Introduction
In growing children, sprains and strains often result in potentially serious growth plate fractures
and physeal fractures. These same sprains and strains in active adults are relatively benign
injuries. This article discusses some of the important orthopedic history relative to the physes,
relevant anatomy, classification systems, and some details of physeal fractures in specific areas
of the body.
An image depicting growth plate fractures can be seen below.
Growth plate (physeal) fractures. Clinical appearance of the knee of a patient
with a minimally displaced Salter-Harris I fracture of the distal femur.
Impressive swelling was noted adjacent to the joint, but no evidence of intra-
articular swelling was present. The patient was markedly tender to palpation
about the distal femoral physis.
History of the Procedure
In the 1500s, Ambroise Pare made the earliest known reference to what is now called the
growth plate when he described the "appendices" of long bones. What Pare referred to as
dislocations of these appendices is now called growth plate fractures. In 1727, Stephen Hales
deduced the specific location of the growth plate. He noted that the distance between drill holes
he made in the diaphyses of leg bones of chickens did not increase as the birds grew. From this
he correctly concluded that longitudinal growth occurred at the ends of these long bones and
not in the middle.
Less than 10 years later, the study of the growth plate took a big step forward when John
Belchier introduced the scientific community to an important bone-staining method using the
plant product called madder. The use of madder (Rubia tinctorum) actually dates back to biblical
times, when it was used as a red dying agent for clothing.
Belchier noted that the bones of madder-fed animals stained red in their growth areas. This
discovery led to the extensive madder dye experiments conducted by John Hunter (1728-1793)
during the late 1700s (see image below). Hunter studied growing chickens and clearly
demonstrated that longitudinal bone growth occurred because of new bone generated by the
physes at the ends of long bones. John Hunter is frequently referred to as the father of the
growth plate, as he was the first to study it in such detail.
Growth plate (physeal) fractures. John Hunter (1728-1793), the "father of the
growth plate."
Problem
Physeal fractures (growth plate fractures) may be defined as a disruption in the cartilaginous
physis of long bones that may or may not involve epiphyseal or metaphyseal bone. These
injuries are classified many ways. Poland earned credit for one of the first systems in 1898; his
4-part classification system progressed from a simple epiphyseal separation to an epiphyseal
separation in which it is split in two. Many other classification systems followed, including a
system suggested by Petersen in 1994. This system was constructed on the basis of a
population-based epidemiologic study and arranged from the physis least involved progressing
to the injury that posed the greatest threat to the physis.
Many classification systems have been used throughout the world, but the Salter and Harris
(SH) classification is preferred and the accepted standard in North America to facilitate
communication among health care professionals.1,2,3 This system was proposed in 1963 by
Robert Salter and W. Robert Harris of Toronto. The various types of fracture patterns within the
SH classification are described as follows:
SH I: This fracture typically traverses through the hypertrophic zone of the cartilaginous
physis, splitting it longitudinally and separating the epiphysis from the metaphysis. When
these fractures are undisplaced, they may not be readily evident on radiographs
because of the lack of bony involvement. In many instances, only mild to moderate soft-
tissue swelling is noted radiographically. Clinical findings may be impressive, as seen in
the first image below; however, subsequent radiographs may demonstrate physeal
widening or new bone growth along physeal margins, indicating the presence of a
healing fracture, as seen in the second image below. In general, the prognosis for this
type of fracture is excellent. Usually, only closed reduction is necessary for displaced
fractures; however, open reduction and internal fixation may be necessary if a stable
satisfactory reduction cannot be maintained.
Growth plate (physeal) fractures. Clinical appearance of the knee of a
patient with a minimally displaced Salter-Harris I fracture of the distal
femur. Impressive swelling was noted adjacent to the joint, but no
evidence of intra-articular swelling was present. The patient was
markedly tender to palpation about the distal femoral physis.
Growth plate (physeal) fractures. Anteroposterior radiograph of the
knee of the patient in the previous image. Note subtle physeal
widening confirming the diagnosis of a Salter-Harris I fracture of the
distal femur.
SH II: The fracture splits partially through the physis and includes a variably sized
triangular bone fragment of metaphysis, as seen in the first image below. This fragment
is often referred to as the Thurstan Holland fragment in honor of the British radiologist,
Charles Thurstan Holland, who drew attention to its existence in 1929. Periosteum on
the side of the Thurstan Holland fragment often remains intact, thus facilitating reduction.
This particular fracture pattern occurs in an estimated 75% of all physeal fractures, and it
is the most common physeal fracture. The second image below illustrates an SH II
fracture of the distal femur.
