Hip dysplasia (human)

Hip dysplasia (human)
Hip dysplasia (human)
Classification and external resources

Congenital dislocation of the left hip in an elderly person. Closed arrow marks the acetabulum, open arrow the femoral head.
ICD-10 Q65
ICD-9 754.3
OMIM 142700
DiseasesDB 3056
MedlinePlus 000971
eMedicine orthoped/456
MeSH D006618

Hip dysplasia, developmental dysplasia of the hip (DDH)[1] or congenital dysplasia of the hip (CDH)[2] is a congenital or acquired deformation or misalignment of the hip joint.



Some sources prefer "developmental dysplasia of the hip" (DDH) to "congenital dislocation of the hip" (CDH), finding the latter term insufficiently flexible in describing the diversity of potential complications.[3]

The use of the word congenital can also imply that the condition already exists at birth. This terminology introduces challenges, because the joint in a newborn is formed from cartilage and still malleable, making the onset difficult to ascertain.

The newer term DDH also encompasses occult dysplasia (e.g. an underdeveloped joint) without dislocation and dislocation developing after the "newborn" phase.

The term is not used consistently. In pediatric/neonatal orthopedics it is used to describe unstable/dislocatable hips and poorly developed acetabula. For adults it describes hips showing abnormal femur head or acetabular x-rays.[4][5]

Some sources prefer the term "hip dysplasia" over DDH, considering it to be "simpler and more accurate", partly because of the redundancy created by the use of the terms developmental and dysplasia.[6] TYPES OF DDH include subluxation,dysplasia,and dislocation.The main types are the result of either laxity of the supporting capsule or an abnormal acetabulum.

Forms of the condition

Types of misalignments of femur head to socket in hip dysplasia. A: Normal. B: Dysplasia. C: Subluxation. D: Luxation

Hip dysplasia can range from barely detectable to severely malformed / dislocated. The congenital form, teratologic or non-reducible dislocation occurs as part of more complex conditions.

The condition can be bilateral or unilateral:

  • If both hip joints are affected one speaks of "bilateral" dysplasia. In this case some diagnostic indicators like asymmetric folds and leg-length inequality do not apply.
  • In unilateral dysplasia only one joint shows deformity, the contralateral side may show resulting effects.[7] In the majority of unilateral cases the left hip has the dysplasia.

If the joint is fully dislocated a false acetabulum often forms (often higher up on the pelvis) opposite the dislocated femoral head position.

In actetabular dysplasia the acetabulum (socket) is too shallow or deformed. The center-edge angle is measured as described by Wiberg.[8] In coxa vara the femur head grows at too narrow an angle to the shaft, in coxa valga the angle is too wide.

A rare type, the "Beukes familial hip dysplasia" is found among Afrikaners that are members of the Beukes family. The femur head is flat and irregular. Sufferers develop osteoarthritis at an early age.[9]

Crowe classification

In 1979 Dr. John F. Crowe [10] et al. proposed a classification to define the degree of malformation and dislocation. Grouped from least severe Crowe I dysplasia to most severe Crowe IV.[11] This classification is very useful for studying treatment results.

Rather than using the Wiberg angle because it makes it difficult to quantify the degree of dislocation they used 3 key elements to determine the degree of subluxation: A reference line at the lower rim of the "teardrop", junction between the femoral head and neck of the respective joint and the height of the pelvis (vertical measurement). They studied anteroposterior pelvic x-rays and drew horizontal lines through the lower rim of a feature called "teardrop". The distance between this line and the middle lines of the junction between femur head and neck gave them a measure of the degree of femur head subluxation. They further established that a "normal" diameter of the femur head measures 20% of the height of the pelvis. If the middle line of the neck-head junction was more than 10% of the pelvis height above the reference line they considered the joint to be more than 50% dislocated.

The following types resulted:

Class Description Dislocation
Crowe I Femur and acetabulum show minimal abnormal development. Less than 50% dislocation
Crowe II The acetabulum shows abnormal development. 50% to 75% dislocation
Crowe III The acetabula is developed without a roof. A false acetabulum develops opposite the dislocated femur head position. The joint is fully dislocated. 75% to 100% dislocation
Crowe IV The acetabulum is insufficiently developed. Since the femur is positioned high up on the pelvis this class is also known as "high hip dislocation". 100% dislocation


Determining the incidence can be difficult.[12][13] In addition there is a wide margin in diagnostic results. A German study comparing two methods resulted in twice the usual rate for one method.

