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AUTHOR AND EDITOR INFORMATION

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Author: Ali Nawaz Khan, MBBS, FRCS, FRCP, FRCR, LRCP, Chairman of Medical Imaging, Professor of Radiology, NGHA, King Fahad National Guard Hospital, King Abdulaziz Medical City, Riyadh, Saudi Arabia

Ali Nawaz Khan is a member of the following medical societies: American Institute of Ultrasound in Medicine, Radiological Society of North America, Royal College of Physicians, Royal College of Physicians and Surgeons of the United States, Royal College of Radiologists, and Royal College of Surgeons of England

Coauthor(s): Nigel Thomas, MBBS, Vice-Chair, Manchester (North) Research Ethics Committee; Honorary Lecturer, Visiting Professor, University of Salford, UK; Sumaira MacDonald, MBChB, PhD, MRCP, FRCR, Lecturer, Sheffield University Medical School; Endovascular Fellow, Sheffield Vascular Institute; Hemalatha Chandramohan, MBBS, Staff Physician, Department of Geriatric Medicine, Stepping Hill Hospital, United Kingdom

Editors: Harris L Cohen, MD, FACR, Vice Chairman/Associate Chairman (Research Activities), Director, Division of Body Imaging, Professor of Radiology, Stony Brook School of Medicine; Visiting Professor of Radiology, Johns Hopkins School of Medicine; Bernard D Coombs, MB, ChB, PhD, Consulting Staff, Department of Specialist Rehabilitation Services, Hutt Valley District Health Board, New Zealand; Karen L Reuter, MD, FACR, Professor, Department of Radiology, Lahey Clinic Medical Center; Robert M Krasny, MD, Consulting Staff, Department of Radiology, The Angeles Clinic and Research Institute; Eugene C Lin, MD, Clinical Assistant Professor of Radiology, University of Washington Medical School

Author and Editor Disclosure

Synonyms and related keywords: exomphalos, anterior abdominal wall defect

INTRODUCTION

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Background

Omphalocele is an anterior abdominal wall defect at the base of the umbilical cord, with herniation of the abdominal contents. The herniated organs are covered by the parietal peritoneum. After 10 weeks' gestation, the amnion and Wharton jelly also cover the herniated mass. 1, 2, 3 4

Omphaloceles are associated with other anomalies in more than 70% of the cases. Most associated anomalies are chromosomal. The anomaly is detected during routine ultrasonographic examination of the fetus or during an investigation of an increased alpha-fetoprotein (AFP) level.

Pathophysiology

The etiology of omphalocele is not known. Various theories have been postulated; these include failure of the bowel to return into the abdomen by 10-12 weeks, failure of lateral mesodermal body folds to migrate centrally, and persistence of the body stalk beyond 12 weeks' gestation.4

Associated anomalies are common (45-88%); the severity of the associated anomalies determines the prognosis.5 Chromosomal anomalies are common. It is thought that a chromosomal anomaly is more likely when oligohydramnios or polyhydramnios complicates the pregnancy. It has been reported that omphaloceles containing only bowel have a higher incidence of karyotypic abnormalities.6, 7

The associated anomalies include the following:

  • Chromosomal anomalies (40-60%): These include trisomies 18,13, and 21 and also Turner, Klinefelter, and triploidy syndromes.
  • Cardiac defects (16-47%): These include ventricular and atrial septal defects, tetralogy of Fallot, pulmonary artery stenosis, pulmonary hypoplasia, a double-outlet right ventricle, bicuspid aortic valve syndrome, transposition of the great vessels, coarctation of the aorta, ectopia cordis, and absence of the inferior vena cava.8
  • Respiratory insufficiency is occasionally seen in association with a giant omphalocele. 
  • Genitourinary anomalies (40%): These include bladder extrophy and omphalocele, bladder extrophy, imperforate anus and spinal anomalies (OEIS) complex; obstruction of the ureteropelvic junction; renal malpositioning (cephalic renal displacement)9; cloacal extrophy; and isolated imperforate anus.10
  • Neural tube and head and neck anomalies: These include neural tube defects, holoprosencephaly, encephalocele, cerebellar hypoplasia, cleft lip, facial clefts, micrognathia, and cystic hygroma.11
  • Gastrointestinal anomalies (40%): These include diaphragmatic hernia, malrotation, intestinal duplications, atresias, and ascites, absence of the gallbladder, abnormal fixation of the liver, tracheoesophageal fistula, and imperforate anus.12
  • Musculoskeletal anomalies (10-30%): These include limb-body wall deficiency (LBWD), scoliosis, hemivertebra, camptomelic dwarfism, clubfeet, and syndactyly, as well as other digital anomalies.
  • Maternal/fetal developmental abnormalities: These include oligohydramnios, polyhydramnios, intrauterine growth restriction (IUGR), single umbilical artery, allantoic cysts, placental chorioangioma, and fetal immaturity and prematurity.
  • Beckwith-Wiedemann syndrome (5-10%): This encompasses a group of disorders involving an omphalocele, macroglossia, and visceromegaly.

