Hand Deformities, Acquired
Hand Deformities
Hand Deformities, Congenital
Joint Deformities, Acquired
Foot Deformities, Acquired
Radial club hand with absence of the biceps muscle treated by centralisation of the ulna and triceps transfer. Report of two cases. (1/224)
Two children with radial club hand and absence of the biceps muscle were treated by centralisation of the ulna into the carpus and triceps transfer. The two operations were performed only a short time apart so that the period between the procedures could be used to stretch the triceps and to enable the children to adapt to an altered position of the wrist and to mobility of the elbow at one step and following a single period of plaster immobilisation. It is very likely that function is better than it would have been had the condition remained untreated. Before operation the children had only a crude hook function of the hand against the forearm and could not bring the hand to the mouth. Even if function is not much improved, the improvement in appearance is considerable and is by itself sufficient to justify the procedures. (+info)Fine mapping of the split-hand/split-foot locus (SHFM3) at 10q24: evidence for anticipation and segregation distortion. (2/224)
Split-hand/split-foot malformation (SHFM, ectrodactyly, or lobster-claw deformity) is a human limb malformation characterized by aberrant development of central digital rays with absence of fingers and toes, a deep median cleft, and fusion of remaining digits. SHFM is clinically heterogeneous, presenting both in an isolated form and in combination with additional abnormalities affecting the tibia and/or other organ systems, including the genitourinary, craniofacial, and ectodermal structures. Three SHFM disease loci have been genetically mapped to chromosomes 7q21 (SHFM1), Xq26 (SHFM2), and 10q24 (SHFM3). We mapped data from a large Turkish family with isolated SHFM to chromosome 10q24 and have narrowed the SHFM3 region from 9 cM to an approximately 2-cM critical interval between genetic markers D10S1147 and D10S1240. In several instances we found evidence for a more severe phenotype in offspring of a mildly affected parent, suggesting anticipation. Finally, data from this family, combined with those from six other pedigrees, mapped to 10q24, demonstrate biased transmission of SHFM3 alleles from affected fathers to offspring. The degree of this segregation distortion is obvious in male offspring and is possibly of the same magnitude for female offspring. (+info)Char syndrome, an inherited disorder with patent ductus arteriosus, maps to chromosome 6p12-p21. (3/224)
BACKGROUND: Patent ductus arteriosus (PDA) is a relatively common form of congenital heart disease. Although polygenic inheritance has been implicated, no specific gene defects causing PDA have been identified to date. Thus, a positional cloning strategy was undertaken to determine the gene responsible for the Char syndrome, an autosomal dominant disorder characterized by PDA, facial dysmorphism, and hand anomalies. METHODS AND RESULTS: A genome scan was performed with 46 members of 2 unrelated families in which the disease was fully penetrant but the phenotype differed. Significant linkage was achieved with several polymorphic DNA markers mapping to chromosome 6p12-p21 (maximal 2-point LOD score of 8.39 with D6S1638 at theta=0.00). Haplotype analysis identified recombinant events that defined the Char syndrome locus with high probability to a 3. 1-cM region between D6S459/D6S1632/D6S1541 and D6S1024. CONCLUSIONS: A familial syndrome in which PDA is a common feature was mapped to a narrow region of chromosome 6p12-p21. Additional analysis with other families and polymorphic markers as well as evaluation of potential candidate genes should lead to the identification of the Char syndrome gene, which will provide insights into cardiogenesis as well as limb and craniofacial development. (+info)Prenatal sonographic diagnosis of Aarskog syndrome. (4/224)
In 1970, Aarskog described a rare X-linked developmental disorder characterized by short stature in association with a variety of structural anomalies involving mainly the face, distal extremities, and external genitalia (faciodigitogenital syndrome). The major facial manifestations of this syndrome include hypertelorism, broad forehead, broad nasal bridge, short nose with anteverted nostrils, long philtrum, widow's peak hair anomaly, and ocular and ear anomalies. Limb abnormalities consist of short broad hands, brachydactyly, interdigital webbing, hypoplasia of the middle phalanges, proximal interphalangeal joint laxity with concomitant flexion and restriction of movement of distal interphalangeal joints, and flat broad feet with bulbous toes. Genital anomalies are characteristics and include shawl scrotum, cryptorchidism, and inguinal hernia. Most affected patients have normal intelligence, but some authors have noted mild neurodevelopmental delay in up to 30% of the cases. We describe a case of Aarskog syndrome diagnosed prenatally by sonography at 28 weeks' gestation in a high-risk pregnancy for this disorder. (+info)Heterozygous germline mutations in the p53 homolog p63 are the cause of EEC syndrome. (5/224)
EEC syndrome is an autosomal dominant disorder characterized by ectrodactyly, ectodermal dysplasia, and facial clefts. We have mapped the genetic defect in several EEC syndrome families to a region of chromosome 3q27 previously implicated in the EEC-like disorder, limb mammary syndrome (LMS). Analysis of the p63 gene, a homolog of p53 located in the critical LMS/EEC interval, revealed heterozygous mutations in nine unrelated EEC families. Eight mutations result in amino acid substitutions that are predicted to abolish the DNA binding capacity of p63. The ninth is a frameshift mutation that affects the p63alpha, but not p63beta and p63gamma isotypes. Transactivation studies with these mutant p63 isotypes provide a molecular explanation for the dominant character of p63 mutations in EEC syndrome. (+info)Clinical and radiological assessment of a family with mild brachydactyly type A1: the usefulness of metacarpophalangeal profiles. (6/224)
