Palatoplasty for the Patient With Campomelic Dysplasia-Report of a Case and Review of the Literature.

Campomelic dysplasia (CMPD) is a skeletal disorder resulting from SOX9 gene mutations. Palatoplasty is rare due to a high lethality rate in infants from respiratory distress. Our patient had characteristic symptoms of CMPD, including short bowed limbs, macrocephaly, low-set ears, short palpebral fissures, hypertelorism, a flat nasal bridge, a long philtrum, micrognathia, and a cleft palate. We performed a Furlow palatoplasty when the patient was 2 years 9 months of age, after respiratory conditions had stabilized. We reviewed the literature of CMPD cases that underwent palatoplasty and discussed the optimal timing and surgical methods.

The presence of diminished white matter and corpus callosal thinning in a case with a SOX9 mutation.

SOX9 is responsible for campomelic dysplasia (CMPD). Symptoms of CMPD include recurrent apnea, upper respiratory infection, facial features, and shortening of the lower extremities. The variant acampomelic CMPD (ACMPD) lacks long bone curvature. A patient showed macrocephaly (+3.9 standard deviations [SD]) and minor anomalies, such as hypertelorism, palpebronasal fold, small mandible, and a cleft of soft palate without long bone curvature. From three months of age, he required tracheal intubation and artificial respiration under sedation because of tracheomalacia. Cranial magnetic resonance imaging was normal at one month of age but showed ventriculomegaly, hydrocephaly, and the corpus callosum thinning at two years of age. Exome sequencing revealed a de novo novel mutation, c. 236A>C, p (Q79P), in SOX9. Sox9 is thought to be crucial in neural stem cell development in the central and peripheral nervous system along with Sox8 and Sox10 in mice. In humans, neuronal abnormalities have been reported in cases of CMPD and ACMPD, including relative macrocephaly in 11 out of 22 and mild lateral ventriculomegaly in 2 out of 22 patients. We encountered a two-year old boy with ACMPD presenting with tracheomalacia and macrocephaly with a SOX9 mutation. We described for the first time an ACMPD patient with acquired diminished white matter and corpus callosal thinning, indicating the failure of oligodendrocyte/astrocyte development postnatally. This phenotype suggests that SOX9 plays a crucial role in human central nervous system development. Further cases are needed to clarify the relationship between human neural development and SOX9 mutations.

Absent pedicles in campomelic dysplasia.

OBJECTIVES: The objective of the present study is to report a case of campomelic dysplasia illustrating the absence of cervical and thoracic pedicles. This report reiterates the importance of this clinical peculiarity in the setting of spine instrumentation. MATERIALS AND METHODS: A 10-year-old female patient with campomelic dysplasia presented with progressive kyphoscoliosis and signs of neural compromise. Imaging studies confirmed thoracic level stenosis and demonstrated absence of multiple pedicles in cervical and thoracic spine. The patient underwent decompression and instrumentation/fusion for her spinal deformity. RESULTS: The patient was instrumented between C2 and L4 with pedicle screws and sublaminar cables. However, pedicle fixation was not possible for the lower cervical and upper-mid thoracic spine. Also, floating posterior elements precluded the use of laminar fixation in the lower cervical spine. Cervicothoracic lumbosacral orthosis (CTLSO) was used for external immobilization to supplement the tenuous fixation in the cervicothoracic area. The patient improved neurologically with no signs of implant failure at the 2-year follow-up. CONCLUSIONS: Absence of pedicles and floating posterior elements present a challenge during spine surgery in campomelic dysplasia. Surgeons should prepare for alternative fixation methods and external immobilization when planning on spinal instrumentation in affected patients. LEVEL OF EVIDENCE: Level IV Case Report.

Novel and recurrent XYLT1 mutations in two Turkish families with Desbuquois dysplasia, type 2.

Desbuquois dysplasia (DBQD) is an autosomal recessive skeletal disorder characterized by growth retardation, joint laxity, short extremities, and progressive scoliosis. DBQD is classified into two types based on the presence (DBQD1) or absence (DBQD2) of characteristic hand abnormalities. CANT1 mutations have been reported in both DBQD1 and DBQD2. Recently, mutations in the gene encoding xylosyltransferase 1 (XYLT1) were identified in several families with DBQD2. In this study, we performed whole-exome sequencing in two Turkish families with DBQD2. We found a novel and a recurrent XYLT1 mutation in each family. The patients were homozygous for the mutations. Our results further support that XYLT1 is responsible for a major subset of DBQD2.

