Abstract
Objectives
Allostatic overload occurs when environmental factors become excessive for the individual capacity of neurobiological response and can trigger internalizing disorders. These disorders have a strong impact on individuals with autism spectrum disorder (ASD) and can exacerbate ASD symptoms and deficits. A non-invasive neurobiological stimulation technology, called the radio electric asymmetric conveyer (REAC), has been shown to be effective in improving internalizing disorders and remodeling the individual allostatic response. On these premises, REAC neurobiological stimulation treatments have been introduced for the treatment of internalizing disorders in ASD. The aim of this current research was to retrospectively verify the effects of REAC treatments on motor, cognitive, and behavioral skills and symptoms, assessed using the Autism Profiling Questionnaire (APQ).
Methods
Data were collected through administration of the APQ to the caregivers of 112 individuals with ASD. The caregivers rated every cluster of the questionnaire with a score based on an evaluation scale ranging from 0 to 10.
Results
At the 3-month follow-up, the caregivers perceived and rated a global improvement of the individuals with ASD in all clusters.
Conclusions
This research suggests that the mitigating effects of REAC neuromodulation treatments in relation to the severity of internalizing disorders can enhance the quality of life and the autonomy of individuals with ASD, as shown by the shift in the median values in all 21 items of the APQ toward an improvement in symptoms and skills.
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Autism spectrum disorder (ASD) is a neurobiological disorder with an incidence that is growing worldwide. Therefore, there is a need to develop therapeutic strategies to improve the quality of life of individuals with ASD. The comorbidity of internalizing disorders, such as depression (DeFilippis, 2018; Gegelashvili, 2019), anxiety (Adams & Emerson, 2021; Vasa et al., 2020), and stress-related disorders (Oerbeck et al., 2021; Taylor et al., 2021), with ASD is very often present and can affect the deficit severity and the overall quality of life of individuals with ASD. Some non-invasive brain stimulation (NIBS) techniques based on different technologies, such as transcranial magnetic stimulation (Enticott et al., 2019) (TMS) and transcranial direct current stimulation (Amatachaya et al., 2014; Garcia-Gonzalez et al., 2021) (TDCS), have been proven to induce improvements in social, health, and behavioral problems among these individuals.
Another non-invasive technique for neurobiological stimulation, called the radio electric asymmetric conveyer (REAC), has been proven in several studies to be effective in psychological and psychiatric disorders, classified in the DSM-5 as internalizing disorders, including depression (Olivieri et al., 2011; Rinaldi et al., 2019), anxiety (Fontani et al., 2011a, 2011b; Pinheiro Barcessat et al., 2020a, 2020b), stress-related disorders (Fontani et al., 2011a, 2011b; Rinaldi et al., 2010), and motor skills (Lorenzini et al., 2016; Olazaran et al., 2014), balance (Fontani et al., 2012), and other psychiatric disorders (Fontani et al., 2011a, 2011b). As these disorders can exacerbate ASD symptoms and deficits, REAC neurobiological stimulation treatments have been used for some years in individuals with ASD to address their social, health, and behavioral problems. The current research is aimed to retrospectively analyze the treatment results collected in a standardized manner using a specific test designed to evaluate the effects of REAC neurobiological stimulation treatments on the degree of expression of some motor, cognitive, and behavioral deficits typical of ASD and conditioned by internalizing disorders.
Method
Participants
The total population included in this international research consisted of 112 children with ASD with an average age of 5.96 ± 3.15 years, including 26 girls with an average age of 7 ± 3.41 years and 86 boys with an average age of 5.65 ± 3.01 years. This population consisted of all children who visited the clinical centers of the International Scientific Society of Neuro Psycho Physical Optimization with REAC Technology (SONC) for over 12 months and who had a previous diagnosis made by a child psychiatrist using the Autism Diagnostic Observation Schedule (ADOS) and Autism Diagnostic Interview-Revised (ADI-R). Besides the existing treatment plans, the children’s caregivers voluntarily opted to add the REAC neuromodulation treatments.
Procedure
The REAC neuromodulation treatments were administered at the SONC clinical facilities, and data were collected for over 12 months.
