Executive Editor: Chris Colton

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

Femur shaft 32-A1 ORIF distal shaft

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1 Principles top

Principles enlarge

Compression plating

Compression plating provides fixation with absolute stability for two-part fracture patterns, where the bone fragments can be compressed. Compression plating alone is usually used for simple fracture patterns with low obliquity, where there is insufficient room for a lag screw. In more oblique fractures, compression plating can be performed, with the addition of a lag screw.

Compression plating can only be undertaken as an open procedure.

The objective of compression plating is to produce absolute stability, abolishing all interfragmentary motion.

Principles enlarge

Dynamic compression principle

Compression of the fracture is usually produced by eccentric screw placement at one or more of the dynamic compression plate holes. The screw head slides down the inclined plate hole as it is tightened, the head forcing the plate to move along the bone, thereby compressing the fracture.

Principles enlarge

Plate position on the femur / tension band principle

As a general rule the plate should be positioned on the lateral aspect of the femur.

A plate acts as a dynamic tension band when applied to the tension side of the bone and when stable cortical contact is present on the opposite side to the plate.

With vertical load, the curved femur creates a tension force laterally and a compression force medially.

A plate positioned on the side of the tensile force resists it at the fracture site, provided there is stable cortical contact opposite to the plate.


It is important to restore axial alignment, length, and rotation. That means, in a simple A type fracture, a direct reduction of the main fragments is required.

Reduction can be performed with direct reduction tools.

2 Preliminary reduction top

Preliminary reduction enlarge

Use of reduction clamps

In an open plating technique, a preliminary reduction can be undertaken to facilitate the final reduction. Most usually, large pointed reduction clamps are used under direct vision.

Preliminary reduction enlarge

A colinear clamp can also be very helpful.

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 midpoint 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 joint.

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 the 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

Condylar screw insertion

First, the condylar screw is inserted to its final position. The T-handle is lined up parallel to the femoral shaft axis in order to ensure an adequate plate placement.

Plate fixation to the distal fragment enlarge

Plate placement

Now the T-handle is detached and the plate barrel is placed over the screw shank. Afterwards, the T-handle is reconnected to the screw …

Plate fixation to the distal fragment enlarge

… and the plate position fine tuned.

4 Plate fixation to proximal fragment top

Plate fixation to proximal fragment enlarge

Insertion of first screw into proximal fragment

Before fixation to the proximal fragment, it is often advisable to insert a cancellous screw into the most distal plate hole, to prevent rotation of the plate about the axis of the condylar screw.

If the overall reduction is found to be sufficient, the first cortical screw is placed in the proximal fragment. To further improve the compression, the screw is placed eccentrically.

Plate fixation to proximal fragment enlarge

Alternative: articulated tension device

In cases of nonunion, the articulated tension device is helpful in achieving compression.

Plate fixation to proximal fragment enlarge

To improve the compression further, the screw is inserted eccentrically.

The tension device is dismantled after two additional screws are inserted into the proximal fragment.

Plate fixation to proximal fragment enlarge

Insertion of additional screws

According to the preoperative planning, additional screws are placed in the proximal and distal fragments.

Plate fixation to proximal fragment enlarge

Pearl: lag screw

The use of supplementary lag screws can be recommended in simple A1 and A2 type fractures, but is not possible in most A3 fractures.

Pearl: osteoporotic bone

In osteoporotic bone, the use of locking-head screws is advantageous.

v1.0 2016-10-24