Tibial Shaft Fractures

Positioning.

The patient is positioned supine on a radiolucent operating table ( Fig. 64.9 ) or on a fracture table set up for IMN of the tibia. On such a table, the leg can be free, supported with a radiolucent triangle, or supported with an external fixator or large distractor. If a fracture table is used, the proximal leg support must be well padded. It is positioned posterior to the distal femoral shaft and not posterior to the popliteal fossa. If compression of the popliteal fossa occurs during the surgery, there may be excessive pressure on neurovascular structures. With a fracture table, rotational alignment must be assessed before draping and intraoperatively. Fluoroscopic visualization and provisional reduction should also be performed before draping. A tourniquet may aid exposure but should not be used during reaming because the absence of blood flow may increase the risk of thermal necrosis. In our practice, we do not use a tourniquet routinely.

Typically, the knee must be flexed more than 90 degrees to permit free access to the tibia nail entry site if using an incision distal to the patella. However, it is also possible to insert the nail with the knee in a semi-extended position with the patella retracted or incision proximal to the patella. Positioning must allow adequate fluoroscopic visualization in the AP and lateral planes from the tibial plateau to the ankle (see Fig. 64.9 ).

The surgeon can stand on the medial or lateral side of the injured leg, with the fluoroscope on the opposite side. Standing on the medial side simplifies medial-to-lateral insertion of locking screws.

Surgical Approach

Reduction Techniques.

The reduction is most often obtained before IM guidewire and nail insertion. It is usually possible to manually reduce the fracture in the acute situation. One surgeon (usually the more experienced surgeon on the team) applies manual traction while simultaneously correcting coronal plane angulation and rotation. Sagittal plane angulation can be corrected using a soft bump behind the leg. A second surgeon is then able to insert the IM guidewire, ream the canal, and insert the nail ( Fig. 64.10 ).

In patients who have a spiral or short oblique tibial fracture, the reduction can be facilitated and maintained with the pointed reduction clamps inserted through small stab incisions about the fracture site. After rotation is corrected manually, one clamp is used to correct and hold reduction of the coronal plane while the other is used to correct and hold the reduction of the sagittal plane ( Fig. 64.11 ). Attention should be given to the correct location of the stab wounds to allow positioning of the reduction clamp tines without excessive pressure on the skin (see Fig. 64.11 ). Typically, the medial and anterior tines are inserted through stab incisions directly over the subcutaneous surface of the medial and anterior cortex of the tibia. The lateral and posterior tines are inserted through stab incisions that are 3 to 4 cm lateral to the tibia crest. The tine is inserted first subcutaneously and then advanced medially over the anterior muscle compartment. Once reaching the lateral cortex of the tibia, the tine is carefully advanced along the lateral cortex until reaching the posterior or lateral cortex. Care must be taken for the reduction clamp tip to stay touching the bone while it is being positioned. This will avoid neurovascular damage.

In fractures where it is difficult to correct shortening with manual traction (e.g., after significant delay from injury to surgery) or when there is significant comminution that prevents accurate length and alignment control, a distractor or temporary external fixator can be used to correct shortening, rotation, and angulation deformities. Moreover, the external fixator and distractor can maintain reduction during the nailing procedure. There are several pin placement patterns that can be utilized to achieve and maintain reduction of the tibia. When applying the femoral distractor, two 5.0-mm half-threaded pins are inserted unicortically from medial to lateral. The first pin is inserted parallel to the knee joint in the proximal tibia at the level of the fibular head and just posterior to the midline but anterior to the fibular head ( Fig. 64.12A ). The second pin is inserted parallel to the ankle joint in the distal tibia at the level of the ankle syndesmosis and over the posterior third of the ankle joint and anterior to the distal fibula (see Fig. 64.12B ).

We have found that it may be more challenging to control coronal plane angulation with a unilateral distractor (see Fig. 64.12 ). A temporary external fixator frame may be used to correct and control the coronal angulation more easily. A centrally threaded transtibial pin is inserted from lateral to medial parallel to the knee joint in the proximal tibia just posterior to the midline and anterior to the fibular head. A second, centrally threaded transcalcaneal pin is inserted from medial to lateral at the safe zone of the calcaneus. The two pins are then connected by two parallel bars to create a rectangular frame. The tibia is then manually reduced to the correct rotation, angulation, and length, and the frame is secured ( Fig. 64.13 ). Distraction jigs can then be used on either one of the bars to add length or to change angulation as needed. Procurvatum and recurvatum can be controlled with a bump under the leg or by adding an anterior pin that is connected to the frame. Care must be taken to position the frame on the posterior aspect of the pins to avoid collision of the frame with the tibial nail targeter.