REAC Technology
The REAC technology for neurobiological stimulation is aimed at optimizing the endogenous bioelectrical activity (EBA) of neural circuits (Baer & Colello, 2016; Levin et al., 2017). EBA generates signals involved in epigenetic cascades and transcriptional changes in cellular properties, such as proliferation, differentiation, migration, shape change, senescence, apoptosis, neuroinflammation, and neurotransmission (Chernet & Levin, 2013; Levin, 2014). The EBA mechanism implies that an asymmetrical gradient exists in all the components of an organism, which allows the creation of ionic flows, consequently producing currents and endogenous bioelectric fields (EBFs) (Tuszynski, 2019). Many mechanisms, including exposome pressure, can invalidate the correct and adequate production of ionic flows and therefore EBFs, causing a wide range of health problems. Because EBFs are also involved in neurotransmission mechanisms, their alteration can cause mood and behavioral problems. The optimization of EBA through the REAC technology is made possible because REAC devices emit radio electric fields in the environment. These radio electric fields interact with an individual’s body through the device’s asymmetric conveyer probe (ACP). This interaction promotes the formation of endogenous gradients that promote the release of charge densities induced by external factors, thus facilitating neuromodulation processes. The data reported by various studies confirm that the REAC technology, used according to specific protocols, can optimize EBA and induce direct cell reprogramming (Maioli et al., 2012, 2013), contrast of senescence (Maioli et al., 2014; Rinaldi, Maioli, et al., 2014), contrast of neuroinflammation (Lorenzini et al., 2016; Panaro et al., 2018), and modulation of neurotransmission even in neurodegenerative diseases (Lorenzini et al., 2016; Rinaldi et al., 2015).
REAC Neuromodulation Treatments
In this study, one session of neuro postural optimization (NPO) treatment (Olazaran et al., 2014; Rinaldi et al., 2014a, 2014b) and one cycle of neuro psycho physical optimization (NPPO/NPPO-CB) treatments (Pinheiro Barcessat et al., 2020a, 2020b; Rinaldi et al., 2019) were administered to mitigate the internalizing disorders that affected the ASD status and quality of life of the children. REAC NPO neuromodulation is a preprogrammed, one-session treatment. It was designed to induce a greater efficiency of the modulatory capacities of the brain response (Mura et al., 2012; Rinaldi et al., 2014a, 2014b) to improve motor control and treat functional dysmetria (FD) (Mura et al., 2012; Rinaldi et al., 2014a, 2014b) even in neurodegenerative diseases, such as Parkinson’s and Alzheimer’s disease (Olazaran et al., 2013). Its therapeutic result is long-lasting, remaining stable after many years.
NPPO treatments were designed to optimize the individual response to environmental stressors, which can induce and sustain a wide range of dysfunctional adaptive behavioral patterns that underlie many internalizing disorders (Pinheiro Barcessat et al., 2020a, 2020b; Rinaldi et al., 2019). NPPO can be administered as follows: (1) NPPO is administered with a punctiform ACP on the auricle and (2) NPPO-CB with a planar ACP in the cervicobrachial region (Pinheiro Barcessat, et al., 2020a, 2020b). These two methods of administration, both non-invasive and equivalent in effectiveness (Pinheiro Barcessat et al., 2020a, 2020b), allow the selection of the option most tolerated by young individuals according to their degree of cooperation. Both NPPO treatments are usually administered in cycles of 18 sessions. The NPPO treatment session lasts for approximately 30 s, while the NPPO-CB session lasts for approximately 4 min. The minimum time interval between the two sessions is 1 h.
The maximum number of sessions per day is usually four. The number of cycles to be administered depends on the individual’s condition. In this current research, the REAC treatment cycle was administered within approximately 3 weeks. The parameters for administering these neuromodulation treatments are set by the manufacturer of the device and cannot be modified by the operators. The models of the equipment used for the administration of the treatments were the BENE 101 and BENE 110 models produced by ASMED SRL (Florence, Italy).
The study time points were scheduled as follows: Autism Profiling Questionnaire (APQ) administration (T0), dysmetria assessment (T1), NPO administration (T2), dysmetria assessment after NPO (T3), NPPO/NPPO-CB administration (T4), dysmetria assessment at follow-up (approximately 3 months after the end of the treatment cycle) (T5), and APQ assessment at follow-up to the children’s parents (T6).
