real-world scenario in a controlled stress-provoking setting. Before the TSST, participants performed the Color Detection Task (CDT) as a cognitive low-demand baseline task.Reference Jennings, Kamarck, Stewart, Eddy and Johnson36 They were asked to count the occurrence of a specific colour of a rectangle over 5 min. The TSST consisted of a preparation phase and two stress tasks. During the preparation phase, participants had 5 min to prepare themselves for an interview for their dream school. During phase 1 of the TSST, they were asked to present themselves in front of two interviewers. They were asked to elaborate on why they were the perfect candidate for a new school. Participants believed that their speech was videotaped. The interviewers did not show any reaction to the participants' speech and did not answer any questions. After 5 min they interrupted the participant and continued with a mental arithmetic test during which the participant had to subtract mentally. Every time the participant made a mistake, they had to start subtracting from the beginning. Before and after the stress task, the participants answered two short questionnaires regarding their momentary mental state (Positive and Negative Affect Schedule (PANAS);Reference Watson, Anna and Tellegen37 Dissociation-Tension Scale (DSS-4)Reference Stiglmayr, Schimke, Wagner, Braakmann, Schweiger and Sipos38), and rated their stress levels on a visual analogue scale ranging from 0 to 100. At the end, all participants were debriefed.

fNIRS measurement

An eight-channel continuous-wave fNIRS system was used for continuous recordings of PFC oxygenation (OctaMon, Artinis Medical Systems, The Netherlands). It is an optical neuroimaging device that contains eight LED light sources and two PIN diode receivers that are placed with a headband onto the forehead of the participant. The light sources emit light in the near-infrared spectrum, which passes the skull cap and is absorbed by the O2Hb and the HbR. The attenuation of light by different tissues is described by the modified Beer-Lambert Law. As O2Hb absorbs light with a wavelength >800 nm and HbR absorbs light with a wavelength <800 nm, the OctaMon device emits light in two wavelengths, 760 nm and 850 nm. Receivers and transmitters are summed up as optodes. The inter-optode distance is 35 mm, which results in an estimated cortical penetration depth of 17 mm. The optodes were placed onto the forehead according to the international 10–20 system for electroencephalography electrodes placement.Reference Jaspers39 The optode configuration and their estimated coordinates according to the Montreal Neurological Institute brain template are displayed in Fig. 1. When placing the headband to the forehead, the instructor made sure that there was no hair between optodes and skin, and that the received light was between 3 and 97% of the emitted light. Values close to 0% indicate that almost no light reaches the receiver, whereas values close to 100% indicate that environmental light is also received. According to the general equation for the differential path length factor and in regard to current study protocols, the differential path length factor was set to 6 cm.Reference Scholkmann and Wolf40 The sampling rate was set to 50 Hz per channel.

Fig. 1 Optode placement on the forehead.Reference Koenig, Höper, van der Venne, Mürner-Lavanchy, Resch and Kaess23 R indicates receiver and S indicates source.

fNIRS data preprocessing

Raw haemoglobin density values (O2Hb and HbR) were recorded by the fNIRS device and sent to a laptop via Bluetooth, where it was stored as *.oxy3-data using the Oxysoft software, version 3.1.103 for Windows (ArtinisMedical Systems, Elst, The Netherlands).41 All fNIRS data were segmented according to the start and end times of the different blocks during the study. In preparation for the preprocessing of the data, they were imported to MATLAB42 for Windows (The Math Works Inc., Natick, Massachusetts, USA) with the oxysoft2matlab function provided by Artinis Medical Systems (The Netherlands). Preprocessing was conducted with the HOMER2 toolbox.Reference Huppert, Diamond, Franceschini and Boas43 First, the raw optical density measures were converted to optical density values (hmrIntensity2OD). Next, we corrected for motion artefacts as recommended.Reference Cooper, Selb, Gagnon, Phillip, Schytz and Iversen44 We applied a two-step correction process. The first step was the application of a wavelet-based motion correction with a probability threshold of α = 0.01 (hmrMotionCorrectWavelet). In the second step, we corrected for motion artifacts by using the hmrMotionArtifact function. This function removes signal changes where the standard deviation exceeds the factor 20 (SDThresh) or where the peak-to-peak amplitude exceeded 0.5 (AMPThresh) within 0.5 s (tMotion). High-frequency noise was removed with a third-order Butterworth filter (LowFrequencyPass), which only allowed frequencies lower than 0.5 Hz so that high-frequency physiological noise (e.g. cardiac) was removed. Finally, optical density rates were converted to haemoglobin concentrations in μmol/L (10−6 mol/L) for O2Hb, HbR and total haemoglobin (O2Hb + HbR), and were exported for segmentation and further analyses to Stata/SE software, version 16.0 for Windows (StataCorp LLC, College Station, Texas, USA).45 After preparing the fNIRS data for analysis, recordings from channel five of one healthy control were removed from the analysis during the CDT and the preparation of the TSST, as the recorded values were unrealistically high, suggesting that external light was absorbed. Visualisations were prepared with BrainNet Viewer, version 1.6 for Windows (www.nitrc.org/projects/bnv/).Reference Xia, Wang and He46