Growth plate (physeal) fractures. Anteroposterior ankle radiograph
demonstrating an impressively displaced Salter-Harris II fracture of
the distal tibial epiphysis (along with comminuted fracture of distal
fibular diaphysis).
Growth plate (physeal) fractures. Displaced Salter-Harris II fracture of
the distal femur. The large Thurstan Holland (metaphyseal) fragment
may serve an important fixation point for either a Steinmann pin or a
lag screw.
SH III: This fracture pattern combines physeal injury with an articular discontinuity. This
fracture partially involves the physis and then extends through the epiphysis into the
joint. It has the potential to disrupt the joint surface. This injury is less common and often
requires open reduction and internal fixation to ensure proper anatomic realignment of
both the physis and the joint surface. Poland included a fracture pattern similar to this in
his scheme, in which both epiphyseal pieces were seen as free-floating fragments
separated from the metaphysis. The image below depicts a common SH III fracture of
the distal tibia, a Tillaux fracture, on CT scan.
Growth plate (physeal) fractures. Multiple computed tomography (CT)
scan images depicting a displaced Salter-Harris III fracture of the
distal anterolateral tibial epiphysis (ie, Tillaux fracture).
SH IV: This fracture runs obliquely through the metaphysis, traverses the physis and
epiphysis, and enters the joint. Good treatment results for this fracture are considered to
be related to the amount of energy associated with the injury and the adequacy of
reduction. The Thurstan Holland sign (ie, a Thurstan Holland fragment) is also seen with
this fracture pattern. The image below illustrates such a fracture of the proximal tibia.
Growth plate (physeal) fractures. Displaced Salter-Harris IV fracture
of the proximal tibia. The lateral portion of the epiphysis (with the
Thurstan Holland fragment) and the medial portion of the epiphysis
are independently displaced (ie, each are free-floating fragments).
SH V: These lesions involve compression or crush injuries to the physis and are virtually
impossible to diagnose definitively at the time of injury. Knowledge of the injury
mechanism simply makes one more or less suspicious of this injury. No fracture lines
are evident on initial radiographs, but they may be associated with diaphyseal fractures.
SH V fractures are generally very rare; however, family members should be warned of
the potential disturbance in growth and that, if growth disturbance occurs, treatment is
still available (depending on the child's age and remaining growth potential). The images
below depict the SH V fracture pattern.
Growth plate (physeal) fractures. The Salter-Harris V fracture pattern
must be strongly suspected whenever the mechanism of injury
includes significant compressive forces. This is the initial injury
radiograph of a child's ankle that was subjected to significant
compressive and inversion forces. It demonstrates minimally
displaced fractures of the tibia and fibula with apparent maintenance
of distal tibial physeal architecture.
Growth plate (physeal) fractures. Follow-up radiograph of the ankle of
the child in the preceding image. This radiograph depicts growth
arrest secondary to the Salter-Harris V nature of the injury. Note the
markedly asymmetric Park-Harris growth recovery line, indicating
that the lateral portion of the growth plate continues to function and
the medial portion does not.
SH VI: An additional classification of physeal fractures not considered in the original SH
classification but now occasionally included is SH VI, which describes an injury to the
peripheral portion of the physis and a resultant bony bridge formation that may produce
considerable angular deformity.4 This injury was suggested by Mr. Lipmann Kessel, as
follows: "A rare injury of growth plate results from damage to the periosteum or
perichondral ring. . . following burns or a blow to the surface of the limb, for example a
run over injury."5 The images below illustrate the SH VI fracture pattern.
Growth plate (physeal) fractures. Mortise radiograph demonstrating
somewhat subtle physeal injury to distal tibia. The Salter-Harris VI
pattern may be suspected based upon history and physical
examination findings. In this case, the radiograph indicates that it is
quite likely that a small portion of the peripheral medial physis (as
well as a small amount of adjacent epiphyseal and metaphyseal bone)
has been avulsed.
Growth plate (physeal) fractures. Clinical photograph of the patient
above with the displaced Salter-Harris II fracture of the distal femur.
This mechanism of injury and physical examination findings are
consistent with the Salter-Harris VI physeal injury pattern. Some may
also refer to this injury type as a Kessel fracture.
Injuries to the physes are more likely to occur in an active pediatric population, in part due to the
greater structural strength and integrity of the ligaments and joint capsules than of the growth
plates. These binding ligamentous structures are 2-5 times stronger than the growth plates at
either end of a long bone and, therefore, are less often injured in children sustaining excessive
external loads to the joints.
