Achondroplasia |
Classification and external resources |
ICD-10 |
Q77.4 |
ICD-9 |
756.4 |
OMIM |
100800 134934 |
DiseasesDB |
80 |
MedlinePlus |
001577 |
eMedicine |
article/1258401-overview |
Patient UK |
Achondroplasia |
MeSH |
D000130 |
Detail of
Las Meninas by Diego Velázquez (1656), showing Maribarbola and Nicolasito Pertusato (right), achondroplastic dwarfs in the entourage of Infanta Margarita
Achondroplasia is a common cause of dwarfism. It occurs as a sporadic mutation in approximately 80% of cases (associated with advanced paternal age) or it may be inherited as an autosomal dominant genetic disorder.
People with achondroplasia have short stature, with an average adult height of 131 centimeters (52 inches) for males and 123 centimeters (48 inches) for females. Achondroplastic adults are known to be as short as 62.8 cm (24.7 in). If both parents of a child have achondroplasia, and both parents pass on the mutant gene, then it is very unlikely that the homozygous child will live past a few months of its life. The prevalence is approximately 1 in 25,000.[1]
Contents
- 1 Causes
- 2 Presentation
- 3 Diagnosis
- 4 Treatment
- 5 Epidemiology
- 6 In other species
- 7 See also
- 8 References
- 9 External links
Causes
Achondroplasia is caused by a mutation in fibroblast growth factor receptor 3 (FGFR3). In normal development FGFR3 has a negative regulatory effect on bone growth. In achondroplasia, the mutated form of the receptor is constitutively active and this leads to severely shortened bones. The effect is genetically dominant, with one mutant copy of the FGFR3 gene being sufficient to cause achondroplasia, while two copies of the mutant gene are invariably fatal (dominant lethal) before or shortly after birth (known as a lethal allele). A person with achondroplasia thus has a 50% chance of passing dwarfism to each of their offspring. People with achondroplasia can be born to parents that do not have the condition due to spontaneous mutation.[2]
New gene mutations leading to achondroplasia are associated with increasing paternal age[3] (over 35 years old). Studies have demonstrated that new gene mutations for achondroplasia are exclusively inherited from the father and occur during spermatogenesis; it is theorized that oogenesis has some regulatory mechanism that prevents the mutation occurring in females.
There are two other syndromes with a genetic basis similar to achondroplasia: hypochondroplasia and thanatophoric dysplasia.
Presentation
- Disproportionate dwarfism
- Shortening of the proximal limbs (called rhizomelic shortening)
- Short fingers and toes with trident hands
- Large head with prominent forehead frontal bossing
- Small midface with a flattened nasal bridge
- Spinal kyphosis (convex curvature) or lordosis (concave curvature)
- Varus (bowleg) or valgus (knock knee) deformities
- Frequently have ear infections (due to Eustachian tube blockages), sleep apnea (which can be central or obstructive), and hydrocephalus
Diagnosis
Achondroplasia can be detected before birth by the use of prenatal ultrasound. A DNA test can be performed before birth to detect homozygosity, wherein two copies of the mutant gene are inherited, a lethal condition leading to stillbirths. Clinical features include megalocephaly, short limbs, prominent forehead, thoracolumbar kyphosis and mid-facial hypoplasia.[4] Complications like dental malocclusion, hydrocephalus and repeated otitis media can be observed.[4] The risk of death in infancy is increased due to the likelihood of compression of the spinal cord with or without upper airway obstruction.
Radiologic findings
A skeletal survey is useful to confirm the diagnosis of achondroplasia. The skull is large, with a narrow foramen magnum, and relatively small skull base. The vertebral bodies are short and flattened with relatively large intervertebral disk height, and there is congenitally narrowed spinal canal. The iliac wings are small and squared,[5] with a narrow sciatic notch and horizontal acetabular roof. The tubular bones are short and thick with metaphyseal cupping and flaring and irregular growth plates. Fibular overgrowth is present. The hand is broad with short metacarpals and phalanges, and a trident configuration. The ribs are short with cupped anterior ends. If the radiographic features are not classic, a search for a different diagnosis should be entertained. Because of the extremely deformed bone structure, people with achondroplasia are often "double jointed".
The diagnosis can be made by fetal ultrasound by progressive discordance between the femur length and biparietal diameter by age. The trident hand configuration can be seen if the fingers are fully extended.
Another distinct characteristic of the syndrome is thoracolumbar gibbus in infancy.
Treatment
At present, there is no known treatment for achondroplasia, even though the cause of the mutation in the growth factor receptor has been found.
