There are no recent studies comparing cable with wire for the fixation of osteotomies or fractures in total hip replacement (THR). Our objective was to evaluate the five-year clinical and radiological outcomes and complication rates of the two techniques. We undertook a review including all primary and revision THRs performed in one hospital between 1996 and 2005 using cable or wire fixation. Clinical and radiological evaluation was performed five years post-operatively. Cables were used in 51 THRs and wires in 126, and of these, 36 THRs with cable (71%) and 101 with wire (80%) were evaluated at follow-up. The five-year radiographs available for 33 cable and 91 wire THRs revealed rates of breakage of fixation of 12 of 33 (36%) and 42 of 91 (46%), respectively. With cable there was a significantly higher risk of metal debris (68% vs 9%; adjusted relative risk (RR) 6.6; 95% confidence interval (CI) 3.0 to 14.1), nonunion (36% vs 21%; adjusted RR 2.0; 95% CI 1.0 to 3.9) and osteolysis around the material, acetabulum or femur (61% vs 19%; adjusted RR 3.9; 95% CI 2.3 to 6.5). Cable breakage increased the risk of osteolysis to 83%. There was a trend towards foreign-body reaction and increased infection with cables. Clinical results did not differ between the groups. In conclusion, we found a higher incidence of complications and a trend towards increased infection and foreign-body reaction with the use of cables

Aims. When performing revision total hip arthroplasty using diaphyseal-engaging titanium tapered stems (TTS), the recommended 3 to 4 cm of stem-cortical diaphyseal contact may not be available. In challenging cases such as these with only 2 cm of contact, can sufficient axial stability be achieved and what is the benefit of a prophylactic cable? This study sought to determine, first, whether a prophylactic cable allows for sufficient axial stability when the contact length is 2 cm, and second, if differing TTS taper angles (2° vs 3.5°) impact these results. Methods. A biomechanical matched-pair cadaveric study was designed using six matched pairs of human fresh cadaveric femora prepared so that 2 cm of diaphyseal bone engaged with 2° (right femora) or 3.5° (left femora) TTS. Before impaction, three matched pairs received a single 100 lb-tensioned prophylactic beaded cable; the remaining three matched pairs received no cable adjuncts. Specimens underwent stepwise axial loading to 2600 N or until failure, defined as stem subsidence > 5 mm. Results. All specimens without cable adjuncts (6/6 femora) failed during axial testing, while all specimens with a prophylactic cable (6/6) successfully resisted axial load, regardless of taper angle. In total, four of the failed specimens experienced proximal longitudinal fractures, three of which occurred with the higher 3.5° TTS. One fracture occurred in a 3.5° TTS with a prophylactic cable yet passed axial testing, subsiding < 5 mm. Among specimens with a prophylactic cable, the 3.5° TTS resulted in lower mean subsidence (0.5 mm (SD 0.8)) compared with the 2° TTS (2.4 mm (SD 1.8)). Conclusion. A single prophylactic beaded cable dramatically improved initial axial stability when stem-cortex contact length was 2 cm. All implants failed secondary to fracture or subsidence > 5 mm when a prophylactic cable was not used. A higher taper angle appears to decrease the magnitude of subsidence but increased the fracture risk. The fracture risk was mitigated by the use of a prophylactic cable. Cite this article: Bone Jt Open 2023;4(7):472–477