One study has shown that periconceptional multivitamin use is associated with a 60% reduction in the risk of nonsyndromic omphalocele.13, 14 These findings await replication.

Another study has shown that women younger than 20 years are at an increased risk for gastroschisis during pregnancy, whereas those aged 40 years or older are disproportionately more likely to have a pregnancy affected by an omphalocele.15, 16, 17, 18, 19

Related eMedicine topics:
Beckwith-Wiedemann Syndrome

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Frequency

United States

Small omphaloceles occur with a rate of 1 case in 5000 live births. Large omphaloceles occur with a rate of 1 case in 10,000 live births.

International

The frequency in the United Kingdom and in continental Europe is the same as that in the United States.20, 21

Mortality/Morbidity

The prognosis depends on the associated anomalies. The mortality rate is 80% when associated anomalies are present, and it increases to 100% when chromosomal and cardiovascular abnormalities are present.22, 23, 24, 25

  • When an omphalocele is an isolated abnormality, the prognosis is good, and the mortality rate is around 10%.
  • Excluding pregnancy termination, over half the fetuses with an omphalocele will die.
  • Complications include infection, inanition, immaturity, hernia rupture, and intestinal obstruction. Infection and surgical complications are responsible for as many as 13% of deaths. Low birth weight causes more than 10% of deaths.
  • An association with oligohydramnios and polyhydramnios portends a worse prognosis.
  • The size of the omphalocele does not affect the prognosis.
  • Whether the presence of fetal ascites is an indicator of a poorer prognosis is controversial. The incidence of associated anomalies is higher in a prenatal series as compared with a postnatal series. This observation is not surprising because many severely affected fetuses die in utero and are never seen by a surgeon.

Race

A study from Hawaii has shown that Pacific Islanders have a low risk of omphalocele, whereas Far East Asians have a low risk of gastroschisis.

Sex

The male-to-female ratio is 1:1.

Age

The earliest that an omphalocele can be detected is at 12 weeks of menstrual age. Woman aged 40 years or older are disproportionately more likely to have a fetus with an omphalocele.

Anatomy

Physiologic umbilical herniation occurs during the eighth week of development when the fetal midgut extends into the extraembryonic celom, occupying the proximal segment of the umbilical cord. This herniation is associated with the development of normal bowel rotation in fetal life.26

The bowel undergoes a 270° counterclockwise rotation, the first 90° of which occurs by week 10, extracoelomically at the base of the umbilicus. The remaining 180° clockwise turn occurs after the bowel returns to the abdomen. Rotation occurs around the axis of the superior mesenteric artery. Theoretically, this may occur because of the large fetal liver and kidneys and because the rapid development of midgut outgrows the abdominal cavity at this stage of development. The midgut returns to the abdominal cavity at 12 weeks of menstrual age.

One of the theories regarding the cause of omphaloceles is failure of the bowel to return to the abdomen. Physiologic umbilical herniation should not persist beyond 12 weeks of gestation. After 12 weeks' gestation, one must consider omphalocele as the cause of mass in the base of the umbilical cord and beyond the confines of the abdominal wall.

Results of ultrasonographic studies suggest that in differentiating between normal physiologic herniation and a concern for omphalocele, one should note that physiologic midgut herniation should not exceed 7 mm in diameter and that physiologic herniation should not be apparent in fetuses with a crown-rump length greater than 44 mm.

Clinical Details

The anomaly is usually detected during routine ultrasonographic surveillance, during an investigation of a disparity of uterine size with time from conception or other obstetric indications, or during an evaluation of an increased maternal serum AFP level. Omphaloceles and gastroschisis are 2 open, ventral wall defects that are detected by means of AFP measurement. Acetylcholinesterase levels may also be increased.27

A weak band of acetylcholinesterase can be detected on chromatography. This finding is thought to be related to the proximity of nerve terminations to the amniotic fluid.28

Preferred Examination

Ultrasonography is an inexpensive, safe, noninvasive real-time technique that is widely available. It remains the imaging modality of choice for the prenatal assessment of the fetus. In experienced hands, ultrasonography is highly accurate in the diagnosis of most complications associated with pregnancy. It is also used as a guide to intervention in pregnancy.

