A 6-Month-Old Boy with Congenital Hydrocephalus and Syn- dactylia Deformity

Background: Craniosynostosis syndromes are rare and prognosis would benefit from early diagnosis and treatment. We tried to establish a fast molecular diagnosis method to detect craniosynostosis syndromes. Methods: One patient aged 6 months was observed and diagnosed at first, and then another 10 patients were included in this study. All of them suffered from congenital hydrocephalus with normal head circumference. Karyotype analysis, chromosome genome microarray analysis and whole exome sequencing were used. Results: The first patient was diagnosed as Apert Syndrome based on his clinical features and whole exome sequencing. The other 10 patients were also detected by the same protocol and one of them was found to be with Crouzon Syndrome. Both of the patients with craniosynostosis syndrome were treated in time and benefited from this new diagnosis protocol. Conclusions: Craniosynostosis syndromes cause hearing loss and deformity. It is worthy to detect mutations on FGFR1, FGFR2 and FGFR3 for children who suffer from congenital hydrocephalus with normal head circumference.

A 3.2 (correct writing form of weight is 3200 gr) kg boy was born with syndactylia deformity in November 2013. The Apar (Apgar) scores were 9.0 and 10 at post-delivery 1 st , 5 th minute, respectively, with no birth injury. His head circumference was 36.3 cm (+ 2SD) [1] and bregma was plump, suspicion of suffering with congenital hydrocephalus. After six months, the child was 6.0 kg in weight, 66 cm in height, 42 cm (-1SD) [1] of head circumference, 3 cm × 3 cm of anterior fontanelle and apophysis, no setting-sun sign, syndactylia deformity occurs both in bilateral fingers and toes, cleft palate ( Figure 1A, Figure 1B, Figure 1C and Figure 1D). All the tests of Cerebrospinal Fluid (CSF) for viruses, bacteria and parasites identification showed negative results. Computed Tomography (CT) scan illustrated bilateral lateral ventricle enlargement ( Figure 1E). by intracranial pressure mismatching body development, and the patient was with head circumference in the normal range [1] even intracranial hypertension. There were excessive hydrocephalus in ventricle and hydrocephalus obviously resulted in intracranial hypertension ( Figure  1A and Figure 1E). It seemed that the patient's head circumference had not been influenced by hydrocephalus alone, and there simultaneously were with other body deformities. Syndrome should be taken into account.
We performed karyotype analysis and chromosome genome microarray analysis (HD Cytoscan, Affymetrix Co. Ltd, USA) for this patient at its initial diagnostics. However, there were no positive findings. After the discussion with the parents to explain the process and purpose of whole exome sequencing, we then applied the whole exome sequencing to detect the patient and his parents' DNA. There were 18 mutations found in the patient's exome and only 4 de novo DNA mutations were found, through comparing with his parents, who do not have any symptoms, and verified by Sanger DNA sequencing (Table 1, Figure 1F, Figure  1G, Figure 1H and Figure 1I).

Patient Follow-up
The syndrome should be attributed to the mutation on FGFR2, which FGFR2 mutations could result in several subtypes of craniosynostosis syndrome, such as Crouzon syndrome, Apert syndrome, Pfeiffer syndrome and so on [2].
FGFR-related craniosynostosis syndrome is complex genetic disorders with clinically distinct phenotypes, although most mutations exist on FGFR1, FGFR2 and FGFR3 genes. The clinical features of Crouzon syndrome, Apert syndrome and Pfeiffer syndrome are referred [FGFR-Related Craniosynostosis Syndromes. Gene Reviews ® . http://www.ncbi. nlm.nih.gov/books/NBK1455/ (Last update June 2011)]. Based on the symptoms of this patient: normal weight and height, hydrocephalus, syndactylia deformity of all the fingers and FGFR2c.755 G > C mutation, all of which are closely related to Apert syndrome. Therefore, the diagnosis of this patient should be Apert syndrome, whose incidence is about 1 in 65,000 live births [3].
There is an odds of 50% to result in intellectual disability for Apert syndrome and drainage could reduce intracranial hypertension to improve the outcome by hydrocephalus surgery if there was no irreversible mental damage had appeared. Gesell development scale test was applied when the patient was six-month-old and the DQ value was 24.4, showing that the intelligence development level of the patient was significantly lower than that of normal children. Since it had caused serious and irreversible mental damage, it was not necessary of hydrocephalus surgery. The incidence of hearing loss in Apert syndrome is nearly 80%, mainly because of skull malformation [4]. Therefore, a comprehensive hearing test was performed and hearing was normal. The patient was advised to receive surgery for cleft palate at the age of one-year.
The patient is alive until August, 2015. Fundoscopic exam and hearing evaluation (pure tone audiometry, acoustic immitance test and auditory brainstem response) were routinely performed and no positive findings. The hydrocephalus symptom is not improved or deteriorated. Therefore, the patient has not received surgery for cleft palate.