Introduction
Pediatric fractures involve the growth plate 15% to 18% of the time. Foucher first described growth plate injuries in 1863, while Poland introduced the first classification system for these injuries in 1898. The most popular descriptive anatomical classification system used today is the Saltar-Harris classification, described by Drs Salter and Harris in 1963. They were the first to recognize that the injury occurred through the zone of provisional calcification of the physis; this zone is weak due to incomplete calcification.[1] Results from injection studies demonstrate that epiphyseal and metaphyseal arteries supply the growth plate. The epiphyseal arteries supply the proliferating chondrocytes, while the metaphyseal vessels provide circulation to calcifying cells.[2] Results from various studies have also shown that the vessels may enter the plate from the epiphyseal periosteum (more common) or the plate's rim if the entire epiphysis is intra-articular.[3] Injury to these blood vessels may result in growth arrest.
Physeal cells are arranged in layers or zones—namely, the reserve, proliferative, and hypertrophic zones. The reserve zone stores lipids, proteoglycans, and glycogen for growth and matrix production. The proliferative zone has the highest extracellular matrix production rate and accounts for the greatest longitudinal growth. Hypertrophic zone cells exist in 3 phases: maturation, degeneration, and provisional calcification. Maturation-phase cells prepare for calcification, degenerative-phase cells prepare the bone matrix, and cells in the provisional calcification zone undergo chondrocyte death and release calcium. Physeal fractures most commonly occur in the zone of provisional calcification, which cannot withstand shearing stress.[4][5] The physis is weaker than the ligaments or periosteum in children; thus, traumatic incidents are more likely to injure the growth plate before these other structures.
Etiology
Register For Free And Read The Full Article
- Search engine and full access to all medical articles
- 10 free questions in your specialty
- Free CME/CE Activities
- Free daily question in your email
- Save favorite articles to your dashboard
- Emails offering discounts
Learn more about a Subscription to StatPearls Point-of-Care
Etiology
The growth plate is 5 times more brittle than the surrounding ligaments. Fractures may occur after mechanical falls, direct trauma, or during sporting events. Other possible causes of pediatric physeal injuries include iatrogenic surgical injuries, radiotherapy, chemotherapy, infection, bone tumors, and metabolic disorders.[6]
Epidemiology
Physeal injuries are common in the pediatric population, accounting for approximately 30% of all bony injuries.[7][8] Most fractures occur in ambulatory children and are especially common in the adolescent population. Those who participate in sports activities have a higher incidence of injury. Overall, physeal injuries are twice as prevalent in boys than in girls. The most commonly involved location is the phalanges, accounting for 30% of these injuries.
Pathophysiology
The growth plate is a key site of chondrocyte proliferation, and injuries to this area can disrupt its blood supply. Epiphyseal blood vessels nourish the zones of active chondrocyte growth, and damage to these vessels may result in necrosis, leading to the arrest of longitudinal bone growth. The growth plate may also close, and a secondary ossification center may anomalously develop at this site. Meanwhile, metaphyseal arterial damage can disrupt endochondral ossification, leading to chondrocyte persistence within the metaphysis and growth plate widening.
Injuries that allow the epiphyseal and metaphyseal arteries to communicate, eg, Salter-Harris fractures, can produce transphyseal bone bridges, also known as physeal bars.[41] These abnormal structures can lead to length discrepancies between paired bones and angular deformity.[42] Growth plate cartilage is less resilient to shearing forces than ligament or adult articular cartilage. Injuries that can cause ligamentous tears or bone dislocation in adults can produce physeal injuries in children.
Histopathology
The physis is divided into the following zones:
- Resting zone: The region closest to the epiphysis that houses the germinal matrix and inactive chondroblasts
- Proliferative zone: Contains active chondroblasts, which synthesize extracellular matrix (ECM) proteins
- Hypertrophic zone: The zone that houses more organized chondroblasts and contributes less to ECM formation; this zone subdivides further into the zones of maturation, provisional degeneration, and provisional calcification
- Calcification zone: The level where cartilage calcifies and becomes bone
The zone of provisional calcification is the growth plate's weakest region. This site is most commonly involved in physeal injuries.
