In utero meconium exposure increases spinal cord necrosis in a rat model of myelomeningocele

In utero meconium exposure increases spinal cord necrosis in a rat model of myelomeningocele

Background/Purpose: The rationale for in utero repair of myelomeningocele has been supported experimentally by the observation of preserved neural function after prenatal closure of surgically created defects compared with nonrepaired controls. The mechanism of injury to the exposed neural elements...

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Bibliographic Details
Published in:Journal of pediatric surgery Vol. 37; no. 3; pp. 488 - 492
Main Authors: Correia-Pinto, Jorge, Reis, Joaquim L., Hutchins, Grover M., Baptista, Maria J., Estev[atilde]o-Costa, Jos[eacute], Flake, Alan W., Leite-Moreira, Adelino F.
Format: Journal Article Conference Proceeding
Language:English
Published: Philadelphia, PA Elsevier Inc 01-03-2002
Elsevier
Subjects:
Amniotic Fluid - physiology
Animals
Biological and medical sciences
Cerebrospinal fluid. Spinal cord. Spinal roots. Spinal nerves
Disease Models, Animal
Female
Humans
Infant, Newborn
Male
Meconium - physiology
Medical sciences
Meningomyelocele - pathology
Meningomyelocele - physiopathology
Necrosis
Neurosurgery
Pregnancy
Rats
Spinal Cord - pathology
Surgery (general aspects). Transplantations, organ and tissue grafts. Graft diseases
Uterus - physiology
Animal model
Nervous system diseases
Corrective surgery
Spinal cord
Pathophysiology
Rat
Rodentia
Congenital disease
In utero
Necrosis
Vertebrata
Mammalia
Treatment
Malformation
Surgery
Animal
Amniotic fluid
Central nervous system disease
Meconium
Fetus
Myelomeningocele
Spinal cord disease
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Summary:Background/Purpose: The rationale for in utero repair of myelomeningocele has been supported experimentally by the observation of preserved neural function after prenatal closure of surgically created defects compared with nonrepaired controls. The mechanism of injury to the exposed neural elements is unknown. Postulated mechanisms include trauma to the herniated neural elements or progressive injury from amniotic fluid exposure as gestation proceeds. A component of amniotic fluid that may contribute to neural injury is meconium. In the current study the effect of human meconium on the exposed spinal cord in a fetal rat model of myelomeningocele was examined. Methods: Twenty time-dated pregnant rats underwent laparotomy at 18[frac12] days of gestation. The exposed uterus was bathed in ritrodrine for tocolysis. The amniotic cavity was opened over the dorsal midline of the fetal rat, and, under a dissecting microscope ([times ]25), a 2- to 3-level laminectomy was performed. Under magnification ([times ]40), the translucent dura was opened using a 25-gauge needle as a knife. Two fetuses per dam were operated on. In the control group, the amniotic fluid was restored with saline solution, whereas in the experimental group a solution of Human meconium diluted (10%) in saline was used to restore the amniotic fluid. Fetuses were harvested by cesarean section at 21[frac12] days' gestational age. The liveborn pups were then killed and fixed in 10% formaline. Sections 10 [mu ]m thick were stained with H[amp ]E and studied by light microscopy for evidence of spinal cord injury. Results: Seven of 20 (35%) experimental rat pups and 6 of 20 (30%) control rat pups were liveborn. All liveborn pups had severe paralysis of the hindlimbs and tail, so that functional differences between the 2 groups could not be detected. Histologic examination of 13 spinal cords at the site of surgical exposure showed that necrosis of neural tissue in 5 of 7 meconium-exposed rat pups was increased when compared with that observed in the 6 fetuses exposed to amniotic fluid without meconium. In general, inflammation was greater and repair processes appeared delayed in meconium-exposed rat pups. Conclusions: Exposure of the spinal cord of fetal rats to amniotic fluid by surgically created myelomeningocele leads to severe functional impairment. Histologically recognizable necrosis of neural elements was increased in those animals that were exposed to diluted human meconium in the amniotic fluid. The results support the hypothesis that meconium may contribute to the pathophysiology of spinal cord injury observed in myelomeningocele.
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ISSN:0022-3468
1531-5037
DOI:10.1053/jpsu.2002.30872