Introduction. Bone transport and distraction osteogenesis have been shown to be an effective treatment for significant bone loss in the tibia. However, traditional methods of transport are often associated with high patient morbidity due to the pain and scarring caused by the external frame components transporting the bone segment. Prolonged time in frame is also common as large sections of regenerate need significant time to consolidate before the external fixator can be removed. Cable transport has had a resurgence with the description of the balanced cable transport system. However, this introduced increasingly complex surgery along with the risk of cable weave fracture. This method also requires frame removal and intramedullary nailing, with a modified nail, to be performed in a single sitting, which raised concern regarding potential deep infection. An alternative to this method is our modified cable transport system with early intramedullary nail fixation. Internal cables reduce pain and scarring of the skin during transport and allow for well controlled transport segment alignment. The cable system is facilitated through an endosteal plate that reduces complications and removes the need for a single-stage frame removal and nailing procedure. Instead, the patients can undergo a pin-site holiday before nailing is performed using a standard tibial nail. Early intramedullary nailing once transport is complete reduces overall time in frame and allows full weight bearing as the regenerate consolidates. We present our case series of patients treated with this modified cable transport technique. Methodolgy. Patients were identified through our limb reconstruction database and clinic notes, operative records and radiographs were reviewed. Since 2019, 8 patients (5 male : 3 female) have undergone bone transport via our modified balanced cable transport technique. Average age at time of transport was 39.6 years (range 21–58 years) with all surgeries performed by the senior author. Patients were followed up until radiological union. We recorded the length of bone transport achieved as well as any problems, obstacles or complications encountered during treatment. We evaluated outcomes of full weight bearing and return to function as well as radiological union. Results. 4/8 bone defects were due to severely comminuted open fractures requiring extensive debridement. All other cases had previously undergone fixation of tibial fractures which had failed due to infection, soft tissue defects or mal-reduction. The mean tibial defect treated with bone transport was 41mm (range 37–78mm). From the start of cable transport to removal of external fixator our patients spent an average of 201 days in frame. 7/8 patients underwent a 2-week pin-site holiday and subsequent insertion of intramedullary nail 2 weeks later. One patient had sufficient bony union to not require further internal fixation after frame removal. 10 problems were identified during treatment. These included 4 superficial infections treated with antibiotics alone and 5 issues with hardware, which could be resolved in the outpatient clinic. 1 patient had their rate of transport slowed due to poor skin quality over the site of the regenerate. 4 obstacles resulted in a return to theatre for additional procedures. 1 patient had a re-do corticotomy and 3 had revision of their internal cable transport constructs due to decoupling or screw pull out. 1 patient had residual ankle joint equinus following treatment which required an Achilles tendon lengthening procedure. Another patient underwent treatment for DVT. There were no deep infections identified and no significant limb length discrepancies or deformities. Conclusions. Overall, we have found that our modified balanced cable transport technique has allowed for successful bone transport for significant defects of the tibia. We have learned from the obstacles encountered during this case series to avoid unnecessary return trips to theatre for our future transport patients. The internal cable system allowed all patients to complete their planned transport without excessive pin tract scarring or pain. Early conversion to intramedullary nail allowed for a shorter time in frame with continued full weight bearing as the regenerate consolidated. No metalwork failure or deformity has occurred in relation to docking site union. All patients have made a good return to pre-operative function during their follow-up period with no evidence of late complications such as deep infection

Aims. The present study aimed to investigate the long-term functional results of scapulothoracic fusion using multifilament cables in patients with facioscapulohumeral dystrophy (FSHD) to identify if the early improvement from this intervention is maintained. Patients and Methods. We retrospectively investigated the long-term outcomes of 13 patients with FSHD (18 shoulders) in whom scapulothoracic fusion using multifilament cables was performed between 2004 and 2007. These patients have previously been reported at a mean of 35.5 months (24 to 87). There were eight men and five women with a mean age of 26 years. Their mean length of follow-up of our current study was 128 months (94 to 185). To evaluate long-term functional results, the range of shoulder flexion and abduction, Quick Disabilities of the Arm, Shoulder and Hand (QuickDASH) scores were analyzed with a comparison of preoperatively, interim and at the final outcomes. The fusion was examined radiographically in all. Results. The complication rate was 33% (six of 18 scapulothoracic fusions) in 13 patients, which comprised failure of fusion in four shoulders (four patients) all occurring within the first year postoperatively. In two shoulders (one patient) wound problems arose due to attribution from the cables which required shortening but the fusion developed satisfactorily. At the final examination, the mean QuickDASH score and range of movement significantly improved in all but one patient (p < 0.001, p < 0.001 and p < 0.001). In the comparison of 13 patients’ mid- and long-term results, the mean QuickDASH score decreased from 9.8 (. sd. 6.7; 3 to 26) in the third year to 9.1 (. sd. 5.6; 3 to 22) in the tenth year (p = 0.7); the mean range of shoulder flexion and abduction decreased from 129° (. sd. 22°; 90° to 160°) and 124° (. sd. 12; 100° to 150°) at the mid-term to 103° (. sd. 12°; 80° to 120°) and 101° (. sd. 8°; 80° to 120°) at the long-term, respectively (p = 0.78 and p = 0.65). Conclusion. Scapulothoracic fusion using a multiple cabling method can confer a considerable improvement in clinical and functional outcomes for most patients with FSHD after a long follow-up period. The technique requires careful execution to avoid complications. Cite this article: Bone Joint J 2018;100-B:953–6

