The zona conoidea comprises the area of the lateral trochlear ridge of the humerus. The purpose of this study is to reintroduce this term ‘zona conoidea’ to the discussion of the human elbow and to investigate its significance in the development of osteoarthritis of the elbow. The upper extremities of 12 cadavers were prepared. With the forearm in neutral, pronation and supination, the distance between the bevel of the radial head and zona conoidea was inspected. A total of 12 healthy volunteers had a CT scan. The distance between the zona conoidea and the bevelled rim of the radial head was measured in these positions. In the anatomical specimens, early osteo-arthritic changes were identified in the posteromedial bevelled rim of the radial head, and the corresponding zona conoidea in supination. Measurement in the CT study showed that in full supination, the distance between the bevel of the radial head and the zona conoidea was at a minimum. This study suggests that the significant contact between the bevel of the radial head and the zona conoidea in supination is associated with the initiation of osteoarthritis of the elbow in this area

A 35-year-old female (age 35Yrs) had primary MOM total hip arthroplasty (THA) in 2008. At 8 months this patient postoperatively developed headaches, memory loss, vertigo, and aura-like symptoms that progressed to seizures. At 18 months review, she complained of progressive hip pain, a popping sensation and crepitus with joint motion. This patient weighed 284lbs with BMI of 38.5. Radiographs revealed the cup had 55° inclination, 39° anteversion (Fig. 1). Metal ion concentrations were high (blood: Co=126 mcg/L, Cr= 64mcg/L). Revision was performed in November 2010 A dark, serous fluid was observed, along with synovitis. The implants were well fixed and the femoral head could not be removed; thus the stem was removed by femoral osteotomy. With the head fused on this femoral stem, for the 1. st. time it was possible to precisely determine the habitual patterns of MOM wear relative to her in-vivo function. We investigated (1) size and location of wear patterns and (2) signs of cup-stem impingement to help explain her symptoms developed over 32 months follow-up. The retrieved MOM was a Magnum™ with head diameter 50mm and 50×56mm cup (Biomet). This was mounted on a Taperloc™ lateralized porous-coated stem. Components were examined visually and wear damage mapped by stereo-microscopy, interferometry, CMM, SEM, and EDS. Main-wear zone (MWZ) areas were calculated using standard spherical equations. 1. and centroidal vectors determined. The head-cup mismatch was 427um with the cup revealing a form factor of 228um. The cup showed wear area of 1275mm² that extended up to the cup rim over 150°arc. The cup rim was worn thin over a 90° arc with loss of cup bevel. The head showed an elliptical wear area of 2200mm. 2. located centrally on the superior-medial surface (ellipsoidal ratio ×1.2). Compared to the hemispherical surface (50mm: hemi-area = 3927mm. 2. ), the worn area represented hemi-area ratio of 56%. The centroidal vectors measured 8° anterior and 24° superior to the head's polar axis (Fig. 2). Stripe wear damage revealed multiple impingement sites. SEM and EDS revealed stripes were contaminated by metal transfer from the stainless-steel instruments used at revision. The main impingement position was identified (Fig. 3) indicating the site of repetitive subluxations whereby the subluxing head thinned the cup, i.e. “edge wear”. Cup and head wear patterns corresponded well, reinforcing our definition of the MWZ locations in vivo. The femoral MWZ was centrally located superiorly and medially with respect to the polar axis of the femoral neck and head. The noted impingement position indicated this patient had experienced repetitive subclinical subluxations (RSS). 2. The taper inside the fused head may also have been a contributory factor that we cannot ignore. Nevertheless her excessive cup thinning was likely a result of a steep cup and considerable anteversion allowing the femoral head to sublux over the cup rim, thus thinning the cup and wearing the rim bevel, and producing MOM wear debris

