Warsaw Genomics
Genetic test

Craniosynostosis and hypochondroplasia - large panel

CAP & EMQN quality control
Price 2194 PLN 31 days from sample registration in laboratory 46 genes Sample Cheek swab or Venous blood or DNA
Genetic testing with clinical consultation at Warsaw Genomics
~100 000
genomes in our reference database
CAP & EMQN
quality control
In-house
our own laboratory, full control
RODO
genetic data encrypted & protected

What's included in the price

  • NGS sequencing — analysis of the full coding sequence
  • In-house result interpretation by our own team
  • Material collection / delivery per instructions
  • Result available online in the patient portal (PDF)

A consultation with a clinical geneticist is available as a separate service. See the clinic

About this test

Craniosynostosis is an abnormality in the development of the skull that involves premature fusion of the cranial sutures. The rate at which the skull fused together can affect the normal development of the brain. Premature suture closure causes the pressure to build up and changes the appearance of the bones in the skull or face from normal, leading to deformation of the skull.

Genetic disorders commonly associated with craniosynostosis include Crouzon, Apert, Carpenter, Saethre-Chotzen, and Pfeiffer syndromes. Hypochondroplasia is skeletal dysplasia characterized by short stature, stocky build, disproportionately short arms and legs, wide, short hands and feet, lax joints, and macrocephaly. Hypochondroplasia is similar to achondroplasia, but much milder. The disease is inherited in an autosomal dominant pattern.

Genes analysed (46)

Gene Inheritance Associated condition
ALPL AD/AR Hypophosphatasia, adult, Hypophosphatasia, adult
ALX3 autosomal recessive Frontonasal dysplasia 1
ALX4 AD/AR Frontonasal dysplasia 2, Parietal foramina 2
BMP4 autosomal dominant Microphthalmia, syndromic 6, Microphthalmia, syndromic 6
CDC45
COLEC10
COLEC11 autosomal recessive
EDN3 AD/AR Central hypoventilation syndrome, Hirschsprung disease, susceptibility to, 4, Tietz albinism-deafness syndrome
EDNRB AD/AR Hirschsprung disease, susceptibility to, 4, Tietz albinism-deafness syndrome, Waardenburg-Shah syndrome
EFNB1 X-linked Craniofrontonasal syndrome
ERF
ESCO2 autosomal recessive Roberts-SC phocomelia syndrome, Roberts-SC phocomelia syndrome
FGFR1 AD/DG/MG Hypogonadotropic hypogonadism 20 with or without anosmia, Trigonocephaly 1
FGFR2 autosomal dominant Apert syndrome, Jackson-Weiss syndrome, Pfeiffer syndrome
FGFR3 AD/AR Camptodactyly, tall stature, and hearing loss syndrome, Camptodactyly, tall stature, and hearing loss syndrome, Camptodactyly, tall stature, and hearing loss syndrome, Crouzon syndrome with acanthosis nigricans, Lacrimoauriculodentodigital syndrome-2, Muenke syndrome
FLNB AD/AR Atelosteogenesis, type III, Boomerang dysplasia, Larsen syndrome
FREM1 AD/AR Bifid nose with or without anorectal and renal anomalies, Manitoba oculotrichoanal syndrome, Trigonocephaly 2
GDF5 AD/AR Acromesomelic dysplasia 2A, Fibular hypoplasia and complex brachydactyly, Multiple synostoses syndrome 2
GLI3 autosomal dominant Acrocallosal syndrome, Greig cephalopolysyndactyly syndrome, Pallister-Hall syndrome, Polydactyly, postaxial, types A1 and B, Polydactyly, preaxial IV
IFT122 autosomal recessive Cranioectodermal dysplasia, Cranioectodermal dysplasia 4
IFT140 autosomal recessive Short-Rib thoracic dysplasia 6 with or without polydactyly
IFT43
IL11RA
MASP1 autosomal recessive 3MC syndrome 1
MEGF8
MITF autosomal dominant Maturity-onset diabetes of the young, type III, Melanoma, cutaneous malignant, susceptibility to, 8, Noonan syndrome 7, Tietz albinism-deafness syndrome
MSX2 autosomal dominant Craniosynostosis 3, Frontonasal dysplasia 2, Parietal foramina 2
NOG autosomal dominant Multiple synostoses syndrome 1, Multiple synostoses syndrome 2
PAX3 AD/AR Craniofacial-deafness-hand syndrome, Tietz albinism-deafness syndrome
POR autosomal recessive Disordered steroidogenesis due to cytochrome P450 oxidoreductase, Disordered steroidogenesis due to cytochrome P450 oxidoreductase
PPP3CA
RAB23
RECQL4 autosomal recessive Baller-Gerold syndrome, RAPADILINO syndrome, Rothmund-Thomson syndrome
RET AD/AR Hirschsprung disease, susceptibility to, 4, Multiple endocrine neoplasia, type IIA, PHEOCHROMOCYTOMA, Thyroid carcinoma, familial medullary
SKI autosomal dominant Shprintzen-Goldberg craniosynostosis syndrome
SOX10 autosomal dominant Peripheral demyelinating neuropathy, central dysmyelination, Waardenburg syndrome, and Hirschsprung disease, Peripheral demyelinating neuropathy, central dysmyelination, Waardenburg syndrome, and Hirschsprung disease, Waardenburg syndrome, type 2E
SPECC1L
TCF12 autosomal dominant Craniosynostosis 3
TGFBR1 autosomal dominant Cardiofaciocutaneous syndrome 2, Loeys-Dietz syndrome 5
TGFBR2 autosomal dominant Cardiofaciocutaneous syndrome 2, Loeys-Dietz syndrome 5
TTR autosomal dominant Dystransthyretinemic euthyroidal hyperthyroxinemia
TWIST1 autosomal dominant Craniosynostosis 3, Saethre-Chotzen syndrome
TWIST2
WDR19 AD/AR Cranioectodermal dysplasia 4, Nephronophthisis 7, Retinitis pigmentosa, Senior-Loken syndrome 5, Short-Rib thoracic dysplasia 6 with or without polydactyly
WDR35 autosomal recessive Cranioectodermal dysplasia 4, Short-Rib thoracic dysplasia 4 with or without polydactyly
ZIC1

Click a gene to see a single-gene test.

