Clinical Research Directory

Safety and Early Efficacy of iPSC-Derived Motor Neuron Progenitor Cells (XS228) in Subacute Spinal Cord Injury: A Phase I Trial

This Phase I clinical trial is designed to evaluate the safety, tolerability of XS228 ( iPSC-Derived Motor Neuron Progenitor Cells) in patients with Subacute Spinal Cord Injury

Efficacy of iPSC-Derived Motor Neuron Cells (XS228) in Subacute Spinal Cord Injury: A Phase II Randomized Controlled Trial

Purpose: This clinical trial is studying an investigational cell therapy called XS228-a lab-made stem cell product designed to help repair damaged nerves in the spinal cord. The goal is to see if XS228 is safe and can improve movement, sensation, and function in people with recent spinal cord injuries. Study Treatment: XS228 contains specialized nerve-supporting cells derived from human stem cells. These cells are injected into the spinal fluid (intrathecal administration) in a single dose. Who Can Join? Adults aged 18-65 with a spinal cord injury (thoracic or lumbar level) that occurred 2-12 weeks before enrollment. Participants must have severe but incomplete paralysis (ASIA Impairment Scale Grade A , B or C). Study Plan: Phase II (Main Study): About 60 participants will be randomly assigned to receive either XS228 or a placebo (inactive solution) in a 2:1 ratio. Follow-up: Patients will be monitored for 1 year, with regular check-ups to assess safety, nerve function, and recovery progress. What Researchers Are Looking For: Primary Goal: Measure changes in leg and arm function using the ASIA Motor Score at 6 months. Secondary Goals: Improvement in ASIA Impairment Scale (AIS) grade (e.g., from "complete" to "incomplete" paralysis). Recovery of sensation and bladder/bowel control. Safety (monitoring for side effects like infections or immune reactions). Exploratory Tests: MRI scans and biomarker tests in spinal fluid to see if the treatment helps nerve regrowth. Why This Study Matters: If successful, XS228 could become the first stem cell therapy to promote meaningful recovery in spinal cord injury patients. Currently, no treatments exist to repair nerve damage-this trial aims to change that.

Developing Derived Induced Pluripotent Stem Cells as a Model to Understand Imprinted Disorders

Fetal and postnatal growth is finely regulated by genetic, epigenetic and environmental mechanisms. Parental imprinting is a regulatory mechanism that allows monoallelic expression of certain genes from a single parental allele through differential DNA methylation. Imprinted genes play a very important role in the control of fetal and postnatal growth. The pathophysiological mechanisms of these epimutations are largely unknown. Studying the consequences of these epimutations on the molecular signature of the imprinted gene network in these patients would provide a better understanding of the epigenetic mechanisms regulating fetal growth. As these genes are weakly expressed in fibroblasts, these studies will be carried out on pluripotent stem cells or IPSCs (Induced Pluripotent Stem Cells).