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Biomechanical Evaluation of Fixation of Intra-Articular Fractures of the Distal Part of the Radius in Cadavera: Kirschner Wires Compared with Calcium-Phosphate Bone Cement*

DURAN N. YETKINLER, M.D., PH.D., AMY L. LADD, M.D., ROBERT D. POSER, D.V.M., BRENT R. CONSTANTZ, PH.D.§ and DENNIS CARTER, PH.D.§, CUPERTINO, CALIFORNIA

Investigation performed at the Biomechanics Laboratory, Norian Corporation, Cupertino

	Abstract

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Background: The purpose of this study was to compare the biomechanical efficacy of an injectable calcium-phosphate bone cement (Skeletal Repair System [SRS]) with that of Kirschner wires for the fixation of intra-articular fractures of the distal part of the radius. Methods: Colles fractures (AO pattern, C2.1) were produced in ten pairs of fresh-frozen human cadaveric radii. One radius from each pair was randomly chosen for stabilization with SRS bone cement. These ten radii were treated with open incision, impaction of loose cancellous bone with use of a Freer elevator, and placement of the SRS bone cement by injection. In the ten control specimens, the fracture was stabilized with use of two horizontal and two oblique Kirschner wires. The specimens were cyclically loaded to a peak load of 200 newtons for 2000 cycles to evaluate the amount of settling, or radial shortening, under conditions simulating postoperative loading with the limb in a cast. Each specimen then was loaded to failure to determine its ultimate strength. Results: The amount of radial shortening was highly variable among the specimens, but it was consistently higher in the Kirschner-wire constructs than in the bone fixed with SRS bone cement within each pair of radii. The range of shortening for all twenty specimens was 0.18 to 4.51 millimeters. The average amount of shortening in the SRS constructs was 50 percent of that in the Kirschner-wire constructs (0.51 ± 0.34 compared with 1.01 ± 1.23 millimeters; p = 0.015). With the numbers available, no significant difference in ultimate strength was detected between the two fixation groups. Conclusions: This study showed that fixation of an intra-articular fracture of the distal part of a cadaveric radius with biocompatible calcium-phosphate bone cement produced results that were biomechanically comparable with those produced by fixation with Kirschner wires. However, the constructs that were fixed with calcium-phosphate bone cement demonstrated less shortening under simulated cyclic load-bearing. Clinical Relevance: A calcium-phosphate bone cement with high compressive strength may provide adequate stability of the fracture and therefore serve as an alternative to Kirschner wires with their associated complications.

	Introduction

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Distal radial fractures, often referred to as Colles fractures, frequently occur in women who are more than forty-five years old and who have fallen on an outstretched hand. The fall creates a compressive load that fractures the dorsal cortex, typically with comminution. The fracture may also include a tensile failure of the volar cortex⁵. Even though most Colles fractures are considered to be low-energy extra-articular injuries that occur in osteopenic bone, intra-articular fractures often are also classified as Colles fractures. The radiographic findings include dorsal angulation and displacement, radial shortening, impaction, and comminution; there also may be a fracture of the ulnar styloid process, carpal instability, and soft-tissue injury²².

The objectives of treatment of a Colles fracture are to restore and maintain the anatomy of the wrist in order to obtain early, painless function²⁸. The current methods of treatment often do not fulfill these goals. The traditional method of closed reduction and use of a cast is indicated for fractures that have little or no displacement or comminution^4,5,8,18. If a cast alone is used to treat an unstable distal radial fracture characterized by comminution, marked displacement of the fragments, and interposition of soft tissue, the fracture has a tendency to redisplace within about two weeks^8,18,29. Percutaneous pins, external fixation, and operative reduction and internal fixation therefore are often used to stabilize an unstable fracture¹. However, these treatment methods have their own inherent problems.

