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AUTHOR AND EDITOR INFORMATION

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Author: William Moore, MD, Staff Physician, Department of Radiology, State University of New York at Stony Brook University Medical Center

William Moore is a member of the following medical societies: Association of University Radiologists and Radiological Society of North America

Coauthor(s): Thomas H Smith, MD, Associate Professor, Departments of Radiology and Pediatrics, State University of New York at Stony Brook

Editors: Beverly P Wood, MD, MS Ed, PhD, Professor, Departments of Radiology and Pediatrics, Division of Medical Education, Keck School of Medicine, University of Southern California; Bernard D Coombs, MB, ChB, PhD, Consulting Staff, Department of Specialist Rehabilitation Services, Hutt Valley District Health Board, New Zealand; Marta Hernanz-Schulman, MD, FAAP, Professor, Radiology, Radiological Sciences, and Pediatrics, Director, Department of Pediatric Radiology, Radiologist-in-Chief, Director, Department of Diagnostic Imaging, Vanderbilt University Medical Center, Vanderbilt Children's Hospital; Robert M Krasny, MD, Consulting Staff, Department of Radiology, The Angeles Clinic and Research Institute; Felix S Chew, MD, EdM, MBA, Professor, Department of Radiology, Section Head of Musculoskeletal Radiology, Vice Chairman for Radiology Informatics, University of Washington

Author and Editor Disclosure

Synonyms and related keywords: growth plate fractures, pediatric fractures, physeal injuries, childhood fractures, Salter-Harris fractures type I, Salter-Harris fractures type II, Salter-Harris fractures type III, Salter-Harris fractures type IV, Salter-Harris fractures type V, Salter-Harris fractures type VI, Salter-Harris fractures type VII, Salter-Harris fractures type VIII, Salter-Harris fractures type IX

INTRODUCTION

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Background

Salter-Harris fractures are fractures through a growth plate; therefore, they are unique to pediatric patients. Several types of fractures have been categorized by the involvement of the physis, metaphysis, and epiphysis. The classification of the injury is important because it affects the treatment of the patient and provides clues to possible long-term complications.

Pathophysiology

The histologic features of the physis are important for understanding the prognosis of physeal fractures. The germinal layer of the cartilage is on the epiphysis and derives nutrition from the epiphyseal vessels. Cartilage cells grow from the epiphysis toward the metaphysis, forming columns of cells that degenerate, fragment, and undergo hypertrophy. The fragments of cells mineralize. This is the zone of provisional calcification forming the metaphyseal border and is not bone. Note that no circulation exists in the cartilage zone.

Neovascularization occurs from the metaphysis toward the epiphysis. Endothelial cells transform into osteoblasts and use the degenerate cell debris to form primary immature bone. This immature bone progressively is remodeled to mature woven bone and, further, is remodeled by cutting cones to form mature haversian system bone. Damage to either epiphyseal or metaphyseal vascular supply disrupts bone growth; however, damage to the layer of cartilage may not be significant if the surfaces are reapposed, and vascular supply to the growing cartilage is not permanently interrupted. When the 2 vascular beds touch, the physis is closed (fused) and no further bone growth is possible.

Age

Salter-Harris fractures are injuries through the physis. Therefore, by definition, they must occur before the physis closes. Typically, physis closure occurs during the teenage years.

Clinical Details

The classification of Salter-Harris fractures is used to describe the extent and site of the epiphyseal injuries. The basic types of  Salter-Harris fracture include the following:

  • Type I

    • A type 1 fracture is a transverse fracture through the hypertrophic zone of the physis. In this injury, the width of the physis is increased. The growing zone of the physis usually is not injured, and growth disturbance is uncommon.


    • On clinical examination, the child has point tenderness at the epiphyseal plate, which is suggestive of a type I fracture.
       
  • Type II

    • A type II fracture is a fracture through the physis and the metaphysis, but the epiphysis is not involved in the injury.


    • These fractures may cause minimal shortening; however, the injuries rarely result in functional limitations.


    • Type II is the most common type of Salter-Harris fracture.
       
  • Type III

    • A type III fracture is a fracture through the physis and the epiphysis. This fracture passes through the hypertrophic layer of the physis and extends to split the epiphysis, inevitably damaging the reproductive layer of the physis.


    • This type of fracture is prone to chronic disability because by crossing the physis, the fracture extends into the articular surface of the bone.


    • However, type III fractures rarely result in significant deformity; therefore, they have a relatively favorable prognosis.