Statistical analysis

All statistical analyses were conducted in Stata/SE software version 16.0.45 In line with previous research,Reference Alderliesten, De Vis, Lemmers, van Bel, Benders and Hendrikse21,Reference Artemenko, Soltanlou, Ehlis, Nuerk and Dresler47Reference Shi, Sakatani, Okamoto, Yamaguchi and Zuo51 we calculated mean values and standard deviations for O2Hb for all relevant time blocks (four time blocks: CDT; Preparation TSST; TSST, divided into the free speech and the mental arithmetic test). For O2Hb, mean values per channel and a grand mean value per block were calculated. First, to check for differences between groups on demographical data and on the clinical interviews, t-tests (continuous variables) and χ 2-tests (categorical variables) were calculated. Second, a linear mixed-effects model was calculated for O2Hb to test the hypothesis that adolescent patients engaging in NSSI would show an increased PFC activation in response to an acute stress task. Predictors were time (CDT, preparation TSST, free speech, arithmetic task) and group (patients versus healthy controls), as well as their interaction included as fixed effects. The participants’ identifiers were addressed as random effect. Where applicable, planned contrasts were used to investigate effects of group at single events of time, to address when effects emerged and how long they lasted. To account for the severity of BPD symptoms and to test the hypothesis that severity of BPD pathology would be positively correlated with the increase in PFC activation in the NSSI group, models were repeated using a dimensional approach of BPD severity based on BSL-23 and the number of BPD criteria (SCID-II). The interaction of time × severity was addressed. Consistency between the two measurement modalities (BSL-23 and SCID-II) was inspected. For consistent interactions between the modalities, margin plots at fixed levels of BPD symptoms (BSL-23: 0, 1, 2, 3, 4; BPD criteria: 0, 3, 6, 9) were composed. Next, effects of self-reported levels of dissociation, stress, and positive as well as negative affect on PFC oxygenation were addressed. Each measure was included separately as a predictor to the mixed linear-effects model on O2Hb, and it was checked whether the inclusion of self-reports improved the overall model fit. Group differences on self-reports in response to stress are reported elsewhere.Reference Koenig, Lischke, Bardtke, Heinze, Kröller and Pahnke26 Finally, connectivity between fNIRS channels across the PFC was analysed; cross correlation coefficients were determined for each time block and analysed in mixed-effects models with time and group as predictors. Contrast analyses were used to address changes in connectivity strength by time and group. Furthermore, BPD dimensionality (BSL-23 and SCID-II) was also included in additional mixed-linear effects models as indicated above. Because of technical issues, one healthy control had to be excluded from the connectivity analysis. Hence, the sample resulted in n = 30 patients engaging in NSSI and n = 28 healthy control participants. For simplicity and in line with previous research, only O2Hb was included in all analyses, as it is the most informative haemoglobin variable and changes in haemoglobin are easier to detect.Reference Koenig, Höper, van der Venne, Mürner-Lavanchy, Resch and Kaess23,Reference Condy, Friedman and Gandjbakhche52

Results

Sample characteristics

For a detailed description of sociodemographic and clinical characteristics of the sample, see Table 1. As illustrated in Table 1, groups differed on BMI as well as on measures of psychopathological distress.

Table 1 Sociodemographic and clinical characteristics by group

All values are means with s.d. in brackets, if not otherwise classified. School: after 4 years of primary school, secondary school is divided into three school forms in Germany; Hauptschule consists of 5 years of secondary school, qualifying for further vocational education; Realschule consists of 6 years and ends with a general certificate of secondary education; Gymnasium takes 8–9 years and ends with a general university entrance qualification. NSSI, adolescents with five or more events of non-suicidal self-injury; BMI, body mass index; BSI-GSI, Brief Symptom Inventory – Global Severity Index; BSL-23, Borderline Symptom List Short Form; CTQ, Childhood Trauma Questionnaire; BPD, borderline personality disorder.

On average, participants of the NSSI group fulfilled 3.53 (s.d. = 1.85) BPD criteria. Predominantly, they reported the criterion of NSSI and/or suicidality (n = 28; 93.33%), followed by emotional instability (n = 21; 70.00%) and unstable and intense relationships (n = 16; 53.33%). The mean age of NSSI onset was 12 years (s.d. = 0.436).

PFC activation

General PFC activation over time is visualised in Fig. 2. The model on O2Hb was significant (Wald χ2(7) = 23.63; P = 0.001). Main effects were found for time (χ2(3) = 9.34; P = 0.025), but not for group (χ2(1) = 0.43; P = 0.512). The interaction between time and group was significant (χ2(3) = 14.33; P = 0.003). Adjacent contrast for time revealed a significant contrast between CDT and preparation of the TSST (χ2(1) = 8.30; P = 0.004), but not for time blocks later on (preparation TSST versus free speech: χ2(1) = 1.18, P = 0.277; free speech versus arithmetic task: χ2(1) = 1.00, P = 0.317). Although the O2Hb in the NSSI group remained unchanged from baseline (CDT) to the preparation phase of the TSST, and increased slowly during the course of the TSST, the level of O2Hb in healthy controls decreased between CDT and preparation phase, and slowly increased again during the free speech and the arithmetic task (see Fig. 2). When comparing O2Hb between groups during the CDT, baseline O2Hb in the NSSI group was descriptively lower compared with healthy controls. The difference just failed to reach statistical significance (t = −1.839; P = 0.071). Results of the exploratory connectivity analyses are provided in the Supplementary Material.

Fig. 2 Prefrontal oxygenation over the course of time. Displayed is the prefrontal oxygenation in μmol/L over the course of the Color Detection Task (CDT) and the Trier Social Stress Test (TSST), divided into preparation phase, free speech task and arithmetic task. NSSI, adolescents engaging in non-suicidal self-injury; ΔHC-NSSI, difference between healthy controls and NSSI group.