Although used by those without achondroplasia to aid in growth, human growth hormone does not help people with achondroplasia. However, if desired, the controversial surgery of limb-lengthening will lengthen the legs and arms of someone with achondroplasia.[6]
Usually, the best results appear within the first and second year of therapy.[7] After the second year of GH therapy, beneficial bone growth decreases.[8] Therefore, GH therapy is not a satisfactory long term treatment.[7]
Gene based therapy may possibly serve as a future treatment option. BioMarin Pharmaceutical Inc. announced in 2012 the initiation of a Phase 1 study in healthy volunteers for BMN-111, an analog of C-type Natriuretic Peptide (CNP), for the treatment of achondroplasia. In June of 2015, BioMarin announced positive results of their Phase 2 study, stating that 10 children experienced a mean increase of 50% in their annualized growth velocity.[9]
Latest research and related efforts are tracked by the non-profit Growing Stronger.
Epidemiology
Achondroplasia is one of 19 congenital conditions with similar presentations, such as osteogenesis imperfecta, multiple epiphyseal dysplasia tarda, achondrogenesis, osteopetrosis, and thanatophoric dysplasia. This makes estimates of prevalence difficult, with changing and subjective diagnostic criteria over time. One detailed and long-running study in the Netherlands found that the prevalence determined at birth was only 1.3 per 100,000 live births.[10] However, another study at the same time found a rate of 1 per 10,000.[10]
In other species
Based on their disproportionate dwarfism, some dog breeds traditionally have been classified as "achondroplastic." This is the case for the dachshund, basset hound, corgi and bulldog breeds.[11][12][13] Data from whole genome association studies in short-limbed dogs reveal a strong association of this trait with a retro-gene coding for fibroblast growth factor 4 (FGF4).[14] Therefore, it seems unlikely that dogs and humans are achondroplastic for the same reasons. However, histological studies in some achondroplastic dog breeds have shown altered cell patterns in cartilage that are very similar to those observed in humans exhibiting achondroplasia.[15]
A similar form of achondroplasia was found in a litter of piglets from a phenotypically normal Danish sow. The dwarfism was inherted dominant in the offspring from this litter. The piglets were born phenotypically normal but became more and more symptomatic as they reached maturity.[16] This involved a mutation of the protein Collagen, type X, alpha 1, encoded by the COL10A1 gene. In humans a similar mutation (G595E) has been associated with Schmid metaphyseal chondrodysplasia (SMCD), a relatively mild skeletal disorder that is also associated with dwarfism.
The now-extinct Ancon sheep was created by humans through the selective breeding of common domestic sheep with achondroplasia. The average-sized torso combined with the relatively smaller legs produced by achondroplasia was valued for making affected sheep less likely to escape without affecting the amount of wool or meat each sheep produced.[17]
See also
- Achondroplasia in children
- List of radiographic findings associated with cutaneous conditions
References
- ^ Wynn J, King TM, Gambello MJ, Waller DK, Hecht JT (2007). "Mortality in achondroplasia study: A 42-year follow-up". Am. J. Med. Genet. A 143 (21): 2502–11. doi:10.1002/ajmg.a.31919. PMID 17879967.
- ^ Richette P, Bardin T, Stheneur C (2007). "Achondroplasia: From genotype to phenotype". Joint Bone Spine 75 (2): 125–30. doi:10.1016/j.jbspin.2007.06.007. PMID 17950653.
- ^ Dakouane Giudicelli M, Serazin V, Le Sciellour CR, Albert M, Selva J, Giudicelli Y (2007). "Increased achondroplasia mutation frequency with advanced age and evidence for G1138A mosaicism in human testis biopsies". Fertil Steril 89 (6): 1651–6. doi:10.1016/j.fertnstert.2007.04.037. PMID 17706214.
- ^ a b Beattie, R.M.; Champion, M.P., ed. (2004). Essential questions in paediatrics for MRCPCH. (1st ed. ed.). Knutsford, Cheshire: PasTest. ISBN 1-901198-99-5.
- ^ "Achondroplasia Pelvis". Archived from the original on 2007-10-22. Retrieved 2007-11-28.
- ^ Kitoh H, Kitakoji T, Tsuchiya H, Katoh M, Ishiguro N (2007). "Distraction osteogenesis of the lower extremity in patients that have achondroplasia/hypochondroplasia treated with transplantation of culture-expanded bone marrow cells and platelet-rich plasma". J Pediatr Orthop 27 (6): 629–34. doi:10.1097/BPO.0b013e318093f523. PMID 17717461.