    • A type of ankle fracture termed a Tillaux fracture is a type of Salter-Harris type III fracture that is prone to disability.


    • The treatment for this fracture is often surgical.
       
  • Type IV

    • A Type IV fracture involves all 3 elements of the bone: The fracture passes through the epiphysis, physis, and metaphysis.


    • Similar to a type III fracture, a type IV fracture is an intra-articular fracture; thus, it can result in chronic disability.


    • By interfering with the growing layer of cartilage cells, these fractures can cause premature focal fusion of the involved bone. Therefore, these injuries can cause deformity of the joint.
       
  • Type V

    • A type V injury is a compression or crush injury of the epiphyseal plate with no associated epiphyseal or metaphyseal fracture.


    • This fracture is associated with growth disturbances at the physis. Initially, diagnosis may be difficult, and it often is made retrospectively after premature closure of the physis is observed. In the older teenagers, the diagnosis is particularly difficult.


    • The clinical history is paramount in the diagnosis of this fracture. A typical history is that of an axial load injury.


    • These injuries have a poor functional prognosis.

When all types of Salter-Harris fractures are considered, the rate of growth disturbance is approximately 30%. However, only 2% of Salter-Harris fractures result in a significant functional disturbance.

Rare types of Salter-Harris fractures include the following:

  • Type VI: This is a rare injury and consists of an injury to the perichondral structures.


  • Type VII: This is an isolated injury to the epiphyseal plate.


  • Type VIII: This is an isolated injury to the metaphysis, with a potential injury related to endochondral ossification.


  • Type IX: This is an injury to the periosteum that may interfere with membranous growth.

Preferred Examination

Radiography always is the preferred examination in a suspected fracture. The use of another modality should not be considered until appropriate plain film radiography has been performed.

In cases of severe injury in which the patient has acute pain, appropriate radiographic examination of the involved area may be difficult because of inadequate patient positioning. In these cases, CT may be beneficial in evaluating the injury after a radiologist has evaluated the plain radiographs. However, the cost of CT may prohibit its use in all cases in which the area of interest is suboptimally evaluated. CT should be considered only when radiographic findings are insufficient. Typically, an orthopedic surgeon and a radiologist make the decision to perform CT.

If an additional study is performed, its purpose is to determine the appropriate management and to assist in surgical planning. Thus, the surgeon performing the operation is best suited to request the imaging study. When further definition of fractures may help in making management decisions or when the injury does not respond to conservative management, the radiologist or orthopedic surgeon can recommend an appropriate examination to perform after plain radiography.

Currently, 2 radiologic examinations can be performed to further evaluate fractures: (1) CT with multiplanar reconstruction and (2) MRI. MRI depicts marrow edema, whereas CT shows cross-sectional bone detail and tomographic multiplanar information. The use of MRI in the evaluation of fractures is described below, but it is still in its infancy. At the present time, MRI is not the standard of care. CT is used more commonly; typically, it is used for planning surgery.

Limitations of Techniques

The primary disadvantages of MRI are related to its expense, time requirement, and availability, which limit the routine use of MRI. As techniques and software improve, the use of MRI in the acute trauma setting is likely to increase.


DIFFERENTIALS

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[Elbow Trauma - Pediatric]
Ankle, Fractures
Wrist, Scaphoid Fractures and Complications

RADIOGRAPH

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Findings

X-ray findings vary according to the type of Salter-Harris fracture.

With type I fractures, initial radiographs may suggest separation of the physis, but this separation may not be apparent. However, soft-tissue swelling is present, and its center typically overlies the physis (see Image 2). Follow-up radiographs obtained 7-10 days after injury help establish the diagnosis. New bone growth (ie, adjacent sclerosis and periosteal reaction) along the epiphyseal plate confirms the diagnosis of a Salter-Harris type I fracture.

In type II fractures, the fracture line passes through the metaphysis into the epiphyseal plate, but no fracture is observed in the epiphysis (see Image 3). The metaphyseal fragment is sometimes called the Thurston-Holland fragment.

Type III fractures pass through the hypertrophic layer of the physis and extend to split the epiphysis (see Image 4). The fracture crosses the physis and extends into the articular surface of the bone.

Type IV fractures pass through the epiphysis, physis, and metaphysis (see Image 5). Similar to a type III fracture, a type IV fracture is an intra-articular fracture.

In type V injuries, initial plain radiographs may not show a fracture line, similar to images of type I fractures (see Image 6). However, soft-tissue swelling at the physis is present. A compression or crush injury of the epiphyseal plate is present without associated epiphyseal or metaphyseal fracture.


