Executive Editor: Peter Trafton

Authors: Martin Hessmann, Sean Nork, Christoph Sommer, Bruce Twaddle

Distal tibia 43-C1 CREF

back to skeleton


1 General considerations top



We would like to express our thanks to Prof. Wade Smith (USA) for additional information and clinical photographs.

The most stable external fixation for distal tibial fractures employs fully circular rings with 3 or 4 connecting rods between each. Typically, one ring with tensioned wires is attached to the distal tibial articular segment. Two proximal rings provide stable anchorage for the distal ring. An extension for the foot and ankle is advisable, at least initially, and particularly for type C (intraarticular) fractures.

The proximal rings can be anchored with Schanz screws or tensioned wires. Wires are usually used in cancellous bone. Wires attached to a circular ring are typically tensioned at 100 to 130 kg-force. Schanz screws may be easier than wires in diaphyseal bone. (Remember to predrill cortical bone before inserting them.) Ring fixator systems are highly adaptable, and can be combined with internal fixation of the articular surface.


Fracture alignment

Unlike simpler fixators, the most stable ring fixators, connected with threaded rods and nuts, are not adjustable without significant modifications. Therefore, it is important that fracture reduction be achieved before the frame is attached, and that it be monitored and maintained during fixator application. This process is easiest if traction is applied preliminarily, and temporary limb supports are employed to prevent angulation due to gravity.

Traction can be provided with a fracture table, separate bridging external fixator or distractor, or with the ring fixator itself, if it is applied initially in ankle bridging mode. However, if this last option is selected, the distal tibial ring and connecting frame may interfere with surgical accesss to the distal tibial fracture site


Frame construction options

The surgeon must decide whether or not the frame should extend to the foot (ankle-joint-bridging), as discussed above. This protects the articular surface, and may decrease problems of loosening and infection involving the distal tibial pins. It may also increase the safety of earlier weight bearing.

Another technical decision the surgeon should consider is whether or not the frame should be assembled before it is applied to the injured leg. This option is usually faster, but may require more experience. The pre-assembled frame is attached to the leg with a transverse proximal tibial wire, and then a transverse calcaneal wire distally. After achieving desired length with axial distraction, additional wires pins are used to complete attachment of the frame to the leg. During this process, the leg position can be supported with suction tubing slings attached to rings as needed, folded towels placed between leg and rings, or other techniques.

Familiarity and experience with Ilizarov’s techniques are very helpful. Review the entire procedure (described in the following steps) before beginning.


Weight bearing

In the hands of experienced surgeons, properly constructed ring fixators may provide sufficient stability for weight bearing when this becomes comfortable.

For distal tibial fractures, this requires extending the frame across the ankle, with a “foot ring” attached with tensioned wires to calcaneus, midfoot, and metatarsals. This frame can be distracted slightly from the one above, so that weight-bearing forces are not transmitted proximally by the talus.

Once sufficient fracture healing has occurred, the foot ring can be removed to allow ankle motion and progressive weight bearing.



Many variations in technique and frame design are possible. Frames like the one described in the following steps can provide excellent stability. When applied and adjusted with care, they should restore satisfactory alignment (axes, rotation, and length). Generally good results with type A distal tibial fractures confirm their efficacy.

However, ring fixators offer limited potential for reduction and stabilization of articular surface fractures. Reduction wires (“olive wires”) may be used to reposition and compress some fractures with suitable patterns. But they are not as effective as ORIF for more complex articular fractures, particularly when fragments are impacted or rotated.

The desired goal for a distal tibial fracture is anatomical restoration of the tibiofibular mortise, so that both tibial and fibular articular surfaces perfectly match their talar counterparts. Thus a most important consideration is whether or not open articular surface reduction (delayed until soft tissues are suitable) should be a part of ring fixator treatment. When ORIF cannot safely be undertaken, a ring fixator might be used to maintain overall alignment until the fracture is healed. If symptomatic posttraumatic arthritis develops, its treatment is easier if the fracture has healed with satisfactory alignment.

In some simpler C1 fractures, reduction wires can be used instead of, or to supplement articular ORIF. For more complex fractures, formal ORIF, with lag screws, small plates and bone graft, may be needed, as may fibular reduction and fixation.

2 Frame construction - first steps top



All rings should be perpendicular to the long axis of the tibia, and parallel with each other.

Proximal rings

A stable base should be created proximally with two parallel rings, centered appropriately about leg and connected with three rods. Full rings are assembled from two half rings. Their size must be adequate for soft-tissue clearance, including swelling that may develop after fixator application. Allow at least 2 cm everywhere between ring and skin.

Distal tibial ring

A full ring is placed just above the level of the ankle joint for distal tibial fixation. Using tensioned wires, sometimes supplemented with a Schanz screw, it is attached to the reconstructed tibiofibular articular block.

Foot ring

A “U”-shaped foot ring completes the frame. Its anterior open end is closed with a half ring, as shown in the illustration. The ring fixator frame can be preplanned and pre-assembled, for easier application in the OR, or it can be built piece by piece on the leg.

Familiarity with the use of ring fixators is very helpful.


Mark ring locations on the skin

It helps to first select ring locations and mark the skin. Place the rings so it is easy to insert wires and pins into preplanned locations, based upon review of the patient’s x-rays. For advice about ring placement, see the following steps.