Following a careful in-depth preoperative plan for revision TKA, the first surgical step is adequate exposure. It is crucial to plan your exposure for all contingencies. Prior incisions have tremendous implications and care must be taken to consider their impact. Due to the medially based vascular supply to the skin and superficial tissues about the knee, consideration for use of the most LATERAL incision should be made. It is essential to avoid the development of flaps which may compromise the skin and soft tissue which can have profound implications. Exposure options can be broken down into either PROXIMALLY based techniques or DISTALLY based options. The proximal based techniques involve a medial parapatella arthrotomy followed by the establishment of medial and lateral gutters. An assessment of the ability to evert or subluxate the patella should be made. Care must be taken to protect the insertion of the patella tendon into the tibial tubercle. If the patella is unable to be mobilised, then extension of arthrotomy proximal is performed. If this is not adequate, then consider inside out lateral release. If still unable to mobilise, then a QUAD SNIP is performed. In rare instances, you can connect the lateral release with quad snip resulting in a V-Y quadplasty, which results in excellent exposure. Another option is to employ DISTALLY based techniques such as the tibial tubercle osteotomy technique described by Whiteside. A roughly 8cm osteotomy segment with distal bevel is performed. The osteotomy must be at least 1.5–2cm thick: too thin and risk of fracture increases. This approach leaves the lateral soft tissues intact and then a “greenstick” of the lateral cortex is performed with eversion of patella and the lateral sleeve of tissue. This technique is excellent for not only exposure but also in instances where tibial cement or a cementless tibial stem needs to be removed. Closure is accomplished with wires either through the canal or around the posterior cortex of the tibia

Introduction: We present a clinical and radiology follow-up of the uncemented titanium coated monobloc Robert Mathys (RM) Acetabular Component (Mathys AG Bettlach, Bettlach, Switzerland). The acetabular component is a monobloc hemispherical cup manufactured from Ultra High Molecular Weight Polyethylene (UHMWPE), with a pure titanium particle coated surface. With heat and pressure, the particles are blasted into the polyethylene surface. The coating promote osseointegration. Stability of the cup is provided by 2 anchoring pegs on the weight bearing part on its outer surface. The inclination of pegs and holes diverge by 5 degrees providing a press-fit effect that increases the rigidity of the primary fixation and this is supplemented by screws inserted through the periphery of the cup. Tow cups designs are available, a full-profile and a bevelled cup. In all cases the bevelled cup was used. The purpose of this study was to assess the clinical performance with 15 years of this cup. Methods: In this study, the status of the uncemented titanium coated RM cup placed in patients who underwent a primary total hip replacement between January 1, 1988 and December 31, 2001 was determined. A total of 1876 cups (1584 patients) were placed in patients with a permanent residence in Berlin. The femoral component was either an uncemented or a cemented stem in an supine lateral approach with either a 28 or 32mm diameter head. The majority of the heads were ceramic and stainless steel. The diagnosis was osteoarthritis, rheumatic arthritis, femur neck fracture, developmental dysplasia of the hip (DDH). 1034 patients were contacted by telephone. Out of this patients group 539 patients (678 cups) were evaluated by clinical examination (HHS), radiographic investigation and social evaluation by the WOMAC and NHS score. 451 patients who had died unrelated to the operation. Lost of follow up were 65 patients (69 Cups) and 34 patients (48 cups) had to be revised. Results: The cumulative survival rate of the RM cup is 98.2 percent at 5 years, 97.5 percent at 10 years and 96.9 percent at 15 years. The survival rate in the ceramic head group is 98.7 at 15 years and by using stainless steel head 91.7 at 15 years. Reseaon for re-opertion was in 34 patients aseptic loosening, 8 patients had infection. Dislocation, malpsition and periprosthetik fracture in 2 patients. In the group with clinical evaluation, the HHS was in 80.2 percent of all patients good and ecellent, 9,7 percent had a moderate result and 10,1 percent had a poor result. Discussion/Conclusion: The low failure rate for loosening demonstrates that this implant has excellent ongrowth and fixation potential. The RM Cup has been shown to function well at up to 15 years post implantation. Its success may in part be due to the one-piece design