BPD symptoms and changes in PFC activation

Both continuous models on BPD severity showed significant model fit for O2Hb (BSL-23: Wald χ2(7) = 23.05, P = 0.002; BPD criteria: Wald χ2(7) = 28.08, P < 0.001). There was a significant time × severity interaction for BPD severity in predicting changes in O2Hb for BSL-23 (χ2(3) = 14.03; P = 0.003), as well as for the number of BPD criteria (χ2(3) = 17.25; P = 0.001). The respective findings are illustrated in Fig. 3. As illustrated, higher self-reported BPD pathology (BSL-23) and greater number of BPD criteria (SCID-II) were associated with lower O2Hb during baseline and higher O2Hb during the preparation of the TSST and during the TSST itself.

Fig. 3 Margins plots between borderline personality disorder symptoms and prefrontal oxygenated haemoglobin over time. BPD, borderline personality disorder; BSL-23, Borderline Symptom List Short Form; SCID-II, Structured Clinical Interview for the DSM-IV; TSST, Trier Social Stress Test.

Self-reported dissociation, stress and mood and changes in PFC activation

To investigate the influence of self-reports (i.e. dissociation, stress, and negative and positive affect), each measure was included separately as predictor to the linear-mixed effects model on O2Hb. Adding self-reported dissociation as a predictor did not improve the respective model fit (Wald χ2(11) = 23.15; P = 0.017). Furthermore, no significant main effect of dissociation on the course of O2Hb occurred (coefficient, 0.022; P = 0.836). In the same vein, self-perceived stress as predictor on O2Hb did not improve the model fit (Wald χ2(11) = 28.42; P = 0.003), and no significant main effect of stress on the course of O2Hb was found (coefficient, −0.003; P = 0.655). For the inclusion of negative affect as a predictor to the model on O2Hb, the model fit remained significant, but did not improve (Wald χ2(11) = 27.31; P = 0.004). The main effect of negative affect was not significant (coefficient, 0.004; P = 0.948). Finally, positive affect was included as a predictor to the linear mixed-effects model on O2Hb. Again, the model fit did not improve (Wald χ2(11) = 37.13; P = 0.0001), and the main effect for positive affect on the course of O2Hb was not significant (coefficient, 0.051; P = 0.180).

Discussion

To our knowledge, this is the first study investigating neural response indicated by PFC oxygenation to stress in adolescents engaging in NSSI across the spectrum of BPD pathology. We examined PFC activation before and during the TSST. Although PFC oxygenation during baseline was descriptively lower in patients engaging in NSSI, it slightly increased in response to stress. In contrast, PFC oxygenation in healthy controls decreased under stress. This result partially supports the hypothesis that there is greater PFC oxygenation in response to stress among adolescents with NSSI. We found evidence for such a group difference; however, it resulted mainly from a decrease in PFC activation in healthy controls. Interestingly, the anticipation of the stressor (preparation of the TSST) was sufficient to cause the decrease in healthy controls. In a former study, we found a significantly attenuated PFC oxygenation at rest in adolescents with NSSI compared with a healthy control group.Reference Koenig, Höper, van der Venne, Mürner-Lavanchy, Resch and Kaess23 Here, in a much smaller sample, the difference at baseline just missed statistical significance, but replicated the finding of lower resting PFC oxygenation in patients engaging in NSSI, in principle.

We can speculate that structural differences, such as lower grey matter volume in PFC areas, might cause lower PFC oxygenation during resting state in patients engaging in NSSI. Decreased grey matter volume in the anterior cingulate cortex of older adults has been related to lower blood flow during resting state.Reference Vaidya, Paradiso, Boles Ponto, McCormick and Robinson53 Research on patients with BPD and NSSI show volume losses in PFC areas,Reference Brunner, Henze, Parzer, Kramer, Feigl and Lutz54 and decreased activation in the dorsolateral PFC.Reference Schulze, Schmahl and Niedtfeld55 Hence, potential volume losses occurring in association with BPD and/or NSSI pathology might account for PFC hypoactivation during rest in patients engaging in NSSI. It has been shown that reduced prefrontal grey matter volume in older adults is associated with a greater increase in PFC activation during dual-task walking compared with single-task walking.Reference Wagshul, Lucas, Ye, Izzetoglu and Holtzer56 In addition, lesion studies found altered stress response in people with lesions in the medial PFC.Reference Buchanan, Driscoll, Mowrer, Sollers, Thayer and Kirschbaum57 This line of reasoning links reduced PFC activation during rest, and overcompensation during demand (e.g. task-based activity), with structural deficits in patients with BPD and NSSI that might compromise their capacity to adequately adapt to psychosocial stress.

We also hypothesised that greater BPD pathology would be related to greater PFC oxygenation in the NSSI group. Here, we found that greater BPD pathology (self-report and clinical interview) was associated with decreased PFC oxygenation at baseline and increased PFC oxygenation during the task on a dimensional level. Hence, our hypothesis was supported. In adults with BPD, a negative correlation between grey matter volume loss in the PFC and temporal areas and self-reported BPD symptoms was found at rest, using MRI.Reference Nenadić, Voss, Besteher, Langbein and Gaser58 Together with the results from the present study, these findings support the assumption of linear alterations of neurobiological systems as a function of BPD severity. As BPD-specific changes in PFC oxygenation seem to be prevalent even in adolescents with NSSI, the need for early detection and therapeutic interventions is emphasised. There are only limited therapeutic options specifically focusing on NSSI. The current work highlights differences in neural activity under stress as a function of BPD severity in patients engaging in NSSI, and therefore emphasises the use of tailored interventions for stress regulation in these patients. Furthermore, PFC oxygenation might serve as biomarker in clinical care to address the efficacy of respective interventions to improve stress response on a neurobiological level. Hence, future studies should examine the use of fNIRS to monitor PFC activation as a biomarker for severity, monitoring and therapeutic outcome in adolescent patients engaging in NSSI.