Spine malformation complex in 3 diverse syndromic entities: Case reports.

RATIONALE: Clinical and radiographic phenotypic characterizations were the base line tool of diagnosis in 3 syndromic disorders in which congenital cervico-thoracic kyphosis was the major deformity. PATIENTS CONCERNS: Directing maximal care toward the radiographic analysis is not only the axial malformation but also toward the appendicular abnormalities was our main concern. We fully documented the diversity of the spine phenotypic malformation complex via the clinical and radiographic phenotypes. DIAGNOSES: We established the diagnosis via phenotypic/genotypic confirmation in 3 diverse syndromic entities namely acampomelic campomelic dysplasia, Larsen syndrome and Morquio syndrome type A (mucopolysaccharidosis type IV A). INTERVENTIONS: Surgical interventions have been carried out in the Larsen syndrome and Morquio syndrome type A, resepectively. OUTCOMES: The earliest the diagnosis is, the better the results are. The necessity to diagnose children in their first year of life has many folds, firstly the management would be in favor of the child's growth and development and secondly, the prognosis could be clearer to the family and the medical staff as well. Our current paper is to sensitize paediatricians, physicians and orthopedic surgeons regarding the necessity to detect the aetiological understanding in every child who manifests a constellation of malformation complex. LESONS: Scoliosis and kyphosis/kyphoscoliosis are not a diagnosis in themselves. Such deformities are mostly a symptom complex correlated to dozens of types of syndromic associations. The rate curve progression and the final severity of congenital spine tilting are related to 3 factors: (a) the type of vertebral malformation present, (b) the patient's phenotype, and

p.His165Pro: a novel SOX9 missense mutation of campomelic dysplasia.

Campomelic dysplasia (CD) is a rare skeletal dysplasia caused by mutation in the SOX9 gene located on chromosome 17q24.3-q25.1, which regulates testis and chondrocyte development. Severe bowing of the long bones was seen at second-trimester scan. DNA analysis demonstrated a previously unreported de novo missense mutation in p.His165Pro. Ultrasound-based, molecular biology diagnosis led to early therapeutic termination of pregnancy. Histologic examination of the femoral epyphyseal growth plate confirmed scanty proliferation zone and maturation zone with degenerated chondrocytes.

Sex-reversed acampomelic campomelic dysplasia with a homozygous deletion mutation in SOX9 gene.

Campomelic dysplasia (CD) is a rare autosomal dominant skeletal malformation with or without sex reversal. About 10% of cases that present with milder skeletal features are referred to as acampomelic campomelic dysplasia (ACD). CD and ACD are caused by mutations in SOX9. We report a patient of homozygous SOX9 deletion with minimal skeletal anomaly and female external genitalia in the presence of a male karyotype. The mechanisms explaining the homozygous deletion include a de novo mutation followed by gene conversion, uniparental disomy, or somatic crossing over. Our report highlights the possibility of ACD in XY sex-reversed patients with minimal skeletal presentation.

Prenatal sonographic features of dyssegmental dysplasia Rolland-Desbuquois type.

Dyssegmental dysplasia is a rare, lethal, autosomal-recessive disorder characterized by severe camptomicromelia and anisospondyly. We describe the prenatal sonographic findings in an index case of the Rolland-Desbuquois type, with the diagnosis made by neonatal skeletal survey. Recognition of the unique vertebral disorganization may be used to prenatally distinguish dyssegmental dysplasia from other severe short-limbed conditions.

A case of campomelic dysplasia without sex reversal.

Campomelic dysplasia (CD; OMIM #114290), a rare form of congenital short-limbed dwarfism, is due to mutations in SOX9, a member of the SOX (SRY-related HMG box) gene family. Multiparous mother at 38 weeks' gestation delivered a 3,272 g baby boy with characteristic phenotypes including bowing of the lower limbs, a narrow thoracic cage, 11 pairs of ribs, hypoplastic scapulae, macrocephaly, flattened supraorbital ridges and nasal bridge, cleft palate, and micrognathia. He underwent a tracheostomy at the age of three months for severe laryngomalacia after a number of repeated hospitalizations due to respiratory problems and died at the age of four months from progressive respiratory failure. He was diagnosed as having CD based on a novel frameshift mutation (p.Gln458ArgfsX12) in the SOX9 gene, the mutation which has not yet been reported in Korea.