Frequency
Mann and Rajmaira collected data on 2650 long bone fractures, 30% of which involved the
physes.6 Neer and Horowitz evaluated 2500 fractures to the physes (growth plate) and
determined that the distal radius was the most frequently injured (44%), followed by the distal
humerus (13%), and distal fibula, distal tibia, distal ulna, proximal humerus, distal femur,
proximal tibia, and proximal fibula.7
According to a 1972 retrospective analysis of 330 acute physeal injuries or growth plate injuries
seen over the course of 20 years, males were affected more than twice as often as females.
Females were most frequently affected at a younger age than males, at age 11-12 years
compared to age 12-14 years in males. These findings correspond with the growth spurts (when
the physes are weakest) of the respective sexes and with males' increased willingness to
engage in high-risk activities. Within this population, upper extremity injuries were more frequent
than lower extremity injuries overall.
Pathophysiology
Physeal fractures (growth plate fractures) are typically believed to occur through the zone of
provisional calcification but may traverse several zones depending upon the type of external
load application. For instance, with application of compression-type loads, the histologic zone of
failure is typically the provisional calcification portion of the hypertrophic zone. Shear forces may
also cause failure in the hypertrophic zone. Tension forces lead to failure of the proliferative
zone.
Presentation
Patients typically complain of what seems to be localized joint pain, often following a traumatic
event (eg, fall, collision). Swelling near a joint with focal tenderness over the physis is usually
present, as seen in the image below. Lower extremity injuries present as an inability to bear
weight on the injured side; upper extremity injuries present with complaints of impaired function
and reduced range of motion, quite similar to ligamentous injury. Ligamentous laxity tests of the
joints of the injured side may elicit pain and positive findings similar to those indicative of joint
injury. (An SH III or SH IV fracture of the distal femur is the classic example.) Do not dismiss
positive joint laxity test findings as only involving the related joint tissues.
Growth plate (physeal) fractures. Clinical appearance of the knee of a patient
with a minimally displaced Salter-Harris I fracture of the distal femur.
Impressive swelling was noted adjacent to the joint, but no evidence of intra-
articular swelling was present. The patient was markedly tender to palpation
about the distal femoral physis.
Indications
SH I and SH II physeal injuries (growth plate injuries) usually can be managed adequately with
closed manipulative reduction. Upon reduction, these injuries are typically stable and casting
suffices. At times, periosteal flaps or other local tissue may interpose into the fracture site and
inhibit complete reduction. This complication may require surgical extraction of the tissues to
enable satisfactory or anatomic reduction.8,1,2
SH III and SH IV physeal injuries represent disruption of the physis and the epiphysis as well as
intra-articular fracture. Intra-articular discontinuity can lead to early degenerative arthritis, and
physeal discontinuity can disturb longitudinal growth. According to Bright,8 proper management
of SH III and SH IV injuries requires anatomic reduction and internal fixation to restore anatomic
alignment of the joint surfaces and proper alignment of juxtaposing physeal surfaces. Many
cases have been presented in which nondisplaced fracture fragments have migrated
subsequent to cast immobilization only.
SH V and VI physeal injuries often result in partial or complete growth arrest (physeal bar
formation). As a result, physeal bar resection may be required or other surgical procedures may
be necessary to prevent or correct deformity.3
Relevant Anatomy
Technically, 2 growth plates may be considered to exist in immature long bones: the horizontal
growth plate (physis) and the spherical growth plate (enables epiphyseal growth). For the
purposes of this article, the horizontal growth plate is addressed. The horizontal growth plate is
easily seen on radiographs of most growing long bones as a horizontal radiolucent region near
the end of the bone. It may also be referred to as the cartilaginous growth plate.
The physis is an organized system of tissue located at the ends of long bones, consisting of an
arrangement of chondrocytes surrounded by a matrix consisting of proteoglycan aggregates.
The chondrocytes of the physis are divided into a system of zones based on different stages of
maturation in the endochondral sequence of ossification and their function, as follows:
Reserve/resting zone: This zone is immediately adjacent of the epiphysis. It consists of
irregularly scattered chondrocytes with low rates of proliferation. This layer supplies
developing cartilage cells and stores necessary materials (lipids, glycogen, proteoglycan
aggregates) for later growth. Injury to this layer results in cessation of growth.
Proliferative zone: Chondrocytes are flattened and stacked upon each other in well-
defined columns. These cells produce necessary matrix and are responsible for
longitudinal growth of the bone via active cell division.