Following a careful in-depth preoperative plan for revision TKR, the first surgical step is adequate exposure. The following steps should be considered: 1.) Prior incisions: due to the medially based vascular supply to the skin and superficial tissues about the knee, consideration for use of the most LATERAL incision should be made. 2.) Avoid the use of flaps which may compromise the skin and soft tissue. 3.) Exposure options can be broken down into: PROXIMALLY based techniques: medial parapatella arthrotomy, establish medial and lateral gutters, eversion or subluxation of the patella, extension of arthrotomy proximal, if unable to “mobilise” patella, consider inside out lateral release, if still unable to mobilise: QUAD SNIP, in rare instances, connect lateral release with quad snip resulting in a V-Y quadplasty, may now turn down for excellent exposure. DISTALLY based techniques: tibial tubercle osteotomy technique described by Whiteside, roughly 8 cm osteotomy segment with distal bevel, osteotomy must be at least 1.5–2 cm thick: too thin and risk of fracture increases, leave lateral soft tissues intact, greenstick” the lateral cortex with eversion of patella, closure with wires

Aims

The aim of this study was to evaluate medium- to long-term outcomes and complications of the Stanmore Modular Individualised Lower Extremity System (SMILES) rotating hinge implant in revision total knee arthroplasty (rTKA) at a tertiary unit. It is hypothesized that this fully cemented construct leads to satisfactory clinical outcomes.

Modification of ordinary jig (angle guide) used for DCS fixation so as to make it more suitable for biological DCS. We have modified the jig used for ordinary DCS fixation so as to make it more suitable for biological DCS. In ordinary DCS jig, the hole for guide wire lies towards one end and the handle is attached at the other end. We have removed the handle and attached it adjacent to hole for guide pin so that the other end is free and can be slided in submuscular plane without actually exposing the whole length of femur. Subsequently, we beveled the free end and removed the sharp points and this helps in making sub muscular plane easily and with minimum soft tissue trauma. The modified jig was applied in a patient with fracture subtrochanteric femur in submuscular plane through 2 cm long incision and its position confirmed by c-arm. Position was found to be similar to that observed with ordinary DCS jig. The idea of making this presentation is that we can modify classical instrumentation used for internal fixation to make them suitable for biological fixation. This is a small innovation in that direction

Minimal or Less Invasive Approaches. Limited medial parapatellar incision – 2–3 inch medial incision; Best for unicompartmental implant; patellar visualization poor; Less invasive but limited visualization therefore overall joint inspection is compromised. MIS TKR approaches - Mini midvastus approach popularised by S.B. Haas - Ideal BMI 30 or less; Incision length 10cm; Vastus incision about 2–3cm; Vastus incision beyond 5–6cm places motor branch to VMO at risk; Coupled with downsized cutting blocks, allows predictable ability to perform TKR; Sliding window concept; Patella eversion not necessary. Mid Subvastus approach – 10cm skin incision; Sub vastus dissection up to septum (watch for bleeders!); VERY difficult in muscular males!. Standard Incisions. Standard medial parapatellar approach - Familiar to most surgeons; Medial arthrotomy facilitates exposure for almost all procedures; Can become more extensile by incising the quad tendon further proximal; Release of posteromedial capsule and semi-membraneosus allows exposure posteriorly. Quad snip - Used occasionally in the fixed varus, flexion contracted knee; More commonly used in revisions; Allows patella eversion without risk of distal avulsion; Motor strength appears to return to baseline level postoperatively. V-Y quadriceps turndown - Technique: initial medial parapatellar arthrotomy, an oblique tenotomy angled toward the tendinous portion of the vastus lateralis and then extended distally; The quadriceps segment is than retracted downward to expose the joint; Tenotomy is closed with robust non-absorbable sutures holding the knee in extension; Postoperative flexion is dictated by integrity of repair while flexing knee at time of closure. Disadvantages include extensor lag, as well as effecting ultimate ROM. Tibial tubercle osteotomy a la Whiteside - Medial arthrotomy; Tubercle segment is 6–8cm long, 2cm wide and 1–1.5cm thick; Segment is beveled distally so as to avoid stress riser; Leave lateral soft tissue intact; Closure with wires preferred although screws or cables have been used as well

