Executive Editor: Chris Colton

Authors: Peter V Giannoudis, Hans Christoph Pape, Michael Sch├╝tz

Femur shaft 32-B3 CRIF distal shaft

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1 Principles top

Principles enlarge

Important module-wide statement

Where appropriate, a “generic” fracture zone will be illustrated and not necessarily the specific fracture morphology under consideration. Where the fracture morphology determines the fixation technique, the specific morphology will be shown.

Principles enlarge

Bridge plating

Bridge plating uses the plate as an extramedullary splint, fixed to the two main fragments, leaving the intermediate fracture zone untouched. Anatomical reduction of intermediate fragments is not necessary. Furthermore, their direct manipulation would risk disturbing their blood supply. If the soft tissue attachments to the fragments are preserved, and the fragments are relatively well aligned, healing is enhanced.

Alignment of the main shaft fragments can be achieved indirectly with the use of traction and the support of indirect reduction tools, or indirectly via the implant.

Mechanical stability, provided by the bridging plate, is adequate for gentle functional rehabilitation and results in satisfactory indirect healing (callus formation). Occasionally, a larger wedge fragment might be approximated to the main fragments with a lag screw.

Principles enlarge

Bridge plate insertion

Bridge plates can be inserted either with an open exposure that respects soft-tissue attachments to the fractures, or through a minimally invasive (MIO) approach that leaves the soft tissues intact over the fracture site. In the latter case, incisions are made proximally and distally, and the plate is inserted through a submuscular tunnel. This normally requires fluoroscopic intensifier monitoring.


It is important to restore axial alignment, length, and rotation.

Reduction can be performed with a single reduction tool (eg, large distractor), or by combining several steps (for example fracture table +/- external fixator, +/- reduction via the implant, etc.) to achieve the final reduction.

The preferred method depends on the fracture and soft-tissue injury pattern, the chosen stabilization device, and the experience and skills of the surgeon.

If a large fragment has separated from the fracture zone and impaled the adjacent muscle, direct reduction may be required.

2 Preliminary reduction top

Preliminary reduction enlarge

Reduction by external fixator or distractor

Sometimes, manual traction is not sufficient to achieve and hold preliminary reduction.

Then the use of an external fixator facilitates the reduction procedure and provide temporary alignment and stability for the bridge plating procedure.

Proximal and distal fixator screws should be inserted carefully not to conflict with the later plating procedure. For this purpose, anterolateral or anterior positions on the femur are safe.

If no traction table is used, folded linen bolsters under the fracture zone may facilitate the reduction maneuver.

3 Plate fixation to the distal fragment top

Plate fixation to the distal fragment enlarge

Guide wire insertion

As a first step, a guide wire for the condylar screw is inserted into the distal femur.

This is an extremely important step, because it determines the later plate positioning in two planes.

The guide wire for the cannulated condylar screw is inserted into the condylar mass from laterally. The entry point lies anterior to the mid point between the anterior and posterior edges of the lateral femoral condyle, in line with the femoral shaft axis, and 2 cm proximal to the knee point.

The guide wire must be parallel to the plane of the tibio-femoral joint (line A) and, at the same time, parallel to the plane of the patello-femoral joint (line B).

Plate fixation to the distal fragment enlarge

Checking correct position of the guide wire

The correct positioning of the guide wire must be checked using image intensifier fluoroscopy. The depth of guide wire insertion is crucial. Remember that the cross-section of the distal femoral condylar mass is trapezoidal and slopes markedly on the medial side. The tip of the guide wire should just engage the medial cortex, and so will appear short of the medial condylar cortex on the AP intensifier image.

Plate fixation to the distal fragment enlarge

Screw length measurement

Next, the surgeon slides the direct measuring device over the guide wire and determines guide wire insertion depth and, thereby, the length of condylar screw required.

Plate fixation to the distal fragment enlarge


After assembling the DCS triple reamer and setting the reamer to the correct depth, the hole for the condylar screw is reamed over the guide wire.

Plate fixation to the distal fragment enlarge

Preliminary screw insertion

The following steps are recommended for the minimally invasive technique.

After tapping, the DCS screw is inserted over the guide wire in a manner so that its outer end is still visible outside the lateral cortex of the distal femur.

Plate fixation to the distal fragment enlarge

Plate placement

The T-handle is now detached and the plate is inserted submuscularly, from distal to proximal.

Pearl: preparation of the plate tunnel

Three options are in use for preparation of the plate path along the proximal main fragment.

  • Insert a long pair of scissors, spread them, and then pull backwards
  • Insert a periosteal elevator and slide it extraperiosteally along the proximal main fragment. (The tip of the plate can be used in a same manner).
  • A soft tissue-retractor is available which serves the same purpose.

Plate fixation to the distal fragment enlarge

Plate and screw combination

The T-handle is then inserted through the barrel of the plate and reconnected to the screw. This can be challenging and often requires abandoning the preliminary reduction.

Plate fixation to the distal fragment enlarge

Final screw placement

When the condylar screw is in its final position (the T-handle is then parallel, on the lateral view, to the long axis of the distal fragment), the barrel is slipped fully over the screw and the T-handle removed. A cancellons screw can then be inserted into the distal screw hole of the plate to prevent rotation of the main distal fragment around the axis of the condylar screw.

4 Plate fixation to proximal fragment top

Plate fixation to proximal fragment enlarge

Verification of reduction

Under image intensifier control, the preliminary reduction is checked again with respect to axial alignment, length and, to a certain degree, rotation (in more complex fractures, judging the clinical accuracy of the rotation becomes more important, while at the same time the associated radiological findings can be challenging to interpret).

Plate fixation to proximal fragment enlarge

Insertion of first screw into proximal fragment

The approaches / stab incisions over the proximal fragment are made according to the planned final screw placement.

Two blunt Hohmann retractors placed ventrally and dorsally around the femoral shaft control the lateral position of the plate.

If the overall reduction is found to be satisfactory, the first cortical screw in the distal part of the proximal fragment is inserted, without being fully tightened. This still allows for the plate position to be fine-tuned.

Plate fixation to proximal fragment enlarge

Pearl: final reduction

If the lateral position prior to the placement of the second screw is inadequate, the use of sterile bolsters is recommended to aid correction.

Plate fixation to proximal fragment enlarge

Inseration of second screw into proximal fragment

The lateral plate position is confirmed by using two Hohmann retractors introduced through the second approach / stab incision over the proximal plate portion, or by palpation.

Once the most proximal screw is inserted, the more distal screw in the proximal fragment is fully tightened.

5 Additional screw insertion top

Additional screw insertion enlarge

According to preoperative planning, additional screws are inserted into the distal and proximal main fragments.

v1.0 2007-12-02