How the test works

  1. 1

    Order online

    No referral needed. You order online.

  2. 2

    Collect the sample

    Sample: Cheek swab or Venous blood or DNA.

  3. 3

    Result

    Available in 31 days from sample registration in laboratory, online.

Methodology
Methodology
Information on the test method:

At first, deoxyribonucleic acid (DNA) is isolated from a blood sample or paraffin embedded tissue block. The quantity and quality of the material is determined in spectrophotometric and fluorometric assays. From mechanically or enzymatically fragmented DNA a library is made to be used for determination, sequencing and examination of selected genes. The library is sequenced on a new generation sequencer. Afterwards, sequencing results are subjected to bioinformatics analysis and clinical interpretation. Genetic variants are identified using BurrowsWheeler Aligner. The test detects 100% of substitutions and 95% of small insertions and deletions.

Information on variant classification:

The study report provides information on variants classified as ‘potentially pathogenic’ and ‘pathogenic’ depending on their suspected clinical significance. The identified variants are classified under the following categories:

Pathogenic variant: the detected change in the gene sequence directly associates with disease development. At the same time, some pathogenic changes may not have full penetration, meaning that a single mutation may not be enough to cause a full-blown disease.

Potentially pathogenic variant: the detected change in the gene sequence may be, with a great probability, associated with disease development however it is not possible to prove this association on the basis of currently available scientific data. Variant pathogenicity confirmation would require additional tests and evidence; it cannot be excluded that further tests might prove that the change has limited or no clinical significance.

Variant of unknown pathogenicity: based on the currently available scientific data it is not possible to determine the significance of the detected change.

Potentially benign variant: the detected change in the gene sequence most probably does not associate with disease development, however based on the currently available scientific data the benignity of the mutation cannot be confirmed. Confirmation of the clinical significance of the variant would require additional tests and evidence; it cannot be excluded that further tests might prove that the detected mutation has clinical significance and would cause disease development.

Benign variant: the detected change does not associate with disease development.

The identified genetic variants are classified based on the guidelines of the American College of Medical Genetics and Genomics and the American Association for Molecular Pathology (S. Richards, Genet Med. 2015 May; 17(5):405-24). In variant classification the following criteria are considered:

  • Previous variant identification in persons burdened with the disease
  • Variant impact of functional gene product synthesis determined through bioinformatics analyses, confirmed by in vitro/in vivo studies
  • Variant location (exon/intron, functional domain)
  • De novo/hereditary change
  • Variant incidence in general population (each variant with incidence >5% in line with Exome Sequencing Project, 1000 Genomes Project or Exome Aggregation Consortium is classified as benign change)

Variant incidence in general population with relation to patient population The final classification of variants is made on the basis of the total of the above-mentioned criteria. The data bases include: 1000GP, ClinVar, ConsensusPathDB, Exome Aggregation Consortium, Exome Variant Server, FATHMM, GO (Gene Ontology), GTEx (Genotype-Tissue Expression), GWAS (Genome Wide Association Study), HGMD, KEGG, MetaLR, MetaSVM, MutationAssessor, MutationTaster, OMIM, PolyPhen-2, PROVEAN, SIFT, SnpEff, dbNSFP, UniProt, VEP (Variant Effect Predictor).

Test limitations:

All sequencing technologies have some limitations. Our tests use new generation sequencing (NGS) to examine coding and splicing regions of disease-associated genes. Sequencing techniques and subsequent bioinformatics analyses are aimed at limiting the significance of pseudo-gene sequences, however presence of highly homologous gene sequences may still occasionally disturb the identification of pathogenic alleles, deletions/duplications. The Sanger sequencing method is used to confirm variants with lower quality parameters. Deletion/duplication analyses show qualitative changes in DNA covering at least one exon and always require confirmation with other methods (qPCR or MLPA). The analyses are not designed for detecting certain types of genomic changes, such as translocations, inversions, dynamic mutations (e.g. increased number of trinucleotide repetitions) or mutations in regulatory or intronic regions. In case increased numbers of di- or trinucleotide repetitions are reported, it should be assumed that the exact number of repetitions is not precise. The test is not intended to detect somatic mosaicism and somatic mutation analyses should be made in the context of the germinal DNA sequence.

It is not possible to exclude mutations in genes and regions other than those covered by the test as well as alternations in the gene copy number. The test report includes information on changes in gene sequence identified on the basis of a comparison against current reference sequences maintained in NCBI Nucleotide and Ensembl databases. Tests are developed by Warsaw Genomics for clinical objectives. All test results collected are interpreted and analysed by scientific and medical experts of Warsaw Genomics.

Frequently asked questions

How long does the Craniosynostosis and hypochondroplasia - large panel test take?

The result is usually available within 31 days from sample registration in laboratory.

Do I need a referral?

No. You can order this genetic test online without a referral.

How many genes does this panel cover?

The panel analyses 46 genes.

How much does the test cost?

The price of the test is 2194 PLN.

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