Performance and durability of total knee arthroplasty is optimised when bone surfaces are prepared with the knee in neutral varus-valgus alignment in the anteroposterior (AP) plane. For the femur, this means resecting the surface perpendicular to the mechanical axis of the femur, which passes through the center of the femoral head and center of the knee. Because the center of the femoral head is not a reliable landmark during the operation, the distal femoral surface can be resected at 5 degrees valgus to the long axis of the femur using an intramedullary (IM) alignment rod to establish the position of the femur's long axis. The IM rod also provides the landmark for alignment of the femoral component in the flexion-extension position. Tibial alignment is established by cutting the upper surface of the tibia perpendicular to the long axis. An extramedullary (EM) rod easily can span the distance between the centers of the tibial surface at the knee and ankle to establish a reference for upper tibial surface resection via the long axis of the tibia. In cases with femoral deformity or bone disease that prevents use of an IM rod as a landmark for the long axis of the femur, plain film radiographs can be used along with intraoperative measurements and hand-held tools that are readily available in the standard total knee instrument set. Using an AP radiograph taken to include the femoral head and knee: 1.) Mark the centers of the femoral head and knee. 2.) Draw a line to connect the centerpoints. 3.) Mark the high points of the medial and lateral femoral condylar joint surfaces. 4.) Draw a line perpendicular to the mechanical axis that crosses the mark on the high point of the most prominent femoral condyle. This marks the position and alignment of the femoral implant surface. 5.) To measure the distal thickness of the femoral component and adding 10% to account for magnification of the radiograph, mark two points proximal to the two high points of the condyles and draw a line perpendicular through these two points to mark the resection line for the distal femoral surfaces. Less than the thickness of the implant will be resected from the least prominent condyle. 6.) Measure the thickness of bone to be resected and the distance between the bone surface and distal surface line. This distance represents the space between the distal femoral cutting guide and the joint surface of the deficient condyle. 7.) Insert a threaded pin into the bone surface with the measured distance protruding from the surface to set this position. 8.) Seat the distal femoral cutting guide against the protruding pin on the low side and against the surface of the femur on the high side. This aligns the distal femoral cutting guide perpendicular to the mechanical axis of the femur. 9.) Draw the AP axis from the center of the intercondylar notch posteriorly to the deepest point of the patellar groove, and use the combined cutting guide to finish the femur. 10.) Make the anterior, posterior, and bevel cuts perpendicular to the AP axis. 11.) Finally, align the tibial surface, with an IM or EM rod, to resect perpendicular to the long axis of the tibia in the AP plane and sloped 4 degrees posteriorly in the lateral plane. 12.) Once the bone surfaces are resected at the proper angle, insert the trials or spacer blocks and finish the arthroplasty with release of tight ligaments