Introduction. Aneurysmal bone cysts commonly found in lower limbs are locally aggressive masses that can lead to bony erosion, instability and fractures. This has major implications in the lower limbs especially in paediatric patients, with potential growth disturbance and deformity. In this case series we describe radical aneurysmal bone cyst resection and lower limb reconstruction using cable transport and syndesmosis preservation. Materials & Methods. Case 1 - A 12-year-old boy presented with a two-week history of atraumatic right ankle pain. An X-ray demonstrated a distal tibia metaphyseal cyst confirmed on biopsy as an aneurysmal bone cyst. The cyst expanded on interval X-rays from 5.5cm to 8.5cm in 9 weeks. A wide-margin en-bloc resection was performed leaving a 13.8cm tibial defect. A cable transport hexapod frame and a proximal tibial osteotomy was performed, with syndesmosis screw fixation. The transport phase lasted 11 months. While in frame, the boy sustained a distal femur fracture from a fall. The femur and the docking site were plated at the same sitting and frame removed. At one-year post-frame removal he is pain-free, with full ankle dorsiflexion but plantarflexion limited to 25 degrees. He has begun graduated return to sport. Results. Case 2 - A 12-year-old girl was referred with a three-month history of lateral left ankle swelling. X-ray demonstrated an aneurysmal bone cyst in the distal fibula metaphysis. The cyst grew from 4.2 × 2.3cm to 5.2 × 3.32cm in 2 months. A distal fibula resection (6.2cm) with syndesmosis fixation and hexapod cable transport frame were undertaken. The frame was in situ for 13 weeks and during this time she required an additional osteotomy for premature consolidation and had one pin site infection. After 13 weeks a second syndesmosis screw was placed, frame removed, and a cast applied. 3 months later she had fibular plating, BMAC and autologous iliac crest bone graft for slow union. At 3 years post-operative she has no evidence of recurrence, is pain-free and has no functional limitation. Conclusions. We describe two cases of ankle syndesmosis preservation using cable transport for juxta-articular aneurysmal bone cysts. This allows wide resection to prevent recurrence while also preserving primary ankle stability and leg length in children. Both children had a minor complication, but both had an excellent final outcome. Cable bone transport and prophylactic syndesmosis stabilization allows treatment of challenging juxta-articular aneurysmal bone cysts about the ankle. These techniques are especially useful in large bone defects

The goal of this study was to determine which of two techniques for the treatment of peri-prosthetic femoral shaft fractures has the greatest torsional integrity. The study designed was a laboratory study, using 13 matched pairs of embalmed femurs. The femurs were implanted with a cemented total hip prosthesis, with a transverse osteotomy distal to the stem. These fractures were fixed either with a metal plate with three proximal unicortical screws and three distal bicortical screws or with three proximal cables and three distal bicortical screws. The fracture fixation was tested to failure in torsion. The pattern of failure and torsional limits were recorded. There was no significant difference to failure level between the two constructs. Failure with the proximal unicortical screws was usually catastrophic versus non-catastrophic with proximal cables. The femurs were significantly more likely to fracture in internal rotation. Treatment with proximal cables has the same load to failure in torsion but significantly less complications than with unicortical screws, in agreement with the literature. The findings of the construct being weaker in internal rotation, appears to be a new finding and an area of possible new research