Delay in treatment with callus formation or soft tissue entrapment in the fracture site may lead to the inability of the surgeon to close reduce the tibial fracture and allow insertion of the IM guidewire from the proximal to the distal fragments of the fracture (see the Nail Insertion and Fixation Technique section). The surgeon may opt to perform an open reduction if an adequate closed reduction cannot be achieved. If the open reduction is performed by disturbing the local soft tissues as little as possible, this technique may not compromise the result.

Nail Insertion and Fixation Technique.

The selected entry site for initial guidewire must lie over the long axis of the tibial canal, and on the anterior edge of the tibial plateau. Radiographically, this usually corresponds to a point just medial to the lateral tibial spine on the AP fluoroscopic image and immediately adjacent and anterior to the articular surface on the lateral fluoroscopic image.

After the guidewire is inserted through the correct entry site, it is advanced for 10 to 15 cm, and a rigid entry reamer is inserted over it to create an entry portal for the subsequent flexible canal reamers and nail. When using an infrapatellar approach, the knee is held in maximal flexion to allow passage of the reamers and nail parallel to the anterior cortex of the tibia. The skin overlying the distal pole of the patella must be protected to avoid trauma during the nailing procedure. The distal aspect of the patella and proximal skin can be protected by use of a cannula for the reamers, a shorter design of the proximal jig and jig bolt, and/or proximal extension of the incision over the inferior pole of the patella.

An IM guide is inserted through the entry portal. The tip of the guidewire is slightly bent to aid in navigating the wire across the fracture site. The wire is advanced by gentle tapping with a mallet on a wire grasper under fluoroscopic imaging. Once the wire reaches the distal fragment, it is advanced to the level of the physeal scar (approximately 1 cm above the tibial plafond) and “docked” in the distal tibia in the AP and lateral images. In the AP fluoroscopic view, the guidewire is positioned over the middle of the dome of the talus because the middle of the distal tibia flares medially. On the lateral view, the guidewire is placed at the junction of the anterior and middle thirds of the distal tibia because the tibia flares posteriorly.

Either a reamed or unreamed nail is then inserted over the IM guidewire. If a reamed nail is chosen, then flexible reamers are inserted one after another in increasing diameters. Typically, a diameter of 8.5 mm with an end-cutting flute is initially inserted, followed by 0.5- to 1-mm larger diameter reamers. Reaming is continued until bone chatter is heard and felt. Generally, no more than 1 to 2 mm of reaming is carried out after the first reamer makes contact with the cortex internally. A nail of a diameter 1 to 2 mm less than the last reamer is then inserted over the guidewire. For young patients with normal bone, we prefer to ream 1 to 1.5 mm larger than the nail diameter to avoid nail entrapment and still create a tight fit between the nail and the bone. A tourniquet is rarely needed to prepare the entry site. If it is used, the tourniquet must be deflated before reaming to aid heat dissipation. The most common cause of tibial necrosis appears to be forceful reaming of the medullary canal in a young patient with a small diameter canal and a thick cortex.

Once reaming is completed, the nail is inserted over the IM ball-tipped guidewire. Some authors recommend exchanging the distally bent guidewire with a straight non–ball-tipped wire to aid in removal of the guidewire after the nail is inserted. We have not found this to be a problem provided the distal tip ball-tip guidewire is bent properly. We recommend making one bend of 10 to 20 degrees approximately 2 cm proximal to the ball tip. This can be optimally performed using a wire grasper (T-handle) and pliers or one of the drilling sleeves from the set ( Fig. 64.14 ).

Once the nail has been fully inserted, fluoroscopy is used to verify that the proximal end of the nail is not too prominent relative to the entry site, and that fracture length, rotation, and alignment are adequate. A particular problem that may arise during insertion of the nail is fracture distraction or creation of a gap at the fracture site. To correct distraction in unstable fracture patterns or achieve compression in stable (transverse/short oblique) fracture patterns, the nail is “backslapped” after distal locking is performed. Adequacy of reduction and nail position is again evaluated. If the tibia is reduced, proximal interlocking is performed. If the fibula is not comminuted or has an easy cortical read, it can be used to assess length as well.