An instability rate of 1:60 has been described, though this rate drops to 1:240 at one week.[14] The condition is eight times more frequent in females than in males.[15]


Hip dysplasia is considered to be a multifactorial condition. That means that several factors are involved in causing the condition to manifest.[16] Cause is unknown but common in breech position or large fetal size.


Some studies suggest a hormonal link.[15] Specifically the hormone relaxin has been indicated.[17]

A genetic factor is indicated by the trait running in families and increased occurrence in some ethnic populations (e.g. native Americans,[18] Lapps[19] / Sami people[20]). A locus has been described on chromosome 13.[21] Beukes familial dysplasia, on the other hand, was found to map to an 11-cM region on chromosome 4q35. With nonpenetrant carriers not affected.[22]


As an acquired condition it has often been linked to traditions of swaddling infants[23] or use of a cradle board which locks the hip joint in an "adducted" position (pulling the knees together tends to pull the heads of the femur bone out of the sockets or acetabulae) for extended periods. Modern swaddling techniques allow some room for leg movement.[24]

Further risk factors include breech birth and firstborns.[25] In breech position the femoral head tends to get pushed out of the socket. A narrow uterus also facilitates hip joint dislocation during fetal development and birth.


Most countries have standard newborn exams that include a hip joint exam screening for early detection of hip dysplasia. It can often be detected by a "click" or more precisely "clunk" in the hip[26] (although not all clicks indicate hip dysplasia).[27] Two maneuvers commonly employed for diagnosis in neonatal exams are the Ortolani maneuver and the Barlow maneuver.

The condition can be confirmed by ultrasound and X-ray. Ultrasound imaging yields better results defining the anatomy until the cartilage is ossified. When the infant is around 3 months old a clear roentgenographic image can be achieved. Unfortunately the time the joint gives a good x-ray image is also the point at which nonsurgical treatment methods cease to give good results. In x-ray imaging dislocation may be indicated if the Shenton's line (an arc drawn from the medial aspect of the femoral neck through the superior margin of the obturator foramen[28]) does not result in a smooth arc. However in infants this line can be unreliable as it depends on the rotation of the hip when the image is taken ([29])

Asymmetrical gluteal folds and an apparent limb-length inequality can further indicate unilateral hip dysplasia. Most vexingly, many newborn hips show a certain ligamentous laxity, on the other hand severely malformed joints can appear stable. That is one reason why follow-up exams and developmental monitoring are important. Routine ultrasound screening has been discussed and rejected mainly because the small benefit would not justify the costs.[30]

The Harris hip score[31] (developed by William H. Harris MD, an orthopedist from Massachusetts) is one way to evaluate hip function following surgery. Other scoring methods are based on patients' evaluation like e.g. the Oxford hip score, HOOS and WOMAC score.[32] Children's Hospital Oakland Hip Evaluation Scale (CHOHES) is a modification of the Harris hip score that is currently being evaluated.[33]


Given the very real possibility of a limp, constant and/or debilitating pain, complicated treatment and impaired mobility later in life, careful developmental monitoring and early intervention are indicated. The worst possible consequence of non treatment is developing early arthritis, sometimes even during teenage years. All treatment aims to delay the onset of arthritis, but no treatment is fully successful in avoiding it.

Harnesses, casts, and traction

Early hip dysplasia can often be treated using a Pavlik harness (see photograph) or the Frejka pillow/splint[34] in the first year of life with usually normal results. Cases of femoral head avascular necrosis have been reported with the use of the Pavlik harness,[35] but whether these cases were due to improper application of the device or a complication encountered in the course of the disorder remains unresolved. Complications arise mainly because the sheet of the iliopsoas muscle pushes circumflex artery against the neck of the femur and decreases blood flow to the femoral head. That is the reason why the Frejka pillow is not indicated in all the forms of the developmental dysplasia of the hip.[citation needed]

Other devices employed include the spica cast, particularly following surgical closed reduction. A few weeks in traction can be used as part of a treatment plan.


In older children the hip abductor and iliopsoas muscles have to be treated surgically because they adapt to the dislocated joint position (contracture). Braces and splints are often used following either of these methods to continue treatment. Although some children "outgrow" untreated mild hip dysplasia[5] and some forms of untreated dysplasia cause little or no impairment of quality of life, studies have as yet been unable to find a method of predicting outcomes. On the other hand, it has often been documented that starting treatment late leads to complications and ends in poor results.

Stem cells

One avenue of research is using stem cells. They are applied in grafting (bone grafting) or by seeding porous arthroplasty prosthesis with autologous fibroblasts or chondrocyte progenitor cells to assist in firmly anchoring the artificial material in the bone bed.