Hypertrophic zone: This zone is divided into maturation, degeneration, and provisional
calcification zones. Cells increase in size, accumulate calcium within their mitochondria,
and deteriorate, ultimately leading to cell death. Upon their death, calcium is released
from matrix vesicles, impregnating the matrix with calcium salt. The calcification of the
matrix is necessary for invasion of metaphyseal blood vessels, destruction of cartilage
cells, and the formation of bone along the walls of the calcified cartilage matrix. No
active growth occurs in this layer; columns of cells extending toward the metaphysis are
at various stages of maturation. This is the weakest portion of the physis and is
commonly a site of fracture or alteration (eg, widening, as in rickets).
The metaphysis, adjacent to the physis, is composed of primary and secondary spongiosa
layers. Primary spongiosa is mineralized to form woven bone and is subsequently remodeled to
form secondary spongiosa. Branches of the metaphyseal and nutrient arteries enter the
secondary spongiosa and form closed capillary loops in the primary spongiosa.
The periphery of the physis consists of 2 elements: the groove of Ranvier and the perichondrial
ring (of Lacroix). The groove of Ranvier is a wedge-shaped zone of cells contiguous with the
epiphysis at the periphery. It supplies chondrocytes to the periphery of the physis, enabling
lateral growth or increased width of the physis. Langenskiold proposed that cells from the
reserve zone migrate into the region of the groove of Ranvier.9 The perichondrial ring is a dense
fibrous ring that surrounds the physis and is critical to the overall stability of the growth plate.
The perichondrial ring's stabilizing effect may be lost in pathologic conditions such as slipped
capital femoral epiphysis (SCFE).
Contraindications
Absolute contraindications to reduction of displaced growth plate fractures are few. They
amount to the unusual situations in which the risks of sedation or general anesthesia are
believed to dramatically outweigh the potential benefits of growth plate fracture reduction.
Relative contraindications to growth plate fracture reduction would be SH I or II fractures with
clinically insignificant displacement. Also, fractures with perhaps somewhat greater
displacement that present in a delayed fashion (perhaps 3 wk or so after injury) are
contraindications. In such cases, the risks of the additional force that would have to be exerted
on the growth plate must be weighed against the likelihood of spontaneous remodeling of the
fracture over time.
Workup
Imaging Studies
Many acute physeal injuries are not clearly visible on plain radiographs due to the
cartilaginous-osseous nature and irregular contours of the physes.o Plain radiographs may depict physeal widening as the only sign of displacement.
In order to help delineate the injury, 2 views (anteroposterior and lateral) are
necessary. Occasionally, comparison views of the opposite extremity may be
helpful. Comparison views can help establish occult separation of the physis, as
in an SH I injury.o Radiographic stress views (varus and valgus) may be indicated in certain
patients. They are not recommended in all instances, as stress maneuvers may
cause further physeal damage. However, stress radiographs may be necessary
in order to accurately diagnose physeal plate injury. Stress views may prove
particularly useful to demonstrate separation between the epiphysis and
metaphysis in injuries around the knee and elbow.10
CT scans are at times necessary to delineate fragmentation and orientation of severely
comminuted epiphyseal and metaphyseal fractures.11
Bone scans are not particularly helpful, as the physes are normally relatively active on
nuclear scans.
Magnetic resonance imaging (MRI) has proven to be the most accurate evaluation tool
for the fracture anatomy when performed in the acute phase of injury (initial 10 d). MRI
can depict altered arrest lines and transphyseal bridging abnormalities prior to their
being evident on plain radiographs.
Treatment
Medical Therapy
Physeal fractures are very commonly treated nonoperatively. Factors that affect treatment
decisions include the severity of the injury, the anatomic location of the injury, the classification
of the fracture, the plane of the deformity, the age of the patient, and the growth potential of the
involved physis. Most SH I and II injuries can be treated with closed reduction and casting or
splinting and then reexamination in 7-10 days to evaluate maintenance of the reduction.
Closed reductions through manipulation and traction need to be performed carefully, with the
patient (and the patient's involved musculature) as relaxed as possible in order to avoid
unnecessary wrestling of the bony components that may lead to grating of the physis on sharp
metaphyseal bone fragments and potential damage to the physis. Less than satisfactory
reductions are preferred over repeated attempts at reduction that may damage the germinal
layer of cells within the physis. To avoid physeal damage, efforts at reduction should focus more
on traction and less on forceful manipulation of the bone fragments.
Disruption of the physis may warrant restoration of its congruency in order to ensure proper joint
mechanics. Angular deformities may also occur, due to malreduction or partial growth arrest.