Measures
The effectiveness of the neurobiological stimulation treatments NPO and NPPO/NPPO-CB on the degree of expression of some motor, cognitive, and behavioral deficits typical of ASD was assessed using the APQ and an evaluation of neurological semiology based on the analysis of FD. The APQ is used at the clinical facilities that adhere to the SONC and is administered to the parents or caregivers of children with ASD. It is not a diagnostic test but only a grid for collecting data on the presence and degree of expression of some motor, cognitive, and behavioral deficits typical of ASD in a standardized manner. The questionnaire includes 21 questions or items divided into three clusters: motor skills, cognitive skills, and behavioral skills and symptoms. Table 1 lists the APQ items and clusters. Herein, the caregivers of the children with ASD rated each item of the questionnaire with a score based on an evaluation scale ranging from 0 to 10 (Table 1). The APQ was administered at follow-up (approximately 3 months after the end of the treatment cycle) (T6). The results of the APQ at T0 and T6 were compared to determine which changes the parents observed in their children after the REAC NPO and NPPO neuromodulation treatments.
FD analysis was also performed. Dysmetria is defined as the inability to perform accurate movements owing to injury or dysfunction of the cerebellum (Manto, 2009). The cerebellum is initially associated exclusively with control of movements but has been known to play a fundamental role in regulating the adequacy of emotional, behavioral, cognitive, and relational responses (Timmann & Daum, 2007). This role can be highlighted through the assessment of dysmetria. When dysmetria is present in healthy individuals (Rinaldi et al., 2014a, 2014b), it is defined as functional (Mura et al., 2012) and is correlated with adaptive phenomena at the base of fluctuating asymmetry. On these premises, FD represents one of the main signs of a neuro-psycho-physio-pathological and dysfunctional adaptive state and can be an epigenetic measure of stress (Parsons, 1990). FD can be observed through an evaluation of neurological semiology, aimed at highlighting the asymmetric activation of symmetrical muscle groups, such as the quadriceps muscles (Mura et al., 2012; Rinaldi et al., 2014a, 2014b). Postmortem (Hampson & Blatt, 2015) and neuroimaging studies (D’Mello et al., 2015; Hashimoto et al., 1995) reported cerebellar anomalies of the anatomical and functional types, respectively, in individuals with ASD (Johnson et al., 2014). Therefore, ASD can be defined as a neurobiological disorder related also to both cerebellar connectivity and dysfunction (Becker & Stoodley, 2013). This impacts the brain areas that govern the cognitive functions, including language and executive functions, as well as affective regulation (Becker & Stoodley, 2013; D’Mello & Stoodley, 2015). The NPO treatment, which can determine a long-lasting disappearance of FD in a single administration (Rinaldi et al., 2014a, 2014b), can serve as an important tool in reducing some ASD deficits. In fact, immediately after the administration of NPO, a stable disappearance of FD and an overall reorganization of postural and motor controls are also observed in neurodegenerative diseases (Fontani et al., 2012).
Data Analysis
Statistical analysis was performed using SPSS version 22 (IBM SPSS). The data collected on the APQ were analyzed using the Wilcoxon and sign tests, performed for each item. Statistical significance was set at P-values of < 0.5. A confidence level of 95% was selected, in association with confidence intervals (CIs), which were specifically identified for each item of each of the three clusters of the APQ. Each CI was set as the mean value of ± 10%.
Results
FD Evaluation
The FD evaluation performed immediately after the administration of NPO treatment (T3) showed the disappearance of FD in 100% of the individuals with ASD. At the 3-month follow-up (T5), the stable disappearance of FD was verified in 100% of the individuals with ASD.