CT SCAN

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Findings

CT has an important role in the evaluation of epiphyseal injuries. Rogers and Poznanski1 discussed the role of CT along with the use of a bone algorithm and multiplanar reconstruction of multiplanar initial images. With CT, a considerable amount of information regarding the nature of the fracture can be gathered. CT techniques typically are used in patients prior to surgery, after a fracture is diagnosed on the basis of plain radiographic findings.

Multiplanar CT findings are similar to plain radiographic findings.

Degree of Confidence

The computer program is able to compensate for imprecise patient positioning. True lateral and true anteroposterior (AP) views of the bone in question can be obtained. As with any study, physicians who request these costly studies should have the knowledge and experience needed to interpret the images. Orthopedic surgeons may be the ones to request CT examinations; however, any physician can order them in consultation with a radiologist.

The advantages of CT over MRI are its greater availability and the faster speed in obtaining images. The disadvantage is that CT requires a relatively large dose of radiation for diagnostic imaging. Raw-data images typically are obtained with 1-mm sections and a high milliampere technique; however, the high collimation reduces the total amount of exposure.

In the near future, multi–detector row technology is likely to affect the utility of CT in the detailed evaluation of fractures.


MRI

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Findings

On MRIs, the typical findings of Salter-Harris fractures include a signal void on T1-weighted images. On T2-weighted images, increased signal intensity, which is consistent with edema, is depicted around the fracture site.

MRI is used for surgical planning. Craig et al2discussed the use of MRI in evaluating partial closure of the growth plates. Patients with functional or growth abnormalities were examined with MRI, and the exact nature of the defects were well described. These findings helped orthopedic surgeons plan appropriate surgery.

Currently, no imaging technique is recommended and uniformly accepted for use in the evaluation of a Salter-Harris injury in children. However, from data in this section, one could conclude that MRI with multiple sequences provides more information than MRI with a single sequence. Thus, T1-weighted, T2-weighted, and gradient-echo imaging without contrast enhancement can be used to evaluate the bony structures, soft tissues, and physis well.

In a recent article, Craig et al2 suggested that a sagittal 3-dimensional (3D) spoiled gradient-recalled (SPGR) sequence is the best sequence for the evaluation of the physeal plate. (According to the article, this sequence is widely available.) They examined 22 patients with this sequence and claimed that it provided excellent detail of the physeal plate. In addition to the SPGR sequence, they used 2-dimensional (2D) sagittal and coronal fast spin-echo sequences (with an echo train length of 3) and 3-mm-thick sections with a 1-mm gap. The field of view was 14 cm. They also used 2D axial and coronal fast spin-echo imaging with fat saturation (with an echo train length of 8) and 5-mm-thick sections with a 1.5-cm gap. The field of view was 18 cm.

If findings from the cited articles are compared, the use of a single sequence does significantly decrease the imaging time; in children, examination time is an important factor. However, Craig and coworkers2 strongly argue that SPGR provides the best images of the physis. To the author's knowledge, no group has used SPGR alone in the examination of children with trauma. Again, the evaluation of Salter-Harris injuries in children is a new use of MRI technology, and no standard is uniformly accepted at this time.

Degree of Confidence

MRI is a relatively new technique. MRI is limited in the assessment of acute injuries because of the length of time involved in the examination. Another limitation is the relative isolation of the patient within the machine.

Currently, MRI has limited utility in the evaluation of Salter-Harris fractures. Therefore, it is most efficiently applied by specialists with specific treatment questions. Orthopedic surgeons are the most appropriate physicians to request MRI; however, in consultation, a radiologist and a clinician may determine a specific need for MRI findings in a given case. Consultation with an orthopedic surgeon is likely to be helpful in complicated injuries that require treatment.

MRI in the setting of acute trauma has been discussed in 2 recent articles. Close and Strouse3 retrospectively evaluated 315 consecutive knee MRIs in children with a history of trauma. They reported that MRI revealed 8 additional fractures that were not fully identified on plain radiographs, and of the 8 fractures found with MRI, 7 had MRI findings that changed the clinical management. This study was limited because of its retrospective nature and selection bias; however, the authors indicate that MRI is better than plain radiography in delineating the exact nature of an injury. In complex cases, this advantage may be of clinical importance.