Rayhack, in a study of displaced distal radial fractures that had been treated with use of percutaneous pins, reported complications that included loss of reduction, pin-track infection, broken pins, migration of pins, tendon irritation and irritation of the radial sensory nerve, rupture of the extensor tendon, and Sudeck atrophy²³. Although external fixation may provide more predictable restoration of radial length, the rate of complications has been as high as 70 percent (thirty-one of forty-four patients in one series¹⁰), mainly because of the extended period of immobilization. These complications have included pin-track infection; fracture through pin sites; radial sensory neuritis; reflex sympathetic dystrophy; and, most importantly, disuse atrophy and stiffness of the joint^5,10,11,25. Sommerkamp et al. attempted to decrease morbidity related to immobilization by using dynamic external fixators, but they encountered insufficient stability at the fracture site, with more settling and other complications²⁷. Despite the increasing popularity of more invasive techniques (open reduction and internal fixation) for the treatment of distal radial fractures, serious complications can occur; these include loss of fixation, neuritis of the median nerve, reflex sympathetic dystrophy, wound infection, and late posttraumatic arthritis¹¹.

Intra-articular fractures in particular present several problems. Incomplete reduction usually results in a poor outcome¹⁵. Joint stiffness, articular incongruity, and posttraumatic arthritis also can occur⁵. Invasive treatment such as bone-grafting and internal fixation may often be needed because of the complex nature of these fractures.

Fernandez and Jupiter suggested the use of Kirschner wires as an effective method for fixation of simple intra-articular compression-type fractures of the distal part of the radius, which usually do not need bone-grafting⁵. An alternative method of fixation of these fractures was biomechanically evaluated in the current in vitro study. We compared the use of SRS (Skeletal Repair System) injectable calcium-phosphate bone cement (Norian, Cupertino, California) with that of Kirschner wires.

	Materials and Methods

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Ten pairs of radii from human cadavera were cleaned of soft tissue. A fracture then was created in each radius with use of a servohydraulic materials testing machine (MTS, Minneapolis, Minnesota). One radius, randomly chosen from each pair, was stabilized with SRS bone cement, and the contralateral radius was stabilized with Kirschner wires. Settling of the scaphoid and lunate fossae and of the entire articular surface was recorded while the fracture constructs were cyclically loaded under conditions simulating intermittent postoperative loading that would occur in a patient. The specimens then were loaded to failure to determine the ultimate strength of the constructs.

Material
SRS bone cement is percutaneously injectable and fast-setting; it cures in vivo to form a carbonated apatite with a low crystalline order and a small grain size similar to the mineral phase of bone³. This cement has been reported to be replaced by host bone through an osteoclast-mediated process similar to normal bone-remodeling^3,6. The cementitious paste was formed by mixing calcium source powder consisting of calcium carbonate (CaCO₃) and -tricalcium phosphate (Ca₃[PO4]₂) and phosphate source powder containing monocalcium phosphate monohydrate (Ca[H₂PO₄]₂·H₂O) with phosphate-buffered solution. After the material has been implanted, it equilibrates to body temperature, accelerating the formation of carbonated apatite. It hardens ten minutes after implantation and achieves 50 percent of its ultimate compressive strength by one hour. Full compressive strength of fifty-five megapascals is attained by approximately twelve hours after implantation³.

Selection and Preparation of the Specimens
Ten pairs of fresh-frozen forearms from human adult cadavera were prescreened with use of plain posteroanterior radiographs to detect gross anatomical abnormalities. Bone-mineral-density measurements of the ultradistal, mid-distal, and one-third distal regions were obtained with use of dual-energy x-ray absorptiometry (Hologic QDR-4500A; Hologic, Waltham, Massachusetts). The average difference between the bone-mineral-density values of the SRS constructs (0.639 ± 0.183 gram per square centimeter) and the Kirschner-wire constructs (0.648 ± 0.199 gram per square centimeter) was 0.009 gram per square centimeter; with the numbers available, this difference was not found to be significant (p = 0.717).

The radii were removed from the forearms by careful dissection of the soft tissue around the bone. All radii were wrapped in towels that had been soaked in saline solution and were stored in tightly sealed plastic bags at -20 degrees Celsius or less. All specimens were thawed at room temperature for at least seven hours before the fractures were created.

Each radius was cleaned of all soft tissue and cut to a standard length of fifteen centimeters from the distal end. The shaft (diaphyseal) end was potted in an aluminum tube with use of dental acrylic polymer (PERM Reline and Repair Resin; Hygenic, Akron, Ohio). In addition, an acrylic mold was made of each articular surface of each radius. Biplanar contact radiographs of the radius and acrylic imprints of the proximal region of the radius were made to provide a template to ensure accurate reduction during fixation of the fracture.