At present, the use of MRI in pregnancy is limited. As more experience is gained, fetal MRI may play a greater role in anomaly analysis. Prenatal MRI is at times a useful adjunct to ultrasonography and may enhance fetal anatomic evaluation when complex anomalies are suspected. MRI facilitates perinatal management and parental counseling.29, 30, 31, 32, 33, 34

Limitations of Techniques

A significant regional variation in the ultrasonographic detection of fetal abdominal wall defects has been described in Europe.20 This variation reflects differences in screening policies, equipment, and operator experience.35

The rate of selective termination still appears to be relatively high, even in cases of omphalocele, without other evident anomalies, which generally have a good prognosis. Although ultrasonography is an accurate and sensitive means for detecting fetal anomalies, it still has limitations, and its dependence on operator skill is a major disadvantage.

Besides the limited availability of MRI, its safety issues have not been completely resolved. Prudence currently dictates that MRI be used in the first trimester only if a clear medical indication is present and only when it offers a definite advantage over ultrasonography.


DIFFERENTIALS

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Gastroschisis
Omphalocele

Other Problems to Be Considered

Physiologic bowel herniation

Physiologic herniation occurs at 10-13 weeks' gestation. The best method for differentiating this from an omphalocele is repeat sonography after 15 weeks' menstrual age. A large defect with liver exteriorized indicates an omphalocele at any gestational age.36

Umbilical hernia

An umbilical hernia is due to a defect in the linea alba, subcutaneous tissues, and skin covering the protruding bowel. Umbilical hernias are common in the first months in 20% of African-American infants and in 3% of white neonates. It is frequent in premature infants, occurring in more than 5% of those weighing less than 1500 g.

Ultrasonography reveals a prominent bulge of the anterior abdominal wall that contains omentum and/or bowel. This may protrude into the umbilical cord. Amniotic-fluid AFP levels may be elevated when the bowel herniates into the umbilical cord.

Gastroschisis

Gastroschisis results from herniation of the bowel, and rarely other structures, through a small (2-5 cm) off-midline abdominal wall defect. This herniation protrudes into the amniotic cavity, usually in the right paraumbilical region. No covering membrane is present. Gastroschisis is thought to result from a vascular event to the omphalomesenteric artery.

Affected patients have malrotated bowel. Vascular compromise may occur from a volvulus, and it may result in bowel obstruction, ischemia, or atresia. Bowel-wall thickening may occur, perhaps in part due to the reaction of bowel (without a membrane separating it) with amniotic fluid. Besides malrotation, gastroschisis is not associated with other abnormalities. Affected patient karyotypes are normal. The prognosis is usually favorable. The presence of liver and spleen herniation has been reported to modify the prognosis and workup. The pancreas, stomach, bladder, uterus, ovaries, and fallopian tubes may also be herniated.

Amniotic band syndrome

Amniotic band syndrome (ABS) is a common cause of abdominal wall defects; in appearance, it may be similar to gastroschisis. An atypical location of the abdominal wall defect should suggest the diagnosis of ABS. Membranes contiguous with such a defect may be identified.

Extrophy of the urinary bladder

Sonographically, bladder extrophy may appear as an external, well-defined, solid or complex mass immediately superior to the fetal genitalia. Prolonged and repeated scans fail to reveal the fetal bladder. The renal collecting system and ureters need not be dilated, and unilateral or horseshoe kidneys may be found. Uterine and adnexal anomalies are relatively frequent. The pubis is abnormally wide, and the umbilical cord insertion may be abnormal.

Thoracoabdominal pentalogy of Cantrell

Ectopia cordis associated with a ventral wall defect should suggest the diagnosis of the pentalogy of Cantrell. This syndrome is often associated with other anomalies.37

Cloacal extrophy

Cloacal extrophy consists of a low omphalocele; bladder or cloacal extrophy; and frequently, other caudal anomalies, including meningomyelocele anal atresia and lower-limb anomalies. Most affected fetuses have a single umbilical artery. Ultrasonography usually shows a low, anterior abdominal mass below the umbilical cord; this is associated with absence of the urinary bladder.

Limb-body wall complex

Limb-body wall complex (LBWC) is a lethal condition with severe anterior abdominal wall defect. The defect is lateral and involves the size of the umbilical cord insertion point. The abdominal contents lie outside within a sac of amnion and mesoderm. LBWC is frequently associated with congenital heart disease, cranial anomalies (encephalocele), limb abnormalities, and scoliosis. Chromosomal defects are usually absent.

