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Foot polydactyly

MedGen UID:
510637
Concept ID:
C0158734
Congenital Abnormality
Synonyms: Accessory digit of foot; Accessory toe; Accessory toes; Duplication of bones of the toes; Extra toe; Polydactyly of feet; Polydactyly of foot; Polydactyly of the foot; Polydactyly of toes; Supernumerary digit of foot
SNOMED CT: Polydactyly of toes (62218008); Accessory toes (62218008); Accessory digit of foot (62218008); Supernumerary digit of foot (62218008); Polydactyly of foot (62218008); Extra toe (62218008); Accessory toe (62218008)
 
HPO: HP:0001829

Definition

A kind of polydactyly characterized by the presence of a supernumerary toe or toes. [from HPO]

Term Hierarchy

Conditions with this feature

Focal dermal hypoplasia
MedGen UID:
42055
Concept ID:
C0016395
Disease or Syndrome
Focal dermal hypoplasia is a multisystem disorder characterized primarily by involvement of the skin, skeletal system, eyes, and face. Skin manifestations present at birth include atrophic and hypoplastic areas of skin; cutis aplasia; fat nodules in the dermis manifesting as soft, yellow-pink cutaneous nodules; and pigmentary changes. Verrucoid papillomas of the skin and mucous membranes may appear later. The nails can be ridged, dysplastic, or hypoplastic; hair can be sparse or absent. Limb malformations include oligo-/syndactyly and split hand/foot. Developmental abnormalities of the eye can include anophthalmia/microphthalmia, iris and chorioretinal coloboma, and lacrimal duct abnormalities. Craniofacial findings can include facial asymmetry, notched alae nasi, cleft lip and palate, and pointed chin. Occasional findings include dental anomalies, abdominal wall defects, diaphragmatic hernia, and renal anomalies. Psychomotor development is usually normal; some individuals have cognitive impairment.
Orofacial-digital syndrome IV
MedGen UID:
98358
Concept ID:
C0406727
Disease or Syndrome
Oral-facial-digital syndrome is actually a group of related conditions that affect the development of the oral cavity (the mouth and teeth), facial features, and digits (fingers and toes).\n\nResearchers have identified at least 13 potential forms of oral-facial-digital syndrome. The different types are classified by their patterns of signs and symptoms. However, the features of the various types overlap significantly, and some types are not well defined. The classification system for oral-facial-digital syndrome continues to evolve as researchers find more affected individuals and learn more about this disorder.\n\nThe signs and symptoms of oral-facial-digital syndrome vary widely. However, most forms of this disorder involve problems with development of the oral cavity, facial features, and digits. Most forms are also associated with brain abnormalities and some degree of intellectual disability.\n\nAbnormalities of the oral cavity that occur in many types of oral-facial-digital syndrome include a split (cleft) in the tongue, a tongue with an unusual lobed shape, and the growth of noncancerous tumors or nodules on the tongue. Affected individuals may also have extra, missing, or defective teeth. Another common feature is an opening in the roof of the mouth (a cleft palate). Some people with oral-facial-digital syndrome have bands of extra tissue (called hyperplastic frenula) that abnormally attach the lip to the gums.\n\nDistinctive facial features often associated with oral-facial-digital syndrome include a split in the lip (a cleft lip); a wide nose with a broad, flat nasal bridge; and widely spaced eyes (hypertelorism).\n\nOther features occur in only one or a few types of oral-facial digital syndrome. These features help distinguish the different forms of the disorder. For example, the most common form of oral-facial-digital syndrome, type I, is associated with polycystic kidney disease. This kidney disease is characterized by the growth of fluid-filled sacs (cysts) that interfere with the kidneys' ability to filter waste products from the blood. Other forms of oral-facial-digital syndrome are characterized by neurological problems, particular changes in the structure of the brain, bone abnormalities, vision loss, and heart defects.\n\nAbnormalities of the digits can affect both the fingers and the toes in people with oral-facial-digital syndrome. These abnormalities include fusion of certain fingers or toes (syndactyly), digits that are shorter than usual (brachydactyly), or digits that are unusually curved (clinodactyly). The presence of extra digits (polydactyly) is also seen in most forms of oral-facial-digital syndrome.