Hip replacement and osteotomy

Hip dysplasia is often cited as causing osteoarthritis of the hip at a comparatively young age. Dislocated load bearing surfaces lead to increased and unusual wear. Although there are studies that contradict these findings. (see [36][37]) Subsequent treatment with total hip arthroplasty (hip replacement) is complicated by a need for revision surgery (replacing the artificial joint) owing to skeletal changes as the body matures, loosening/wear or bone resorption.

Osteotomies are either used in conjunction with arthroplasty or by themselves to correct misalignment.

Cultural references

In the television program "ER," Kerry Weaver uses a crutch owing to congenital hip dysplasia. In season 12, she undergoes a hip replacement to cure her dysplasia when her previously untreated joint worsens.[38]

See also


  1. ^ "Your Orthopaedic Connection: Developmental Dysplasia of the Hip". http://orthoinfo.aaos.org/topic.cfm?topic=A00347. 
  2. ^ "Definition: congenital dysplasia of the hip from Online Medical Dictionary". http://cancerweb.ncl.ac.uk/cgi-bin/omd?congenital+dysplasia+of+the+hip. 
  3. ^ "Developmental Dysplasia of the Hip - October 15, 2006 -- American Family Physician". http://www.aafp.org/afp/20061015/1310.html. 
  4. ^ Dr. Rose's Peripheral Brain-DEVELOPMENTAL DYSPLASIA OF THE HIP
  5. ^ a b Screening for Developmental Dysplasia of the Hip - July 1999 - American Academy of Family Physicians
  6. ^ "eMedicine - Developmental Dysplasia of the Hip : Article by James McCarthy, MD, FAAOS". http://www.emedicine.com/orthoped/topic456.htm. 
  7. ^ Jacobsen S, Rømer L, Søballe K (2006). "The other hip in unilateral hip dysplasia". Clin. Orthop. Relat. Res. 446: 239–46. doi:10.1097/01.blo.0000201151.91206.50. PMID 16721954. 
  8. ^ Wiberg G. Studies of acetabular and congenital subluxation of the hip joint with special reference to complication of osteoarthritis Acta Chir Scand 1939, 83(Suppl. 58)
  9. ^ Cilliers HJ, Beighton P (1990). "Beukes familial hip dysplasia: an autosomal dominant entity". Am. J. Med. Genet. 36 (4): 386–90. doi:10.1002/ajmg.1320360403. PMID 2389793. 
  10. ^ http://www.onsmd.com/Jon-F-Crowe-MD
  11. ^ Crowe JF, Mani VJ, Ranawat CS (1979). "Total hip replacement in congenital dislocation and dysplasia of the hip". J Bone Joint Surg Am 61 (1): 15–23. PMID 365863. 
  12. ^ Bialik V, Bialik GM, Blazer S, Sujov P, Wiener F, Berant M (1999). "Developmental dysplasia of the hip: a new approach to incidence". Pediatrics 103 (1): 93–9. doi:10.1542/peds.103.1.93. PMID 9917445. http://pediatrics.aappublications.org/cgi/pmidlookup?view=long&pmid=9917445. 
  13. ^ Kokavec M, Bialik V (2007). "Developmental dysplasia of the hip. Prevention and real incidence". Bratisl Lek Listy 108 (6): 251–4. PMID 17972535. 
  14. ^ "UNSW Embryology- Musculoskeletal System - Abnormalities". http://embryology.med.unsw.edu.au/Notes/skmus2.htm. 
  15. ^ a b Clinical Practice Guideline: Early Detection of Developmental Dysplasia of the Hip - Committee on Quality Improvement, Subcommittee on Developmental Dysplasia of the Hip 105 (4): 896 - AAP Policy
  16. ^ Lynn T Staheli, Fundamentals of Pediatric Orthopedics, p 13
  17. ^ Forst J, Forst C, Forst R, Heller KD (1997). "Pathogenetic relevance of the pregnancy hormone relaxin to inborn hip instability". Arch Orthop Trauma Surg 116 (4): 209–12. doi:10.1007/BF00393711. PMID 9128773. 
  18. ^ CHSC01
  19. ^ The occurrence of hip joint dislocation in early Lappic populations of Norway, Per Holck, Anthropological Department, Anatomical Institute, Box 1105 Blindern, N-0317 Oslo 3, Norway
  20. ^ Forsdahl A (2000). "[A physician from Finnmark who pointed out the significance of heredity in congenital hip dysplasia]" (in Norwegian). Tidsskr. Nor. Laegeforen. 120 (22): 2672–3. PMID 11077514. 