In exploratory analyses, connectivity across the PFC over time was investigated using mixed linear-effects models. Results revealed significant model fit mainly concerning connectivity between channels covering the left PFC when accounting for BPD symptom severity over time. The left PFC seems to play a crucial role in stress compensation, especially for those reporting greater BPD pathology. Prior research indicates a higher vulnerability of the left PFC to higher cortisol levels and chronic stress compared with the right hemisphere.Reference Cerqueira, Almeida and Sousa59 Studies on frontal asymmetry found that left individual frontal activity predicted greater cortisol increases during stress.Reference Quaedflieg, Meyer, Smulders and Smeets60 Decreased activity in the orbitofrontal PFC seems to be related to an increased cortisol secretion after stress.Reference Dedovic, Duchesne, Andrews, Engert and Pruessner17 Interestingly, cortisol response is reported to be attenuated after stress in adolescent NSSI.Reference Kaess, Hille, Parzer, Maser-Gluth, Resch and Brunner61

As reported elsewhere,Reference Koenig, Lischke, Bardtke, Heinze, Kröller and Pahnke26 cortisol secretion of the present sample increased after the stress task in both groups. However, compared with controls, the cortisol increase after stress in patients engaging in NSSI was attenuated and greater BPD pathology (self-report and clinical interview) was associated with a more attenuated increase in cortisol secretion after stress.Reference Koenig, Lischke, Bardtke, Heinze, Kröller and Pahnke26 These results on the cortisol response are in line with prior findings and add to the overall picture. In the control group, prefrontal oxygenation decreased under stress and cortisol secretion increased, in line with findings from studies in healthy adults.Reference Pruessner, Dedovic, Khalili-Mahani, Engert, Pruessner and Buss62 This finding suggests a maladaptive interplay between the PFC and the hypothalamus-pituitary-adrenal axis in NSSI. Findings from this study extended by the results from Koenig et alReference Koenig, Lischke, Bardtke, Heinze, Kröller and Pahnke26 suggest that neural mechanisms as a function of BPD severity are associated with the observed attenuation in physiological stress reactivity (i.e. blunted cortisol response) in NSSI. This blunted cortisol response in adolescents with NSSI has been described previously and replicated in independent studies,Reference Klimes-Dougan, Begnel, Almy, Thai, Schreiner and Cullen16 and might present a physiological marker for difficulties in emotion regulation in NSSI. Here, we provide evidence on a potential neural mechanism associated with this phenomenon, related to alterations in PFC oxygenation and its connectivity. Importantly, this pattern seems to manifest on a continuum as a function of BPD severity. Prior research found that greater connectivity between prefrontal and limbic areas in healthy adolescents during rest was associated with greater cortisol reactivity to an acute stressor, whereas this relationship was only weak or inversed in depressed adolescents with and without NSSI.Reference Thai, Westlund Schreiner, Mueller, Cullen and Klimes-Dougan63 In a sample of patients at ultra-high risk for psychosis, reduced grey matter volume in the PFC was associated with a blunted response of the hypothalamus-pituitary-adrenal axis.Reference Valli, Crossley, Day, Stone, Tognin and Mondelli64 Taken together, structural deficits of the PFC resulting in altered activation patterns in adolescent NSSI may compromise the capacity to regulate emotions and stress, both on a psychological and physiological level, and seem to be related to BPD severity. Future research should assess real-time prefrontal reactivity to stress in relation to physiological reactivity in NSSI, to disentangle the temporal associations between cortex activation and physiological response – also in consideration of neural feedback loops.

The use of the TSST to examine alterations in neural responding in adolescent NSSI is a novelty of the present study. Former research on neural alterations in adolescent NSSI is sparse and mainly limited to social exclusion paradigms (such as the Cyberball task) or other stress-inducing paradigms (such as stress induced by time pressure, using the Montreal Imaging Stress Test), using fMRI. Although social exclusion marks an important stressor in BPD, the examination of neural responses to different stress tasks in a real-world setting may help to better understand differences in neural activity in adolescent NSSI, and ease translation of research findings to real-world clinical care.

This study comes with several limitations. First, only female adolescents were investigated. For neural activation, gender differences are often reported.Reference Domes, Schulze, Böttger, Grossmann, Hauenstein and Wirtz65,Reference Stevens and Hamann66 Hence, findings from this study are not readily transferable to male adolescents with NSSI, and further research is needed. Second, sample size was a limiting factor when investigating the influence of BPD pathology. Finally, connectivity measures implemented in the present study are limited because of the limited spatial resolution of NIRS measurement compared with other neuroimaging techniques. Other neuroimaging modalities such as fMRI have a greater spatial resolution, and even provide insight into the connectivity with deeper subcortical brain structures such as the limbic system, which is known to be relevant in emotion regulation and BPD.