Two other important structures surround the physis:
- Groove of Ranvier: This is located on the diaphyseal side of the growth plate and is composed of osteoblasts, fibroblasts, and chondroblasts. The groove of Ranvier supports horizontal epiphyseal growth.
- Ring of LaCroix: This is a fibrous structure that makes the physis more stable. The ring of LaCroix securely connects the metaphysis to the epiphysis.
Epiphyseal arteries terminate at the periosteum.
History and Physical
In all high-trauma situations, assessment of the ABCs (airway, breathing, and circulation) must be prioritized. Once emergency conditions have been ruled out, other injuries may be examined. On history, the mechanism of trauma must be elicited to determine the potential extent of damage; for example, a recent sports-related collision, motor vehicular crash, fall from a height, or assault may be reported. The patient may present with multiple injuries or be brought to the emergency department unconscious. Initiate resuscitation if the patient is unconscious, apneic, and pulseless. Physical examination may reveal deformity, swelling, and tenderness in the affected area, and sensorimotor weakness distal to the site may indicate nerve damage in the fractured region.
A wound or skin tenting on the site may signify an open fracture or an impending one. Compartment syndrome—with symptoms of pain, pallor, paralysis, paresthesia, and pulselessness—must be ruled out. Refer to an orthopedic surgeon immediately if these signs are present, as these conditions are surgical emergencies.[9] Non-accidental trauma must be ruled out in all pediatric fractures. Non-accidental trauma presenting as orthopedic injuries include metaphyseal corner fractures, fractures in various states of healing, multiple fractures, long-bone fractures producing inability to ambulate, and epiphyseal separation.[10][11]
Evaluation
Imaging studies help elucidate the type and severity of injury. Plain radiography is enough to locate the fracture and assess its severity in most cases. Physeal fractures are classified using the Salter-Harris classification (see Image. Salter-Harris Classification of Physeal Injuries), which is as follows:
- Salter-Harris I: Fracture through the growth plate, with epiphyseal and metaphyseal separation
- Salter-Harris II: Break through the physis with extension into the metaphysis
- The name of the metaphyseal fragment is "Thurston-Holland fragment." This type is the most common.
- Salter-Harris III: Physeal disruption with epiphyseal extension
- This type predisposes to post-traumatic arthritis.
- Salter-Harris IV: Extension of fracture line through the metaphysis, physis, and epiphysis
- This injury may predispose to growth disturbance, depending on the fracture location.[12]
- Salter-Harris V: Physeal crush injury
- Salter-Harris VI: Physeal fracture that includes the periphery of the physis
- This injury is also called "perichondral ring fracture."
- Salter-Harris VII: Isolated injury to the epiphyseal plate
Higher-numbered injuries in the Salter-Harris classification have a greater risk of growth arrest. Study results have shown moderate interobserver reliability using this classification, which improves with experience.[13] Ultrasound may be used in young patients whose cartilage ossification has not started.[14] The inability to rule out a physeal injury despite normal x-ray findings warrants computer tomography (CT) or magnetic resonance imaging (MRI).
Treatment / Management
Pediatric physeal injuries may be managed conservatively or surgically, depending on factors like injury type and extent of involvement. This section explains pediatric physeal injury management.