Ring selection

Choose appropriately sized half-rings that will be joined to create the three full rings. At least 2 cm clearance between leg and each ring is necessary to accommodate swelling. Use the same size rings, if possible, as they are easier to interconnect. (Special fittings are available for attaching threaded connecting rods to different size rings.) Select also an appropriate sized foot ring and half-ring for its anterior end.

3 Proximal frame top



Connect the two proximal rings with three threaded rods. Final tightening of their connections should await confirmation of satisfactory alignment. Bolts connecting half-rings should be placed where wires or pins are not desired.

The length of these rods should be chosen so the lower ring is anchored to intact diaphysis above the fracture zone, yet proximal enough not to interfere with attaching wires and pins to the distal tibial ring (approximately 10 cm above the fracture).


Attach most proximal ring to tibia

The most proximal ring should lie 2 or more centimeters below the proximal tibial articular surface. Place a transverse 2 mm wire through the tibia at this location. Attach the proximal ring to this with appropriate connectors. Tighten the wire. Make sure to allow at least 2 cm at all points between the leg and the ring.

With the ring perpendicular to the tibia, insert an anteromedial Schanz screw into the subcutaneous surface proximal to the anterior compartment muscles (Gerdy’s tubercle). Attach this to the ring.

Insert a second Schanz screw “dropped” (with a short connecting rod or post) somewhat more distally into the anteromedial subcutaneous tibial surface as illustrated.

Pearl - positioning aids

Folded towels placed between rings and leg can help to hold the ring assembly in position. Alternative positioning aids include suction tubing and special limb supports.


Fixation of the middle ring

Ensure that this ring lies distally over intact tibial diaphysis. It must be perpendicular to the tibia, with at least 2 cm clearance circumferentially. Stabilize it temporarily with folded towels or other technique as mentioned above. Place an anteromedial Schanz screw on the proximal surface of this ring. Next, place another Schanz screw below the ring on a appropriate connector. Place it through the safe zone, at a different angle from the first pin.

Reconfirm ring assembly position and tighten all connections.

4 Attachment of distal ring top


Reduction and wire placement according to preoperative plan

This illustration presumes a type A fracture, without displacement of the tibiofibular syndesmosis. The distal tibial fracture should be reduced before inserting wires or pins. Adjustment of reduction later is possible but difficult, and may compromise stability. Preliminary fibular fixation or the use of a temporary external bridging frame aids reduction.

The location of distal tibial wires and pins should be planned preoperatively. A CT scan is very helpful. For some type C fractures, reduction wires (with olives) might be considered for interfragmentary compression and reduction, if desired (see step 6).


Insertion of first distal tibial wire

This illustration shows the placement of the distal tibial ring and its anchorage into a reduced type A distal tibial fracture. A typical first wire is placed from the fibula posterolaterally through the anteromedial tibia. If the fracture location permits, this should be at least 2 cm above the ankle joint.

Place this first wire perpendicularly to the tibial axis, with sufficient length on each side of the ankle to allow ring mounting. Assemble the selected ring and confirm that its diameter is sufficient. Mount the ring on this first distal wire, with sufficient soft tissue clearance, and located to permit fracture reduction. Tension the wire for stability.

An analogous distal wire might be placed through the calcaneus, for stabilizing a pre-assembled frame with foot ring.


Insertion of second distal wire

Using the ring and an appropriately positioned wire bolt as guide, insert a second wire in its preplanned location. Advance it through the bone and soft tissue with attention to neurovascular structures.

Attach it to both sides of the ring. Tension this wire. Simultaneous wire tensioning may help maintain fracture reduction.

5 Connect distal ring to proximal ring assembly top


Maintaining axial alignment and rotation, and adjusting length correctly, attach the distal ring with three threaded rods to the lower ring of the proximal ring assembly. Tighten the nuts to stabilize this relationship.

6 Option: reduction wires top


Wire selection

2 mm diameter wires are recommended. Some wires have small beads called “olives”. Wire tension can pull the olive against a bone fragment, and thus these wires inserted and tensioned in opposite directions can produce interfragmentary compression. Such wires must be inserted on the side where the olive is desired.


Articular fracture compression

In this illustration, two reduction (olive) wires are used to compress the medial and lateral articular fragments of a suitably oriented C1 distal tibial fracture.

The reduction wires have been inserted according to preoperative plan, perpendicularly to the fracture plane and centrally in each fragment after preliminary reduction. One olive is on each side of the fracture. When tensioned appropriately, these wires will compress the fracture.


Simultaneous tensioning of reduction wires

Tensioning the two reduction wires simultaneously (or in alternating fashion) helps avoid displacement of  the distal fragments during this process.

Reconfirm appropriate alignment. Add an additional wire or Schanz screw to increase stability of the distal fragment. Confirm that all connections are securely tightened, all wires are appropriately tensioned, and fracture alignment remains satisfactory.

Bend the wires around the clamps so they are not prominent, and apply end caps.

7 Foot and ankle fixation top


To protect the distal tibial fracture, and avoid equino-varus contractures, the frame can be extended to support calcaneus and forefoot. This may permit early weight bearing.

Two (or more) wires or pins can be placed in the calcaneus, oblique wires in the midfoot, and a wire in the 1st, 2nd, and 3rd metatarsals distally (as shown in the illustration).

A variety of options are available. For example, short extensions permit placement of small Schanz screws into first and fifth metatarsals.

v1.0 2016-11-22