Multiple cavernous hemangiomas

Multiple cavernous hemangiomas are most frequently found over the lower body. They are often associated with Klippel-Trenaunay-Weber syndrome, which is diagnosed in the presence of multiple surface masses that cause limb hypertrophy. Hydrops may occur.

Pseudo-omphalocele

During scanning of the fetal abdomen, pressure from the transducer may give an impression of an omphalocele, particularly during scanning in an oblique plane. The angle formed between such a pseudomass and the fetal abdominal wall is usually obtuse.

A pseudo-omphalocele may also occur as a result of oligohydramnios or compression of the lateral thoracic wall from other causes. With medial compression of the lower thoracic wall, the abdomen may have an hourglass-like appearance when imaged in a transverse plane. Omphalocele associated with oligohydramnios is exceptionally rare.


MRI

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Findings

Prenatal MRI enhances the fetal anatomic evaluation; it can be a valuable adjunct to ultrasonography before surgical intervention for selected life-threatening fetal defects. MRI helps in corroborating and refining the ultrasonographic diagnosis of complex fetal defects.

The prognosis and mortality rate in omphalocele is determined more by the presence of associated anomalies, such as cardiovascular and chromosomal defects, than by the omphalocele itself. Prenatal MRI can be used to screen for anomalies such as complex cardiac defects and nervous system anomalies.

Degree of Confidence

The diagnostic accuracy of MRI has been reported to be superior to that of sonography in selected cases of cerebral malformations because of the high resolution of the soft tissues and because of its more global depiction of complex fetal disorders.

Unlike ultrasonography, MRI is not operator dependent. Imaging, however, is dependent on magnet strength and the pulse sequences chosen. The field of view obtained with MRI is larger than that obtained with sonography; the large field of view allows good anatomic orientation. MRI is not limited by maternal obesity or oligohydramnios. Fetal movement can make MRI difficult.

MRI is considered safe for the developing fetus. At present, no clinical or experimental evidence suggests that MRI causes teratogenic or other adverse affects during pregnancy, although a few studies in laboratory animals have shown that prolonged, high-level exposure to electromagnetic radiation might result in teratogenicity. A recommendation from the National Institute of Health Consensus Development Conference states, "MRI should be used during the first trimester pregnancy only when there are clear medical indications and when it offers clear advantage over other modalities."

False Positives/Negatives

The fine detail of internal structures of the abdomen and pelvis is not well demonstrated with fast T2-weighted sequences.


ULTRASOUND

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Findings

An omphalocele is diagnosed when a fetal anterior midline abdominal mass is demonstrated. The mass consists of abdominal contents that have herniated through a midline central defect at the base of umbilical cord insertion. The mean size of the defect is 2.5-5 cm. The mass has a smooth surface and contains abdominal viscera, usually the liver, bowel, and stomach (see Images 1-2). The covering of the mass, which comprises the peritoneum and amnion, may rarely rupture. The membrane is not always visible. Wharton jelly may be detectable as a hypoechoic lining between the layers of the covering of the membrane.

The umbilical cord attaches to the apex of the herniated mass, where the umbilical vein can be seen within the mass. The cord may be widened where it joins the fetal skin.

Fetal ascites is common and is seen within the herniated sac. Polyhydramnios, and occasionally oligohydramnios, may be present. Other major anomalies may be apparent in as many as 70% of cases.

A number of sonographic features differentiate an omphalocele from a physiologic midgut herniation (see Images 3-4). A midgut herniation seldom exceeds 7 mm in diameter, whereas omphaloceles are much larger. Midgut herniation is invariably smaller in diameter than the abdomen, whereas the diameter of an omphalocele can be larger than that of the abdomen. The size of the omphalocele is best measured by using the ratio of the transverse diameter of the omphalocele to the transverse diameter of the abdomen. A midgut herniation seldom persists after 12 weeks of gestation or in a fetus with a crown-length measurement of more than 44 mm.

When the ratio of the diameter of the omphalocele to the transverse diameter of the abdomen is less than 60%, the lesion usually contains bowel and not liver (see Image 5). The relative size of the omphalocele may decrease during pregnancy.

A measurement of the ratio of the transverse area of the lung to that of the thorax may be useful in predicting associated pulmonary hypoplasia in a giant omphalocele. However, antenatal detection requires prolonged ventilation, which may be difficult and requires further study.12, 38, 39, 40

Degree of Confidence

Ultrasonography is a sensitive technique, but it remains operator dependent. Its great advantage is that it can be quickly and frequently repeated as required. A definitive diagnosis of omphalocele is possible only beyond 12 weeks' gestation, when confusion with physiologic midgut herniation is no longer possible.

