Plating is the standard technique for treating forearm fractures in adults and is therefore best considered for skeletally mature or nearly mature children.
Children with open physes have thick active periosteum favoring stability and rapid healing with the ESIN method. Where such techniques are unavailable plating may be used in younger children.
If technically possible, ESIN is biologically favored. If plating is used, soft-tissue and periosteal stripping should be minimized.
Plating of oblique or spiral forearm shaft fractures
Plating of pediatric forearm shaft fractures follows the technique for plate fixation in adults.
For oblique or spiral forearm shaft fractures, interfragmentary compression can be achieved by one of the following techniques:
- Lag screw outside the plate
- Lag screw through the plate
- Compression plate with consecutive lag screw through the plate
This results in absolute fracture stability.
Large wedge fragments may be fixed to one of the main segments before plate fixation with a lag screw, placed through or outside the plate.
For unstable multifragmentary forearm shaft fractures, bridge plating may be applied. This results in relative fracture stability.
Instruments and implants
A small fragment set consists of:
- 2.7 or 3.5 mm plates and screws
- Power driver
- 2.7 or 3.5 mm insertion set
Compression by lag screw
For interfragmentary compression a lag screw can be inserted either through a plate hole (1) or separate from the plate (2).
Axial compression results from eccentric screw (load screw) insertion with compression plates.
Depending on the surgical approach, the plate will be applied to either the anterior or posterior surface of the radius.
In the following example, a plate applied to the anterior surface is illustrated.
Make sure that the plate is seated on the bone without any soft-tissue interposition, apart from periosteum which should not be stripped.
In rare cases, the posterior interosseous nerve is visible. In such cases it is recommended that the position of the nerve in relationship to the plate be noted and documented in the operation report.
Choice of approach
For proximal radial shaft fractures, the
anterior approach (Henry)
is most often used to minimize the risk of damage to the posterior interosseous nerve, which crosses the proximal radius within the supinator.
In mid and distal radial shaft fractures, either the
anterior approach (Henry)
posterolateral approach (Thompson)
can be used, depending on surgeon’s preference.
This procedure is normally performed with the patient in a
Reduction and fracture stability in children
Children’s periosteum is thick, tough tissue and is often intact on the concave (compression) side of a fracture.
Reduction maneuvers should be gentle to take advantage of the stability of the intact periosteum.
Exaggeration of the fracture deformity may be required to loosen the periosteum and allow for gentle reduction.
In pediatric fractures there is often a combination of patterns of bone failure. Residual plastic deformity may prevent anatomical reduction of some of the fracture edges. Provided the alignment of the bone is anatomical and overall reduction is stable it is not necessary to perfectly reduce the entire fracture.
Reduce the fracture anatomically, using a reduction forceps on each main fragment.
The use of blunt, as opposed to pointed, reduction forceps can be helpful, particularly if greater forces are required.
Pearl: twisting a reduction forceps
Reduction of overlapping oblique fractures can be achieved by twisting a reduction forceps, thereby lengthening the fracture.
Maintaining fracture reduction
Maintain the fracture reduction with pointed reduction forceps.
Place the forceps such that it will not interfere with the planned plate position.
In the forearm, in addition to any lag screw, three bicortical plate screws are suggested in each main fracture fragment due to the high torsional stresses.
Not every plate hole needs to be occupied by a screw.
In oblique or spiral forearm shaft fractures an empty plate hole may be necessary at the level of the fracture to introduce a lag screw.
If the fracture morphology dictates that the interfragmentary lag screw be positioned separate from the plate, the plate then acts as a neutralization plate and axial compression should not be applied.
Insertion of lag screw
Insert a lag screw of appropriate length as perpendicular to the fracture plane as possible.
Maintain the reduction by leaving the pointed reduction forceps in situ.
To protect the primary lag screw fixation, apply a precisely contoured plate adjacent to the screw head without axial compression and all screws in the neutral position.
The pointed reduction forceps can then be removed.
In some fracture configurations, it is advantageous to initially compress the fracture by inserting a lag screw through the relevant plate hole.
If this technique has been used, then axial compression must not be applied secondarily through the plate.
Insertion of lag screw through plate
Apply a precisely contoured plate to the surface of the anatomically reduced fracture and fix it to one main fragment, either with a neutral screw, or with a bone forceps as illustrated.
Then insert an interfragmentary lag screw through the appropriate plate hole as perpendicular to the fracture plane as possible.
Insertion of plate screws
Complete the fixation by inserting the plate screws in neutral mode, usually alternating between both main fragments.
Insertion of 1st screw
The aim of this maneuver is to create an “axilla” into which the other fragment can be compressed and locked either with a compression screw or using a push-pull technique.
Fix the plate to the appropriate fragment with a screw in neutral mode such that an axilla is created.
Place a reduction forceps on the opposite fragment to hold it in the reduced position against the plate.
Insertion of 2nd screw eccentrically
Insert a second screw eccentrically into the reduced fragment.
By tightening the eccentrically inserted screw, axial compression is achieved.
Insertion of lag screw
The stability of plate fixation in oblique fractures can be increased by inserting a lag screw through the plate after primary axial compression has been achieved.
Before inserting additional screws check reduction of the fracture and rotation of the forearm.
Additional screws in each fragment are inserted in a neutral position and do not produce additional compression.
Small wedge fragments
Small wedge fragments that do not have a significant effect on stability should not be addressed. They will become incorporated into the fracture by indirect bone healing.
The two main fragments will be fixed with plating.
Large wedge fragments
Larger wedge fragments, that contribute to the stability of the fixation, may be fixed to one main fragment.
Fixation of the wedge to one main fragment may assist reduction of the residual fragment.
The two main fragments will then be fixed with compression plating either with the lag screw through the plate or separate to the plate.
Check the completed osteosynthesis with image intensification. These images should be retained for documentation or alternatively an x-ray should be obtained before discharge.
Make sure that the plate is at the correct location, the screws are of appropriate length and the desired reduction has been achieved.
Stabilize the elbow at the epicondyles and check the forearm rotation.