Taken together, this study shows differences in the neural response of the PFC to a psychosocial stress task comparing adolescents with and without NSSI. Although PFC oxygenation decreased in healthy controls, PFC oxygenation slightly increased in adolescents with NSSI. The trajectory of PFC oxygenation from rest to stress overall was associated with the severity of BPD pathology. To our knowledge, this is the first study to investigate PFC oxygenation during stress in a sample of adolescents with and without NSSI across the spectrum of BPD pathology. Further research is needed to replicate and extend these findings. Future studies should build on these findings, using different stress paradigms and neuroimaging modalities. The finding that the severity of BPD pathology is associated with alterations in PFC activation during stress emphasises that not only patients with full-blown BPD might benefit from tailored therapeutic interventions to improve stress regulation, but also patients engaging in NSSI who only partially fulfil BPD criteria. The consideration of BPD severity in tailoring interventions might be beneficial: PFC activation may serve as biomarker in this regard. Hence, future studies should examine the use of fNIRS to monitor changes in PFC oxygenation during treatment. Furthermore, future studies may extend the current study by comparing prefrontal activation not only against a healthy control group, but also against clinical control groups (e.g. patients with depression).

Supplementary material

Supplementary material is available online at https://doi.org/10.1192/bjo.2024.728

Data availability

The data that support the findings of this study are available from the corresponding author, J.K., on reasonable request.

Acknowledgements

We would like to thank all participants and their caregivers, as well as the clinical staff for their help in recruiting patients. This work was supported by the Dres. Majic/Majic-Schlez-Fundation, Germany. This work was part of the thesis of one of the authors (S.H.).Reference Höper67

Author contributions

S.H. contributed to study conceptualisation, formal analysis, visualisation and writing the original draft of the manuscript. F.K., A.-L.H. and K.F.B. contributed to the study investigation and data acquisition. M.K. contributed to study conceptualisation, project administration, study supervision and reviewing and editing of the manuscript. J.K. contributed to study conceptualisation, formal analysis, funding acquisition, project administration, study supervision and writing the original draft of the manuscript.

Funding

This work was supported by the Dres. Majic/Majic-Schlez-Fundation, Germany (principal investigator J.K.).

Declaration of interest

None.

Footnotes

Joint last authors.