- ^ a b Vajo, Z; Francomano, CA; Wilkin, DJ (2000). "The molecular and genetic basis of fibroblast growth factor receptor 3 disorders: the achondroplasia family of skeletal dysplasias, Muenke craniosynostosis, and Crouzon syndrome with acanthosis nigricans.". Endocrine Reviews 21 (1): 23–39. doi:10.1210/er.21.1.23. PMID 10696568.
- ^ Aviezer, D; Golembo, M; Yayon, A (2003). "Fibroblast growth factor receptor-3 as a therapeutic target for Achondroplasia—genetic short limbed dwarfism.". Current drug targets 4 (5): 353–65. doi:10.2174/1389450033490993. PMID 12816345.
- ^ "BioMarin Surges On Positive Results From Phase-2 Study Of Dwarfism Drug". NASDAQ.com. The NASDAQ OMX Group, Inc. Retrieved 23 June 2015.
- ^ a b Online 'Mendelian Inheritance in Man' (OMIM) ACHONDROPLASIA; ACH -100800
- ^ "WebMD".
- ^ Jones, T.C.; Hunt, R.D.; (1979). "The musculoskeletal system". In Jones, T.C.; Hunt, R.D.; Smith, H.A. Veterinary Pathology (5th ed.). Philadelphia: Lea & Febiger. pp. 1175–6. ISBN 0812107896.
- ^ Willis M.B. (1989). "Inheritance of specific skeletal and structural defects". In Willis M.B. Genetics of the Dog. Great Britain: Howell Book House. pp. 119–120. ISBN 087605551X.
- ^ Parker HG, VonHoldt BM, Quignon P et al. (August 2009). "An expressed fgf4 retrogene is associated with breed-defining chondrodysplasia in domestic dogs". Science 325 (5943): 995–8. doi:10.1126/science.1173275. PMC 2748762. PMID 19608863.
- ^ Braund KG, Ghosh P, Taylor TK, Larsen LH (September 1975). "Morphological studies of the canine intervertebral disc. The assignment of the beagle to the achondroplastic classification". Res. Vet. Sci. 19 (2): 167–72. PMID 1166121.
- ^ Nielsen VH, Bendixen C, Arnbjerg J et al. (December 2000). "Abnormal growth plate function in pigs carrying a dominant mutation in type X collagen". Mamm. Genome 11 (12): 1087–92. doi:10.1007/s003350010212. PMID 11130976.
- ^ Gidney, Louisa (May–June 1019). "Earliest Archaeological Evidence of the Ancon Mutation in Sheep from Leicester, UK". International Journal of Osteoarchaeology (John Wiley and Son) 15 (27): 318–321. doi:10.1002/oa.872. ISSN 1099-1212.
External links
|
Look up achondroplasia in Wiktionary, the free dictionary. |
- Pauli RM (1998). "Achondroplasia". In Pagon RA, Bird TD, Dolan CR et al. GeneReviews. Seattle WA: University of Washington, Seattle. PMID 20301331. NBK1152.
- UK Support charity for individuals and families with Achondroplasia and other forms for restricted growth
- USA support group for little people
- USA based group supporting dwarfism through research
- Infographic on Achondroplasia, Bahtiar - Informasi
- Achondroplasia
Osteochondrodysplasia (Q77–Q78, 756.4–756.5)
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Osteodysplasia//
osteodystrophy |
Diaphysis |
- Camurati–Engelmann disease
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Metaphysis |
- Metaphyseal dysplasia
- Jansen's metaphyseal chondrodysplasia
- Schmid metaphyseal chondrodysplasia
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Epiphysis |
- Spondyloepiphyseal dysplasia congenita
- Multiple epiphyseal dysplasia
- Otospondylomegaepiphyseal dysplasia
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Osteosclerosis |
- Raine syndrome
- Osteopoikilosis
- Osteopetrosis
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Other/ungrouped |
- FLNB
- Opsismodysplasia
- Polyostotic fibrous dysplasia
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Chondrodysplasia/
chondrodystrophy
(including dwarfism) |
Osteochondroma |
- osteochondromatosis
- Hereditary multiple exostoses
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Chondroma/enchondroma |
- enchondromatosis
- Ollier disease
- Maffucci syndrome
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Growth factor receptor |
FGFR2: |
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FGFR3: |
- Achondroplasia
- Thanatophoric dysplasia
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COL2A1 collagen disease |
- Achondrogenesis
- Hypochondrogenesis
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SLC26A2 sulfation defect |
- Achondrogenesis
- Autosomal recessive multiple epiphyseal dysplasia
- Atelosteogenesis, type II
- Diastrophic dysplasia
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Chondrodysplasia punctata |
- Rhizomelic chondrodysplasia punctata
- Conradi–Hünermann syndrome
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Other dwarfism |
- Fibrochondrogenesis
