Clinical Research Directory

Optical Imaging in X-linked Disorders.

Fragile X syndrome (FXS, OMIM #300624) and Creatine Transporter Deficiency (CTD, #300352) are the two most common causes of X-linked intellectual disability. FXS and CTD affect hemizygous males and with highly variable severity heterozygous females. Both these neurodevelopmental disorders (NDDs) have a dramatic impact on the family quality of life and the health-care system. These disorders share common clinical traits, including intellectual disability, autistic-like features, behavioural and mood alterations and seizures. Brain anatomy appears largely normal, suggesting that functional deficits result from subtle changes in synaptic connectivity. Moreover, common physiological mechanisms related to brain energetics might concur to the pathophysiology of FXS and CTD. Indeed, FMR1 and SLC6A8 are directly involved in the regulation of metabolism and the loss-of-function of both genes leads to a disruption of the mitochondrial network. There is no cure for these disorders and the efficacy study of potential treatments is hindered by the scarcity of unbiased, quantitative, non-invasive biomarkers for monitoring brain function. This is a critical problem, since the often-used phenotypic observation of behavioural endpoints to score NDDs such as FXS and CTD is highly prone to subjective bias. For successful clinical trials, the availability of objective readouts is crucial to evaluate the therapeutic response to new drugs. There are multiple techniques to visualize neural circuit activity in the living brain. Interestingly, FXS and CTD are the only two NDDs that at preclinical level show an abnormally large hemodynamic response to sensory stimulation in functional imaging studies of intrinsic optical signals. The objective of this project is to exploit optical imaging techniques to devise a measurable and non-invasive biomarker of brain function in FXS and CTD. Since a disruption of brain energy metabolism is a major disease mechanism linking these disorders, we hypothesized that the assessment of the cerebral blood flow and oxygen consumption represents a sensitive readout for quantifying functional alterations of neural circuits. Functional near-infrared spectroscopy (fNIRS), allows quantifying changes of hemoglobin species and local blood flow in the cerebral cortex of humans, providing an indirect measure of neuronal activity. In the clinical framework, this blood-oxygen-level-dependent signal is similar to that detected with functional MRI (fMRI). However, fNIRS has the advantage of being completely non-invasive, low-cost, portable, noiseless, endowed with high experimental flexibility and easy to implement in both laboratory and clinical settings. Moreover, fNIRS is more tolerant to motion artifacts than fMRI, and robust methods for motion detection/correction allow to image very young children without sedation. These methodological strengths make fNIRS as an outstanding choice for investigating neural circuits in clinically relevant populations at the very-low cost. Although introduced into the clinical care almost 40 years ago, fNIRS gained much popularity in the study of brain development and NDDs only recently. To date, however, fNIRS has been used primarily to investigate the typical maturation of speech perception and language, sensory and motor functions, social communication and interaction, object and action processing in toddlers and children. In this proposal, the investigators hypothesize that by combining the above-mentioned strengths of fNIRS to the clinical study of several cognitive and motor parameters, the investigators can define unique "fNIRS signatures" for FXS and CTD as brain biomarkers for the diagnosis and the assessment of treatment outcomes. Since the measurement of visual responses has been introduced as a quantitative method to assess brain function in NDDs, the investigators will test the value of visually-evoked fNIRS signals in classifying patients and predicting symptom severity in the FXS and CTD clinical population. Preliminary data in the mouse models of CTD and FXS strongly suggest that visual hemodynamic responses (vHDR) are markedly altered in the occipital cortex of mutant animals. Morever, the investigators will use a standardized procedure with high entertaining value to measure vHDR in the occipital cortex of children.

Intensive Multimodal Neurorehabilitation Targeting Neuroplasticity in Pediatric Neurodevelopmental and Chromosomal Disorders

This observational study evaluates functional and developmental outcomes in pediatric participants undergoing a two week intensive multimodal neurorehabilitation program. The program is designed for children with neurodevelopmental disorders, including but not limited to cerebral palsy, autism spectrum disorder, developmental delay, hypoxic ischemic encephalopathy (HIE), and chromosomal or genetic abnormalities. Participants receive individualized therapy sessions for approximately 2.5 hours per day over a two week period. The intervention is not standardized but is tailored to each child's specific needs and may include components such as sensory integration, motor planning, reflex integration, oculomotor training, executive functioning activities, communication support, and other brain based therapeutic approaches. The purpose of this study is to observe changes in functional abilities, including attention, motor coordination, emotional regulation, communication, and activities of daily living. Outcomes are assessed using clinician observation and parent reported changes before and after the intensive program, with limited follow-up when available. This study does not assign participants to a specific treatment as part of a research protocol. Instead, it collects real world data from children already participating in a clinical therapy program to better understand potential benefits of intensive, individualized neurorehabilitation approaches.