Creation of the Fractures
The specimens were placed vertically with 75 degrees of dorsiflexion and 10 degrees of ulnar deviation on an MTS table to simulate the position of the radius during a fall^7,20. Stress-risers were created with a combination of drilling (1.6-millimeter-diameter drill-holes spaced two millimeters apart) and scoring of the cortical bone around the desired three-part intra-articular fracture line¹⁹. The fractures were created by impaction of the specimens, in the same orientation as just described, against the load-cell in an MTS minibionix servohydraulic materials testing machine at twenty-five millimeters per second, and were compressed until a fifteen-millimeter displacement of the actuator was achieved²⁰. If the desired intra-articular fracture line (Fig. 1) was not created, then an osteotome was used to complete the fracture. The reproducible three-part intra-articular fractures that were made with this method were consistent with the fracture types treated with Kirschner wires as described by Fernandez and Jupiter⁵.

View larger version (14K): [in this window] [in a new window]   FIG1: Fig. 1 Drawing showing the articular surface (A) and an anteroposterior view (B) of the desired Colles fracture (AO pattern, C2.1).

Fixation of the Fractures
One radius from each pair was randomly chosen for fixation with 1.6-millimeter Kirschner wires (Figs. 2 and 3-A)⁵. The contralateral radius was stabilized with SRS bone cement (Fig. 3-B).

View larger version (22K): [in this window] [in a new window]   FIG2: Fig. 2 Drawing showing Kirschner-wire fixation of a three-part intra-articular distal radial fracture. Two Kirschner wires were placed horizontally across the sagittal fracture line, and an additional two wires were placed in an oblique pattern across the horizontal fracture line.

View larger version (105K): [in this window] [in a new window]   FIG3-A: Fig. 3-A: Radiograph showing fixation of a fracture with Kirschner wires.

View larger version (112K): [in this window] [in a new window]   FIG3-B: Fig. 3-B: Radiograph showing fixation of a fracture with SRS bone cement.

The operative technique for the control specimens, after the fractures had been appropriately reduced, involved insertion of two horizontal and two oblique Kirschner wires.

An orthopaedic surgeon specializing in hand surgery reduced and fixed all of the specimens. Both specimens of each pair were wrapped in a plastic bag and were incubated in 100 percent humidity at 37 degrees Celsius in order to simulate physiological body conditions and to allow curing of the SRS bone cement. The specimens were incubated for twelve to twenty-four hours before testing. No specimens were refrozen after fixation and before testing.

Calculations of Force on the Distal Part of the Radius
The current study involved simulation of immediate postoperative weight-bearing on the distal part of the radius. When a patient's arm is in a cast, compressive forces may occur on the wrist joint and at the fracture site because of flexion of the digits. Two major muscle-tendon units cross over the wrist joint in order to flex the digits; these are the flexor digitorum profundus and the flexor digitorum superficialis². In vivo measurements of the tendon forces on these muscles have been reported while the digits were in flexion². These forces ranged from thirty-nine to 196 newtons and from twelve to 147 newtons for the flexor digitorum profundus and the flexor digitorum superficialis, respectively². (The force values were converted from the original mass equivalent.) If the minimum tendon forces are thirty-nine and twelve newtons, then the total force is fifty-one newtons. It has been demonstrated that only 80 percent of the load is transferred by the distal part of the radius at the wrist joint³⁰; thus, 80 percent of fifty-one newtons (40.8 newtons) is the force that will be applied to the distal part of the radius by flexion of each digit. In the current study, a zero to 200-newton cyclic load (the approximate load due to flexion of five digits) was used to simulate the immediate postoperative load borne by the distal part of the radius.

Biomechanical Testing of the Fracture Constructs
After the SRS bone cement had cured, the specimens were placed vertically on the MTS minibionix servohydraulic materials testing machine (Fig. 4). The molded acrylic template that was formed from the individual articular surface of each radius was used to maximize the load-bearing contact area across the radiocarpal joint after fixation. Six linear variable differential transducers were placed around the potting tube and were used to measure the axial displacement of the two distal fracture fragments at six different anatomical sites (Fig. 4). Data with regard to time, displacement (of the linear variable differential transducers and the MTS crosshead), and load were collected with Teststar (Minneapolis, Minnesota) on an Excel-5.0 spreadsheet (Microsoft, Redmond, Washington) with use of an HP Vectra N2 4/33si computer (Hewlett-Packard, Palo Alto, California).