False Positives/Negatives

Carey et al4 reviewed the correlation between MRI results and plain radiographic findings in Salter-Harris fractures and found a trend similar to that of Close and Strouse.3 In 2001, a Finnish study revealed no misclassification in patients with minor ankle fractures; MRI was helpful in evaluating complex injuries in the ankle.5

A study performed in 1996 by Petite et al6 revealed a small benefit with the use of MRI versus plain radiography They found a misclassification rate of only 3% in patients with acute trauma. This study was limited because only gradient-echo imaging was used. Carey et al4 and Close and Strouse3 used multiple MRI techniques. The conclusion of Petite et al6 is similar to that of the other studies: MRI can be helpful in complex cases or when plain radiographic findings are normal and the clinical findings are highly suggestive of fracture.


ULTRASOUND

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Findings

Ultrasonography (US) has a limited role in the diagnosis of fractures.

Degree of Confidence

In a recent study, Hubner et al7 compared the results of primary US diagnosis of fractures with the results of plain radiography. They were able to accurately diagnose fractures with US; however, complex fractures were more difficult to assess with US. Salter-Harris type I fractures and nondisplaced fractures with less than 1 mm of separation were reliably detected with US.


NUCLEAR MEDICINE

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Findings

Although nuclear medicine studies had a role in the diagnosis of Salter-Harris fractures in the past, MRI and CT have replaced nuclear medicine study in the evaluation of subtle fractures.


MULTIMEDIA

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Media file 1:  Illustration of uninjured bone
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Media type:  Image

Media file 2:  Salter-Harris fracture type I
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Media file 3:  Salter-Harris fracture type II
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Media file 4:  Salter-Harris fracture type III
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Media file 5:  Salter-Harris fracture type IV
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Media file 6:  Salter-Harris fracture type V
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Media file 7:  Salter-Harris type II fracture of the distal tibia
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Media file 8:  Salter-Harris type III fracture of the distal tibia
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Media file 9:  Salter-Harris type IV fracture of the distal tibia
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Media type:  X-RAY

Media file 10:  Anteroposterior (AP) plain radiograph of the knee in a child with persistent knee pain after trauma. The radiographic findings appear normal.
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Media type:  X-RAY

Media file 11:  Lateral view obtained in the same patient as in Image 10 shows only a joint effusion.
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Media type:  X-RAY

Media file 12:  Coronal MRI obtained several weeks after an initial radiograph was obtained to assess ligamentous injury shows an unexpected finding of a Salter-Harris type III fracture.
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Media type:  MRI

Media file 13:  Sagittal MRI in the same patient as in Image 10
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Media type:  MRI


REFERENCES

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  1. Rogers LF, Poznanski AK. Imaging of epiphyseal injuries. Radiology. May 1994;191(2):297-308. [Medline].
  2. Craig JG, Cramer KE, Cody DD. Premature partial closure and other deformities of the growth plate: MR imaging and three-dimensional modeling. Radiology. Mar 1999;210(3):835-43. [Medline].
  3. Close BJ, Strouse PJ. MR of physeal fractures of the adolescent knee. Pediatr Radiol. Nov 2000;30(11):756-62. [Medline].
  4. Carey J, Spence L, Blickman H, Eustace S. MRI of pediatric growth plate injury: correlation with plain film radiographs and clinical outcome. Skeletal Radiol. May 1998;27(5):250-5. [Medline].
  5. Lohman M, Kivisaari A, Kallio P. Acute paediatric ankle trauma: MRI versus plain radiography. Skeletal Radiol. Sep 2001;30(9):504-11. [Medline].
  6. Petit P, Panuel M, Faure F. Acute fracture of the distal tibial physis: role of gradient-echo MR imaging versus plain film examination. AJR Am J Roentgenol. May 1996;166(5):1203-6. [Medline].
  7. Hubner U, Schlicht W, Outzen S, et al. Ultrasound in the diagnosis of fractures in children. J Bone Joint Surg Br. Nov 2000;82(8):1170-3. [Medline].
  8. Brown JH, DeLuca SA. Growth plate injuries: Salter-Harris classification. Am Fam Physician. Oct 1992;46(4):1180-4. [Medline].
  9. Keret D, Mendez AA, Harcke HT, MacEwen GD. Type V physeal injury: a case report. J Pediatr Orthop. Jul-Aug 1990;10(4):545-8. [Medline].
  10. Mac Nealy GA, Rogers LF, Hernandez R. Injuries of the distal tibial epiphysis: systematic radiographic evaluation. AJR Am J Roentgenol. Apr 1982;138(4):683-9. [Medline].

Salter-Harris Fractures excerpt

Article Last Updated: Mar 21, 2007