Acro-renal-mandibular syndrome
MedGen UID:
395425
Concept ID:
C1860166
Disease or Syndrome
A very rare multiple congenital anomalies syndrome with characteristics of limb deficiencies and renal anomalies that include split hand-split foot malformation, renal agenesis, polycystic kidneys, uterine anomalies and severe mandibular hypoplasia.
Bardet-Biedl syndrome 1
MedGen UID:
422452
Concept ID:
C2936862
Disease or Syndrome
Bardet-Biedl syndrome is an autosomal recessive and genetically heterogeneous ciliopathy characterized by retinitis pigmentosa, obesity, kidney dysfunction, polydactyly, behavioral dysfunction, and hypogonadism (summary by Beales et al., 1999). Eight proteins implicated in the disorder assemble to form the BBSome, a stable complex involved in signaling receptor trafficking to and from cilia (summary by Scheidecker et al., 2014). Genetic Heterogeneity of Bardet-Biedl Syndrome BBS2 (615981) is caused by mutation in a gene on 16q13 (606151); BBS3 (600151), by mutation in the ARL6 gene on 3q11 (608845); BBS4 (615982), by mutation in a gene on 15q22 (600374); BBS5 (615983), by mutation in a gene on 2q31 (603650); BBS6 (605231), by mutation in the MKKS gene on 20p12 (604896); BBS7 (615984), by mutation in a gene on 4q27 (607590); BBS8 (615985), by mutation in the TTC8 gene on 14q32 (608132); BBS9 (615986), by mutation in a gene on 7p14 (607968); BBS10 (615987), by mutation in a gene on 12q21 (610148); BBS11 (615988), by mutation in the TRIM32 gene on 9q33 (602290); BBS12 (615989), by mutation in a gene on 4q27 (610683); BBS13 (615990), by mutation in the MKS1 gene (609883) on 17q23; BBS14 (615991), by mutation in the CEP290 gene (610142) on 12q21, BBS15 (615992), by mutation in the WDPCP gene (613580) on 2p15; BBS16 (615993), by mutation in the SDCCAG8 gene (613524) on 1q43; BBS17 (615994), by mutation in the LZTFL1 gene (606568) on 3p21; BBS18 (615995), by mutation in the BBIP1 gene (613605) on 10q25; BBS19 (615996), by mutation in the IFT27 gene (615870) on 22q12; BBS20 (619471), by mutation in the IFT172 gene (607386) on 9p21; BBS21 (617406), by mutation in the CFAP418 gene (614477) on 8q22; and BBS22 (617119), by mutation in the IFT74 gene (608040) on 9p21. The CCDC28B gene (610162) modifies the expression of BBS phenotypes in patients who have mutations in other genes. Mutations in MKS1, MKS3 (TMEM67; 609884), and C2ORF86 also modify the expression of BBS phenotypes in patients who have mutations in other genes. Although BBS had originally been thought to be a recessive disorder, Katsanis et al. (2001) demonstrated that clinical manifestation of some forms of Bardet-Biedl syndrome requires recessive mutations in 1 of the 6 loci plus an additional mutation in a second locus. While Katsanis et al. (2001) called this 'triallelic inheritance,' Burghes et al. (2001) suggested the term 'recessive inheritance with a modifier of penetrance.' Mykytyn et al. (2002) found no evidence of involvement of the common BBS1 mutation in triallelic inheritance. However, Fan et al. (2004) found heterozygosity in a mutation of the BBS3 gene (608845.0002) as an apparent modifier of the expression of homozygosity of the met390-to-arg mutation in the BBS1 gene (209901.0001). Allelic disorders include nonsyndromic forms of retinitis pigmentosa: RP51 (613464), caused by TTC8 mutation, and RP55 (613575), caused by ARL6 mutation.
Meckel syndrome, type 1
MedGen UID:
811346
Concept ID:
C3714506
Disease or Syndrome