View larger version (21K): [in this window] [in a new window]   FIG4: Fig. 4 Drawing showing top and side views of the placement of the linear variable differential transducers (LVDT) around the distal fragments of the distal radial fracture for measurement of movement of the fragments in the axial direction. The data that were obtained were used to calculate settling of the lunate and scaphoid fossae as well as dorsal and volar step-off. (Only linear variable differential transducer 5 is shown in the side view for the purpose of simplification.)

Posteroanterior and lateral radiographs were made after cycling. The linear variable differential transducers then were removed, and the specimen was loaded to failure at twenty-five millimeters per second with a maximum displacement of fifteen millimeters. The values for force and crosshead displacement were sampled and recorded at 100 hertz during the load-to-failure part of the experiment. Final posteroanterior and lateral radiographs were made.

Analysis of the Data

Outcome Parameters
Settling due to the simulated immediate postoperative load-bearing of the distal part of the radius was measured by displacement of the MTS crosshead. Settling of the lunate and scaphoid fossae was calculated by averaging the measurements of the displacement of the three linear variable differential transducers around each anatomical fossa (Fig. 4). Linear variable differential transducers 1, 2, and 3 were used for calculations for the scaphoid fossa, and linear variable differential transducers 4, 5, and 6 were used for calculations for the lunate fossa. The step-off at the volar and dorsal sides of the distal part of the radius was calculated according to the absolute value of the difference between the displacement measurements from two adjacent linear variable differential transducers across the intra-articular fracture line (Fig. 4). Linear variable differential transducers 1 and 6 determined the volar step-off, and linear variable differential transducers 3 and 4 determined the dorsal step-off. Finally, after cyclic loading, the ultimate load to failure was determined according to the applied peak force during static loading.

Statistical Analysis
A nonparametric analysis, the Wilcoxon signed-rank test, was used to determine differences between the two types of fixation. Our null hypothesis was that there was no significant difference (p > 0.05) between the outcome parameters measured in the specimens that had been stabilized with Kirschner wires and those measured in the specimens that had been stabilized with calcium-phosphate bone cement (SRS).

	Results

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Overall, there was significantly more displacement (settling) in the Kirschner-wire constructs than in the SRS constructs (range, 0.18 to 4.51 millimeters compared with 0.19 to 1.29 millimeters; p = 0.015) (Table I and Fig. 5). With the numbers available, no significant difference in ultimate strength was detected between the SRS constructs and the Kirschner-wire constructs (average [and standard deviation], 1996 ± 1413 newtons compared with 1842 ± 796 newtons; p = 0.721) (Table I).

View larger version (15K): [in this window] [in a new window]   FIG5: Fig. 5 Graph showing settling of the entire articular surface of the Kirschner-wire (K-wire) constructs compared with that of the SRS constructs. Each data point represents one pair of specimens.

View larger version (19K): [in this window] [in a new window]   FIG6: Fig. 6 Graph showing settling of the scaphoid and lunate fossae in the Kirschner-wire (K-wire) constructs compared with that in the SRS constructs. Each data point represents one pair of specimens.

View larger version (18K): [in this window] [in a new window]   FIG7: Fig. 7 Graph showing volar and dorsal step-off in the Kirschner-wire (K-wire) constructs compared with that in the SRS constructs. Each data point represents one pair of specimens.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

 
The findings in this study demonstrated that the fracture fragments of the SRS constructs settled significantly less than did those of the Kirschner-wire constructs. From a practical point of view, these data indicate that SRS bone cement can provide initial stability that is comparable with or better than that achieved with use of Kirschner-wire fixation.

Clinically, when the radius settles, the ulna carries more load, thereby altering the normal biomechanics of the wrist. This phenomenon is known as ulnar impaction syndrome and is diagnosed on the basis of radiographic changes, associated pain, decreased grip strength, and limited rotation of the forearm^26,31. In a clinical study of distal radial fractures, Hutchinson et al. found that treatment with pins and plaster caused an average of 2.5 millimeters of shortening of the radius at four months¹⁰. In the current study of cadavera, the amount of settling in the Kirschner-wire constructs ranged from 0.18 to 4.51 millimeters. In both study groups, the scaphoid fossa settled slightly more than did the lunate fossa, suggesting that the scaphoid fossa may be more important in terms of load transfer under the loading conditions that were imposed. This finding is supported by those of previous reports indicating that most of the force (50 percent more than that in the lunate fossa) is transmitted through the scaphoid fossa³⁰.

