The history: Myelomeningocele - also known as spina bifida- is a devastating congenital anomaly of the central nervoussystem that is caused by the malformation of the spinal cordand vertebral column during embryogenes...The history: Myelomeningocele - also known as spina bifida- is a devastating congenital anomaly of the central nervoussystem that is caused by the malformation of the spinal cordand vertebral column during embryogenesis. Depending onthe location of the spina bifida lesion on the spine, patientssuffer from neurological dysfunction ranging from paresisand incontinence to complete paralysis. The current standardof care for spina bifida is in utero surgical repair of the defect,which has been shown to minimize the secondary deficits associatedwith this disorder (Adzick et al., 2011). Despite thesesuccesses, this approach does not reliably improve neurologicfunction of affected children. Several groups, including ourown, have performed studies aimed at augmenting the inutero surgical repair of spina bifida by applying principlesof stem cell and tissue engineering to provide an enhancedprotection of the exposed neural elements (Saadai et al., 2011,2013; Wang et al., 2015; Brown et al., 2016). The ultimategoal of these studies is to improve the neurologic function inpatients while maintaining the benefits of the existing fetalsurgical treatment.展开更多
基金supported by NIH(No.5R01NS100761-02,5R03HD091601-02)Shriners Hospital for Children research grants(No.87410-NCA-17 and 85119-NCA-18)March of Dimes Foundation(No.5FY1682)to AW
文摘The history: Myelomeningocele - also known as spina bifida- is a devastating congenital anomaly of the central nervoussystem that is caused by the malformation of the spinal cordand vertebral column during embryogenesis. Depending onthe location of the spina bifida lesion on the spine, patientssuffer from neurological dysfunction ranging from paresisand incontinence to complete paralysis. The current standardof care for spina bifida is in utero surgical repair of the defect,which has been shown to minimize the secondary deficits associatedwith this disorder (Adzick et al., 2011). Despite thesesuccesses, this approach does not reliably improve neurologicfunction of affected children. Several groups, including ourown, have performed studies aimed at augmenting the inutero surgical repair of spina bifida by applying principlesof stem cell and tissue engineering to provide an enhancedprotection of the exposed neural elements (Saadai et al., 2011,2013; Wang et al., 2015; Brown et al., 2016). The ultimategoal of these studies is to improve the neurologic function inpatients while maintaining the benefits of the existing fetalsurgical treatment.