References

International Society for the Study of Self-Injury. What Is Self-Injury? International Society for the Study of Self-Injury, 2018 (https://www.itriples.org/aboutnssi/what-is-self-injury).Google Scholar
Ghinea, D, Edinger, A, Parzer, P, Koenig, J, Resch, F, Kaess, M. Non-suicidal self-injury disorder as a stand-alone diagnosis in a consecutive help-seeking sample of adolescents. J Affect Disord 2020; 274: 1122–5.CrossRefGoogle Scholar
Chanen, A, Sharp, C, Hoffman, P. Prevention and early intervention for borderline personality disorder: a novel public health priority. World Psychiatry 2017; 16: 215–6.CrossRefGoogle ScholarPubMed
Johnson, JG, Cohen, P, Kasen, S, Skodol, AE, Oldham, JM. Cumulative prevalence of personality disorders between adolescence and adulthood. Acta Psychiatr Scand 2008; 118: 410–3.CrossRefGoogle ScholarPubMed
Kaess, M, von Ceumern-Lindenstjerna, I-A, Parzer, P, Chanen, AM, Mundt, C, Resch, F, et al. Axis I and II comorbidity and psychosocial functioning in female adolescents with borderline personality disorder. Psychopathology 2013; 46: 5562.CrossRefGoogle ScholarPubMed
Kaess, M, Fischer-Waldschmidt, G, Resch, F, Koenig, J. Health related quality of life and psychopathological distress in risk taking and self-harming adolescents with full-syndrome, subthreshold and without borderline personality disorder: rethinking the clinical cut-off? Bord Pers Disord Emot Dysregul 2017; 4: 7.Google ScholarPubMed
Daros, AR, Williams, GE. A meta-analysis and systematic review of emotion-regulation strategies in borderline personality disorder. Harvard Rev Psychiatry 2019; 27: 217–32.CrossRefGoogle ScholarPubMed
Thomas, N, Gurvich, C, Hudaib, A-R, Gavrilidis, E, Kulkarni, J. Systematic review and meta-analysis of basal cortisol levels in borderline personality disorder compared to non-psychiatric controls. Psychoneuroendocrinology 2019; 102: 149–57.CrossRefGoogle ScholarPubMed
Glaser, J-P, Os, JV, Mengelers, R, Myin-Germeys, I. A momentary assessment study of the reputed emotional phenotype associated with borderline personality disorder. Psychol Med 2008; 38: 1231–9.CrossRefGoogle ScholarPubMed
Deckers, JWM, Lobbestael, J, van Wingen, GA, Kessels, RPC, Arntz, A, Egger, JIM. The influence of stress on social cognition in patients with borderline personality disorder. Psychoneuroendocrinology 2015; 52: 119–29.CrossRefGoogle ScholarPubMed
Drews, E, Fertuck, EA, Koenig, J, Kaess, M, Arntz, A. Hypothalamic-pituitary-adrenal axis functioning in borderline personality disorder: a meta-analysis. Neurosci Biobehav Rev 2019; 96: 316–34.CrossRefGoogle ScholarPubMed
Reitz, S, Kluetsch, R, Niedtfeld, I, Knorz, T, Lis, S, Paret, C, et al. Incision and stress regulation in borderline personality disorder: neurobiological mechanisms of self-injurious behaviour. Br J Psychiatry 2015; 207: 165–72.CrossRefGoogle ScholarPubMed
Groschwitz, RC, Plener, PL, Groen, G, Bonenberger, M, Abler, B. Differential neural processing of social exclusion in adolescents with non-suicidal self-injury: an fMRI study. Psychiatry Res 2016; 255: 43–9.CrossRefGoogle ScholarPubMed
Westlund Schreiner, M, Klimes-Dougan, B, Mueller, BA, Eberly, LE, Reigstad, KM, Carstedt, PA, et al. Multi-modal neuroimaging of adolescents with non-suicidal self-injury: amygdala functional connectivity. J Affect Disord 2017; 221: 4755.CrossRefGoogle ScholarPubMed
Kaess, M, Parzer, P, Koenig, J, Resch, F, Brunner, R. Dual-task performance under acute stress in female adolescents with borderline personality disorder. Eur Child Adolesc Psychiatry 2016; 25: 1027–35.CrossRefGoogle ScholarPubMed
Klimes-Dougan, B, Begnel, E, Almy, B, Thai, M, Schreiner, MW, Cullen, KR. Hypothalamic-pituitary-adrenal axis dysregulation in depressed adolescents with non-suicidal self-injury. Psychoneuroendocrinology 2019; 102: 216–24.CrossRefGoogle ScholarPubMed
Dedovic, K, Duchesne, A, Andrews, J, Engert, V, Pruessner, JC. The brain and the stress axis: the neural correlates of cortisol regulation in response to stress. NeuroImage 2009; 47: 864–71.CrossRefGoogle ScholarPubMed
Schaal, NK, Heppe, P, Schweda, A, Wolf, OT, Krampe, C. A functional near-infrared spectroscopy study on the cortical haemodynamic responses during the Maastricht acute stress test. Sci Rep 2019; 9: 13459.CrossRefGoogle Scholar
Wang, J, Rao, H, Wetmore, GS, Furlan, PM, Korczykowski, M, Dinges, DF, et al. Perfusion functional MRI reveals cerebral blood flow pattern under psychological stress. Proc Natl Acad Sci U S A 2005; 102: 17804–9.CrossRefGoogle ScholarPubMed
Otto, A, Jarvers, I, Kandsperger, S, Reichl, C, Ando, A, Koenig, J, et al. Stress-induced alterations in resting-state functional connectivity among adolescents with non-suicidal self-injury. J Affect Disord 2023; 339: 162–71.CrossRefGoogle ScholarPubMed
Alderliesten, T, De Vis, JB, Lemmers, PMA, van Bel, F, Benders, MJNL, Hendrikse, J, et al. Simultaneous quantitative assessment of cerebral physiology using respiratory-calibrated MRI and near-infrared spectroscopy in healthy adults. NeuroImage 2014; 85: 255–63.CrossRefGoogle ScholarPubMed
Quaresima, V, Ferrari, M. A mini-review on functional near-infrared spectroscopy (fNIRS): where do we stand, and where should we go? Photonics 2019; 6: 87.CrossRefGoogle Scholar
Koenig, J, Höper, S, van der Venne, P, Mürner-Lavanchy, I, Resch, F, Kaess, M. Resting state prefrontal cortex oxygenation in adolescent non-suicidal self-injury – a near-infrared spectroscopy study. NeuroImage 2021; 31: 102704.CrossRefGoogle ScholarPubMed