APQ Results
The variations between the data collected at T0 and T6 were analyzed separately for each of the three clusters: motor skills, cognitive skills, and behavioral skills and symptoms. The data were represented using box plots, a method for graphically depicting groups of numerical data through quartiles. Quartiles divide a rank-ordered dataset into four equal parts. The values that separate the parts are called the first, second, and third quartiles and are denoted by Q1, Q2, and Q3, respectively. The interquartile range (IQR) indicates the distance between the first quartile and the third quartile (Q1 − Q3) and measures how spread out the data points are from the mean of the data set. It is graphically represented by the height of the box: The higher the IQR, the more spread out the data points; in contrast, the smaller the IQR, the more bunched up the data points are around the mean. Box plots may also have lines extending from the boxes (whiskers), indicating variability outside the upper and lower quartiles. The height of the box plot indicates the values within which 50% of the measured values are contained, while the length of the whiskers represents the tails of the distribution: The greater their length, the greater the dispersion of the values below the first quartile and/or above the third quartile. To isolate potential outliers, we used Tukey’s fences method, which is a nonparametric method developed to detect observations outside the normal range using IQRs. The ranges between Q2 − k(Q3 − Q1) and Q2 + k(Q3 − Q1) are referred to as fences. Data points that are below the lower fence or above the higher fence are identified as outliers. The value k determines the width of the fences. The larger the value of k, the lower the number of outliers that will be detected. In our analysis, we set the value of k as 1.5. The box plot was used because it was the best visual tool to determine how much the values were dispersed from the median value in the pre- and post-treatment data. Moreover, it allowed the identification of the outliers rapidly and accurately, in comparison with other numerical indices, such as the mean and standard deviation. In fact, if there were anomalous values, these would be represented in the boxplot as isolated asterisks positioned above and/or below the distribution whiskers. This feature allowed us to highlight very interesting observations, considering how profoundly the profiles of individuals with ASD can differ.
In the behavioral skill and symptom clusters, two distinct box plots were prepared for better visualization of the T0/T6 comparison. In fact, since 5 of the 10 items of this cluster aim to evaluate a skill, the possible improvement of individuals with ASD post-treatment can be detectable if and to the extent in which an increase in values is observed. In contrast, since the other five items of the cluster aim to detect the presence of a symptom and evaluate its degree of severity, the possible improvement is detectable if and to the extent to which a reduction in values is observed. A statistical significance of P < 0.5 was found for the five items aimed at detecting the presence of behavioral symptoms and P < 0.05 for all the other 16 items.
Cluster Motor Skills
Gross Motor Skills
At T0, the Q1 value was 4, and the median value was 6; the Q3 value was 8, and the IQR was 4. At T6, the Q1 value was 5, and the median value was 7; the Q3 value was 8, and the IQR was 3 (Fig. 1). Statistical significance was set at P-values of < 0.05.
Fine Motor Skills
At T0, the Q1 value was 2, and the median value was 4,5; the Q3 value was 7, and the IQR was 5. At T6, the Q1 value was 5, and the median value was 6; the Q3 value was 8, and the IQR was 3 (Fig. 1). Statistical significance was set at P-values of < 0.05.
Cluster Cognitive Skills
Language Production Skills
At T0, the Q1 value was 1.75, and the median value was 4; the Q3 value was 5, and the IQR was 3.25. At T6, the Q1 value was 3, and the median value was 6; the Q3 value was 8, and the IQR was 5 (Fig. 2). Statistical significance was set at P-values of < 0.05.
Language Comprehension Skills
At T0, the Q1 value was 3, and the median value was 5; the Q3 value was 7, and the IQR was 4. At T6, the Q1 value was 4, and the median value was 6; the Q3 value was 8, and the IQR was 4 (Fig. 2). Statistical significance was set at P-values of < 0.05.
Attention and Concentration
At T0, the Q1 value was 3, and the median value was 5; the Q3 value was 5, and the IQR was 2. At T6, the Q1 value was 4, and the median value was 6; the Q3 value was 7.25, and the IQR was 3.25 (Fig. 2). Statistical significance was set at P-values of < 0.05.
Learning and Memory
At T0, the Q1 value was 3, and the median value was 5; the Q3 value was 7, and the IQR was 4. At T6, the Q1 value was 5, and the median value was 6; the Q3 value was 8, and the IQR was 3 (Fig. 2). Statistical significance was set at P-values of < 0.05.
Executive Functions
At T0, the Q1 value was 3, and the median value was 5; the Q3 value was 6, and the IQR was 3. At T6, the Q1 value was 4, and the median value was 6; the Q3 value was 8, and the IQR was 4 (Fig. 2). Statistical significance was set at P-values of < 0.05.
Personal Autonomy
At T0, the Q1 value was 2, and the median value was 4; the Q3 value was 6, and the IQR was 4. At T6, the Q1 value was 3.75, and the median value was 5; the Q3 value was 7, and the IQR was 3.25 (Fig. 2). Statistical significance was set at P-values of < 0.05.