Nonoperative Management
As previously mentioned, assessing patients with trauma must start with the ABCs. Emergent injuries like compartment syndrome and open fractures must also be ruled out immediately. A more thorough investigation and specific treatment may begin once emergencies have been ruled out. The therapeutic objectives for physeal fractures are maintaining normal limb function and physeal development. These goals can be accomplished by physeal and articular anatomic reduction.[15] Salter-Harris I and II fractures may be managed immediately by immediate reduction and immobilization. Patients must be given adequate pain control before the procedure. Muscle relaxation can make the bone more amenable to closed reduction. Forceful closed reduction and repeated manipulations must be avoided. Displacement in Salter-Harris I and II fractures presenting 7 to 10 days after injury should be assessed cautiously, as complications may have already developed at this time.[16][17](B3)
Operative Management
Physeal fracture displacement greater than 2 mm is an indication of open reduction, with pins and wires as the preferred fixation instruments.[18] Smooth pins are preferred over threaded ones, and small-diameter wires or pins are recommended.[19] Insertion at the physeal perimeter has a greater risk of growth arrest than insertion at the center. Titanium may cause physeal tethering more than stainless steel. Implants must be positioned parallel to the physis if the fracture geometry permits it. Additionally, positioning perpendicular to the physis will do less harm than placement at an oblique angle. Compression of transphyseal implants must be avoided.[20] Smith et al reported that 1 out of 5 patients who have had temporary transphyseal pinning for upper extremity fractures experienced physeal arrest.[21][22](B2)
Salter-Harris I and II fractures may be treated with closed manipulation, reduction, and 4 to 6 weeks of immobilization. Growth arrest risk after the fracture starts to heal is higher. Late-appearing deformities may be treated with osteotomy. Salter-Harris I and II injuries with greater than 3 mm of displacement are also at increased risk of growth arrest. Most Salter-Harris type I fractures may be successfully treated with closed reduction and casting. However, these fractures must be monitored for at least 3 months to ensure growth discrepancies do not develop. Soft tissue edema and pain may be the only initial symptoms of these injuries, although radiographs may reveal joint expansion or new bone growth at the anatomical borders.[23][24]
About 75% of physeal injuries are classified as Salter-Harris type II. Repeated reduction attempts of these injuries may damage the physis owing to the metaphyseal spike. The Thurston-Holland (metaphyseal) fragment may be internally fixated into the metaphysis if the fracture is unstable. Transphyseal internal fixation may be required if the metaphyseal segment is too small to hold an implant. Reduction performed more than 5 days following an extra-articular physeal fracture (Salter-Harris type I or II) should be avoided to reduce the risk of iatrogenic physeal damage and growth arrest. Instead, these injuries may be allowed to heal spontaneously, even if the process results in malunion, which is often simpler to treat than growth arrest.
Salter-Harris III and IV fractures should be surgically reduced regardless of the timing of presentation. Surgical reduction is recommended due to articular involvement. Salter-Harris type III fractures usually affect older children. Thus, the growth arrest risk is less. Potential complications of these injuries include posttraumatic arthritis, articular disruption, and minor growth arrest.[25] Salter-Harris type IV fractures require physeal and articular alignment during surgical reduction. Unstable fractures are internally fixated from epiphysis to epiphysis or metaphysis to metaphysis to minimize physeal damage. Regardless of the time of diagnosis, displaced intra-articular physeal fractures (Salter-Harris types III and IV) should be surgically treated with internal fixation.[26]
Joint arthrograms, fluoroscopy, direct visualization, and arthroscopic evaluation can help determine the adequacy of articular reduction after surgical treatment of Salter-Harris III and IV fractures. The appearance of asymmetric Park-Harris growth lines indicates growth impairment.[27] During open reduction, the fracture should be approached from the tension side to access interposed tissues easily; periosteal resection on each side of the physis may reduce the risk of bony bar development. Exposed or crushed physeal injuries may be covered with free fat grafts to avoid growth arrest.[28] Salter-Harris types III and IV fractures should be immobilized for 4 to 8 weeks after surgery.[29] Post-reduction CT may help assess reduction quality. Unstable fractures require closed reduction and percutaneous pinning. Open reduction and internal fixation (ORIF) may be necessary when treating fractures with an interposed periosteum.(B3)
Physeal Bar Development
Physeal bar formation can result in growth arrest. Physeal bar treatment depends on the patient's skeletal maturity and the amount of bone development remaining. Thus, skeletal age must be determined to help guide treatment. Boys typically grow until age 16, while girls grow until age 14. Green and Anderson growth graphs can help determine the amount of skeletal growth a patient has left.