Current tibial IM nails have holes in various configurations for interlocking screws at both proximal and distal ends. The interlocking screws help control rotation and length in unstable fracture patterns. Because of the lower density of metaphyseal bone, we prefer to lock the IM nail with two proximal and two distal screws ( Fig. 64.15 ). The two proximal screws are typically inserted through the nail-targeting jig. The distal screws are typically inserted using a freehand technique with a fluoroscopic “perfect circle” method. When inserting the distal locking screws freehand, the image intensifier is aligned with a nail hole to create a perfect circle, indicating coaxial alignment of the C-arm and the screw hole in the nail. An incision is made through the skin and fascia, down to the cortex at this site. The tip of the drill is positioned on the lateral cortex of the shaft, aligned with the center of the circular image (creating a “packman” image). A hole is then drilled parallel to the radiograph beam of the C-arm. Imaging is used to verify the passage of the drill through the interlocking hole. A useful technique is to drill the near cortex and then gently tap the drill bit through the nail to the far cortex. We then verify that the drill bit is in the correct position within the nail aperture with the C-arm. Then we drill the far cortex. Screw length is then measured using a depth gauge, and a screw is inserted freehand using the same trajectory as the drill bit. The process is then repeated for the other distal hole. Different devices and imaging techniques have been developed in recent years in order to reduce the amount of time and radiation associated with the freehand technique. It is our preference to insert both proximal and distal interlocking screws from medial to lateral. Although lateral-to-medial screws distally may be theoretically less likely to injure the posterior tibial neurovascular bundle and superficial peroneal nerve, they are not as mechanically stable. AP and oblique distal locking screws require special attention to soft tissue anatomy.

Most statically locked tibial fractures heal with the locking screws in place. Most nail designs have one of the proximal interlocking holes designed for dynamic locking. The dynamization hole is oblong allowing controlled vertical compression of the fracture site with weight bearing.

Use of both proximal and distal locking screws, in a static-locked pattern, requires that the nail and screws endure forces not borne by the tibia. Thus the several components of a statically locked nail are at risk of fatigue failure, which occurs most commonly at the distal interlocking screw holes of the nail or when the screws break. Clinically, distal tibial fractures close to the nail's distal locking screws are most at risk of causing nail failure. Implant material and design, especially outer diameter, determine the strength and endurance of IM nails and locking screws.

Reamed Versus Unreamed Nailing.

Both reamed and unreamed nail designs are available for tibial nailing. Unreamed nails are of smaller diameter and can be solid. Reamed nails are cannulated, of larger diameter, and with larger interlocking screws. Although reamed nails offer an ultimately stronger biomechanical construct, unreamed nails have been suggested as a quicker, less traumatic option. However, the Study to Prospectively Evaluate Reamed Intramedullary Nails in Patients with Tibial Fractures (SPRINT) investigators found that there was a statistically significant decrease in reoperation rates in reamed versus unreamed nails.

IMN, with or without reaming, affects endosteal blood circulation. There is an immediate loss of medullary arterial flow with a variable thickness of bone necrosis around the nail. To compensate, the periosteal blood supply assumes a larger role in perfusing the cortex. If immobilization is sufficient and there is sufficient space between the nail and the internal surface of the cortex, then the medullary arterial system regenerates within a few weeks. Cortical necrosis is significantly less when a smaller diameter IM nail is inserted without reaming than when a larger diameter nail is inserted after reaming the medullary canal. This is the theoretical justification for using nonreamed nails for open tibial fractures. Clinical experience and research have shown the same amount of callus formation after both reamed and unreamed nails. On the contrary, shorter healing times and reduced reoperation rates have been demonstrated with reamed nails.