Sphincteric Control
At T0, the Q1 value was 1.75, and the median value was 5; the Q3 value was 9, and the IQR was 7.25. At T6, the Q1 value was 3, and the median value was 6; the Q3 value was 10, and the IQR was 7 (Fig. 2). Statistical significance was set at P-values of < 0.05.
Night Rest
At T0, the Q1 value was 4, and the median value was 6; the Q3 value was 9, and the IQR was 5. At T6, the Q1 value was 6, and the median value was 8; the Q3 value was 9, and the IQR was 3 (Fig. 2). Statistical significance was set at P-values of < 0.05.
Sensory Issues
At T0, the Q1 value was 3, and the median value was 5; the Q3 value was 6, and the IQR was 3. At T6, the Q1 value was 3.75, and the median value was 5; the Q3 value was 7, and the IQR was 3.25 (Fig. 2). Statistical significance was set at P-values of < 0.05.
Cluster Behavioral Skills and Symptoms
Non-verbal Communication Skills
At T0, the Q1 value was 4, and the median value was 5; the Q3 value was 7, and the IQR was 3. At T6, the Q1 value was 5, and the median value was 7; the Q3 value was 8, and the IQR was 3 (Fig. 3). Statistical significance was set at P-values of < 0.05.
Voluntary Eye Movements and Eye Contact
At T0, the Q1 value was 3.75, and the median value was 5; the Q3 value was 7, and the IQR was 3.25. At T6, the Q1 value was 4, and the median value was 6; the Q3 value was 8, and the IQR was 4 (Fig. 3). Statistical significance was set at P-values of < 0.05.
Adaptation to Changes
At T0, the Q1 value was 4, and the median value was 5; the Q3 value was 7, and the IQR was 3. At T6, the Q1 value was 5, and the median value was 6; the Q3 value was 8, and the IQR was 3 (Fig. 3). Statistical significance was set at P-values of < 0.05.
Ability to Follow Social Rules in an Interaction
At T0, the Q1 value was 3, and the median value was 4; the Q3 value was 5.25, and the IQR was 2.25. At T6, the Q1 value was 4, and the median value was 5; the Q3 value was 6, and the IQR was 2 (Fig. 3). Statistical significance was set at P-values of < 0.05.
Interest in Socialization and Social Contact
At T0, the Q1 value was 3, and the median value was 5; the Q3 value was 6, and the IQR was 3. At T6, the Q1 value was 4, and the median value was 6; the Q3 value was 7, and the IQR was 3 (Fig. 3). Statistical significance was set at P-values of < 0.05.
Self-aggressive Behaviors
At T0, the Q1 value was 0, and the median value was 2; the Q3 value was 4, and the IQR was 4. At T6, the Q1 value was 0, and the median value was 1; the Q3 value was 3, and the IQR was 3 (Fig. 4). Statistical significance was set at P-values of < 0.5.
Hetero-aggressive Behaviors
At T0, the Q1 value was 0, and the median value was 2; the Q3 value was 4, and the IQR was 4. At T6, the Q1 value was 0, and the median value was 1; the Q3 value was 3, and the IQR was 3 (Fig. 4). Statistical significance was set at P-values of < 0.5.
Agitation and Hyperactivity
At T0, the Q1 value was 5, and the median value was 6; the Q3 value was 8, and the IQR was 3. At T6, the Q1 value was 4, and the median value was 5; the Q3 value was 7, and the IQR was 3 (Fig. 4). Statistical significance was set at P-values of < 0.5.
Irritability and Oppositive Behaviors
At T0, the Q1 value was 4, and the median value was 6; the Q3 value was 8, and the IQR was 4. At T6, the Q1 value was 3, and the median value was 5; the Q3 value was 7, and the IQR was 4 (Fig. 4). Statistical significance was set at P-values of < 0.5.
Stereotyped Behaviors
At T0, the Q1 value was 3, and the median value was 5; the Q3 value was 7, and the IQR was 4. At T6, the Q1 value was 2.75, and the median value was 4; the Q3 value was 6, and the IQR was 3.25 (Fig. 4). Statistical significance was set at P-values of < 0.5.
Adverse Events
No adverse events were reported by the participants or observed by the investigators.
Discussion
Internalizing problems are characterized by anxiety, depressive symptoms, social withdrawal, and somatic complaints (Gobel et al., 2016). The scientific literature provides ample support to the fact that the comorbidity of internalizing disorders, such as depression (DeFilippis, 2018; Gegelashvili, 2019), anxiety (Kim et al., 2021; Vasa et al., 2020), and stress-related disorders (Corbett et al., 2021; Taylor et al., 2021), in ASD can affect the deficit severity, symptomatologic expression, and overall quality of life of individuals with ASD.