The brachydactylies are a group of conditions in which various subtypes have been defined based upon the specific pattern of digital bones involved. Type A1 brachydactyly is principally characterised by maximal involvement of the middle phalanges. We report an extended family with a mild brachydactyly A1 which was, except for some short stature, not associated with any of the additional clinical findings reported in several published families. While all the hand bones tended to be small, the principal features of the affected members were shortened middle and distal phalanges, proximal 1st phalanges, and 5th metacarpals. The feet were similarly involved and tended to have a broad, slightly adducted forefoot. The two affected children showed multiple coned epiphyses. This paper provides a detailed description of the family including the radiographic signs and metacarpophalangeal profiles, which proved to be useful in distinguishing the mildly affected persons. (+info)Novel HOXA13 mutations and the phenotypic spectrum of hand-foot-genital syndrome. (7/224)
Hand-foot-genital syndrome (HFGS) is a rare, dominantly inherited condition affecting the distal limbs and genitourinary tract. A nonsense mutation in the homeobox of HOXA13 has been identified in one affected family, making HFGS the second human syndrome shown to be caused by a HOX gene mutation. We have therefore examined HOXA13 in two new and four previously reported families with features of HFGS. In families 1, 2, and 3, nonsense mutations truncating the encoded protein N-terminal to or within the homeodomain produce typical limb and genitourinary abnormalities; in family 4, an expansion of an N-terminal polyalanine tract produces a similar phenotype; in family 5, a missense mutation, which alters an invariant domain, produces an exceptionally severe limb phenotype; and in family 6, in which limb abnormalities were atypical, no HOXA13 mutation could be detected. Mutations in HOXA13 can therefore cause more-severe limb abnormalities than previously suspected and may act by more than one mechanism. (+info)Split-hand/split-foot malformation is caused by mutations in the p63 gene on 3q27. (8/224)
Split-hand/split-foot malformation (SHFM), a limb malformation involving the central rays of the autopod and presenting with syndactyly, median clefts of the hands and feet, and aplasia and/or hypoplasia of the phalanges, metacarpals, and metatarsals, is phenotypically analogous to the naturally occurring murine Dactylaplasia mutant (Dac). Results of recent studies have shown that, in heterozygous Dac embryos, the central segment of the apical ectodermal ridge (AER) degenerates, leaving the anterior and posterior segments intact; this finding suggests that localized failure of ridge maintenance activity is the fundamental developmental defect in Dac and, by inference, in SHFM. Results of gene-targeting studies have demonstrated that p63, a homologue of the cell-cycle regulator TP53, plays a critically important role in regulation of the formation and differentiation of the AER. Two missense mutations, 724A-->G, which predicts amino acid substitution K194E, and 982T-->C, which predicts amino acid substitution R280C, were identified in exons 5 and 7, respectively, of the p63 gene in two families with SHFM. Two additional mutations (279R-->H and 304R-->Q) were identified in families with EEC (ectrodactyly, ectodermal dysplasia, and facial cleft) syndrome. All four mutations are found in exons that fall within the DNA-binding domain of p63. The two amino acids mutated in the families with SHFM appear to be primarily involved in maintenance of the overall structure of the domain, in contrast to the p63 mutations responsible for EEC syndrome, which reside in amino acid residues that directly interact with the DNA. (+info)Acquired hand deformities refer to structural changes in the hand or fingers that occur after birth, as a result of injury, illness, or other external factors. These deformities can affect any part of the hand, including the bones, joints, muscles, tendons, ligaments, and nerves. Common causes of acquired hand deformities include trauma, infection, degenerative diseases such as arthritis, tumors, and neurological conditions.
The symptoms of acquired hand deformities can vary depending on the severity and location of the deformity. They may include pain, stiffness, swelling, decreased range of motion, loss of function, and changes in appearance. Treatment for acquired hand deformities may involve a combination of medical interventions, such as medication, physical therapy, or splinting, as well as surgical procedures to correct the underlying structural problem. The goal of treatment is to relieve symptoms, improve function, and restore normal appearance and movement to the hand.
Hand deformities refer to any abnormal changes in the shape or structure of the hand, which can result from various causes such as genetic factors, injuries, illnesses, or aging. These deformities may affect one or more parts of the hand, including the bones, joints, muscles, tendons, ligaments, and nerves. Common examples of hand deformities include:
1. Trigger finger: A condition where the affected finger or thumb gets locked in a bent position and can only be straightened with a snapping motion.
2. Dupuytren's contracture: A progressive hand deformity that causes the fingers to bend towards the palm due to thickening and shortening of the palmar fascia.
3. Mallet finger: An injury to the extensor tendon at the end joint of a finger, causing it to droop and making it difficult to straighten the fingertip.