Unreamed tibial nails have smaller diameters and require smaller diameter locking screws, and they thus have an increased risk of mechanical failure, which might lead to loss of fracture fixation and alignment. Compared with larger diameter nails intended for insertion with reaming, their smaller diameter shafts, proportionately larger locking screw holes, and smaller locking screw diameters typically result in reduced ultimate strength and shorter fatigue life. Therefore, unless there is cortical contact between the proximal and distal fragments with a simple fracture pattern, limited weight bearing is advisable until healing of the tibia is advanced enough to protect the IM fixation. In practice, fatigue fracture of nonreamed IM tibial nails rarely occurs. Locking screw failure is not unusual, but it rarely leads to significant problems. However, the surgeon must discuss such possibilities with the patient when planning treatment. The surgeon must also keep in mind the problems of removal of broken locking screws, particularly of retrieval and removal of a broken solid IM nail. More difficult for the surgeon than mechanical failure of nonreamed tibial nails is the challenge of inserting them into a medullary canal that may be a poor fit because of its inner diameter, mismatched curvature, or both. A study from Sweden found that even 8-mm nails could not be inserted without reaming in a significant percentage of adults.

Reaming has been suggested as a possible cause for compartment syndrome or systemic effects after tibial fractures. Nassif and colleagues’ prospective randomized study showed no difference in compartment pressures between reamed and nonreamed nailing. Systemic effects of IMN, perhaps more of a concern regarding femoral fractures, have also been discussed as a reason for using nonreamed IM tibial nails. Although it is clear that medullary fat and debris enter the vascular system during IMN, there is little evidence that there are any significant clinical consequences. Systemic hemodynamic effects—increased central venous and pulmonary artery pressures and relative hypoxia—are related more to the tibial fracture than to IM nail insertion.

From the information currently available, it appears that medullary reaming is a beneficial part of IMN for most if not all closed tibial fractures.

Intramedullary Nailing After External Fixation.

External fixation offers a quick and less invasive means of stabilizing tibial shaft fractures that may benefit the patient with multiple injuries, with severe soft tissue wounds, or who will be transferred elsewhere for definitive care. The use of any IM nail after an external fixator may cause an increased risk of infection secondary to bacterial contamination through the pin sites. If infection of the fracture wound or at pin sites occurs after external fixation, even if it is treated successfully, its recurrence after subsequent IMN is possible. In planning treatment for a tibial fracture, the surgeon should remember the problems that may result from external fixator pins placed in the tibia before IM nails.

Tornetta and DeMarco have postulated that nailing after external fixation can be separated into early cases, done by protocol as planned “sequential” treatment, and later “reconstructive” cases. Problems with infection are more likely in the reconstructive setting and should be less frequent if IMN is avoided when pin wounds have been infected or heavily contaminated. Overall, if done in the first 2 weeks after external fixation, revision to IM nails appears to be safe a procedure with minimal morbidity.

Surgical Approaches.

With its triangular external cross section, the tibial shaft offers three potential surfaces for plate application. The medial and lateral surfaces are readily available from an anterior approach. The less accessible posterior surface may also be mechanically less satisfactory for plate fixation ( Fig. 64.16 ).

It is crucial to assess the condition of the skin and soft tissues carefully before choosing plate fixation and before exposing the tibia. The subcutaneous anteromedial surface of the tibia is often injured, and it may not be suitable for plate application, especially after direct local trauma. There is a high risk of wound slough if an incision is made near or through contusions, lacerations, or abrasions. For this reason, many believe that the anteromedial surface should rarely, if ever, be used for acute tibial fractures. A safer alternative may be the anterolateral surface, which is covered by the anterior compartment muscles, although a plate applied here interferes with an important route of blood supply to the healing fracture. Thus each injured leg should be evaluated on the basis of its own characteristics and those of the injury. The presence of a posteromedial incision for vascular repair or fasciotomy provides easy access to the medial surface of the tibia, which might also be the best site for a plate if extensive soft tissue wounds mandate from the outset the use of a muscle pedicle flap for medial coverage. In such a situation, there seems to be little merit to detaching any remaining anterior compartment muscles from the bone fragments. An anterolateral incision risks slough of the intervening skin flap if it is combined with one on the posteromedial leg.

The tibia is approached with the patient supine. A thigh tourniquet should be used cautiously because there may be an increased incidence of wound problems. The leg is prepared sterilely and draped free on the standard or radiolucent operating table. Additional padding under the ipsilateral buttock may aid access to the lateral calf.