On these premises, the use of NIBS methods for treating ASD is growing, and studies conducted with these techniques have reported positive effects on social, health, and behavioral problems in individuals with ASD (Khaleghi et al., 2020). Existing evidence demonstrates that NIBS methods could be helpful in treating some dimensions of ASD, such as repetitive and stereotyped behaviors, sociability, or some aspects of executive and cognitive functions (Khaleghi et al., 2020). The global effects induced by REAC NPO and NPPO/NPPO-CB treatments in individuals with ASD can be contextualized in studies reporting the positive effects of NIBS methods on ASD-related behavioral, cognitive, and neurophysiological dysfunctions. In fact, the results obtained in this research demonstrate a positive correlation between the REAC NPO and NPPO treatments and improvement in the typical deficits of ASD perceived by caregivers at approximately 3 months after the end of the treatment cycle. Even in individuals with ASD, a single REAC treatment cycle has been able to mitigate the impact of internalizing disorders, as already proven in a non-ASD population (Rinaldi et al., 2019). This effect allowed the reduction of the severity of some ASD deficits and symptoms, optimizing the existing skills and improving the mental health conditions and functional outcomes of patients.
A comparison of the results obtained using different NIBS methods is very difficult because of the very large heterogeneity and variability among studies in terms of patients’ profiles, study designs, schedules, and stimulation parameters (Khaleghi et al., 2020).
Moreover, while demonstrating its effectiveness in the same ASD dimensions on which other NIBS techniques are effective, the REAC technology differs in its mechanism of action. In fact, other NIBS methods yield their effects through administration on specific brain areas, depending on their hypotheses regarding the origin of the neural ASD impairments; their capacity to evoke neuroplasticity effects is related to the stimulation site, intensity, and frequency (Khaleghi et al., 2020) because their actions are carried out by inducing inhibitory or excitatory stimulations.
The REAC technology has not a main target brain region for stimulation because it is able to globally reorganize the level of synaptic activities and the related neural circuitry dynamics in the brain (Zippo et al., 2015), not eliciting specific inhibitory or excitatory stimulations, but optimizing EBA and rearranging neural dynamics within “opportune” ranges when altered.
Limitation and Future Research
One of the major limitations of this study is the lack of a control group and the fact that one of the two verification tests involves a parental self-report method. Further studies are needed to better understand the effects of multiple treatment cycles with appropriate follow-up periods. This study suggests promoting further research to verify the effects of REAC NPO and NPPO/NPPO-CB treatments in low-functioning individuals toward high functionality and on relational linguistic skills.
Data Availability
All raw data are available on request in the form of an Excel file.
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Acknowledgements
We thank Dr. Alessandra Cappelli and Dr. Ing. Matteo Lotti Margotti for their precious cooperation.
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AR designed and executed the study, assisted with the data analyses, and wrote the manuscript. MCMM, PCFC, NAPOS, JAVM, VF, and SR designed the study and wrote the manuscript. MM analyzed the data and wrote a part of the results. AR, MM, VF, and SR wrote and edited the final manuscript.
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This research was approved by the Institutional Review Board of the Centre for Developmental Biology and Reprogramming of the University of Sassari, Italy, and performed in accordance with the ethical standards as laid down in the 1964 Declaration of Helsinki and its later amendments or comparable ethical standards.
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Informed consent was obtained from all parents after a detailed explanation of the treatments, granting researchers’ permission to access patient data for the purpose of scientific study and publication while ensuring patient anonymity.
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Financial interests: SR and VF are authors of the REAC technology patent. The other authors declare no conflicts of interest regarding the publication of this paper.
Non-financial interests: AR is the daughter of SR and VF.
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Rinaldi, A., Maioli, M., Marins Martins, M.C. et al. REAC Non-invasive Neurobiological Stimulation for Mitigating the Impact of Internalizing Disorders in Autism Spectrum Disorder. Adv Neurodev Disord 5, 446–456 (2021). https://doi.org/10.1007/s41252-021-00217-7
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DOI: https://doi.org/10.1007/s41252-021-00217-7