Introduction: The amount of tension which surgeons apply to a two-side Dall-Miles cable during the fixation of periprosthetic fracture has not been reported. Current study is the first report that reveals the real cable tension data which was intraoperatively measured. Methods: In vivo data of tightening torque was measured intraoperatively during Dall-Miles cable fixation surgeries for periprosthetic fracture of the femur. And the numerical relationship between torque and cable tension was assessed through mechanical tests. Using the torque vs. cable tension relationship, intraoperatively measured tightening torque was converted into a cable tension. Intraoperative measurement of tightening torque In vivo data of the maximal torque which was applied by an experienced surgeon was measured using a torquemeter. Total 11 cases of periprosthetic femoral fractures from 11 patients were participated with their agreement. A two-side Dall-Miles cable tightener (Stryker Co., USA) was used. To measure the torque of Dall-Miles tightener applied by a surgeon, a torquemeter (Torque driver 80FTD2-N-S, TOHNICHI, JAPAN) was connected to the Dall-Miles tightener through a square groove. The groove was machined with 1cm × 1cm × 1cm in dimension on the proximal end of the rotational shaft of the Dall-Miles tightener. Laboratory measurement of torque and tension To reveal the relationship between the torque of Dall-Miles cable tensioner and the tension of the cable, mechanical tests were done. A two-side Dall-Miles cable tightener were mounted to INSTRON (INSTRON, Norwood, MA, USA) using a customized fixation jig. One cable of 2 mm in diameter was connected to the upper head of INSTRON, and another to the lower headA preload was slowly applied to the cables up to 10 N so that the initially loose interaction among a tightener, two cables, and two loading heads of INSTRON became tight. Once the preloading finished, tightening torque and cable tension were simultaneously measured. The tightening torque was increased in increment of 1 N-m; accordingly, at each torque the tension hung to Dall-Miles cable was measured by reading loadcell data of INSTRON. Results: Intraoperative tightening torque Intraoperatively measured maximal torque applied to the Dall-Miles cable tensioner was 5.7±0.5 N-m. Numerical expression of torque-tension relationship Based on the data of tightening torque and cable tension measured from mechanical tests, the relationship between the torque (T) and tension (P) of Dall-Midles cable fixation system was numerically expressed. Total range of measured tightening torques and cable tensions was linearized. The linear expression was “T=106.8 × P”. Based on this numerical relationship, the amount of cable tension applied to the cable was calculated as 606.6±58 N. Discussion: This study revealed that 606.6±58 N of cable tension has been applied when an experienced surgeon does cable fixation of periprosthetic fracture. Authors believe that the torque-tension relationship will provide a key biomechanical clue for biomechanics scientists, and the amount of intraoperative cable tension measured at the time of Dall-Miles cable fixation for periprosthetic fracture will provide an important surgical key reference for the surgeons who use the cable fixation system

Background. A variety of cerclage systems are available for the fixation of periprosthetic fractures. The aim of this study was to compare the forces applied by these systems. Methods. We designed and manufactured a device to measure the forces applied to a cylindrical structure by a cerclage cable. Five different commonly used systems were evaluated. The forces exerted were measured at four different locations on the cylinder and this was compared to the force indicated by the tensioning device. Results. Only one of the devices consistently indicated the correct force. Some of the cables became frayed after being used more than twice. There was a pattern of increase in force closer to the point of crossing of the cables. Conclusion and Clinical Relevance. The true force applied to the bone is not reflected by the value indicated by the tensioning device. Some cables should not be retensioned more than twice. The device connecting the cable should be placed on the strongest part of the bone as this is the area where the maximum force is exerted. NO DISCLOSURES

Wire cerclage is one of the oldest forms of internal fixation. Cerclage has numerous applications in orthopaedics as a primary method of fracture fixation and as a supplement to other forms of fixation. Traditional wire cerclage, however, has several disadvantages. Monofilament wire is prone to breakage. Multifilament braided cables tend to undergo fatigue failure and fray, releasing metallic particulate debris into the body. Both have a limited ability to maintain compression. This paper presents performance data on a novel flexible, high strength, high fatigue life cable that addresses the inherent problems associated with traditional metal wire cerclage. The iso-elastic cerclage cable consists of a nylon core encased in a jacket of UHMWPE braided fibers. A tensioning instrument tightens the assembly with a metal clasp. Cable assemblies were tested under in vitro static and dynamic loading conditions. Viscoelastic response and wear behavior under in vitro loading conditions were characterized. The iso-elastic cerclage cable displayed an ultimate tensile strength of pproximately 650 MPa and withstood over one million cycles of simulated physiologic load without failure. After 8 weeks of static loading, initial cable tension decreased by approximately 40%. After one million loading cycles against a bone plate, the iso-elastic cable displayed no evidence of fraying or fiber breakage. The ultimate strength of the iso-elastic cable is comparable to that of traditional metal cable while its fatigue strength is clearly superior. After initial relaxation, the iso-elastic cable maintained compressive forces that are typical of the initial compression held by metal cerclage wires. The wear characteristics of the iso-elastic cable are clearly superior to those of multifilament metal cerclage cables. The iso-elastic cable shows high tensile strength and fatigue life. An iso-elastic cable has been developed to compensate for micro-movement within the bone fracture construct while maintaining a continuous compressive force across the fracture

We used the stainless steel cable grip system described by Dall and Miles in 1983 to fix trochanters in 40 hips after total arthroplasty with trochanteric osteotomy. The cable broke in 32.5% of the hips; the trochanter failed to unite in 37.5%. Significantly more cables broke when placed inside the femoral canal than when the cable was placed round the femoral shaft (58% as against 9.5%, difference p less than 0.01). The high incidence of breakage may have resulted from contact between the stainless steel cable and the titanium prosthesis, from the acute angulation, or because of the lower fatigue strength of stainless steel. Better results have been obtained using cables with a higher fatigue strength, passed outside the proximal femur