The same skin incision can be used to access both the anteromedial and anterolateral tibial surfaces. This incision should be made over the muscles of the anterior compartment at least 1 cm lateral to the anterior tibial crest (see Fig. 64.16 ). If there is significant soft tissue contusion, a more lateral incision ensures that bone and hardware will remain covered by soft tissue, even if skin closure is not possible. Similarly, a posteromedial incision can be used to access the tibia's anteromedial surface. The incision is carried down directly through the deep fascia without creating subcutaneous flaps. Preservation of a fasciocutaneous flap composed of skin, subcutaneous tissue, and underlying deep fascia is important because the dermal blood supply depends on vascular connections with the fascia. The resulting anterior flap is elevated from the underlying muscles and reflected only as much as required for exposure. A longer incision is safer than overvigorous retraction. Self-retaining retractors should be used briefly and gently or not at all.

Depending on the surgeon's choice, the tibial shaft is next exposed on either its anterolateral or anteromedial aspect. To preserve blood supply, only minimal soft tissue should be reflected from the other surface. The tibia can be exposed either subperiosteally or extraperiosteally. Fracture healing after plate fixation appears to be equivalent with either exposure.

Minimally Invasive Approaches.

The tibial shaft can be plated using minimally invasive approaches. These approaches minimize soft tissue stripping and preserve blood supply to the fracture site. Either a proximal anterolateral approach or a distal anteromedial approach is typically used. A more detailed description of the minimally invasive technique is available in the sections on proximal and distal tibial shaft fractures.

Reduction Techniques.

Reduction techniques can be either under direct visualization or with the use of fluoroscopic imaging. Direct visualization may be easier but is often traumatic to the soft tissues surrounding the fracture site in the area of already compromised muscle and skin. Minimally invasive, submuscular, extraperiosteal fracture reduction is more technically demanding and may need fluoroscopic imaging and the AO distractor or an external fixator to aid in controlling length, rotation, and alignment ( Fig. 64.17 ). Another indirect reduction technique involves attachment of an appropriately contoured plate to one major fragment, with which it can be manipulated relative to the other, often with the aid of the articulated tension device or a bone spreader and screw.

Fixation Technique.

The most common plate for most diaphyseal tibial fractures is the 4.5-mm compression plate. A tibial plate should be sufficiently long that at least four secure screws attach each end to the proximal and distal fragments. A longer plate with at least three bicortical screws can increase stability. Increasing the span between the most distal and most proximal screw improves stability more than can be obtained by using more screws in a shorter span. One must be cautious about undisplaced comminution. Locking plates are rarely needed for the fixation of tibial shaft fractures. When used, they are typically of the “periarticular” type and in cases where a minimally invasive approach is used. Osteoporotic bone can be an indication for using locking plates. The use of these plates is described in the sections on proximal and distal shaft fractures.

Plate Length and Screw Density.

Bridge plates with angular stable screws should be at least three times longer than the fracture zone. Three cortical screws on either side of the fracture may be sufficient with two screws close to the fracture and one distant to the fracture. Plates with expanded metaphyseal area, and the selection of locking head screws, may be advisable for short periarticular segments and for osteoporosis. Unicortical locking head screws gain less fixation as bicortical screws of the same diameter and should be used sparingly.

External Fixation.

External fixation for closed tibial shaft fracture is done similarly to open fractures and is described later in that section.

Pitfalls and Avoidance of Complications.

Adequate radiographs of the injured limb are needed to ensure that the fracture is suitable for IMN and to identify fracture propagation into the knee or ankle. Occasionally an undisplaced metaphyseal fracture can be fixed with lag screws before IMN. When there is marked comminution of the tibia and fibula, making radiographic interpretation difficult, then measuring the uninjured limb is essential. Measurement via a measuring tape from the apex of the tibial tubercle to the tip of the medial malleolus is a preliminary guide to tibial length and leg length. It may be more accurate than using a radiographic ruler or templates. Radiographic determination of medullary canal diameter can be unreliable and better measured with an IM reamer or a “sound” of known outside diameter.

The surgeon should review and know the technical details of the selected implant system. It is critical to know the available length and diameter of the nails and the locations of locking screw holes and proximal and distal bends. It is also crucial to know the length and width of the available plates. Careful inspection of the patient's uninjured leg is helpful as a guide to correct alignment, particularly rotation (e.g., foot–thigh angle with the knee at 90 degrees and bimalleolar angle). Preoperative images of the AP or lateral uninjured knee and ankle can also be taken without moving the leg and compared with intraoperative images of the injured leg to assess for rotational malreduction of the tibia.

