First trimester scan, which is routinely performed between 11 and 13 weeks and 6 days gestation, is a well-established study for routine aneuploidy screening, but it also facilitates anatomical assessment allowing early diagnosis of structural anomalies(1). ISUOG (International Society of Ultrasound in Obstetrics and Gynecology) practice guidelines for first trimester scan require identification of the fetal head, appropriate development of cranial bones, and identification of choroid-plexus and cerebral ventricles(2). Cranial ossification should be visible from the 11th week onwards.
Acrania-exencephaly-anencephaly sequence is a rare malformation with an estimated incidence ranging between 3.68 to 5.4 for 10,000 live births(3). A Danish group(3) demonstrated that two-dimensional (2D) ultrasound detection rate of acrania-exencephaly-anencephaly sequence improves with training and when performed by a maternal-fetal medicine (MFM) operators, it ranges from 69% to 86% (mean detection rate of 58.5% during basic scan) with many undiagnosed cases when gestational age is less than 11 weeks(3). In contrast, higher detection rates (100%) were achieved by another research group(4).
The introduction of the transvaginal approach has enabled detection of acrania-exencephaly-anencephaly sequence at an early stage of fetal development, with the earliest diagnosis at 9 weeks and 3 days and 10 weeks onwards(5–10). In addition, an increased echogenicity of the amniotic fluid at 11–14 weeks by 2D ultrasound is a useful sonographic marker of cases of acrania-anencephaly sequence that may be seen in 89% of cases(11).
The aim of this pictorial essay is to show the different phenotypic appearance at 2D- and 3D-ultrasound in fetuses with acrania-exencephaly-anencephaly sequence diagnosed at first trimester scan.
Voluson E8/E10 (GE Medical Systems, Milwaukee, WI) ultrasound systems equipped with real-time high frequency 4–8.5 MHz transabdominal/transvaginal 2D and 3D/4D volumetric probes (RIC 5–9W and RAB 4–8L) were used. For the purpose of standardization, ultrasound was performed according to the ISUOG guidelines for first trimester scan. In some cases, acrania was detected at an early stage (8 weeks); in these instances, transvaginal approach was employed. Two and three-dimensional volume datasets were digitally acquired during fetal rest period and analyzed in the ultrasound system during the examination. The embryos and fetuses were insonated preferentially in the coronal and sagittal plane with a sweep time of 8–15 s for volume acquisition. Multiplanar mode with surface rendering was used as standard 3D ultrasound visualization. Lightening technique (HDlive™) was also applied to enhance image rendering. Written informed consent signed by each participant was obtained during exams at the Monash Ultrasound for Women, Clayton, Victoria, Australia.
Two-dimensional ultrasound was routinely used for normal and pathological cases. In the latter ones, 3D ultrasound was applied as a complementary diagnostic tool. An ultrasound perspective of different phenotypic appearance of acrania-exencephaly-anencephaly sequences is described (acrania with increased amniotic fluid echogenicity; “Mickey-Mouse” bi-lobular face, cystic, elongated, and irregular head shape) and shown in Fig. 1, Fig. 2, Fig. 3, Fig. 4, Fig. 5, Fig. 6, Fig. 7.
Notwithstanding, discordant amniotic fluid echotexture in the setting of twin pregnancies may be the first sign of acrania-exencephaly-anencephaly sequence (Fig. 8, Fig. 9). Furthermore, a very rare malformation was observed at 13 weeks and 6 days, when acrania-exencephaly was seen in both monochorionic/monoamniotic (MCMA) twins. In this case, TRAP (twin reversed arterial perfusion) sequence was the underlying cause of acrania and acardia in the cotwin (Fig. 10). Finally, acrania-exencephaly-anencephaly sequence may be present in only one fetus of dichorionic twin pregnancies (Fig. 11).
Exencephaly can be greatly visualized by using 3D ultrasound especially at an early stage of embryonic development (8 weeks and 2 days) or to document associated facial dysmorphism such as low set ears at later stage (Fig. 12). This defect can be clearly displayed at necropsy (Fig. 13).
Although it may be challenging, precise antenatal differentiation between acrania-exencephaly-anencephaly sequence and other types of NTDs such as meningo-encephalocele is fundamental for appropriate genetic counseling and pregnancy management (Fig. 14). The additional use of 3D ultrasound enables patients to better understand brain malformations, which is of value in certain situations when a patient is doubtful about the diagnosis, particularly if folate prophylaxis was implemented.
Another differential diagnosis which may be considered is craniopagus parasiticus (Fig. 15), an extremely rare form of conjoined twins which occurs in approximately 5 per 10 million births and presents with a parasitic head attached to the normal head in the developed twin.
First trimester scan is a well-established examination during routine obstetric practice. The examination has the potential to identify embryo-fetal defects in pregnant women who are at increased risk of congenital anomalies.
The use of a standardized protocol in the ultrasonographic assessment of the embryo-fetal anatomy is fundamental for the early prenatal diagnosis of fetal abnormalities. If the ultrasound examination is performed by a maternalfetal medicine operator using high frequency real-time 2D/3D ultrasound equipment, the sensitivity of the detection of major congenital anomalies overall can be assessed to be around 60% in high-risk pregnancy populations, while a detection rate of nearly 100% can be reported for acrania(1).
Combining abdominal and transvaginal ultrasonography can be extremely helpful in improving the diagnostic accuracy. In the case of a retroverted uterus, elevated body mass index, and myomata, the transvaginal approach is beneficial in most cases. Limitation in the movements of the transvaginal probe and patient’s acceptance are conditions which may limit the value of transvaginal ultrasonography(12,13).
Acrania represents the first stage of this maldevelopment sequence that takes place 18–20 days post-fertilization(14) and the progression from exencephaly to anencephaly was first described by Wilkings
Tonni
A training program for the detection and definition of the diverse types of NTDs as well as precise knowledge of embryologic development according to the Carnegie Classification(25) are important in understanding the pathogenesis and achieving accurate diagnoses in clinical practice(26,27). The diagnosis of the acrania-exencephaly-anencephaly sequence is particularly difficult at lower gestational ages, and many cases still remain undetected at this stage of pregnancy(4,28).