The location and direction of the deformity need to be considered when planning treatment. In
general, greater angular deformity can be tolerated in the upper extremity than in the lower
extremity, more valgus deformity can be tolerated than varus, and more flexion deformity can be
tolerated than extension. More proximal deformities of the lower extremity (in the hip) are better
compensated for than distal deformities (the knee and, least of all, the ankle). Spontaneous
correction of angular deformities is greatest when the asymmetry is in the plane of flexion or
extension (ie, the plane of joint motion), with function often returning to normal unless the
fracture occurs near the end of growth.
The age of the patient at the time of injury is of paramount importance in helping predict clinical
outcomes because more correction can be anticipated in younger patients. For instance, injuries
to the physes of 14- to 15-year-old girls or 17- to 18-year-old boys are of little consequence due
to their limited growth potential. As a result, any growth plate injury is unlikely to be clinically
significant. However, injuries in younger children with full growth potential can cause significant
problems and a wide range of clinical effects.
Surgical Therapy
More severe injuries involving intra-articular fractures (SH III and IV) typically require anatomic
reduction with open reduction and internal fixation that avoids crossing the physis. Smooth pins
should parallel the physis in the epiphysis or metaphysis, avoiding the physis. Oblique
application of pins across the physis should be considered only when satisfactory internal
fixation is unattainable with transverse fixation. Any internal fixation devices should be easily
removable yet adequate for internal fixation.
Type V fractures are rarely diagnosed acutely, and unfortunately, treatment is often delayed
until the formation of a bony bar across the physis is evident. A high level of clinical suspicion is
necessary to detect this complication early. In many cases, "early" may not be until 6 months or
more after the injury.
Follow-up
Long-term follow-up is essential to determine whether or not complications will occur. Most
physeal injuries (growth plate injuries) should be reevaluated in the short term to ensure
maintenance of reduction and proper anatomic relationships. Some physeal fractures (growth
plate fractures) are more problematic than others when it comes to risk of growth arrest.
Physeal fractures that are considered to be at increased risk for growth arrest include fractures
to the following growth plates:
Distal femur13
Distal tibia14
Distal radius and ulna
Proximal tibia
Triradiate cartilage
After initial fracture healing has occurred, physeal fractures require additional follow-up
radiographs 6 months and 12 months following injury to assess for growth disturbance.
Management of such physeal fractures can thus be divided into 2 phases. The first phase
involves ensuring bone healing, and the second phase is monitoring growth.
Complications
Growth acceleration
Growth acceleration is a possible complication of physeal injuries; however, it is uncommon.
This complication usually occurs in the first 6-18 months after the initial injury. The rapid healing
of the physis enables an increased vascular response that is usually of shorter duration than
that for healing of bony fractures. Accelerated growth patterns also may be associated with the
use of implants and fixation devices that may stimulate longitudinal growth. The greater growth
is rarely significant but may require future assessment by the clinician. Treatment for this
acceleration in adolescents may involve an epiphysiodesis of the longer limb to avoid producing
disproportionate limbs. If more than 6 cm of correction is desired, this is not a treatment option,
and the clinician may consider lengthening procedures for bilateral limb-length equilibration.
Growth arrest
Complete growth retardation or partial growth arrest may result in progressive limb-length
discrepancies. Complete growth arrest is uncommon and depends on when the injury to the
physis occurs in relation to the remaining skeletal growth potential. The younger the patient, the
greater the potential for problems associated with growth.
Premature partial growth arrest is far more common and can appear as peripheral or central
closures. These can result in angular deformities and limb-length discrepancies. Premature
partial arrests are produced when a bridge of bone (bone bar/bridge) forms, connecting
metaphysis to epiphysis, traversing the physis. This bone bar inhibits growth, and the size and
location of this bar determines the clinical deformity. For example, if the bar is located medially
in the physis of the distal femur, the normal physis continues to grow laterally, producing a varus
deformity (genu varum), and vice versa for a genu valgum deformity. Recent investigation into
gait analysis for patients with genu valgum deformity revealed improvements in cosmesis and
corrected joint kinematics with hemiphyseal stapling. Anterior bone bars in the distal femoral
physis allow for normal physeal growth posteriorly but result in a genu recurvatum deformity.
Similarly, central growth arrests result in tented lesions of the physis and epiphysis due to a
central osseous tether with the metaphysis, resulting in the characteristic physeal coning. As the
physis tries to push the epiphysis away from the metaphysis, the bony bridge hypertrophies in
an effort to overcome the increased tension placed on it. Bone tissue under constant tension
usually atrophies, but in this instance, a dense reactive cortical bone develops.
Some longitudinal growth continues in patients with growth retardation, though at a much slower
rate; thus, a progressive shortening of the limb occurs. Partial growth arrests may be visible on
radiographs as early as 3-4 months postinjury or may be delayed as long as 18-24 months.