Meckel syndrome, also known as Meckel-Gruber syndrome, is a severe pleiotropic autosomal recessive developmental disorder caused by dysfunction of primary cilia during early embryogenesis. There is extensive clinical variability and controversy as to the minimum diagnostic criteria. Early reports, including that of Opitz and Howe (1969) and Wright et al. (1994), stated that the classic triad of Meckel syndrome comprises (1) cystic renal disease; (2) a central nervous system malformation, most commonly occipital encephalocele; and (3) polydactyly, most often postaxial. However, based on a study of 67 patients, Salonen (1984) concluded that the minimum diagnostic criteria are (1) cystic renal disease; (2) CNS malformation, and (3) hepatic abnormalities, including portal fibrosis or ductal proliferation. In a review of Meckel syndrome, Logan et al. (2011) stated that the classic triad first described by Meckel (1822) included occipital encephalocele, cystic kidneys, and fibrotic changes to the liver. Genetic Heterogeneity of Meckel Syndrome See also MKS2 (603194), caused by mutation in the TMEM216 gene (613277) on chromosome 11q12; MKS3 (607361), caused by mutation in the TMEM67 gene (609884) on chromosome 8q; MKS4 (611134), caused by mutation in the CEP290 gene (610142) on chromosome 12q; MKS5 (611561), caused by mutation in the RPGRIP1L gene (610937) on chromosome 16q12; MKS6 (612284), caused by mutation in the CC2D2A gene (612013) on chromosome 4p15; MKS7 (267010), caused by mutation in the NPHP3 (608002) gene on chromosome 3q22; MKS8 (613885), caused by mutation in the TCTN2 gene (613846) on chromosome 12q24; MKS9 (614209), caused by mutation in the B9D1 gene (614144) on chromosome 17p11; MKS10 (614175), caused by mutation in the B9D2 gene (611951) on chromosome 19q13; MKS11 (615397), caused by mutation in the TMEM231 gene (614949) on chromosome 16q23; MKS12 (616258), caused by mutation in the KIF14 gene (611279) on chromosome 1q32; MKS13 (617562), caused by mutation in the TMEM107 gene (616183) on chromosome 17p13; and MKS14 (619879), caused by mutation in the TXNDC15 gene (617778) on chromosome 5q31.
Asphyxiating thoracic dystrophy 1
MedGen UID:
1648057
Concept ID:
C4551856
Congenital Abnormality
Short-rib thoracic dysplasia (SRTD) with or without polydactyly refers to a group of autosomal recessive skeletal ciliopathies that are characterized by a constricted thoracic cage, short ribs, shortened tubular bones, and a 'trident' appearance of the acetabular roof. SRTD encompasses Ellis-van Creveld syndrome (EVC) and the disorders previously designated as Jeune syndrome or asphyxiating thoracic dystrophy (ATD), short rib-polydactyly syndrome (SRPS), and Mainzer-Saldino syndrome (MZSDS). Polydactyly is variably present, and there is phenotypic overlap in the various forms of SRTDs, which differ by visceral malformation and metaphyseal appearance. Nonskeletal involvement can include cleft lip/palate as well as anomalies of major organs such as the brain, eye, heart, kidneys, liver, pancreas, intestines, and genitalia. Some forms of SRTD are lethal in the neonatal period due to respiratory insufficiency secondary to a severely restricted thoracic cage, whereas others are compatible with life (summary by Huber and Cormier-Daire, 2012 and Schmidts et al., 2013). There is phenotypic overlap with the cranioectodermal dysplasias (Sensenbrenner syndrome; see CED1, 218330). Genetic Heterogeneity of Asphyxiating Thoracic Dysplasia SRTD1 has been mapped to chromosome 15q13. See also SRTD2 (611263), caused by mutation in the IFT80 gene (611177); SRTD3 (613091), caused by mutation in the DYNC2H1 gene (603297); SRTD4 (613819), caused by mutation in the TTC21B gene (612014); SRTD5 (614376), caused by mutation in the WDR19 gene (608151); SRTD6 (263520), caused by mutation in the NEK1 gene (604588); SRTD7 (614091), caused by mutation in the WDR35 gene (613602); SRTD8 (615503), caused by mutation in the WDR60 gene (615462); SRTD9 (266920), caused by mutation in the IFT140 gene (614620); SRTD10 (615630), caused by mutation in the IFT172 gene (607386); SRTD11 (615633), caused by mutation in the WDR34 gene (613363); SRTD13 (616300), caused by mutation in the CEP120 gene (613446); SRTD14 (616546), caused by mutation in the KIAA0586 gene (610178); SRTD15 (617088), caused by mutation in the DYNC2LI1 gene (617083); SRTD16 (617102), caused by mutation in the IFT52 gene (617094); SRTD17 (617405), caused by mutation in the TCTEX1D2 gene (617353); SRTD18 (617866), caused by mutation in the IFT43 gene (614068); SRTD19 (617895), caused by mutation in the IFT81 gene (605489); SRTD20 (617925), caused by mutation in the INTU gene (610621); and SRTD21 (619479), caused by mutation in the KIAA0753 gene (617112). See also SRTD12 (Beemer-Langer syndrome; 269860).