Wounds are usually closed primarily, and suction drains may be used as clinically decided by the surgeon. When performing an open reduction, the fascia should be left open to decrease the risk of compartment syndrome. Should one side of the wound be more tenuous, it may be appropriate to use Algöwer's modified Donnati stitch, passing only through subcuticular tissue on the side at greater risk. After application of a sterile dressing and adequate padding, the foot and ankle are splinted in neutral, and the leg is moderately elevated during the initial postoperative period. Prophylactic antibiotics are generally discontinued within 24 hours after ORIF of a closed fracture.

Postoperative Care and Rehabilitation After Plating.

Patients are much more comfortable in a splint than with the foot and ankle free after fixation of all but the most proximal tibial fractures. Moreover, equinus contracture can be avoided if the ankle is positioned in plantigrade in the splint until swelling has decreased and physical therapy can begin. Early motion, if desired, may begin within a few days. A splint or Velcro boot is helpful between exercise sessions for comfort and to keep the ankle in plantigrade.

Assessment of Healing.

Union of a tibial fracture is assessed using clinical and radiographic parameters. There is progressive bone remodeling with eventual obliteration of the fracture zone over many months after union has been achieved. Conventionally, union is diagnosed when there is no pain or tenderness at the fracture site and at least three cortices are bridged by bone on AP and lateral radiographs. AP and lateral radiographs are standard for monitoring alignment of tibial fractures, but the addition of both 45-degree oblique views aids in the evaluation of healing. Union is also evident when a patient can bear weight on the fractured tibia without pain at the fracture site. CT may be helpful but may not be conclusive relative to well-exposed standard films and may occasionally show false positives (specificity of 62%). If the tibial fracture is not united 6 months after surgical or nonsurgical treatment, radiographs are performed at 1-month intervals to see if there is progression of healing at the fracture site. If there is progressive healing, surgical intervention for a nonunion may be avoided. If there is no progression of healing 9 months after fracture treatment began, a nonunion is diagnosed. Strain gauges attached to external fixator pins can be used in the laboratory to document bending stiffness, the mechanical property assessed manually by the clinician as “fracture site stability.” Using such strain gauges, Richardson and coworkers demonstrated that sagittal plane stiffness of 15 Nm/degree is a threshold that defines tibial fracture union. Overall, it is difficult to assess fracture healing from a single set of radiographs. Hammer and coworkers showed this clearly for tibial fractures. The patient's serial films over 3 months should be reviewed carefully for signs of problems or progression of healing. Problems can be in the form of progressive deformity, hardware failure, lack of maturing callus, and an increasingly evident fracture cleft.

Anatomic reduction and interfragmentary compression are hallmarks of rigid internal fixation. If achieved, the fracture line may not be evident on the initial postfixation radiographs. Fractures thus fixed with absolute stability exhibit minimal external callus formation. In this situation, healing must be diagnosed primarily by the absence of pain and absence of radiographic signs of instability (e.g., external callus, loss of fixation, or bone resorption around implants) as the patient progresses from non–weight-bearing to full weight-bearing activity over an appropriate time period, according to the surgeon's judgment and experience. Because internal fixation does not accelerate union, 3 or more months must typically be allowed before unrestricted activity can be allowed.

Weight Bearing.

IM nails vary significantly with regard to strength and stiffness depending on diameter and cross-sectional design. Tibial anatomy also varies from person to person and from one location to another. These factors, in addition to the wide spectrum of tibial fracture configurations, make it essential to individualize postoperative care for patients with nailed tibial fractures.

When the nail acts primarily as a gliding splint and bone contact allows the tibia to bear compressive loads, full weight bearing can be allowed as soon as the patient can tolerate it. If comminution or poor contact is present, then significant weight bearing must be deferred to prevent failure of fixation. With early and progressive healing, as revealed by periodic radiographs, weight bearing can be increased progressively. At a minimum, knee, ankle, and foot exercises should begin for all patients as soon as possible in the postoperative period to prevent decreased ROM at these joints. The patient should not sit with the leg dependent for the first few weeks. Instead, it should be elevated above the heart when the patient is not walking.