Kaess, M, Ghinea, D, Fischer-Waldschmidt, G, Resch, F. Die ambulanz für risikoverhalten und selbstschädigung (AtR!Sk) – ein pionierkonzept der ambulanten früherkennung und frühintervention von borderline-persönlichkeitsstörungen [The outpatient clinic for risk-taking and self-harming behavior (AtR!Sk) – a pioneer concept of ambulant early detection and intervention of borderline personality disorder.]. Prax Kinderpsychol Kinderpsychiatr 2017; 66: 404–22.CrossRefGoogle Scholar
Andover, MS, Primack, JM, Gibb, BE, Pepper, CM. An examination of non-suicidal self-injury in men: do men differ from women in basic NSSI characteristics? Arch Suicide Res 2010; 14: 7988.CrossRefGoogle Scholar
Koenig, J, Lischke, A, Bardtke, K, Heinze, A-L, Kröller, F, Pahnke, R, et al. Altered psychobiological reactivity but no impairment of emotion recognition following stress in adolescents with non-suicidal self-injury. Eur Arch Psychiatry Clin Neurosci 2023; 273(2): 379–95.CrossRefGoogle ScholarPubMed
Fischer, G, Ameis, N, Parzer, P, Plener, PL, Groschwitz, R, Vonderlin, E, et al. The German version of the self-injurious thoughts and behaviors interview (SITBI-G): a tool to assess non-suicidal self-injury and suicidal behavior disorder. BMC Psychiatry 2014; 14: 265.CrossRefGoogle ScholarPubMed
Wittchen, H-U, Zaudig, M, Fydrich, T. SKID. Strukturiertes Klinisches Interview für DSM-IV. Achse I und II. Handanweisung [SCID Structured Clinical Interview for DSM-IV Axis I and Axis II. Manual]. Hogrefe, 1997 (https://pure.mpg.de/pubman/faces/ViewItemOverviewPage.jsp?itemId=item_1646481).Google Scholar
Sheehan, DV, Lecrubier, Y, Sheehan, KH, Amorim, P, Janavs, J, Weiller, E, et al. The Mini-international neuropsychiatric interview (M.I.N.I): the development and validation of a structured diagnostic psychiatric interview for DSM-IV and ICD-10. J Clin Psychiatry 1998; 59: 2233.Google ScholarPubMed
Bohus, M, Kleindienst, N, Limberger, MF, Stieglitz, R-D, Domsalla, M, Chapman, AL, et al. The short version of the borderline symptom list (BSL-23): development and initial data on psychometric properties. Psychopathology 2009; 42: 32–9.CrossRefGoogle ScholarPubMed
Klinitzke, G, Romppel, M, Häuser, W, Brähler, E, Glaesmer, H. Die deutsche version des childhood trauma questionnaire (CTQ) – psychometrische eigenschaften in einer bevölkerungsrepräsentativen stichprobe [The German version of the childhood trauma questionnaire (CTQ) – psychometric characteristics in a representative sample of the general population.]. Psychother Psychosom Med Psychol 2012; 62: 4751.Google Scholar
Spitzer, C, Freyberger, HJ, Stieglitz, R-D, Carlson, EB, Kuhn, G, Magdeburg, N, et al. Adaptation and psychometric properties of the German version of the dissociative experience scale. J Traum Stress 1998; 11: 799809.CrossRefGoogle ScholarPubMed
First, MB, Spitzer, RL, Gibbon, M, Williams, JBW. Structured Clinical Interview for DSM-IV-TR Axis I Disorders, Research Version, Non-Patient Edition. (SCID-I/NP). New York State Psychiatric Institute, 2002.Google Scholar
Kirschbaum, C, Pirke, K-M, Hellhammer, DH. The ‘trier social stress test’ – a tool for investigating psychobiological stress responses in a laboratory setting. Neuropsychobiology 1993; 28: 7681.CrossRefGoogle Scholar
Seddon, JA, Rodriguez, VJ, Provencher, Y, Raftery-Helmer, J, Hersh, J, Labelle, PR, et al. Meta-analysis of the effectiveness of the trier social stress test in eliciting physiological stress responses in children and adolescents. Psychoneuroendocrinology 2020; 116: 104582.CrossRefGoogle ScholarPubMed
Jennings, JR, Kamarck, T, Stewart, C, Eddy, M, Johnson, P. Alternate cardiovascular baseline assessment techniques: vanilla or resting baseline. Psychophysiology 1992; 29: 742–50.CrossRefGoogle ScholarPubMed
Watson, D, Anna, L, Tellegen, A. Development and validation of brief measures of positive and negative affect: the PANAS scales. J Pers Soc Psychol 1988; 54: 1063–70.CrossRefGoogle ScholarPubMed
Stiglmayr, C, Schimke, P, Wagner, T, Braakmann, D, Schweiger, U, Sipos, V, et al. Development and psychometric characteristics of the dissociation tension scale. J Pers Assess 2010; 92: 269–77.CrossRefGoogle ScholarPubMed
Jaspers, HH. Report of the committee on methods of clinical examination in electroencephalography. Electroencephalogr Clin Neurophysiol 1958; 10: 370–5.Google Scholar
Scholkmann, F, Wolf, M. General equation for the differential pathlength factor of the frontal human head depending on wavelength and age. J Biomed Opt 2013; 18: 105004.CrossRefGoogle ScholarPubMed
Artinis Medical Systems. Oxysoft. Artinis Medical Systems, 2016 (https://www.artinis.com/oxysoft).Google Scholar
The MathWorks Inc. MATLAB R2015a. The MathWorks Inc., 2015 (https://www.mathworks.com/products/matlab.html).Google Scholar
Huppert, TJ, Diamond, SG, Franceschini, MA, Boas, DA. HomER: a review of time-series analysis methods for near-infrared spectroscopy of the brain. Appl Opt 2009; 48: 280–98.CrossRefGoogle Scholar
Cooper, R, Selb, J, Gagnon, L, Phillip, D, Schytz, HW, Iversen, HK, et al. A systematic comparison of motion artifact correction techniques for functional near-infrared spectroscopy. Front Neurosci 2012; 6: 110.CrossRefGoogle ScholarPubMed
StataCorp. STATA Statistics/Data Analysis. StataCorp, 2019.Google Scholar
Xia, M, Wang, J, He, Y. BrainNet Viewer: a network visualization tool for human brain connectomics. PLoS One 2013; 8: e68910.CrossRefGoogle ScholarPubMed
Artemenko, C, Soltanlou, M, Ehlis, A-C, Nuerk, H-C, Dresler, T. The neural correlates of mental arithmetic in adolescents: a longitudinal fNIRS study. Behav Brain Funct 2018; 14: 113.CrossRefGoogle ScholarPubMed