  21. ^ Mabuchi A, Nakamura S, Takatori Y, Ikegawa S (2006). "Familial osteoarthritis of the hip joint associated with acetabular dysplasia maps to chromosome 13q". Am. J. Hum. Genet. 79 (1): 163–8. doi:10.1086/505088. PMC 1474113. PMID 16773577. http://linkinghub.elsevier.com/retrieve/pii/S0002-9297(07)60018-4. 
  22. ^ AJHG - Autosomal Dominant (Beukes) Premature Degenerative Osteoarthropathy of the Hip Joint Maps to an 11-cM Region on Chromosome 4q35
  23. ^ Mahan ST, Kasser JR (2008). "Does swaddling influence developmental dysplasia of the hip?". Pediatrics 121 (1): 177–8. doi:10.1542/peds.2007-1618. PMID 18166571. http://pediatrics.aappublications.org/cgi/pmidlookup?view=long&pmid=18166571. 
  24. ^ "The Right Way to Swaddle - Well - Tara Parker-Pope - Health - New York Times Blog". The New York Times. January 14, 2008. http://well.blogs.nytimes.com/2008/01/14/the-right-way-to-swaddle/. Retrieved May 4, 2010. 
  25. ^ "Developmental Dislocation of the Hip - Wheeless' Textbook of Orthopaedics". http://www.wheelessonline.com/ortho/developmental_dislocation_of_the_hip. 
  26. ^ "HipDysplasia - Newborn Nursery at LPCH - Stanford University School of Medicine". http://newborns.stanford.edu/HipDysplasia.html. 
  27. ^ Kamath S, Bramley D (2005). "Is 'clicky hip' a risk factor in developmental dysplasia of the hip?". Scott Med J 50 (2): 56–8. PMID 15977515. 
  28. ^ "Shenton's line (www.whonamedit.com)". http://www.whonamedit.com/synd.cfm/2456.html. 
  29. ^ "Radiographic features: DDH". Weeless' Textbook of Orthopaedics. http://www.wheelessonline.com/ortho/radiographic_features_ddh. 
  30. ^ http://www.york.ac.uk/inst/crd/projects/hipdysplasia.htm
  31. ^ Harris Hip Score - Orthopaedic Scores
  32. ^ Wylde V, Learmonth ID, Cavendish VJ (2005). "The Oxford hip score: the patient's perspective". Health Qual Life Outcomes 3: 66. doi:10.1186/1477-7525-3-66. PMC 1283979. PMID 16259627. http://www.hqlo.com/content/3//66. 
  33. ^ Aguilar CM, Neumayr LD, Eggleston BE, et al. (2005). "Clinical evaluation of avascular necrosis in patients with sickle cell disease: Children's Hospital Oakland Hip Evaluation Scale--a modification of the Harris Hip Score". Arch Phys Med Rehabil 86 (7): 1369–75. doi:10.1016/j.apmr.2005.01.008. PMID 16003666. http://linkinghub.elsevier.com/retrieve/pii/S0003999305002145. 
  34. ^ Czubak J, Piontek T, Niciejewski K, Magnowski P, Majek M, Płończak M (2004). "Retrospective analysis of the non-surgical treatment of developmental dysplasia of the hip using Pavlik harness and Fredjka pillow: comparison of both methods". Ortop Traumatol Rehabil 6 (1): 9–13. PMID 17676003. 
  35. ^ Nakamura J, Kamegaya M, Saisu T, Someya M, Koizumi W, Moriya H (2007). "Treatment for developmental dysplasia of the hip using the Pavlik harness: long-term results". J Bone Joint Surg Br 89 (2): 230–5. doi:10.1302/0301-620X.89B2.18057. PMID 17322441. http://www.jbjs.org.uk/cgi/pmidlookup?view=long&pmid=17322441. 
  36. ^ Lau EM, Lin F, Lam D, Silman A, Croft P (1995). "Hip osteoarthritis and dysplasia in Chinese men". Ann. Rheum. Dis. 54 (12): 965–9. doi:10.1136/ard.54.12.965. PMC 1010061. PMID 8546528. http://ard.bmj.com/cgi/pmidlookup?view=long&pmid=8546528. 
  37. ^ Lievense AM, Bierma-Zeinstra SM, Verhagen AP, Verhaar JA, Koes BW (2004). "Influence of hip dysplasia on the development of osteoarthritis of the hip". Ann. Rheum. Dis. 63 (6): 621–6. doi:10.1136/ard.2003.009860. PMC 1755018. PMID 15140766. http://ard.bmj.com/cgi/pmidlookup?view=long&pmid=15140766. 
  38. ^ "Out on a Limb". http://www.erheadquarters.com/episodes/12/12261.htm. 

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