Outpatient Care.

Patients with isolated tibia fractures can be treated as outpatients once pain is managed with oral medications; they are ambulatory; and there is no evidence of compartment syndrome, skin problems, or increasing pain. Instructions are provided for bracing and non–weight-bearing activity as detailed previously. Follow-up visits are needed at regular intervals until the fracture is healed and the limb rehabilitated. Robertson and colleagues found that patient management was not affected by radiographs obtained during the first 10 weeks after IMN. Therefore an initial radiograph is needed postoperatively to assess initial fixation and alignment and then after 6 weeks. Thereafter, radiographs at least every 6 weeks should be monitored for bridging callus, which will determine weight-bearing and physical therapy prescriptions. Oblique views, as well as AP and lateral views, may be valuable to assess fracture healing. When bridging callus is evident and after the fibula has healed, there is usually little reason to be concerned about persistent, slowly healing fracture lines. If a nonunion is diagnosed, it may be wise to change to a larger reamed nail and/or bone graft. The timing of such a rarely needed procedure is adjusted according to the estimated durability of the patient's nail.

Nail Removal.

Removal of locking screws to accelerate healing (so-called dynamization) has not been proven to increase union rates significantly. In spite of intraoperative efforts to prevent it, the tibial fracture site may remain distracted after IM nail fixation. If observed during nailing, this should be remedied by compressive backslapping after distal locking. Rotation must be controlled during this part of the procedure and then checked before locking.

Symptoms at the insertion site are common with or without nail prominence. Some patients may have a resolution of knee pain after the nail removal. Many patients may request nail removal when so informed. Removal of asymptomatic nails may be considered optional. The surgeon must discuss with the patient the possibility of nail incarceration during extraction. Nail designs that make extraction difficult include slotted nails and nails with a distal bend. However, removal at a convenient time after healing can be a reasonable option for symptomatic younger patients and those with prominent hardware, with an acceptably low rate of complications.

Before hardware removal, the surgeon must correctly identify the type of implant and obtain the necessary instruments for nail extraction. The manufacturer's instructions should be reviewed preoperatively because instrumentation might be used differently during removal than during insertion. Different methods have been described for nail removal when the nail extraction instrumentation is unavailable or cannot be used due to a damaged nail. Particular attention must be given to broken or bent nails, broken screws, and older nail designs. Occasionally, IM nail removal may prove so difficult that a longitudinal osteotomy of the entire diaphysis is required to extract the nail without excessive force. The patient must be aware of complications that may occur from the removal of a nail preoperatively. These include retained hardware, continued knee pain, refracture, intraoperative fracture, infection, and failure of the procedure to remove the nail or pain.

Rehabilitation After Plating.

Properly performed plate fixation for tibial fractures should provide sufficient stability for the motion of adjacent joints and myotendinous units. This helps prevent stiffness, particularly if it is combined with the use of resting splints in ankle dorsiflexion. However, it is essential to delay significant weight bearing on the plated tibial fracture until healing is advanced enough to protect the fixation from cyclic loading and resulting failure. Optimally, this means limited weight bearing on crutches, using only an elastic stocking as needed to control edema. However, when patient cooperation is questionable or fixation is tenuous, additional external support is advised. In the most unreliable patient, this might be a long leg cast with the knee flexed and the dorsum of the foot portion removed to permit ankle dorsiflexion above neutral. A functional cast or fracture brace could be employed, but these may not provide enough protection for the bone–plate construct and are perhaps too easily discarded by the patient.

Periodic outpatient follow-up is required until the fracture is healed and the patient rehabilitated. The patient is instructed to report promptly any increase in pain or wound problems. Unless problems are noted, radiographs are needed only every 4 to 6 weeks until union is achieved. No weight bearing is allowed during the first 6 weeks. Weight bearing can be gradually increased during the second 6 weeks after fracture if radiographs demonstrate maintenance of fixation and progressive obliteration of any fracture lines. Weight bearing should increase slowly after more severe injuries with increased fracture comminution and/or soft tissue compromise.