A Study to Investigate the Effects and Safety of SPG601 for the Treatment of Fragile X Syndrome in Male Participants

This Phase 2b/3, randomized, double-blind, placebo-controlled, 2-part study will evaluate the efficacy, safety and tolerability of different dose regimens of SPG601 in adult male participants with Fragile X syndrome.

The Neurocognitive Bases of Trust in Intellectual Disability

This project studies the neurocognitive basis of trust adjustment in intellectual disability (ID), a source of significant vulnerability for these patients, focusing on two target populations chosen for their specific social characteristics: people with Down syndrome, who are often described as being hypersocial, and people with Fragile X syndrome, who are often characterized by a completely opposite social behaviour profile, with a withdrawn attitude and significant social anxiety. The three different types of mechanisms that contribute to the adjustment of interpersonal trust: affective evaluation, trait attribution, and epistemic evaluation of informants, will be studied. Affective evaluation processes recruit subcortical structures such as the amygdala and assess potential social threats in the environment. The second mechanism for selecting whom to trust consists of forming a representation of a person's dispositions, such as benevolence and competence (also known as traits), and using it to predict that person's future behaviour. Trait attribution processes recruit a cortico-cerebellar network comprising the mPFC, CRUS I and posterior lobule VI. The third mechanism, called epistemic vigilance, allows to adjust our trust in what others communicate to us. This mechanism involves linking the assessment of the reliability of individuals who communicate (based on their benevolence and competence) with the reliability of the communicated information. Epistemic assessment involves frontal areas and areas associated with the representation of mental states in order to enable the evaluation of the truthfulness of the communicated information. All of these mechanisms become functional very early on, before a child's sixth birthday. There are reasons to expect that several of these central mechanisms supporting selective trust will behave atypically in intellectual disability.

Group CBT in Adolescents With Fragile X Syndrome and in Adolescents With Autism Spectrum Disorder

Fragile X Syndrome (FXS) is a rare genetic syndrome, caused by a mutation in the FMR1 gene located on the X chromosome. It is considered the leading hereditary cause of intellectual disability (ID) and the primary cause of Autism Spectrum Disorder (ASD) due to a single gene-mutation. Many individuals with FXS exhibit symptoms overlapping with those of ASD, including difficulties in social-communication skills, challenges in peer relationships, restricted and repetitive behaviors/interests and deficits in adaptive functioning. Both in ASD and FXS, individuals with greater deficits in executive functions, socio-pragmatic, and socio-relational skills also demonstrate lower adaptive functioning and, consequently, reduced autonomy/independence throughout the life course and greater severity of the disorder. Among empirically validated treatments recommended by National and International Guidelines for the treatment of ASD, cognitive-behavioral and psychosocial interventions have been shown to improve some aspects of ASD, such as core symptoms, emotional-behavioral disturbances, adaptive skills, and quality of life. Currently, it appears that cognitive-behavioral therapies, which include psychoeducation programs, are particularly appropriate for ASD, with greater efficacy for group interventions compared to individual ones. Regarding FXS, despite the well-established knowledge of the cognitive-behavioral phenotype and the clear need for scientifically validated programs, research on intervention strategies remains quite limited. Considering the similarities between ASD and FXS and the need for standardized interventions, the present research project aims to conduct an RCT to evaluate the feasibility of Cooperative Group Therapy (CGT) in two different groups of adolescents with ASD and FXS. The decision to target the intervention to adolescents is due to the few clinical studies on this age group, which is a crucial target since, in FXS, there is often a plateau or reversal of intellectual and adaptive development after the age of 10, and in adolescents with ASD, the development and complexity of social, pragmatic skills, and executive functions are crucial for good adaptive functioning and a basic quality of life. Te main hypothesis is that CGT could contribute to the reduction of severity illness and in the enhancement of socio-communicative skills.