Follow-up checks may be necessary for 1-2 years postinjury to monitor physeal healing and
growth response.
Articular problems are also a possibility, particularly in physeal fractures that lead to
discontinuities of the articular surface (ie, SH III, SH IV). These lesions can result in intra-
articular step-offs and early degenerative joint disease if they are not properly treated and
anatomically reduced. Central growth arrest can promote the physeal tenting phenomena and,
ultimately, result in a deformed articular surface.
Outcome and Prognosis
Distal femur fractures
Distal femoral fractures account for approximately 5% of all physeal fractures (growth plate
fractures). Displacement of the fracture in the sagittal plane may be associated with
neurovascular injury in the popliteal fossa and instability on closed reduction. A common
mechanism of injury is hyperextension causing an anterior displacement of the epiphysis.
Physeal fracture displacement in the coronal plane is not associated with other injuries, and the
joint may be stable after closed reduction.15
Clinically, the thigh may appear angulated and shortened as compared with the contralateral
thigh; and pain, knee effusion, and soft-tissue swelling usually are severe. Hemarthrosis may be
more severe in SH III and SH IV fractures, and vascular examinations may reveal diminished or
absent distal pulses. Neurologic symptoms also may be evident distally due to disruption of the
posterior tibial and common peroneal nerve distributions.
Injuries to the distal femoral physis may result in angular deformities. Certain levels of
angulation are acceptable. Posterior angulation up to 20° remodels in children younger than 10
years; but injuries in adolescent patients do not remodel, and these patients do not tolerate this
degree of angulation. Varus and valgus angulations are less acceptable; no angulation greater
than 5° is acceptable for the distal femoral physis.
Treatment for distal femoral physeal fractures varies according to severity of injury. Displaced
SH I or SH II fractures are treated with closed reduction and splinting with hip spica. SH III and
SH IV injuries usually require anatomic reduction, which cannot be obtained with closed
reduction, and are very often unstable. Operative treatment is required because even slight
residual displacement can result in formation of a bone bar that causes limb-length discrepancy
and angular deformity.
Complications of distal femoral fractures include growth arrest (partial or complete) with
progressive angulation, shortening, or both in 30-80% of patients. Physeal fractures of the distal
femur (particularly the common SH I and SH II fracture patterns) have been shown to be
associated with an approximately 50% rate of growth disturbance.16
Because the incidence of growth arrest is high, even with satisfactory reduction, a lower
extremity limb-length discrepancy of more than 2 cm may develop in one third of patients.
Shortening and angulation are related more to degree of initial displacement than to the
accuracy of the reduction. An angulation deformity of more than 5° may develop in one third of
patients. A persistent angular deformity in the coronal plane may not correct spontaneously with
further growth.
Distal tibia fractures
Fractures of the distal end of the tibia in children often involve the physis. They are of particular
importance because partial growth arrest can occur and result in angular deformity, lower
extremity limb-length discrepancy, incongruity of the joint surface, or a combination of these.
Triplane and Tillaux fractures are the 2 distinct types of distal tibial fractures.
In a triplane fracture classification, 2 types of fractures exist: 2-part and 3-part fractures. A 2-part
fracture is a type of SH IV fracture that primarily occurs when the medial portion of the distal
tibial epiphysis is closed. Three-part fractures are a combination of SH II and SH III fractures
that occur when only the middle portion of the distal tibial epiphysis is closed. This injury
involves fracture of the anterolateral portion of the epiphysis of the distal tibia (similar to Tillaux
fracture) and fracture of a large posterior fragment comprising the posterior and medial portions
of the tibial epiphysis plus a large metaphyseal fragment of variable size; the fibula also may be
fractured. These injuries most commonly occur just before epiphyseal closure and are due to
external rotation forces.
Tillaux fractures are SH III fractures involving avulsion of the anterolateral tibial epiphysis. This
portion of epiphysis is involved because the physis of the distal tibia closes in the middle first.
The medial portion then closes, and finally, the lateral portion closes. This injury occurs in older
adolescents, after the middle and medial parts of epiphyseal plate have closed but before the
lateral part closes (usually in adolescents aged 12-15 y). Since this fracture occurs in
adolescents with relatively mature growth plates, minimal potential exists for deformity due to
growth plate injury.
Treatment of displaced SH III and SH IV fractures of the distal tibia require open reduction. This
injury leads to premature physeal closure unless it is anatomically reduced. Development of an
angular deformity is possible. Varus deformities, secondary to an osseous bridge formation on
the medial aspect of the plate, are the most common complications found with distal tibia growth
plate injuries. Limb shortening is the second most common problem associated with these
injuries.