Surgical reduction with or without internal fixation may remove physeal bars but does not always prevent growth arrest. Factors like deformity, remaining development, limb-length disparity, and injury extent, nature, position, and size affect how growth arrest is managed. Langenskiold surgery entails free fat graft interposition after removing the partially arrested physis, which prevents physeal re-tethering. Further, metaphyseal and epiphyseal metal markers can aid in tracking post-surgical growth.[30]
Another option to prevent bar reformation is polymethylmethacrylate, which is accessible, affordable, inert, and effective in providing bone structural support.[31] External fixation using Canadell and De Pablos distraction technique has also been used successfully to correct bony bars and malalignment. The technique can address these complications by physeal distraction, dispensing the need to remove the bone bridge.[32] Bollini et al reported that external fixation by the Ilizarov method can successfully treat a centrally positioned lower tibial bony bridge.[33](B3)
Early physeal closure, variable physeal growth, and pin site infection are possible complications of these physeal procedures, while physeal bar replacement with a healthy physis can induce development and treat growth arrest. The proximal fibula, distal ulna, phalangeal physis, costal cartilage, distal clavicle, and iliac crest apophysis are potential physeal cartilage donor sites.[34] Whole physeal impaction results in full growth arrest, resulting in delayed bone formation and limb shortening; perimeter physeal bars can cause angular deformity and slow bone growth. Centrally positioned physeal bars may be accessed by making a metaphyseal cortical window, preserving the perichondrial ring, and peripheral physeal bars may also be accessed through this window. The bony bar may be removed after periosteal excision until a healthy physis is seen. Hematoma formation may lead to bony bar reformation and must be avoided.[35](B3)
Other treatment approaches to physeal bar formation include the following:
- Observation: This is indicated when the entire physis is involved, and the degree of angular deformity or limb-length inequality is acceptable, ie, less than 2 cm. The patient must have minimal growth remaining in the contralateral extremity.
- Physeal bar completion: This is indicated when the angular deformity is acceptable but has a risk of progressing with continued growth. Limb-length inequality must be evaluated before the procedure. If the patient has greater than 2 to 2.5 cm growth remaining or a 2 to 5 cm leg-length discrepancy is present, contralateral epiphysiodesis may be performed. Ulnar and fibular epiphysiodesis must be considered to avoid ulnar wrist impaction and sub-fibular impingement, which result from the continued growth of neighboring bones.
- Resection: This may be considered in partial growth arrest, where the physis has substantial growth. Bony bar resection with fat autograft interposition may be performed when the physeal bar spans less than 50% of the physis. The technique may fail with greater than 50% involvement. Type A physeal bars must be resected until the area is surrounded completely by healthy physis. Type B or C physeal bars require osteotomy or drill excision to reach the area; intraoperative marker placement can aid in postoperative radiographic monitoring.
- Osteotomy: This is indicated if the physeal bar is accompanied by greater than 20° angulation. Normal growth may correct the angulation if it is less than 20°.[36]
Leg lengthening is required if the leg-length discrepancy is greater than 5 cm.
Differential Diagnosis
Physeal injuries often present with vague symptoms that can make them resemble the following conditions:
- Infection
- Muscle strain
- Metaphyseal or diaphyseal fracture
- Bone bruise
- Ligamentous injuries
Careful evaluation can help distinguish between these conditions.
Prognosis
The most important factors that impact the prognosis of physeal injuries include initial fracture type, location, time to treatment, quality of reduction, and orthopedic follow-up. The prognosis of extra-articular pediatric physeal fractures (Salter-Harris types I and II) is generally good. Most of these injuries heal with good alignment after closed reduction and conservative treatment. Inappropriate initial management increases the risk of growth arrest, malalignment, and lifelong mobility problems.[37] Salter-Harris types III and IV fractures have the greatest risk of growth arrest.
Complications
Physeal complications occur in 2% to 14% of patients after growth plate injury. Growth arrest is relatively rare. However, injuries to the distal tibia result in premature growth plate closure in 27.2% of the cases. This location has a high risk of physeal bar formation, especially if periosteal interposition is present. MRI or CT can help detect physeal bar formation. Growth arrest may not be evident until months after the injury.