Introduction. Mechanical stabilization following periprosthetic fractures is challenging. A variety of cable and crimping devices with different design configurations are available for clinical use. This study evaluated the mechanical performance of 5 different cable systems in vitro. The effect of crimping device position on the static failure properties were examined using a idealized testing set up. Materials and Methods. Five cable systems were used in this study; Accord (Smith & Nephew), Cable Ready (Zimmer), Dall-Miles (Stryker), Osteo Clage (Acumed) and Control Cable (DePuy). Cables were looped over two 25 mm steel rods. Cable tension was applied to the maximum amount using the manufactures instrumentation. Devices were crimped by orthopaedic surgeon according to instructions. Crimping device/sleeve was secured in two different positions; 1. Long axis in-line with the load; 2. Long axis perpendicular to the load (Fig 1). Four constructs were tested for each cable system at each position. All constructs were tested following equilibration in phosphate buffered saline at 37 degrees Celsius using a servohydraulic testing machine (MTS 858 Bionix Testing Machine, MTS Systems) at a displacement rate of 10 mm per minute until failure. The failure load, stiffness and failure model (cable failure or slippage) was determined for all samples. Data was analysed using a two way analysis of variance (ANOVA) followed by a Games Howell post hoc test. One sample of each cable – crimping construct was embedded in PMMA and sectioned to examine the crimping mechanism. Results. In vitro mechanical performance of the five cable systems tested differed between systems. Position of the crimping device was also a significant variable which influenced the peak load, stiffness as well as failure mode. Cable failure, cable failure inside crimping sleeve as well as cable slippage was observed when the crimper was perpendicular to the applied load while cable slippage was found when the load was in line with the crimper. Peak loads of the systems ranged from well over 5 kN (Cable Ready) to 1 kN (Accord) (Fig 2). Analysis of the crimping technique varied between systems as was achieved either with direct or indirect cable compression (Fig 3). Discussion. Cable systems achieve fixation through different means as demonstrated in this study. These differences translated into different failure modes as well as a wide range of mechanical properties when tested under idealized conditions. Placement of the crimping device can influence the failure loads as noted in the current testing

Purpose: Presently, tension band figure-of-eight fixation of olecranon fractures is usually performed with stainless steel wire. A polyethylene cable cerclage has been proposed as an alternative to lessen the complications associated with wire. This study compared the stability of tension band constructs for olecranon fracture fixation using a polyethylene cable cerclage or a stainless steel wire cerclage. Methods: Ten matched pairs of fresh-frozen cadaveric elbows, without radiographic abnormality, were selected for the study. In each specimen, a transverse fracture was created by an osteotomy at the middle of the sigmoid notch of the olecranon. One elbow of each pair was randomized for tension band fixation with a figure-of-eight construct while the other was fixed by tension banding with a loop cerclage. Two different materials, stainless steel wire and isoelastic polyethylene cable, were randomly selected to create the cerclage constructs in each elbow. The triceps tendon was controlled and cyclic loads were applied to the dorsal cortex of the ulna 8 cm distal to the fracture site to create a bending moment. The elbow was initially preconditioned at 45 N for 100 cycles, followed by four periods of 300 cycles each, from 45 N to 120 N in 25 N increments. Dynamic and static fracture gap for the different configurations and materials were recorded. Results: No difference in static gap was found between the metal figure-of-eight, cable figure-of-eight and cable loop constructs (p> 0.05). The metal loop was found to have significantly greater gap (p=0.0013) than the other 3 constructs. No difference was observed in dynamic gap at the peak loads for any of the constructs (p=0.3379). Conclusion: This study demonstrated that the biomechanical performance of tension band fixation in an olecranon fracture model using a polyethylene cable in either figure-of-eight or loop construct is similar to that of the stainless steel wire figure-of-eight construct and should be considered as an option to the traditional stainless steel wire. This type of soft and tissue tolerant fixation may lessen the known clinical complications of wire fixation while providing equivalent stability under physiologic loads which would permit early rehabilitation