Kling et al, when evaluating distal tibial physeal fractures that required open reduction,
suggested that SH III, SH IV, and perhaps SH II fractures of the distal end of the tibia commonly
cause disturbance of growth in the tibia and that anatomic reduction of the physis by closed or
open means may decrease the incidence of these disturbances of growth, including shortening
and varus angulation of the ankle.17 SH IV fracture of the distal tibia has indeed been associated
with premature physeal closure unless anatomically reduced, usually with internal fixation.
A high rate of premature physeal closure (PPC) has been reported to occur in SH type I or II
fractures of the distal tibia. Rohmiller et al reported a PPC rate of 39.6% in SH type I or II
fractures of the distal tibia physis and determined that fracture displacement following reduction
was the most important determinant of PPC development.1 Barmada et al investigated the
incidence and predictors of PPC after distal tibia SH type I and II fractures and found that when
residual gapping of the physis was greater than 3 mm following reduction, the incidence of PPC
was 60%; when the physeal gap was less than 3 mm, there was a 17% incidence of PPC. Upon
open reduction of residual gapping, the periosteum was found to be entrapped within the physis,
thereby preventing closure of the gap and preventing appropriate recreation of the anatomy.18
Distal radius and ulna fractures
Physeal injuries of the distal ulna occur much less frequently than those of the distal radius, but
physeal injuries of the distal ulna are associated with a higher incidence of growth arrest, due to
the ulna deriving 70-80% of its longitudinal growth from its distal physis. As a result, growth
arrest can cause significant ulnar shortening.
The distal radial physis is the most frequently injured physis in children, usually occurring in
children aged 6-10 years. Children typically sustain the injury by falling on an outstretched hand.
A great majority of these injuries are SH I and SH II fractures. The distal radial and ulnar physes
provide 75-80% of total growth of the forearm, so potential for remodeling and correction of any
deformity is excellent.19 Lee et al found that significant distal radial growth disturbance occurred
in about 7% of physeal fractures20 ; the rate of distal ulnar growth arrest following physeal
fracture is probably at least as high.
The acceptable amount of residual displacement for distal radial and ulnar fractures is not
specifically known; however, 30% physeal displacement heals readily, and 50% displacement
may often completely remodel in 1.5 years.
Proximal tibia fractures
While fractures involving the tibia and fibula are the most common lower extremity pediatric
fractures, those involving the proximal tibial epiphysis are among the most uncommon but have
the highest rate of complications. When displacement occurs, the popliteal artery is vulnerable.
At the tibial metaphysis, the artery is just posterior to the popliteus muscle. Moore and
Mackenzie found that in SH I injuries, half are nondisplaced and diagnosed by stress
radiographs.21 SH I injuries occur at an earlier age (average age 10 y). SH II are the most
common type, and one third are nondisplaced. SH III injuries are often associated with lateral
condyle fractures or medial collateral ligament (MCL) injury. SH IV injuries are often associated
with angular deformity. SH V injuries are usually diagnosed retrospectively. Anterior physis
closure can cause significant genu recurvatum.
Complications of these injuries include vascular insufficiency and peroneal nerve palsy,
however transient.
Triradiate cartilage fractures
Traumatic disruptions of the acetabular triradiate cartilage occur infrequently and may be
associated with progressive acetabular dysplasia and subluxation of the hip. The volume of
cartilage in a child's acetabulum allows a greater capacity for energy absorption than in adults.
Thus, in children, fractures of the acetabulum are consistently the result of high-energy trauma.
Unfortunately, a younger age at the time of injury is associated with a greater chance of
developing acetabular dysplasia.
Disruption of the acetabular triradiate cartilage in patients older than 12 years results in minimal
subsequent growth disturbance; however, in younger patients, acetabular growth abnormality is
a frequent complication. Growth abnormalities include shallow acetabula and progressive
subluxation of the hip.
Triradiate cartilage injuries occurring during adolescence result in fewer growth changes in
acetabular morphology and hip joint congruencies. However, in younger children, especially
those who are younger than 10 years, acetabular growth abnormality is a frequent complication
of this injury and may result in a shallow acetabulum similar to that seen in patients with
developmental dysplasia of the hip (DDH). By the time patients reach skeletal maturity,
disparate growth increases the incongruity of the hip joint and may lead to progressively more
severe subluxation of the hip. Acetabular reconstruction may be necessary to correct the
gradual subluxation of the femoral head.