Partial physeal arrest can be categorized according to the Peterson classification:
- Type A: Peripheral bar
- Type B: Central bar that crosses entire physis (anterior to posterior) with healthy physis on the sides
- Type C: Central bar surrounded by healthy physis
Limiting the reduction attempts can help prevent physeal arrest after a fracture treatment. One reduction attempt increases the growth arrest risk to 11%. Two attempts increase the risk to 24%.[38] Harris growth arrest lines may form after a physeal injury and can be used to assess subsequent growth. Lines transverse or parallel to the physis allow the growth plate to expand evenly. Asymmetric Harris growth arrest lines may result in uneven growth. Other possible complications of physeal injuries include infection, nonunion, malunion, infection, neurovascular injury, and osteonecrosis.
Consultations
Physeal fracture management requires the services of the following clinicians:
- Pediatric orthopedic surgeons play a central role in diagnosing and managing physeal fractures, whether through conservative management or surgical intervention.
- Pediatricians or primary care clinicians provide the initial evaluation and referral for suspected physeal fractures in the outpatient clinic. They coordinate care and oversee the child's health.
- Pediatric radiologists interpret imaging studies in young patients.
- Pediatric anesthesiologists provides specialized anesthesia care tailored to the child's needs and ensures their safety during surgery
Collaboration among these healthcare professionals is essential to ensure accurate diagnosis and appropriate treatment of pediatric physeal fractures.
Deterrence and Patient Education
Preventing pediatric physeal injuries involves several strategies aimed at reducing the risk of growth plate trauma during physical activities. These measures include the following:
- Adult supervision during playtime or sports activities
- Ensuring that children wear the appropriate sports gear
- Adequate warm-up before physical activity
- Limiting children to age-appropriate activities
- Ensuring that children use the correct movement techniques during sports activities
- Allowing young people adequate rest and recovery
- Regular medical checkups
- Healthy lifestyle
Additionally, providers must look for clues in the patient's family or social history for physical abuse.[39][40]
Pearls and Other Issues
The most important points to remember when managing pediatric physeal fractures are the following:
- Rule out emergency conditions in all trauma patients before performing a detailed evaluation and management.
- Pediatric physeal injuries are classified by the Salter-Harris system. Salter-Harris types I and II have the best prognosis and response to conservative treatment. More severe injuries have a poor prognosis, as they usually require surgery and are associated with lifelong complications like growth arrest and limb-length discrepancy.
- The treatment approach depends on factors like injury severity, time to diagnosis, and amount of remaining growth.
- Immediate and appropriate intervention produces better outcomes.
- Multiple reductions can increase the risk of growth plate injury.
- Growth arrest is a possible complication of intra-articular fractures.
- Look for signs of non-accidental trauma in pediatric patients and report to state authorities.
Additionally, referrals to different specialists may be necessary for managing these injuries, as young individuals have different physical needs from adults.
Enhancing Healthcare Team Outcomes
An interprofessional team approach is essential for the optimal management of pediatric physeal fractures in pediatric patients. This team includes the following:
- Emergency medicine or primary care clinician: These healthcare professionals are the first to evaluate, diagnose, and provide initial treatment for the injury. Other important tasks of these specialists include discussing imaging results with the radiologist and referral to a pediatric orthopedic surgeon. The primary care physician also oversees the patient's health needs during and after recovery.
- Pediatric orthopedic surgeon: This provider specializes in diagnosing and treating pediatric musculoskeletal conditions, including physeal fractures.
- Pediatric radiologist: This specialist aids in treatment decisions by interpreting imaging studies to diagnose and classify physeal fractures accurately.
- Pediatric anesthesiologist: This specialist provides anesthesia care when the condition requires surgery.
- Pediatric nurse: Nurses assist in patient care and education. They also support the child and their family throughout the treatment process.
- Rehabilitation team: The physical therapist designs and implements rehabilitation programs to restore function, mobility, and strength in the affected limb. The occupational therapist helps the patient regain functional independence after treatment.