Purpose: Greater trochanter reattachment is frequently accomplished using cable grip type systems. There is a relatively high failure rate for these systems, the mechanisms of which are unclear. One possible source of instability could be femoral neck cut location. Another concern is the effect of variability in cable tension. The objective is to create a femur implant model which allows for variation in cable tension, common muscle forces and the placement of the femoral neck cut in order to analyse trochanter fragment fixation. Method: A finite element model (FEM) of a femur with simulated greater trochanter osteotomy (30°) was combined with the femoral component of a hip prosthesis and a greater trochanter reattachment system with 4 cables (Cable-Ready®, Zimmer). A total of 18 simulations were modeled in a full factorial design using three independent variables; cable tightening (178N, 356 N and 534 N), muscle forces (rest, walking and stair climbing) and femoral neck cut (10 mm and 15 mm above the lesser trochanter). Displacement of the fragment, in terms of both gap and shear components, as well, stress in the bone were investigated. Results: The location of the femoral neck cut reduced contact surface area by 20% and had the largest influence on displacement (0.24 mm). Pivoting of the fragment was observed with a maximum gap (0.38 mm) and maximum total displacement (0.41 mm) at the bottom of the fragment. This was observed during stair climbing, while the cables were tightened to 177.9 N and with the femoral neck cut at 10 mm. Increased tightening of the cables provided no significant reduction in fragment displacement. However, higher cable tension significantly increased the stress in the bone (8 MPa and 26 MPa for cable tension of 178 N and 534 N respectively). Conclusion: Placement of the femoral neck cut closer to the lesser trochanter significantly increased fragment displacement. Preservation of the contact surface area is recommended. Excessive cable tightening did not reduce fragment movement and only exacerbated bone stress. Caution must be used to not over tighten the cables. This model can be used to test and compare the performance of new implant designs

Introduction: While providing an easier compression, cable tensioners also bring the risk of an iatrogenic fracture when they are unnecessarily over-tightened. In this pilot study we have designed a split femur fracture/osteotomy model to assess the minimal force providing rotational stability for a femoral prosthetic stem during tightening with a cable tensioner. Methods: Twelve volunteer residents of orthopedics were asked to tighten gradually a cerclage wiring of steel cable with a cable tensioner on a longitudinally split bone encircling a prosthetic stem. Each resident repeated the test 10 times and they aimed to tighten until to a point to provide rotational stability for the stem, that they decided with manual control. The fracture model was reproduced on the distal diaphysis of a 12 mm diameter femur bone of a one-year old sheep cadaver. The femur bone was longitudinally split with an oscillating saw and a semi-cylindrical 5 cm long bone window was split. A 13 mm diameter femoral stem (Restoration HA, Styker) was then inserted into the open segment of the diaphysis and the bone window was closed on it and gently hold in place with a cerclage of steel cables. A special aluminum cable tensioner, integrated with a special digital strain measurement device (Vishay MM, NJ, USA), was used for tightening of the cable. The minimal tension loads that the residents found enough to provide a rotational stability were recorded. The descriptive modules and Student t-test were used in statistical analysis. The p values < 0.05 were considered statistically significant. Results: Mean tension loads provided by 12 residents were between 176±32N and 876±211N. The mean tension loads of the total 120 tigtening trials was 540 N. Significant difference was found between the highest and the lowest (p< 0.0001). Plateau of the rotational stability was 6N/m. First tension load for reaching this level was found to be 550±45N. The force to break the bone was found to be around 2000N. Discussion: For secure use, the force interval that will ensure a secure fixation without causing a fracture should be known and the tensioner should be tightened in these ranges. In this in-vitro experimental pilot study we have compared the individual assessment of secure fixation during cable tensioner use. Our results suggest that the individual decision for rotational stability depends largely on the person who evaluates it. A torque-meter can be implemented to our experiment model to obtain more objective assessment of the optimal tightening of the cable tensioner for secure fixation with rotational stability. After determining the force interval for secure fixation a torquesensitive crank can be designed and implemented to the cable tensioner. Such a device should provide a more safe and secure fixation during tightening of cerclage wirings

To review the results of periprosthetic femoral fractures treated using Dall-Miles cable and plates. Periprosthetic femoral fractures are increasingly common and their treatment is challanging for Orthopaedic surgeons. Dall-Miles cable and palte system is the current impalnt of choice for periprosthetic femoral fractures following hip arthroplasty. Between January 1999 and December 2001, twenty-two patients with periprosthetic femoral fracture around hip arthroplasty were treated with Dall-Miles system. Thirteen patients required bone grafting (allograft) at time of surgery. The average age of the group was 82 with eighteen females and four men. Thirteen were Vancouver type B2, two type B1, six type C and one type A fracture. All patients were followed up to fracture union. Two patients had fracture of the plate and required further surgery. Two patients had symptomatic loosening even though the fracture had united and underwent revision hip replacement. These four patients were Vancouver type B2. Nine Vancouver B2 patients had fracture union with no need for revision. All other patients had fracture union with no major complications. The Dall-Miles cable and plate system provides an easy to use implant with satisfactory outcome. The simplicity of the system allows widespread acceptance in these increasingly common fractures. It is particularly useful to obtain bony union in elderly patients not fit enough for a major revision surgery