- Short rib – polydactyly syndrome
- Majewski's polydactyly syndrome
- Léri–Weill dyschondrosteosis
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Index of bones and cartilage
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Description |
- Anatomy
- bones
- skull
- face
- neurocranium
- compound structures
- foramina
- upper extremity
- torso
- pelvis
- lower extremity
- Physiology
- Development
- Cells
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Disease |
- Congenital
- Neoplasms and cancer
- Trauma
- Other
- Symptoms and signs
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Treatment |
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Cell surface receptor deficiencies
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G protein-coupled receptor
(including hormone) |
Class A |
- TSHR (Congenital hypothyroidism 1)
- LHCGR (Luteinizing hormone insensitivity, Leydig cell hypoplasia, Male-limited precocious puberty)
- FSHR (Follicle-stimulating hormone insensitivity, XX gonadal dysgenesis)
- GnRHR (Gonadotropin-releasing hormone insensitivity)
- EDNRB (ABCD syndrome, Waardenburg syndrome 4a, Hirschsprung's disease 2)
- AVPR2 (Nephrogenic diabetes insipidus 1)
- PTGER2 (Aspirin-induced asthma)
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Class B |
- PTH1R (Jansen's metaphyseal chondrodysplasia)
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Class C |
- CASR (Familial hypocalciuric hypercalcemia)
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Class F |
- FZD4 (Familial exudative vitreoretinopathy 1)
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Enzyme-linked receptor
(including
growth factor) |
RTK |
- ROR2 (Robinow syndrome)
- FGFR1 (Pfeiffer syndrome, KAL2 Kallmann syndrome)
- FGFR2 (Apert syndrome, Antley–Bixler syndrome, Pfeiffer syndrome, Crouzon syndrome, Jackson–Weiss syndrome)
- FGFR3 (Achondroplasia, Hypochondroplasia, Thanatophoric dysplasia, Muenke syndrome)
- INSR (Donohue syndrome
- Rabson–Mendenhall syndrome)
- NTRK1 (Congenital insensitivity to pain with anhidrosis)
- KIT (KIT Piebaldism, Gastrointestinal stromal tumor)
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STPK |
- AMHR2 (Persistent Müllerian duct syndrome II)
- TGF beta receptors: Endoglin/Alk-1/SMAD4 (Hereditary hemorrhagic telangiectasia)
- TGFBR1/TGFBR2 (Loeys-Dietz syndrome)
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GC |
- GUCY2D (Leber's congenital amaurosis 1)
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JAK-STAT |
- Type I cytokine receptor: GH (Laron syndrome)
- CSF2RA (Surfactant metabolism dysfunction 4)
- MPL (Congenital amegakaryocytic thrombocytopenia)
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TNF receptor |
- TNFRSF1A (TNF receptor associated periodic syndrome)
- TNFRSF13B (Selective immunoglobulin A deficiency 2)
- TNFRSF5 (Hyper-IgM syndrome type 3)
- TNFRSF13C (CVID4)
- TNFRSF13B (CVID2)
- TNFRSF6 (Autoimmune lymphoproliferative syndrome 1A)
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Lipid receptor |
- LRP: LRP2 (Donnai–Barrow syndrome)
- LRP4 (Cenani–Lenz syndactylism)
- LRP5 (Worth syndrome, Familial exudative vitreoretinopathy 4, Osteopetrosis 1)
- LDLR (LDLR Familial hypercholesterolemia)
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Other/ungrouped |
- Immunoglobulin superfamily: AGM3, 6
- Integrin: LAD1
- Glanzmann's thrombasthenia
- Junctional epidermolysis bullosa with pyloric atresia
EDAR (EDAR Hypohidrotic ectodermal dysplasia)
- PTCH1 (Nevoid basal cell carcinoma syndrome)
- BMPR1A (BMPR1A Juvenile polyposis syndrome)
- IL2RG (X-linked severe combined immunodeficiency)
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- See also
- cell surface receptors
Index of cells
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Description |
- Structure
- Organelles
- peroxisome
- cytoskeleton
- centrosome
- epithelia
- cilia
- mitochondria
- Membranes
- Membrane transport
- ion channels
- vesicular transport
- solute carrier
- ABC transporters
- ATPase
- oxidoreduction-driven
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Disease |
- Structural
- peroxisome
- cytoskeleton
- cilia
- mitochondria
- nucleus
- scleroprotein
- Membrane
- channelopathy
- solute carrier
- ATPase
- ABC transporters
- other
- extracellular ligands
- cell surface receptors
- intracellular signalling
- Vesicular transport
- Pore-forming toxins
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