- Social worker: Social workers may provide counseling and care coordination to children with unstable homes and who have been victims of abuse.
- Psychiatrist: This provider's services may be necessary if a child develops behavioral issues after the injury.
Effective communication, shared decision-making, and coordinated efforts among these team members ensure the best outcomes after pediatric physeal injury.
References
Cepela DJ, Tartaglione JP, Dooley TP, Patel PN. Classifications In Brief: Salter-Harris Classification of Pediatric Physeal Fractures. Clinical orthopaedics and related research. 2016 Nov:474(11):2531-2537 [PubMed PMID: 27206505]
TRUETA J, MORGAN JD. The vascular contribution to osteogenesis. I. Studies by the injection method. The Journal of bone and joint surgery. British volume. 1960 Feb:42-B():97-109 [PubMed PMID: 13855127]
Langenskiöld A. Role of the ossification groove of Ranvier in normal and pathologic bone growth: a review. Journal of pediatric orthopedics. 1998 Mar-Apr:18(2):173-7 [PubMed PMID: 9531398]
Level 3 (low-level) evidenceShaw N, Erickson C, Bryant SJ, Ferguson VL, Krebs MD, Hadley-Miller N, Payne KA. Regenerative Medicine Approaches for the Treatment of Pediatric Physeal Injuries. Tissue engineering. Part B, Reviews. 2018 Apr:24(2):85-97. doi: 10.1089/ten.TEB.2017.0274. Epub 2017 Sep 28 [PubMed PMID: 28830302]
Salter RB. Injuries of the epiphyseal plate. Instructional course lectures. 1992:41():351-9 [PubMed PMID: 1588078]
Singh A, Mahajan P, Ruffin J, Galwankar S, Kirkland C. Approach to Suspected Physeal Fractures in the Emergency Department. Journal of emergencies, trauma, and shock. 2021 Oct-Dec:14(4):222-226. doi: 10.4103/JETS.JETS_40_21. Epub 2021 Dec 24 [PubMed PMID: 35125788]
Erickson CB, Shaw N, Hadley-Miller N, Riederer MS, Krebs MD, Payne KA. A Rat Tibial Growth Plate Injury Model to Characterize Repair Mechanisms and Evaluate Growth Plate Regeneration Strategies. Journal of visualized experiments : JoVE. 2017 Jul 4:(125):. doi: 10.3791/55571. Epub 2017 Jul 4 [PubMed PMID: 28715376]
Caine D, Purcell L, Maffulli N. The child and adolescent athlete: a review of three potentially serious injuries. BMC sports science, medicine & rehabilitation. 2014:6():22. doi: 10.1186/2052-1847-6-22. Epub 2014 Jun 10 [PubMed PMID: 24926412]
Wuerz TH, Gurd DP. Pediatric physeal ankle fracture. The Journal of the American Academy of Orthopaedic Surgeons. 2013 Apr:21(4):234-44. doi: 10.5435/JAAOS-21-04-234. Epub [PubMed PMID: 23545729]
Pandya NK, Baldwin K, Wolfgruber H, Christian CW, Drummond DS, Hosalkar HS. Child abuse and orthopaedic injury patterns: analysis at a level I pediatric trauma center. Journal of pediatric orthopedics. 2009 Sep:29(6):618-25. doi: 10.1097/BPO.0b013e3181b2b3ee. Epub [PubMed PMID: 19700994]
Level 2 (mid-level) evidenceSink EL, Hyman JE, Matheny T, Georgopoulos G, Kleinman P. Child abuse: the role of the orthopaedic surgeon in nonaccidental trauma. Clinical orthopaedics and related research. 2011 Mar:469(3):790-7. doi: 10.1007/s11999-010-1610-3. Epub [PubMed PMID: 20941649]
Chadwick CJ, Bentley G. The classification and prognosis of epiphyseal injuries. Injury. 1987 May:18(3):157-68 [PubMed PMID: 3508842]