For the management of displaced patellar fractures, surgical fixation using cannulated screws along with anterior tension band wiring is getting popular. Clinical and biomechanical studies have reported that using cannulated screws and a wire instead of the modified tension band with Kirschner wires improves the stability of fractured patellae. However, the biomechanical effect of screw proximity on the fixed construction remains unclear. The aim of this study was to evaluate the mechanical behaviors of the fractured patella fixed with two cannulated screws and tension band at different depths of the patella using finite element method. A patella model with simple transverse fracture [AO 34-C1] was developed; the surgical fixation consisted of two 4.0-mm parallel partial-threaded cannulated screws with a figure-of-eight anterior tension band wiring using a 1.25-mm stainless steel cable. Two different locations, including the screws 5-mm and 10-mm away from the leading edge of the patella, were used. A tension force of 850 N was applied on the patellar apexes at two loading angles (45° and 0° [parallel] to the long axis) to simulate different loading conditions while knee ambulation. The proximal side (base) of the patella was fixed, and the inferior articular surface was defined as a compression-only support in ANSYS to simulate the support from distal femur condyles. Compression-only support enables the articular surfaces of the present patella to only bear compression and no tension forces. Under different loading conditions, the fixed fractured patella yielded higher stability during 0° loading of tension force than during 45° loading. When the screws were parallel placed at the depth of 5 mm away from the patellar surface, the deformation of patellar fragment and maximum gap opening at the fracture site were smaller than those obtained by screws placed at the depth of 10 mm away from the patellar surface. Compared to the superficial screw placement, the deeper placement (10 mm) increased the maximum gap opening at the fracture site by 1.56 times under 45° loading, and 1.58 times under 0° loading. The load on the tension band wire of the 10-mm screw placement was 3.12 times (from 230 to 717 N) higher than that of the 5-mm placement. Under the wire, the contact pressure on the patellar surface was higher with the 10-mm screw placement than the 5-mm screw placement. The peak bone contact pressures with the 10-mm placement were 7.7 times (99.5 to 764 MPa) higher. This is the first numerical study to examine the biomechanical effects of different screw locations on the fixation of a fractured patella using screws and tension band. Based on a higher stability and lower cable tension obtained by the superficial screws placement, the authors recommended the superficial screw placement (5 mm below the leading edge of the patella) rather than the deep screws while fixing the transverse patellar fracture with cannulated screws and cable

Purpose: To evaluate the Cable-Ready Cable Grip System in the treatment of peri-prothetic femoral fractures. Materials and Methods: Twenty cases of treated with Cable-Ready Cable Grip System were reviewed retrospectively. Outcome was measured using clinical and radiological observations. Mechanism of injury, fracture types and complications were noted. Results: Eighteen of the twenty cases reviewed had good or excellent results. One case required re-operation for implant failure, complications included continued pain and mal union. Conclusions: The cable-ready cable grip system is a simple and secure fixation system for peri-prosthetic femoral fractures. The system functions optimally in situations where the prosthesis remains stable and the correct length of plate is employed

There are many management solutions for the fixation of Periprosthetic fractures with intact stem of Hip and shoulder arthroplasties. The Bio Mechanics of single plate application are unlikely to be strong enough to commence mobilisation and its effectiveness against torsional strain with an osteoporotic bone quality is of concern. Double plate fixation as discussed at the last South African Orthopaedic Congress by Mr Floyd et al is another option but this again may have some biomechanical concerns and biological compromise at the fracture site due to periosteal stripping. Implant revision with a longer stem is a bigger surgical insult to a potentially frail group of patients with questionable bone quality. We report a short series of 16 peri-prosthetic fractures with intact stem that are managed with Zimmer cable plate fixation System. The results were very satisfactory and we consider this an attractive option to be considered in the management of this difficult presentation. This is a retrospective study. We present the results of 13 Periprosthetic Femoral Shaft fractures and 3 humeral periprosthetic fractures in 16 patients treated with cable plate fixation system. Majority of the patients were over 60 years with an ASA rating of 3–4. The procedures were performed in a district general hospital in the UK between August 2001 to December 2005. The patients presented with in 1–20 years following initial Arthroplasty. All the fractures were fixed with Zimmer cable plate fixation system. An 8 hole plate was most commonly used for femoral fractures through the lateral approach for TYPE 2 fractures. The proximal end of the plate was secured with 3–4 cable ties. Early partial weight bearing was encouraged. The majority of the patients were discharged within 12 weeks. Of the 3 humeral fractures union was achieved at 12 weeks in 2. There was 1 case of implant failure due to a further fracture noted in a manic depressive patient, who was not compliant. All proximal femoral fractures showed evidence of clinical and radiological union by 6 months. The majority (7/13) had united within 20 weeks. There were no complications noted. We recommend this effective method should seriously be considered in the management of this difficult and increasingly occurring complication in a frail population

