Brain Stimulation and Sensory Integration in Children With ASD

Autism Spectrum Disorder (ASD)

Transcranial Magnetic Stimulation, Theta Burst Stimulation, Pediatric Neurostimulation, Neurodevelopmental Disorders, Multimodal Biomarkers, Electrophysiology, Functional Near-Infrared Spectroscopy, Magnetic Resonance Imaging, Genetic Markers, Randomized Controlled Trial, Sham-Controlled Trial, Child Neuropsychology, Autism Spectrum Disorder, Sensory Processing, Audiovisual Integration, Temporal Binding Window, Sound-Induced Flash Illusion, Temporal Perception

The goal of this clinical trial is to find out if brain stimulation can help improve sensory integration in children ages 6 to 12 with autism spectrum disorder (ASD). The main questions it aims to answer are: Does brain stimulation using continuous theta-burst stimulation (cTBS) on bilateral dorsolateral prefrontal cortex (DLPFC) improve how children process sights and sounds together? Can brain functioning, structure, and genetics help predict who responds best to this treatment? Researchers will compare the results of the randomly assigned active brain stimulation to sham (inactive) stimulation groups to see if the treatment works. Participants will: Receive 10 sessions of either active or sham cTBS over 2 weeks Complete a sensory task involving flashes and beeps before and after stimulation Take part in brain scans, namely magnetic resonance imaging (MRI) and functional near-infrared spectroscopy (fNIRS), and provide a saliva sample for genetic testing

This study explores how noninvasive brain stimulation may support children with Autism Spectrum Disorder (ASD) by improving how their brains process and combine sounds and images. It also investigates whether changes in brain function, brain structure, and specific genes can help predict how well a child might respond to this type of stimulation. The study is focused on a core challenge in ASD: differences in how children experience sensory input-especially how their brains process what they see and hear together. The central concept in this research is something called the Temporal Binding Window (TBW). TBW refers to the brief time window in which the brain naturally fuses sensory information from different senses-like sight and sound-into a single event. For most people, this window is quite narrow: sounds and images that are even slightly out of sync are perceived as separate. But in many children with ASD, this window is wider. That means they may confuse the order or timing of sensory inputs, which can affect communication, behavior, and learning. To address this, the study uses a method called transcranial magnetic stimulation (TMS). This technique delivers brief, painless pulses of magnetic energy to the surface of the brain using a special coil held against the scalp. The type of TMS used here is called continuous theta burst stimulation (cTBS), which delivers rapid bursts of magnetic pulses designed to gently decrease the excitability of targeted brain areas. In this study, cTBS is used to modulate activity in a region called the dorsolateral prefrontal cortex (DLPFC), which is important for regulating attention, working memory, and sensory control. A total of 40 children between the ages of 6 and 12 will take part. All participants must have a formal diagnosis of ASD, confirmed using a structured caregiver interview known as the Autism Diagnostic Interview - Revised (ADI-R). They must also demonstrate average or above-average cognitive ability, based on a two-subscale IQ measure from the Wechsler Intelligence Scale for Children - Fifth Edition (WISC-V). This ensures that all children can understand the tasks and safely undergo the procedures. Participants are randomly assigned to one of two groups: an active TMS group or a sham TMS group. In the sham group, the same equipment is used, but no actual magnetic stimulation reaches the brain. This allows researchers to compare outcomes while keeping the children, their families, and the staff unaware of group assignments. Each child completes ten sessions of either active or sham TMS, over approximately two weeks. The stimulation is applied alternately to the left and right sides of the forehead area, corresponding to the DLPFC. Each session lasts only a few minutes. The stimulation is calibrated individually using a simple test to determine the strength needed to trigger a small movement in the child's hand. All children wear ear protection and are supervised closely by trained staff. The main outcome of the study is a measure of how well children can process timing between visual and auditory signals. This is assessed using a behavioral task known as the Sound-Induced Flash Illusion (SIFI). In this task, the child looks at a screen and hears beeps while seeing flashes of light. Sometimes there is only one flash, but if it is paired with two quick beeps, some children perceive two flashes instead of one. By changing the timing between the flash and the beeps, researchers can measure the range of delays where the child still experiences the illusion. This range is called the Temporal Binding Window. The wider the window, the more likely the child's brain is to fuse signals that actually happened at different times. This task is performed before and after the TMS intervention. In addition to this behavioral task, the study uses two caregiver questionnaires to track any changes in symptoms: The Autism Treatment Evaluation Checklist (ATEC) is a brief form filled out by parents. It includes four sections: communication skills, social behavior, sensory awareness, and physical health. It is used to detect broad changes in behavior and well-being. The Short Sensory Profile (SSP) is another caregiver questionnaire that focuses on how children respond to sensory experiences. It includes questions about sensitivity to touch, sound, movement, and visual stimuli. These tools are chosen because they are simple, validated, and commonly used in ASD research. They are also sensitive to changes in daily functioning and sensory behavior. To explore how brain function might change as a result of stimulation, the study uses a technique called functional near-infrared spectroscopy (fNIRS). This is a safe, quiet, and noninvasive method that measures how much oxygen is in the blood within specific brain regions. The child wears a soft cap with small sensors that shine near-infrared light into the scalp. This light reflects back differently depending on how much oxygen is being used in the brain underneath. The sensors are placed over the same area that receives the stimulation (the prefrontal cortex), and the recording is done while the child sits quietly with eyes open. There is no task or performance required-this is simply a measurement of the brain's resting state. Recordings are done once before the stimulation begins and again after the final session. The study also includes a one-time brain scan using magnetic resonance imaging (MRI). MRI provides a detailed image of the structure of the brain, including its size, shape, and thickness in different regions. This helps researchers look for any physical brain characteristics that might explain differences in sensory processing or predict whether a child will respond to the stimulation. The scan is done in a hospital or imaging center using standard pediatric procedures. Children are given headphones, padding, and visual aids to help them feel comfortable and reduce movement. They do not receive any injections or medications. Finally, the study includes a one-time saliva collection to analyze DNA. This is done using a small sterile tube into which the child spits or where saliva is collected using a swab. The sample is stored and later processed in a genetics lab. Researchers analyze specific single-nucleotide polymorphisms in genes known to be involved in brain development and sensory processing. These include genes such as SHANK3, CNTNAP2, NRXN1, and SCN2A. The goal is to determine whether certain gene variants are associated with differences in how children respond to the stimulation or process multisensory information. This part of the study is exploratory and does not involve returning results to families. All procedures are conducted in compliance with safety guidelines for pediatric brain stimulation and neuroimaging. Children are monitored throughout the study, and staff are trained to recognize and manage any discomfort or side effects. The TMS procedures are designed to be brief, well-tolerated, and minimally invasive. Participation is voluntary, and families can withdraw at any time. This research is part of a broader effort to develop personalized approaches to brain stimulation in children with developmental conditions. By combining behavioral tasks, brain imaging, and genetics, the study aims to understand which children are most likely to benefit from neuromodulation and how their sensory systems can be supported. The long-term goal is to inform clinical interventions that are evidence-based, child-centered, and tailored to individual needs. This study is conducted at a research site in Almaty, Kazakhstan and is funded by the Ministry of Science and Higher Education of the Republic of Kazakhstan under grant number IRN BR27198099. Ethical approval was obtained from the Local Ethical Committee of Al-Farabi Kazakh National University (Protocol No. IRB-A843). The study does not involve U.S. FDA-regulated products and is not conducted under an IND or IDE.

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