期刊名称:ePlasty: Open Access Journal of Plastic and Reconstructive Surgery
印刷版ISSN:1937-5719
出版年度:2016
卷号:16
语种:English
出版社:Open Science Co. LLC
摘要:DESCRIPTIONA 3-day-old female patient was evaluated in the neonatal intensive care unit for ‘extra fingers’ on bilateral upper extremities (Fig 1). X-ray images were taken (Fig 2) and genetic testing was done on the basis of numerous congenital abnormalities. The patient received a diagnosis of Ellis-van Creveld syndrome.QUESTIONSHow is polydactyly defined?What syndromes and patient populations are associated with polydactyly?What are the major classifications of polydactyly?How does the embryonic limb develop?DISCUSSIONThe most common congenital anomaly of the hand is polydactyly, characterized by partial or complete duplication of a digit on a normal 1-thumb and 4-finger hand.1These supernumerary digit anomalies can be classified into 3 distinct categories on the basis of their location: postaxial (ulnar), preaxial (radial), and central polydactyly. Each subset of polydactyly has its own specific genetic and ethnic association, with some being more heterogeneous than others.Certain ethnicities and races have higher prevalence of polydactyly. African Americans have a 10-fold risk of ulnar polydactyly with an incidence of 1 in 143. Conversely, radial duplication is more common in whites but overall less common.2Currently, more than 300 polydactyly disorders have been identified, with a majority being of syndromic association. These encompass all patterns of Mendelian inheritance as well as non-Mendelian forms. Certain syndromes are associated with specific forms of polydactyly. For example, trisomy 13 and Ellis-van Creveld and Smith-Lemli-Opitz syndromes are highly associated with ulnar polydactyly. Alternatively, Fanconi pancytopenia and Townes-Brocks and Holt-Oram syndromes are most frequently seen with radial anomalies.3Postaxial polydactyly is the most common of these categories, with the presence of supernumerary digit(s) on the ulnar side of the hand. Many classification systems exist for describing postaxial polydactyl. A new system recently proposed by Duran et al4subclassifies the digital anomalies based on anatomical features of the duplication. Type I is characterized by a skin nub that contains no nail or bone, whereas type II is defined by a hypoplastic proximal phalanx. Type III involves malformation of the proximal phalanx and is further divided into IIIA representing a bifid proximal phalanx and IIIB a duplicated proximal phalanx. Type IV consists of metacarpal malformations and can be further divided as follows: IV-A, fusion of the metacarpal; IV-B, bifid metacarpal; and IV-C, duplication of the metacarpal. Type V (complicated type) includes triplication of the small finger, polysyndactyly, or both.4The second most common congenital duplication is preaxial, or radial polydactyly. The incidence of radial polydactyly is estimated to be 1 in 3000 live births.1,2The most widely accepted and utilized classification system for preaxial polydactyly is the Wassel classification system, which is divided into 7 classes progressing distal to proximal. The even types (2, 4, and 6) bifurcate at the joints (distal interphalangeal, metacarpophalangeal, and carpometacarpal, respectively), with type 4 being most common at 40%.5Central polydactyly is the least common and is the presence of a supernumerary digit between the thumb and the fifth digit, most commonly at the ring finger. It is most often found in conjunction with syndactyly.1,2,6Previous studies of central polydactyly cases suggest an autosomal dominant pattern of inheritance.5Embryological development of the upper limbs begins shortly after week 4 of gestation. It is at this time that the limb is most susceptible to congenital abnormalities caused by disruption of the signaling centers and/or aberrant production of key regulatory proteins. Three critical signaling centers have been identified to play a substantial role in embryological development. These lead to the asymmetric development of the hand and include the apical ectodermal ridge (AER), zone of polarizing activity (ZPA), and the dorsal ectoderm Wingless-type signaling center (WNT).1,2AER is a highly specialized ectodermal region that expresses critical fibroblast growth factor family (FGF-2,-4,-8) molecules, which contribute to the growth along the proximal-distal axis and interdigital apoptosis.1,2Formation and growth along the anterior-to-posterior (radioulnar) axis is tightly regulated by sonic hedgehog (SHH). SHH forms a gradient through diffusion originating from the ZPA, which is located within the lateral plate mesoderm in what will become the ulnar limb (Fig 3). Secretion of SHH also induces growth via AER by increasing expression of FGF-4.7Dorsoventral differentiation (Fig 4) is controlled by WNT-7a protein expression from the WNT signaling center in the dorsal ectoderm. WNT-7a induces LIM Homeobox (Lmx-1b) gene expression resulting in dorsoventral limb growth.6Complementary protein Engrailed-1 blocks WNT-7a and allows for specific ventral (volar) surface differentiation.1,2Despite advancement of gene identification and interaction in limb development, the molecular mechanism of polydactyly remains unclear but is likely heterogeneous.