There was more volar articular incongruity in the Kirschner-wire constructs than in the SRS constructs. The volar cortex was more prone to have articular step-off than was the dorsal cortex in both test groups. This finding confirms that a major portion of the load is transferred by the volar cortex³⁰. Failure to achieve an anatomical reduction (an articular step-off of less than one to two millimeters) of intra-articular fragments has been associated with radiographic evidence of arthritis in most if not all patients¹⁵. In a study of young adults, twenty-two (92 percent) of twenty-four patients who had articular step-off were symptomatic¹⁵. With an adequate and properly maintained reduction, the rate of radiocarpal arthritis may be reduced to 5 to 10 percent (one of thirteen patients in one study¹² and three [10 percent] of thirty-one in another study⁹), even in patients who have a severely comminuted fracture.

Unstable distal radial fractures involving osteopenic bone may not be amenable to open treatment with metal fixation devices because of the low bone strength. However, the problem of attaining stability without an extended period of immobilization remains. Insertion of a structural material that can transfer load without causing a loss of stability at the fracture site is an attractive alternative for the treatment of these comminuted fractures. An intramedullary core of acrylic bone cement has been used in this manner for primary fixation of distal radial fractures involving osteopenic bone^14,21,24. The patients have been able to use the hand immediately postoperatively without the need for additional fixation. Periosteal bone formation has occurred and osseous union has been established within six to seven weeks after this procedure¹⁶. The incompatible nature of acrylic bone cements as well as late loosening as a result of the progression of osteoporosis make the use of polymeric materials unattractive for the treatment of distal radial fractures. The same immediate postoperative stability may be achieved with SRS bone cement without compromising fracture-healing or long-term structural integrity.

Jupiter et al. reported that SRS bone cement can be administered percutaneously and can support the reduction of the fracture by countering compressive forces that occur in the comminuted metaphyseal region of the fractured distal part of the radius¹³. Those authors concluded that the material is biocompatible and that it did not cause any serious complications. Kopylov et al., in another clinical study, found that distal radial fractures that were treated with SRS bone cement needed a shorter period of immobilization because of the stability that was attained by the filling of the metaphyseal bone defects¹⁷.

A related issue that was not addressed in the current study is the substantial effect that even short-term exposure to the aqueous biological milieu has on the degradation of the bone cement, resulting in the immediate loss of stabilization within the bone. The effectiveness with which the cement can be implanted in the laboratory setting is not likely to be duplicated in a clinical situation. There is a question as to whether the experimental methodology that we used to determine settling had the necessary precision to reveal small differences in the amounts of settling between the two treatment groups.

Operative treatment with use of SRS bone cement necessitates an open incision and impaction of loose cancellous-bone fragments, and this might increase the operative time and the rate of complications compared with those associated with Kirschner-wire fixation. In addition, the specimens in the current study required twelve to twenty-four hours of incubation in 100 percent humidity at 37 degrees Celsius, and this might have had a negative impact on both treatment groups, especially the Kirschner-wire specimens.

In conclusion, the findings in the current study suggest that use of a minimum operative exposure to prepare the fracture void properly as well as filling of regions of cancellous-bone voids with a biocompatible calcium-phosphate (SRS) bone cement provides adequate fixation to maintain reduction of intra-articular distal radial fractures. Patients may start to use the affected limb soon after the operation in order to restore the function of the hand to the prefracture level.

	Footnotes

 
*One or more of the authors has received or will receive benefits for personal or professional use from a commercial party related directly or indirectly to the subject of this article. Funds were received in total or partial support of the research or clinical study presented in this article. The funding source was the Norian Corporation, Cupertino, California.

Norian Corporation, 10260 Bubb Road, Cupertino, California 95014-4166. E-mail address: duran_yetkinler@norian.com.

900 Welch Road, Suite 15, Palo Alto, California 94304.

§Division of Biomechanical Engineering, Terman Building, Rooms 550 (B. R. C.) and 561 (D. C.), Stanford University, Stanford, California 94305.

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