Performance and durability of total knee arthroplasty is optimised when bone surfaces are prepared with the knee in neutral varus-valgus alignment in the anteroposterior (AP) plane. For the femur, this means resecting the surface perpendicular to the mechanical axis of the femur, which passes through the center of the femoral head and center of the knee. Because the center of the femoral head is not a reliable landmark during the operation, the distal femoral surface can be resected at 5 degrees valgus to the long axis of the femur using an intramedullary (IM) alignment rod to establish the position of the femur's long axis. The IM rod also provides the landmark for alignment of the femoral component in the flexion-extension position. Tibial alignment is established by cutting the upper surface of the tibia perpendicular to the long axis. An IM rod is not necessary for alignment since the ankle is accessible for reference. An extramedullary (EM) rod easily can span the distance between the centers of the tibial surface at the knee and ankle to establish a reference for upper tibial surface resection via the long axis of the tibia. In cases with femoral deformity or bone disease that prevents use of an IM rod as a landmark for the long axis of the femur, computer-assisted alignment can be helpful to establish the mechanical axis of the femur and to determine the level of resection of the femoral surface to create a plane that is perpendicular to the mechanical axis of the femur and positioned to place the joint surface at the correct level. Whereas this can be done with CT scan or MRI imaging and robotic instrumentation, the cost in time and money is substantial. Rather, plane film radiographs can be used along with intra-operative measurements and hand-held tools that are readily available in the standard total knee instrument set. Using an AP radiograph taken to include the femoral head and knee: Mark the centers of the femoral head and knee. Draw a line to connect the centerpoints. Mark the high points of the medial and lateral femoral condylar joint surfaces. Draw a line perpendicular to the mechanical axis that crosses the mark on the high point of the most prominent femoral condyle. This line marks the position and alignment of the femoral implant surface. Next, measure the distal thickness of the femoral component and add 10% to account for magnification of the radiograph. Draw a parallel line this distance proximal to the femoral surface line. This is the femoral resection line. Less than the thickness of the implant will be resected from the least prominent condyle. On the low side, measure the thickness of bone to be resected and the distance between the bone surface and distal surface line. Insert a threaded pin into the bone surface with the measured distance protruding from the surface to set this position. Seat the distal femoral cutting guide against the protruding pin and against the surface of the femur on the high side. Resect with the cutting guide fixed perpendicular to the long axis of the femur. This resects the thickness of the implant from the prominent side and resects the prescribed amount from the low side to set the distal cut perpendicular to the mechanical axis of the femur. Draw the AP axis from the center of the intercondylar notch posteriorly to the deepest point of the patellar groove, and use the combined cutting guide to finish the femur. Make the anterior, posterior, and bevel cuts perpendicular to the AP axis. Finally, align the tibial surface, with an IM or EM rod, to resect perpendicular to the long axis of the tibia in the AP plane and sloped 4 degrees posteriorly in the lateral plane. Once the bone surfaces are resected at the proper angle, insert the trials or spacer blocks and finish the arthroplasty with release of tight ligaments

Use of “CPR” distance has proven clinical utility in stratifying risks of “steep cups” in MOM failures.[1, 4] The CPR indice has been defined as distance between point of intersection of the hip reaction force (Fig. 1: vector-R in contact patch) and closest point on the inner cup rim.[4] However, the CPR indice has limitations. It assumes that, (1) the hip load-vector (R) will be angled 10°-medial in all patients, (2) the contact patch will be same size in all patients, and (3) the contact patch will be invariant with increasing MOM diameter. In contrast it is known from retrieval studies that larger MOM bearings created much larger wear patches.[3] Furthermore, the size of cup wear-patches in MOM bearings can now be estimated with some certainty using simulator wear data.[2] Our objective was to develop an algorithm that would predict (i) contact-patch size for all cup designs and diameters, (ii) determine actual margin of safety (Fig. 1: MOS) for different laterally-inclined cups, and (iii) predict critical test angles for “steep” cup studies in hip simulators. The ‘CPR-distance’ (Fig. 1) is subtended by the CPA angle, but the true margin of safety is the distance from edge of wear patch to cup rim, indicated here by MOS angle. In this algorithm the wear-patch size (CAP angle) is a key parameter, as derived from MOM wear data (Fig. 2). The CAP angles decrease with increasing MOM diameter, as defined by strong linear trend (R=0.998). The key 2nd parameter is cup inclination angle that juxtaposes the wear-pattern to the cup rim (CCI). For hemispherical cups the critical inclination is given by CCI = 90 – CAP/2, where articulation angle ABA = 180o. The cup bearing-surface is typically reduced < 180o(sub-hemispherical profile, instrumentation groove, rim bevel, etc). These effects are grouped under ‘rim-detail’, as defined by RD = (180-ABA)/2 (Fig. 1). Thus critical inclination any cup is given by CCI = 90o – (CAP/2) – RD = (ABA – CAP)/2. The margin-of-safety (Fig. 1) is then represented by the equation MOS = 100 – (CIA + CAP/2 + RD). Applicability of the new algorithm can be visualized with a 48mm MOM (cup ABA=160o) run in a standard simulator test (Fig. 3). The algorithm predicts that with cup at 40o inclination there is good margin of safety (11.8o), representing a 5mm distance. This would become much reduced at CIA = 50o, while true edge-wear appears at the 60o test inclination (Fig. 3. EW = −8.2o). For clinical comparison with ‘CPR-distances’, the algorithm shows that positioning the wear patch 10o-medial (Figs. 1, 3) has margin of safety averaging 11.5 mm (MOS) less than was predicted by the CPR indice. While CPR has shown clinical utility, it is believed that compensating for actual size of cup wear-patterns provides a more realistic risk assessment for different MOM diameters in different cup positions. Thus the new algorithm permits accurate depiction of cup wear-patterns for use in both clinical and simulator studies