External callus is rarely seen with rigid internal fixation in short oblique, spiral, or transverse fractures treated with lag screw technique or compression plating (absolute stability). However, callus formation can be expected with bridge plating in fractures with comminution (relative stability). If healing of a plated tibial fracture does not progress over 3 to 6 months, serious consideration should be given to early revision of fixation, rather than delaying necessary surgery while the tibia becomes more osteoporotic. Ankle and subtalar ROM exercises should begin early after plating of a tibial fracture to minimize late disability resulting from contractures of the ankle joints. Low-resistance strength and endurance exercises are progressively increased as the fracture heals, and functional rehabilitation is completed once bone healing and soft tissues permit. By 4 or 5 months, most plated tibial fractures are healed enough for unsupported weight bearing. Rarely is it wise for the patient to return to contact sports and risky activities in less than 6 to 9 months. Time estimates for tibial fracture healing increase with more severe injuries. Clinical and radiographic progress of healing is continually critically reassessed to ensure that union is complete before excessive loading is begun. Local pain, warmth, swelling, and tenderness may indicate mechanical instability or occult infection. Adequate radiographs, wound aspiration, sedimentation rate, C-reactive protein, and perhaps indium-labeled leukocyte scans may be helpful for distinguishing infection.

Plate Removal.

Hardware removal should be delayed at least 18 months or more for severe injuries. Dual-energy x-ray absorptiometry (DXA) studies have shown that there is no progressive decrease in bone density under tibial plates in current use, as can occur in stress-protected proximal femurs with some total joint implants. Incomplete healing of severe fractures, continued remodeling of necrotic bone, and the temporary stress-riser effect of recently removed screws all predispose to refracture after hardware removal. Delay until completion of both bone union and remodeling, with protection from undue stress for 6 to 12 weeks after plate and screw removal, is important to minimize the risk of refracture.

Nailing Proximal Tibial Fractures in a Semi-Extended Position.

Semi-extended tibial nailing was initially developed for greater ease of reduction and imaging, mitigating many of the challenges associated with flexed-knee IMN. Various incisions for semi-extended tibial nailing have been described, including lateral and medial knee arthrotomies, suprapatellar IM nail insertion, and extraarticular parapatellar approaches.

External Fixation Assisted Nailing.

Buehler and colleagues suggested the use of a universal distractor during nailing in flexion. They used an AO distractor medially, correcting any posterior displacement of the diaphyseal fragment with traction and a manipulating Schantz screw or clamp. They proposed creating the entry site with the knee in hyperflexion ( Fig. 64.18 ). The entry portal in the proximal segment is anterior to the lateral eminence on the AP view and is confirmed radiographically on the lateral view to start at the anterior edge of the articular surface and to progress parallel to the anterior cortex of the proximal fragment. This helps avoid posterior displacement of the distal piece caused by impingement of the nail's proximal bend on the posterior cortex of the distal segment. The distal and posterior displacements can be avoided by selection of a proper entry path. The recommendations for entry and reduction included the following:

• 1.

  AO femoral distractor placed on medial tibia

• 2.

  Correct overlapping posterior walls, with distraction and Schantz screw if needed

• 3.

  Proximal and lateral starting point in line with the lateral intercondylar eminence

• 4.

  Hyperflexion of the knee for nail insertion

• 5.

  Sagittal plane entry point parallel to the anterior cortex of the proximal fragment under radiographic control

• 6.

  Proximal interlocking with knee in full extension

Alternately, an external fixator can be used to achieve and maintain length, rotation, and coronal alignment. This technique uses a centrally threaded 6-mm-diameter external fixation pin placed from lateral to medial in the proximal fragment and parallel to the tibial plateau ( Fig. 64.19 ). Another centrally threaded 6-mm-diameter external fixation pin can be placed in the calcaneus or distal tibia from medial to lateral parallel to the tibial plafond. Two bars are then connected to the pins, and length, rotation, and alignment in the coronal plane are achieved. A pin can be placed into the anterior aspect of the proximal fragment, making sure not to interfere with the future nail path. This pin can then be attached to the external fixator to counteract procurvatum of the proximal fragment. The knee can then be hyperflexed to achieve entry into the tibia anterior to the lateral intercondylar eminence and in the anterior third and parallel to the proximal tibia. With more contemporary short tibial targeting jigs, the knee can be extended after nail insertion and the proximal fragment locked in that position with two or more nonparallel screws.