4. Boutonnière deformity: A condition where the middle joint of a finger is dislocated and cannot be straightened due to damage to the central slip of the extensor tendon.
5. Camptodactyly: A congenital hand deformity characterized by permanent flexion of one or more fingers, typically affecting the little finger.
6. Rheumatoid arthritis: An autoimmune disease that can cause joint inflammation and damage, leading to hand deformities such as swan neck deformity and boutonnière deformity.
7. Fractures or dislocations: Trauma to the hand can result in various deformities depending on the severity and location of the injury.
8. Nerve injuries: Damage to nerves in the hand can lead to muscle weakness, numbness, tingling, and deformities such as claw hand or ulnar claw hand.
9. Osteoarthritis: A degenerative joint disease that commonly affects the hands, causing pain, stiffness, and potential deformities in the fingers and thumb.
10. Congenital hand differences: Birth defects that result in missing or abnormally formed parts of the hand, such as radial clubhand or cleft hand.
Congenital hand deformities refer to physical abnormalities or malformations of the hand, wrist, and/or digits (fingers) that are present at birth. These deformities can result from genetic factors, environmental influences during pregnancy, or a combination of both. They may affect the bones, muscles, tendons, joints, and other structures in the hand, leading to varying degrees of impairment in function and appearance.
There are numerous types of congenital hand deformities, some of which include:
1. Polydactyly: The presence of extra digits on the hand, which can be fully formed or rudimentary.
2. Syndactyly: Webbing or fusion of two or more fingers, which may involve soft tissue only or bone as well.
3. Clinodactyly: A curved finger due to a sideways deviation of the fingertip, often affecting the little finger.
4. Camptodactyly: Permanent flexion or bending of one or more fingers, typically involving the proximal interphalangeal joint.
5. Trigger Finger/Thumb: A condition where a finger or thumb becomes locked in a bent position due to thickening and narrowing of the tendon sheath.
6. Radial Club Hand (Radial Ray Deficiency): Underdevelopment or absence of the radius bone, resulting in a short, curved forearm and hand deformity.
7. Ulnar Club Hand (Ulnar Ray Deficiency): Underdevelopment or absence of the ulna bone, leading to a short, curved forearm and hand deformity.
8. Cleidocranial Dysplasia: A genetic disorder affecting bone growth, resulting in underdeveloped or absent collarbones, dental abnormalities, and occasionally hand deformities.
9. Apert Syndrome: A rare genetic disorder characterized by the fusion of fingers and toes (syndactyly) and other skeletal abnormalities.
10. Holt-Oram Syndrome: A genetic disorder involving heart defects and upper limb deformities, such as radial ray deficiency or thumb anomalies.
Treatment for hand deformities varies depending on the specific condition and severity. Options may include physical therapy, bracing, splinting, medications, or surgical intervention.
Acquired joint deformities refer to structural changes in the alignment and shape of a joint that develop after birth, due to various causes such as injury, disease, or wear and tear. These deformities can affect the function and mobility of the joint, causing pain, stiffness, and limited range of motion. Examples of conditions that can lead to acquired joint deformities include arthritis, infection, trauma, and nerve damage. Treatment may involve medication, physical therapy, or surgery to correct the deformity and alleviate symptoms.
Acquired foot deformities refer to structural abnormalities of the foot that develop after birth, as opposed to congenital foot deformities which are present at birth. These deformities can result from various factors such as trauma, injury, infection, neurological conditions, or complications from a medical condition like diabetes or arthritis.
Examples of acquired foot deformities include:
1. Hammertoe - A deformity where the toe bends downward at the middle joint, resembling a hammer.
2. Claw toe - A more severe form of hammertoe where the toe also curls under, forming a claw-like shape.
3. Mallet toe - A condition where the end joint of a toe is bent downward, causing it to resemble a mallet.
4. Bunions - A bony bump that forms on the inside of the foot at the big toe joint, often causing pain and difficulty wearing shoes.
5. Tailor's bunion (bunionette) - A similar condition to a bunion, but it occurs on the outside of the foot near the little toe joint.
6. Charcot foot - A severe deformity that can occur in people with diabetes or other neurological conditions, characterized by the collapse and dislocation of joints in the foot.
7. Cavus foot - A condition where the arch of the foot is excessively high, causing instability and increasing the risk of ankle injuries.
8. Flatfoot (pes planus) - A deformity where the arch of the foot collapses, leading to pain and difficulty walking.
9. Pronation deformities - Abnormal rotation or tilting of the foot, often causing instability and increasing the risk of injury.
Treatment for acquired foot deformities varies depending on the severity and underlying cause but may include orthotics, physical therapy, medication, or surgery.
In medical terms, a hand is the part of the human body that is attached to the forearm and consists of the carpus (wrist), metacarpus, and phalanges. It is made up of 27 bones, along with muscles, tendons, ligaments, and other soft tissues. The hand is a highly specialized organ that is capable of performing a wide range of complex movements and functions, including grasping, holding, manipulating objects, and communicating through gestures. It is also richly innervated with sensory receptors that provide information about touch, temperature, pain, and proprioception (the sense of the position and movement of body parts).