Purpose: Plate and cable alone constructs to treat periprosthetic fractures around a well-fixed femoral stem in total hip replacements, have been reported with high failure rates. The aim of this study was to evaluate the results of our surgical treatment algorithm to reliably use lateral plate and cable constructs in these fractures. Method: One hundred and six periprosthetic fractures in 102 patients were treated between 1996 and 2006. Forty-five fractures were pre-operatively assessed as Vancouver type B1 fractures. The joint was always dislocated and stability of the implant was meticulously evaluated. This led to the identification of nine (20%) unstable stems leaving 36 fractures to be real B1-type fractures. The fracture was considered to be suitable for lateral plate and cable alone fixation if the medial cortex was not comminuted and an anatomical reduction of the medial cortex could be achieved. Twenty-nine B1- and 5 C-type fractures had been treated with a single lateral plate and cable construct. The mean length of follow-up was 43.2 months. The paired Student’s T-test with a confidence interval of 95% and a significant p-value of p< 0.05 was used to compare the pre- and postoperative UCLA hip scores. Results: Four (12%) patients died within one month from surgery leaving 30 patients for follow-up. Twenty-nine fractures united at a mean of 6.4 months. One B1-type construct failed due to inappropriate proximal fixation. Two fractures united uneventfully with a mean of 8° of varus alignment of the proximal fragment. One patient with a C-type fracture sustained a fracture distal to the tip of the plate. There were three plate infections (8.8%). There was no significant difference between the pre- and post-operative UCLA hip scores (25 versus 23 resp.). Conclusion: These fractures represent a difficult problem with a high complication rate of 30%. The presented treatment algorithm contributed significantly to the 97% union rate with plate and cable alone constructs that was comparable to the union rates achieved with combined plate and strut graft fixation

Introduction: With an aging population, the number of hemiarthroplasties and Total Hip Replacements is on a rise. Though uncommon, one of the serious postoperative complications is periprosthetic fracture of femur. Dall Miles cable plate system is widely used for fixation of these fractures. Patient and Methods: We present a series of of 19 patients who underwent Dall Miles cable plate fixation for periprosthetic fracture over a hemiarthroplasty or a total hip replacement during the last 5 years, reporting clinical and radiological outcome measures. Results: Female to male ratio was 2:1. The average age was 77.33 (range from 55 to 93). Eight patients had the periprosthetic fracture after hemiarthroplasty while 11 had it after Total Hip Replacement. These two group were completely different in terms of their fitness, activities and expectations. Twelve were Vancouver B 1, 7 were Vancouver C. Five were initially managed with two plates, the remainder had one plate only. Patients were followed up at an average of 3.1 years (range 3.2 months to 5.1 years). Three patients had died at the time of our follow up due to unrelated medical problems. One patient had deep infection that required revision and 1 had superficial infection that healed with antibiotics. 1 patient underwent revision to a THR for hip pain. Of those managed with a single plate, 3 patients had plate/cable failure and underwent revision DM plating with 2 plates and cables along with allogenic bone grafting; all of these healed well. All of these patients had periprosthetic # following a THR. Five patients managed initially with 2 DM plates healed without any complications. Discussion: Even in this small series, we feel it is evident that Dall Miles plating using a single plate has a high incidence of plate failure (3 of 13). Orthogonal plating has been widely used in past for fixation of complex fractures and nonunions. We feel there is a distinct advantage of using two plates of uneven lengths to improve chances of healing, preventing implant failure and reducing stress riser effect. We advocate primary fixation of periprosthetic fractures of proximal femur over THR using 2 Dall Miles cable plates and bone graft. We would like to present our results and discuss this complex topic further