False Positives/Negatives

An anterior abdominal-wall mass has a wide differential diagnosis. It may be difficult to differentiate between a midline omphalocele and physiologic midgut herniation in early pregnancy; it may also be difficult to differentiate omphalocele from bowel herniation of gastroschisis.

Gastroschisis usually poses no problems of differentiation from an omphalocele. The only finding that the 2 share is that they both arise from the anterior abdominal wall. Gastroschisis has no membranous covering and usually presents with a ragged edge, which almost never contains liver. In addition, gastroschisis is typically right-sided, with the umbilical cord entering the abdomen to the left of the herniation (rather than on the herniation, as in an omphalocele). Spontaneous rupture of an omphalocele membrane may cause problems in differentiation, but this is so rare that it should seldom enter the differential diagnosis.


INTERVENTION

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Diagnostic amniocentesis is indicated when an omphalocele is suspected on antenatal sonograms. Amniocentesis may also be performed in the investigation of an increased maternal AFP level.41

Medical/Legal Pitfalls

  • Investigators assessing the accuracy of routine ultrasonography in detecting fetal anterior abdominal-wall defects reported a detection rate of 60%, with a false-positive rate of 5.3%.42
    • In this study, sonographic examination was performed between weeks 16 and 22 in an unselected population.
    • Fetuses with gastroschisis were incorrectly identified as having exomphalos in 14.7% of cases recognized before week 22.
    • The diagnosis of associated, detectable anomalies was accurate in 71.6% of cases.
  • The diagnostic problems with ultrasonography must be considered when couples are counseled about a possible fetal anomaly.
  • In a tertiary referral center, the detection of anomalous fetuses was shown to be significantly better with targeted ultrasonography than with routine ultrasonographic screening.43
  • Currently, no convincing evidence supports the routine use of cesarean delivery in the management of fetal anterior wall defects.44
    • Most babies with abdominal wall defects should be delivered in a tertiary referral center where neonatal and surgical expertise is readily available.
    • In every case, an antenatal diagnosis should lead to parental counseling and decision making by a multidisciplinary team.

See also the Medscape topic Medical Malpractice and Legal Issues.


Special Concerns

  • The fear of a second omphalocele may dominate the reproductive choices of potential parents, although the recurrence rate is quoted as being less than 1%.
  • In some families, an omphalocele is inherited as an autosomal dominant or X-linked recessive trait. In these families, the likelihood of recurrence is higher than in others.
  • The finding of an omphalocele should prompt a targeted ultrasonographic examination to search for associated anomalies. Fetal echocardiography and karyotyping should be performed as well.
    • The finding of associated anomalies before fetal viability should be discussed with the parents so that they can make an informed choice about terminating the pregnancy.
    • After viability, surgical intervention during delivery should be avoided in the presence of associated anomalies.
  • Fetuses with an isolated omphalocele should be delivered in a tertiary referral center. The available data do not support a policy of cesarean delivery of babies with abdominal wall defects.


MULTIMEDIA

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Media file 1:  Sagittal antenatal scan in a 13-week-old fetus shows an omphalocele-containing liver.
Click to see larger pictureClick to see detailView Full Size Image
Media type:  Image

Media file 2:  Sagittal antenatal scan on a 13- or 14-week-old fetus shows an omphalocele-containing liver.
Click to see larger pictureClick to see detailView Full Size Image
Media type:  Image

Media file 3:  Axial sonogram through the mid abdomen of a fetus shows exteriorized bowel in relation to the anterior abdominal wall. Multiple loops of bowel are apparent. Because the bowel loops are not covered, they have irregular edges. L indicates the liver.
Click to see larger pictureClick to see detailView Full Size Image
Media type:  Image

Media file 4:  Axial sonogram through the mid to upper abdomen shows free-floating exteriorized bowel in relation to the anterior abdominal wall. S indicates the stomach; V, spine.
Click to see larger pictureClick to see detailView Full Size Image
Media type:  Image

Media file 5:  Diagram of the transverse section of the fetal abdomen shows gastroschisis. Note the bowel herniation in the right paramedian/paraumbilical region. The cord is inserted in the normal location to the left of the herniation. No membranous covering exists over the herniated bowel.
Click to see larger pictureClick to see detailView Full Size Image
Media type:  Image


REFERENCES

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Omphalocele excerpt

Article Last Updated: Apr 7, 2008