Phenotype of five cases of prenatally diagnosed campomelic dysplasia harboring novel mutations of the SOX9 gene.

OBJECTIVES: Campomelic dysplasia is a rare congenital skeletal disorder characterized by bowing of the long bones and a variety of other skeletal and extraskeletal defects, many of which can now be identified prenatally using advanced ultrasound equipment. The disorder is caused by mutations in SRY-box 9 (SOX9), a gene that is abundantly expressed in chondrocytes as well as in other tissues. However, the correlation between genotype and phenotype is still unclear. We report five cases of prenatally detected campomelic dysplasia in which the diagnosis was confirmed by molecular analysis. METHODS: Ultrasound examinations were performed between 12 and 32 weeks. Standard fetal biometric measurements were obtained. Fetal sex was determined sonographically and confirmed by chromosomal analysis. Genomic DNA was obtained in four cases before termination of pregnancy from chorionic villi or amniocytes and in one case postnatally from peripheral blood. RESULTS: Skeletal dysplasia, most often limb shortening and bowed femora, was observed in one case in the first trimester, in three cases in the second trimester and in one case, presenting late for antenatal care, in the third trimester. Four of the pregnancies were terminated and one was carried to term. Postmortem/postnatal physical and radiographic examinations confirmed the presence of anomalies characteristic of campomelic dysplasia. A de novo mutation in the SOX9 gene was detected in all four cases that underwent termination. The father of the proband in the case that went to term was a carrier of a somatic mosaic mutation without clinical or radiographic signs of campomelic dysplasia. CONCLUSIONS: It is likely that the integrated expertise of ultrasonographers, obstetricians, pediatricians and clinical geneticists will markedly improve the likelihood of accurate prenatal clinical diagnoses of campomelic dysplasia. This will, in turn, encourage more specific molecular testing and facilitate comprehensive genetic counseling.

Familial acampomelic form of campomelic dysplasia caused by a 960 kb deletion upstream of SOX9.

Campomelic dysplasia (CD) is a rare autosomal dominant osteochondrodysplasia with or without XY disorders of sexual development (DSD). Campomelia is absent in about 10% of the cases, referred to as the acampomelic form of CD (ACD). Most CDs are caused by mutations within the SOX9 coding region. Several CD patients with balanced chromosome rearrangements involving the 17q24 region have been reported suggesting the presence of cis-regulatory elements upstream and/or downstream of the gene. Deletions upstream of SOX9 represent a third mechanism of mutation. To date, a 1.5 Mb de novo deletion in the SOX9 upstream region has been identified in a single 46,XY patient with ACD and DSD. We report here for the first time on a familial ACD caused by an inherited deletion mapping upstream of the SOX9 gene. Using high-density oligoarray comparative genomic hybridization (CGH), we showed that the size of the deletion was 960 kb in the XY-DSD child and her mother, both affected. The deletion lying from 517 kb to 1.477 Mb upstream of SOX9 remove several highly conserved elements and reduce the minimum critical size and therefore the number of highly conserved sequence elements responsible for ACD.

Campomelic dysplasia: echographic suspicion in the first trimester of pregnancy and final diagnosis of two cases.

OBJECTIVE: Campomelic dysplasia (CD) is a rare skeletal dysplasia characterized by marked femoral and tibial angulations, hypoplasic scapulae, normal upper limbs and sex reversal in 3/4 of 46,XY fetuses. Most cases are lethal in the neonatal period. Heterozygous mutations in the SOX9 gene are responsible for CD. The diagnosis is not usually made until the mid-second trimester or later. METHODS: We describe 2 cases of CD suspected by ultrasonography in the first trimester. RESULTS: The 2 cases presented with hygroma colli along with anomalies in the lower but not the upper limbs. Terminations of pregnancy were obtained at 14+3 and 20+6 gestational weeks. Fetopathological examinations confirmed sonographic findings. CONCLUSION: When first trimester hygroma colli is accompanied by specific findings of the lower limbs, the diagnosis of CD can be investigated through SOX9 mutation analysis.