Segmental Spinal Dysgenesis: Neuroradiologic Findings with Clinical and Embryologic Correlation

Case 10: 2-month-old girl with SSD and associated questionable coccygeal agenesis.

A, Lateral radiograph at age 1 day shows severe hypoplasia and posterior dislocation of L2 (arrow) with absence of posterior vertebral elements. There is marked kyphosis in the upper lumbar spine and questionable absence of the coccyx, as its ossification may be incomplete in the neonate.

B–D, Sagittal SE (600/20/4) (B) and axial SE (600/16/2) (C and D) T1-weighted MR images at age 12 months show that the upper cord ends at the midthoracic level in a wedge shape (open arrow, B) and contains a thin hydromyelic cavity. Below, no cord is discernible even on the axial images (C and D). At the apex of the kyphosis, the spinal canal is extremely narrowed (black arrow, B). Below, a bulky, low-lying lower cord is visible in the thecal sac (white arrow, B) and appears to fill it almost completely (D).

Case 1: 8-month-old boy.

A and B, Sagittal SE T1-weighted MR image (500/14/2) (A) and 3-mm-thick reformatted sagittal MR image obtained from a 3D gradient-echo sequence (20/7/1) with 30° flip angle (80 original 1-mm-thick partitions) (B) at age 9 years. In this case the malformation involves the upper lumbar segment. The degree of kyphosis is moderate, and there is no disconnection of the spinal canal. The upper cord (open arrow, A) is continuous with a hypoplastic cord segment (arrowheads, A). Below, the lower cord (solid arrow, A) is bulky and low-lying. The abrupt change in caliber of the spinal cord may be seen more easily on the reformatted image (arrowheads, B).

fig 5.  Case 5: 5-month-old boy with SSD involving the lumbosacral spine. Sagittal SE T1-weighted (600/20/4) MR image at age 2 years shows marked kyphosis in the lumbosacral spine with absent or undetermined vertebrae. The spinal cord is hypoplastic and blends with the filum terminale, surrounding the dysgenetic vertebral bodies and apparently tethering to the sacrum (arrowheads). Because the dysgenesis involves the lowermost portion of the neural plate, there cannot be a lower cord segment; in fact, this particular case illustrates an overlap between SSD and CRS. There is concurrent hydromyelia in the thoracic spinal cord (arrows).

A, Normal human gastrulation. Prospective endodermal and mesodermal cells of the epiblast migrate toward the midline and ingress (arrows) through defects in the basement membrane at the primitive streak to become definitive endoderm and mesoderm.

B, Normal human gastrulation. Prospective notochordal cells located along the anterior margin of Hensen's node ingress through the primitive pit to become the notochordal process located between the ectoderm and endoderm.

C, Abnormal gastrulation resulting in a failure of midline axial integration. The primitive streak is abnormally wide; prospective notochordal cells therefore begin ingression more laterally than normal. As a result, two notochordal processes are formed. The caudal neuroepithelium, comprising two columns of tissue that flank and are separated by the primitive streak, fails to become integrated to form a single neuroepithelial sheet and instead forms two hemineural plates. The type of resultant malformation depends on the level and extent of the abnormality, and the success of subsequent reparative efforts. Reproduced from (22) with permission of S. Karger AG, Basel, Switzerland.