Tzavellas AN, Kenanidis E, Potoupnis M, Pellios S, Tsiridis E, Sayegh F. Interobserver and intraobserver reliability of Salter-Harris classification of physeal injuries. Hippokratia. 2016 Jul-Sep:20(3):222-226 [PubMed PMID: 29097889]
Jawetz ST, Shah PH, Potter HG. Imaging of physeal injury: overuse. Sports health. 2015 Mar:7(2):142-53. doi: 10.1177/1941738114559380. Epub [PubMed PMID: 25984260]
Segal LS, Shrader MW. Periosteal entrapment in distal femoral physeal fractures: harbinger for premature physeal arrest ? Acta orthopaedica Belgica. 2011 Oct:77(5):684-90 [PubMed PMID: 22187848]
Level 3 (low-level) evidenceAbzug JM, Little K, Kozin SH. Physeal arrest of the distal radius. The Journal of the American Academy of Orthopaedic Surgeons. 2014 Jun:22(6):381-9. doi: 10.5435/JAAOS-22-06-381. Epub [PubMed PMID: 24860134]
Pennock AT, Ellis HB, Willimon SC, Wyatt C, Broida SE, Dennis MM, Bastrom T. Intra-articular Physeal Fractures of the Distal Femur: A Frequently Missed Diagnosis in Adolescent Athletes. Orthopaedic journal of sports medicine. 2017 Oct:5(10):2325967117731567. doi: 10.1177/2325967117731567. Epub 2017 Oct 10 [PubMed PMID: 29051906]
Ayas MS, Kalkışım M, Turgut MC, Dincer R, Aslan O, Öner K, Köse A. Analysis of Clinical Outcomes in Pediatric Distal Tibia Triplanar Fractures Treated Surgically and Conservatively. Cureus. 2021 Dec:13(12):e20723. doi: 10.7759/cureus.20723. Epub 2021 Dec 26 [PubMed PMID: 35111420]
Level 2 (mid-level) evidenceDayton P, Feilmeier M, Coleman N. Principles of management of growth plate fractures in the foot and ankle. Clinics in podiatric medicine and surgery. 2013 Oct:30(4):583-98. doi: 10.1016/j.cpm.2013.07.004. Epub 2013 Aug 8 [PubMed PMID: 24075137]
Little RM, Milewski MD. Physeal fractures about the knee. Current reviews in musculoskeletal medicine. 2016 Dec:9(4):478-486 [PubMed PMID: 27604531]
Boyden EM, Peterson HA. Partial premature closure of the distal radial physis associated with Kirschner wire fixation. Orthopedics. 1991 May:14(5):585-8 [PubMed PMID: 2062735]
Level 3 (low-level) evidencePaley D, Bhave A, Herzenberg JE, Bowen JR. Multiplier method for predicting limb-length discrepancy. The Journal of bone and joint surgery. American volume. 2000 Oct:82(10):1432-46 [PubMed PMID: 11057472]
Level 2 (mid-level) evidenceNguyen JC, Markhardt BK, Merrow AC, Dwek JR. Imaging of Pediatric Growth Plate Disturbances. Radiographics : a review publication of the Radiological Society of North America, Inc. 2017 Oct:37(6):1791-1812. doi: 10.1148/rg.2017170029. Epub [PubMed PMID: 29019753]
Sananta P, Lesmana A, Alwy Sugiarto M. Growth plate injury in children: Review of literature on PubMed. Journal of public health research. 2022 Jul:11(3):22799036221104155. doi: 10.1177/22799036221104155. Epub 2022 Jul 18 [PubMed PMID: 35923296]
Singh V, Garg V, Parikh SN. Management of Physeal Fractures: A Review Article. Indian journal of orthopaedics. 2021 Jun:55(3):525-538. doi: 10.1007/s43465-020-00338-6. Epub 2021 Jan 13 [PubMed PMID: 33995857]
Huntley SR, Summers SH, Stricker SJ. Salter-Harris type-IV displaced distal radius fracture in a 5-year-old. Journal of pediatric orthopedics. Part B. 2016 Mar:25(2):170-3. doi: 10.1097/BPB.0000000000000228. Epub [PubMed PMID: 26426506]