Bucholz et al found 9 patients with triradiate physeal-cartilage injury who were classified
according to the degree of displacement and the probable type of growth-plate disruption.22 They
determined that 2 main patterns of injury occurred. The first was a shearing (SH I or II) growth
mechanism injury, with central displacement of the distal portion of the acetabulum. This injury
pattern seemed to have a favorable prognosis for continued normal acetabular growth, although
occasional premature closure of the triradiate physes occurred. The other pattern appeared to
be a crushing SH V growth mechanism injury; this type has a poor prognosis, with premature
closure of the triradiate physes occurring secondary to the formation of a medial osseous
bridge. Prognosis is dependent on the age of the patient at the time of injury and on the extent
of chondro-osseous disruption.
Stubbed great toe
The images below illustrate the respective radiographic and clinical appearance of an injury that
has been termed the pediatric stubbed great toe. It is a somewhat occult open fracture due to
the fact that the growth plate of the distal phalanx is remarkably close to the nail plate. When a
subungual hematoma occurs in conjunction with a growth plate fracture, this does in fact
represent an open fracture. In the great toe (or at times lesser toes), this injury has been termed
a Pinckney fracture or Pinckney lesion.23 In the hand, such fractures of the terminal phalanx may
be called Seymour fractures.24
Growth plate (physeal) fractures. Radiographic evidence of a pediatric
stubbed great toe.
Growth plate (physeal) fractures. Clinical appearance of a pediatric stubbed
great toe. Note the subungual hematoma, representative of an open fracture.
Future and Controversies
Growth plate transplantation
Several experiments have been performed to evaluate the efficacy of interpositioning materials
(eg, bone wax, fat, cartilage, silicon rubber, polymethylmethacrylate) into defects resulting from
physeal bar excision. No single material has been deemed superior in the prevention of physeal
bar reformation. Cartilage may prove ideal, and several possible sources for graft material exist,
but each has associated difficulties such as the following:
Apophyseal cartilage may lack the growth potential of epiphyseal cartilage.
Laboratory-procured chondrocyte allograft transplants may take a long time to develop
and may not have any real possibility for interhuman transfer due to the impending
immune response.
In physeal cartilage transfer, difficulties abound in procuring and transferring physes
from one site to another.
Tissue engineering
Most of the research involved in cartilage regeneration has focused on articular cartilage, but
much of what may be learned through research may be applicable to growth plate cartilage. At
present, no reliable means of regeneration exists. Cartilage is unable to regenerate itself, partly
because of its low cellularity and lack of vascular supply. In addition, chondrocytes in articular
cartilage are well differentiated, and the number of multipotent progenitor cells is relatively low.
As a result, cartilage is able to heal the margins of damage but does not form a scar to join the
edges of the defect together.
Many tissue-engineering strategies have been developed, including implantation of
chondrogenic cells at various developmental stages into the defect site, implantation of cartilage
itself (ie, osteochondral autograft/mosaic arthroplasty), cartilage transplantation, and allogenic
grafts. Periosteal and perichondrial tissue grafts have been considered because of their
stockpile of multipotent osteochondral progenitor cells. The use of scaffolds to provide a
substrate for chondroprogenitor cell attachment and migration across cartilaginous defects has
been studied as well.
These techniques have had variable success. Tissue scaffolding has proven effective at
overcoming some deficiencies in tissue engineering. Collagen, a natural tissue, and poly-
lactide-co-glycolide (PLGA), a polymer that elicits small acute immune responses, have shown
promise as cartilage repair scaffolds. Chitin has recently been determined to be effective as a
scaffolding for attaching and carrying stem cells for the repair of growth plate defects.
Some studies have combined gene therapy and tissue-engineering approaches to regenerate
articular cartilage defects in the hope of application toward epiphyseal cartilage repair. One
such study employed a retroviral vector to introduce the human bone morphogenic protein-7
(BMP-7) complementary DNA into periosteal-derived rabbit mesenchymal stems cells. BMP-7
stimulates the synthesis of type II collagen and aggrecan. Grafts containing the BMP-7 gene
modified cells consistently showed complete or near-complete articular cartilage regeneration at
8 and 12 weeks; grafts from control groups exhibited poor regeneration.
The future also holds promise for specific intracellular signaling approaches to posttraumatic
disturbances of the growth plate. At the University of Massachusetts, Leboy et al found that
important regulators of physeal chondrocyte hypertrophy include special bone morphogenic
proteins: activated cytoplasmic proteins (called Smads) and multifunctional transcription factors
(called Runx proteins).25 Another potent stimulator of embryonic epiphyseal cartilage is growth
differentiation factor 5 (GDF-5). Buxton and colleagues found that GDF-5 promotes both cell
adhesion and proliferation during limb development.
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