Clinical Research Directory

Fetoscopic Repair of Isolated Fetal Spina Bifida

The purpose of this investigation is to evaluate maternal and fetal outcomes following fetoscopic repair of fetal spina bifida at the Johns Hopkins Hospital. The hypothesis of this study is that fetoscopic spina bifida repair is feasible and has the same effectiveness as open repair of fetal spina bifida, but with the benefit of significantly lower maternal and fetal complication rates. The fetal benefit of the procedure will be the prenatal repair of spina bifida. The maternal benefit of fetoscopic spina bifida repair will be the avoidance of a large uterine incision. This type of incision increases the risk of uterine rupture and requires that all future deliveries are by cesarean section. The use of the minimally invasive fetoscopic surgical technique may also lower the risk of preterm premature rupture of membranes and preterm birth compared to open fetal surgery. Finally, successful fetoscopic spina bifida repair also makes vaginal delivery possible.

The Role of CSF in Chiari II Brain Malformation

Spina bifida, particularly its most severe form known as open spina bifida (myelomeningocele), is a significant congenital disorder that results in profound neurological impairments, including Chiari II malformation. This malformation is associated with the downward displacement of the cerebellum and brainstem into the spinal canal, often leading to hydrocephalus, a condition where cerebrospinal fluid (CSF) accumulates in the brain1. These conditions can result in a range of complications, including cognitive and motor disabilities, learning difficulties, and, in severe cases, early mortality1,2. While surgical interventions, including prenatal and postnatal surgeries, have been developed to manage the physical manifestations of spina bifida and Chiari II malformation, these procedures have not been fully successful in addressing the associated brain anomalies3. This study aims to explore the hypothesis that the composition of CSF plays a critical role in the development of these brain defects. Specifically, it is hypothesized that the rapid replenishment of CSF, due to its leakage from the open spine in spina bifida, results in a "less mature" fluid composition, which negatively affects neurogenesis and neuronal migration during critical periods of brain development.