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PubMed

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Recent clinical studies

Etiology

Farr S, Jauker F, Ganger R, Kranzl A
Bone Joint J 2021 Feb;103-B(2):415-420. doi: 10.1302/0301-620X.103B2.BJJ-2020-1341.R2. PMID: 33517731
Kubat O, Antičević D
Foot Ankle Surg 2018 Aug;24(4):353-358. Epub 2017 Apr 13 doi: 10.1016/j.fas.2017.04.001. PMID: 29409237
Osborn EJ, Davids JR, Leffler LC, Gibson TW, Pugh LI
J Pediatr Orthop 2014 Apr-May;34(3):346-51. doi: 10.1097/BPO.0000000000000094. PMID: 24045588
Pritsch T, Ezaki M, Mills J, Oishi SN
J Hand Surg Am 2013 Mar;38(3):453-8. doi: 10.1016/j.jhsa.2012.12.012. PMID: 23428187
Belthur MV, Linton JL, Barnes DA
J Pediatr Orthop 2011 Jun;31(4):435-47. doi: 10.1097/BPO.0b013e3182199a68. PMID: 21572282

Diagnosis

Farr S, Jauker F, Ganger R, Kranzl A
Bone Joint J 2021 Feb;103-B(2):415-420. doi: 10.1302/0301-620X.103B2.BJJ-2020-1341.R2. PMID: 33517731
Kelly DM, Mahmoud K, Mauck BM
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Piette N, Zambelli PY, N'Dele D
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Stoll C, Dott B, Alembik Y, Roth MP
Eur J Med Genet 2015 Dec;58(12):674-80. Epub 2015 Nov 11 doi: 10.1016/j.ejmg.2015.11.003. PMID: 26578241
Coppolelli BG, Ready JE, Awbrey BJ, Smith LS
J Foot Surg 1991 Jan-Feb;30(1):12-8. PMID: 2002180

Therapy

Minakami H, Kubo T, Nakai A, Saito S, Unno N
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Prognosis

Farr S, Jauker F, Ganger R, Kranzl A
Bone Joint J 2021 Feb;103-B(2):415-420. doi: 10.1302/0301-620X.103B2.BJJ-2020-1341.R2. PMID: 33517731
Stoll C, Dott B, Alembik Y, Roth MP
Eur J Med Genet 2015 Dec;58(12):674-80. Epub 2015 Nov 11 doi: 10.1016/j.ejmg.2015.11.003. PMID: 26578241
Osborn EJ, Davids JR, Leffler LC, Gibson TW, Pugh LI
J Pediatr Orthop 2014 Apr-May;34(3):346-51. doi: 10.1097/BPO.0000000000000094. PMID: 24045588
Pritsch T, Ezaki M, Mills J, Oishi SN
J Hand Surg Am 2013 Mar;38(3):453-8. doi: 10.1016/j.jhsa.2012.12.012. PMID: 23428187
Belthur MV, Linton JL, Barnes DA
J Pediatr Orthop 2011 Jun;31(4):435-47. doi: 10.1097/BPO.0b013e3182199a68. PMID: 21572282

Clinical prediction guides

Farr S, Jauker F, Ganger R, Kranzl A
Bone Joint J 2021 Feb;103-B(2):415-420. doi: 10.1302/0301-620X.103B2.BJJ-2020-1341.R2. PMID: 33517731
Burger EB, Lalé SA, Hovius SER, Nieuwenhoven CAV, Bus SA
Foot Ankle Int 2019 Apr;40(4):414-421. Epub 2018 Dec 20 doi: 10.1177/1071100718816733. PMID: 30569754
Stoll C, Dott B, Alembik Y, Roth MP
Eur J Med Genet 2015 Dec;58(12):674-80. Epub 2015 Nov 11 doi: 10.1016/j.ejmg.2015.11.003. PMID: 26578241
Cox KF, Kerr NC, Kedrov M, Nishimura D, Jennings BJ, Stone EM, Sheffield VC, Iannaccone A
Vision Res 2012 Dec 15;75:77-87. Epub 2012 Aug 24 doi: 10.1016/j.visres.2012.08.005. PMID: 22940089
Belthur MV, Linton JL, Barnes DA
J Pediatr Orthop 2011 Jun;31(4):435-47. doi: 10.1097/BPO.0b013e3182199a68. PMID: 21572282

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