Niu, H-J, Li, X, Chen, Y-J, Ma, C, Zhang, J-Y, Zhang, Z-J. Reduced frontal activation during a working memory task in mild cognitive impairment: a non-invasive near-infrared spectroscopy study. CNS Neurosci Ther 2013; 19: 125–31.CrossRefGoogle ScholarPubMed
Pinti, P, Tachtsidis, I, Hamilton, A, Hirsch, J, Aichelburg, C, Gilbert, S, et al. The present and future use of functional near-infrared spectroscopy (fNIRS) for cognitive neuroscience. Ann N Y Acad Sci 2020; 1464(1): 529.CrossRefGoogle ScholarPubMed
Seidel, O, Carius, D, Kenville, R, Ragert, P. Motor learning in a complex balance task and associated neuroplasticity: a comparison between endurance athletes and nonathletes. J Neurophysiol 2017; 118: 1849–60.CrossRefGoogle Scholar
Shi, J, Sakatani, K, Okamoto, M, Yamaguchi, Y, Zuo, H. Correlation between LIFG and autonomic activation during stressful tasks: a functional near-infrared spectroscopy (fNIRS) study. J Huazhong Univ Sci Technol Med Sci 2014; 34: 663–71.CrossRefGoogle ScholarPubMed
Condy, EE, Friedman, BH, Gandjbakhche, A. Probing neurovisceral integration via functional near-infrared spectroscopy and heart rate variability. Front Neurosci 2020; 14: 575589.CrossRefGoogle ScholarPubMed
Vaidya, JG, Paradiso, S, Boles Ponto, LL, McCormick, LM, Robinson, RG. Aging, grey matter, and blood flow in the anterior cingulate cortex. NeuroImage 2007; 37: 1346–53.CrossRefGoogle ScholarPubMed
Brunner, R, Henze, R, Parzer, P, Kramer, J, Feigl, N, Lutz, K, et al. Reduced prefrontal and orbitofrontal gray matter in female adolescents with borderline personality disorder: is it disorder specific? NeuroImage 2010; 49: 114–20.CrossRefGoogle ScholarPubMed
Schulze, L, Schmahl, C, Niedtfeld, I. Neural correlates of disturbed emotion processing in borderline personality disorder: a multimodal meta-analysis. Biol Psychiatry 2016; 79: 97106.CrossRefGoogle ScholarPubMed
Wagshul, ME, Lucas, M, Ye, K, Izzetoglu, M, Holtzer, R. Multi-modal neuroimaging of dual-task walking: structural MRI and fNIRS analysis reveals prefrontal grey matter volume moderation of brain activation in older adults. NeuroImage 2019; 189: 745–54.CrossRefGoogle ScholarPubMed
Buchanan, TW, Driscoll, D, Mowrer, SM, Sollers, JJ, Thayer, JF, Kirschbaum, C, et al. Medial prefrontal cortex damage affects physiological and psychological stress responses differently in men and women. Psychoneuroendocrinology 2010; 35: 5666.CrossRefGoogle ScholarPubMed
Nenadić, I, Voss, A, Besteher, B, Langbein, K, Gaser, C. Brain structure and symptom dimensions in borderline personality disorder. Eur Psychiatry 2020; 63: e9.CrossRefGoogle ScholarPubMed
Cerqueira, JJ, Almeida, OFX, Sousa, N. The stressed prefrontal cortex. Left? Right!. Brain Behav Immunity 2008; 22: 630–8.CrossRefGoogle ScholarPubMed
Quaedflieg, CWEM, Meyer, T, Smulders, FTY, Smeets, T. The functional role of individual-alpha based frontal asymmetry in stress responding. Biol Psychol 2015; 104: 7581.CrossRefGoogle ScholarPubMed
Kaess, M, Hille, M, Parzer, P, Maser-Gluth, C, Resch, F, Brunner, R. Alterations in the neuroendocrinological stress response to acute psychosocial stress in adolescents engaging in nonsuicidal self-injury. Psychoneuroendocrinology 2012; 37: 157–61.CrossRefGoogle ScholarPubMed
Pruessner, JC, Dedovic, K, Khalili-Mahani, N, Engert, V, Pruessner, M, Buss, C, et al. Deactivation of the limbic system during acute psychosocial stress: evidence from positron emission tomography and functional magnetic resonance imaging studies. Biol Psychiatry 2008; 63: 234–40.CrossRefGoogle ScholarPubMed
Thai, M, Westlund Schreiner, M, Mueller, BA, Cullen, KR, Klimes-Dougan, B. Coordination between frontolimbic resting state connectivity and hypothalamic–pituitary–adrenal axis functioning in adolescents with and without depression. Psychoneuroendocrinology 2021; 125: 105123.CrossRefGoogle ScholarPubMed
Valli, I, Crossley, NA, Day, F, Stone, J, Tognin, S, Mondelli, V, et al. HPA-axis function and grey matter volume reductions: imaging the diathesis-stress model in individuals at ultra-high risk of psychosis. Transl Psychiatry 2016; 6: e797.CrossRefGoogle ScholarPubMed
Domes, G, Schulze, L, Böttger, M, Grossmann, A, Hauenstein, K, Wirtz, PH, et al. The neural correlates of sex differences in emotional reactivity and emotion regulation. Hum Brain Mapp 2010; 31: 758–69.CrossRefGoogle ScholarPubMed
Stevens, JS, Hamann, S. Sex differences in brain activation to emotional stimuli: a meta-analysis of neuroimaging studies. Neuropsychologia 2012; 50: 1578–93.CrossRefGoogle ScholarPubMed
Höper, S. Präfrontale Oxygenierung bei Jugendlichen mit Störungen der Emotionsregulation [Prefrontal Oxygenation in Adolescents with Emotion Regulation Disorders]. Heidelberg University, 2023 (https://doi.org/10.11588/heidok.00033754).Google Scholar
Figure 0

Fig. 1 Optode placement on the forehead.23 R indicates receiver and S indicates source.

Figure 1

Table 1 Sociodemographic and clinical characteristics by group

Figure 2

Fig. 2 Prefrontal oxygenation over the course of time. Displayed is the prefrontal oxygenation in μmol/L over the course of the Color Detection Task (CDT) and the Trier Social Stress Test (TSST), divided into preparation phase, free speech task and arithmetic task. NSSI, adolescents engaging in non-suicidal self-injury; ΔHC-NSSI, difference between healthy controls and NSSI group.

Figure 3

Fig. 3 Margins plots between borderline personality disorder symptoms and prefrontal oxygenated haemoglobin over time. BPD, borderline personality disorder; BSL-23, Borderline Symptom List Short Form; SCID-II, Structured Clinical Interview for the DSM-IV; TSST, Trier Social Stress Test.

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