Georgiadis AG, Gannon NP. Park-Harris Lines. The Journal of the American Academy of Orthopaedic Surgeons. 2022 Dec 1:30(23):e1483-e1494. doi: 10.5435/JAAOS-D-22-00515. Epub 2022 Sep 21 [PubMed PMID: 36137096]
Edmonds EW, Doan JD, Farnsworth CL. Periosteal incarceration versus interposition adipose tissue grafting in physeal fractures: pilot study in immature rabbits. Journal of experimental orthopaedics. 2019 Dec 1:6(1):46. doi: 10.1186/s40634-019-0214-4. Epub 2019 Dec 1 [PubMed PMID: 31788750]
Level 3 (low-level) evidenceDugan G, Herndon WA, McGuire R. Distal tibial physeal injuries in children: a different treatment concept. Journal of orthopaedic trauma. 1987:1(1):63-7 [PubMed PMID: 3506588]
Langenskiöld A. Surgical treatment of partial closure of the growth plate. Journal of pediatric orthopedics. 1981:1(1):3-11 [PubMed PMID: 7341649]
Dabash S, Prabhakar G, Potter E, Thabet AM, Abdelgawad A, Heinrich S. Management of growth arrest: Current practice and future directions. Journal of clinical orthopaedics and trauma. 2018 Mar:9(Suppl 1):S58-S66. doi: 10.1016/j.jcot.2018.01.001. Epub 2018 Jan 6 [PubMed PMID: 29628701]
Level 3 (low-level) evidenceCanadell J, de Pablos J. Correction of angular deformities by physeal distraction. Clinical orthopaedics and related research. 1992 Oct:(283):98-105 [PubMed PMID: 1395277]
Bollini G, Tallet JM, Jacquemier M, Bouyala JM. New procedure to remove a centrally located bone bar. Journal of pediatric orthopedics. 1990 Sep-Oct:10(5):662-6 [PubMed PMID: 2394821]
Level 3 (low-level) evidenceMayr JM, Pierer GR, Linhart WE. Reconstruction of part of the distal tibial growth plate with an autologous graft from the iliac crest. The Journal of bone and joint surgery. British volume. 2000 May:82(4):558-60 [PubMed PMID: 10855882]
Level 3 (low-level) evidenceStricker S. Arthroscopic visualization during excision of a central physeal bar. Journal of pediatric orthopedics. 1992 Jul-Aug:12(4):544-6 [PubMed PMID: 1613105]
Level 3 (low-level) evidenceKhoshhal KI, Kiefer GN. Physeal bridge resection. The Journal of the American Academy of Orthopaedic Surgeons. 2005 Jan-Feb:13(1):47-58 [PubMed PMID: 15712982]
Sabharwal S, Sabharwal S. Growth Plate Injuries of the Lower Extremity: Case Examples and Lessons Learned. Indian journal of orthopaedics. 2018 Sep-Oct:52(5):462-469. doi: 10.4103/ortho.IJOrtho_313_17. Epub [PubMed PMID: 30237603]
Level 3 (low-level) evidenceLeary JT, Handling M, Talerico M, Yong L, Bowe JA. Physeal fractures of the distal tibia: predictive factors of premature physeal closure and growth arrest. Journal of pediatric orthopedics. 2009 Jun:29(4):356-61. doi: 10.1097/BPO.0b013e3181a6bfe8. Epub [PubMed PMID: 19461377]
Level 2 (mid-level) evidenceArnold A, Thigpen CA, Beattie PF, Kissenberth MJ, Shanley E. Overuse Physeal Injuries in Youth Athletes. Sports health. 2017 Mar/Apr:9(2):139-147. doi: 10.1177/1941738117690847. Epub 2017 Feb 6 [PubMed PMID: 28165873]
Caine D, DiFiori J, Maffulli N. Physeal injuries in children's and youth sports: reasons for concern? British journal of sports medicine. 2006 Sep:40(9):749-60 [PubMed PMID: 16807307]
Level 1 (high-level) evidence