The August 2024 Foot & Ankle Roundup³⁶⁰ looks at: ESWT versus surgery for fifth metatarsal stress fractures; Minimally invasive surgery versus open fusion for hallux rigidus; Diabetes and infection risk in total ankle arthroplasty; Is proximal medial gastrocnemius recession useful for managing chronic plantar fasciitis?; Fuse the great toe in the young!; Conservative surgery for diabetic foot osteomyelitis; Mental health and outcome following foot and ankle surgery.

Introduction: In most of the reported series, scapular notching in inverse shoulder arthroplasty has been identified as a major problem. Therefore, a novel concept has been developed in order to minimize the incidence and the evolution (pathophysiology) of scapular notching. The current cohort study is now large enough to examine the results with special attention on notching. Methods: A dual peg design of the metaglene with CaP coating provides high primary and secondary stability. “Geometrical” notching is reduced by inferior (eccentric) fixation of the glenosphere on the metaglene, beveling of the medial part of the humeral inlay, and by the choice of three different sizes of the glenosphere (36, 39 and 42). “Biological” notching is addressed by inversion of the components: the epiphysis – as the mobile part – is metallic. Its contact to the scapula, should this occur, cannot lead to polyethylene wear. This study is a prospective multicentric study on Affinis Inverse and Affinis Fracture Inverse shoulder prosthesis (Mathys Ltd Bettlach, Switzerland), which is running in 7 European hospitals since December 2007. All cases but two (lost to follow-up) are included. Preoperative and all postoperative radiographs were reviewed. Notching has been graded 0 to 4, on a scale adapted after Sirveaux. Results: At submission deadline for the abstract, 163 cases were included. Grade 1 notching was detected in 8 cases (4.9%), and grade 2 notching in one. In those cases, notching developed early, but was not progressive over time. There were no cases of grade 3 or 4. In 17 cases, the X-rays were not assessable and therefore it was impossible to definitively rule out a possible grade 1 notching. None of the Affinis Fracture Inverse prostheses produced any notching. New bone apposition on the inferior aspect of the scapula was detected in 15 cases. We postulate this to be a metaplasia of the long head of the triceps due to local periosteal stimulation. Conclusions: The present design leads to a very low rate of scapular notching. Even in the 9 cases where notching was present, it appears that the epiphysis only created the space it needed, without any ongoing osteolytic process beyond this. Specific prosthetic design improves both quantity and quality of scapular notching

Introduction and Aims: I was presented with a Land-mine victim with closed fracture of right talus, compound injury to left lower limb, and defect in heelpad. Distal third of tibia and most of hindfoot were missing. Left foot neurovascularly intact and he was able to move his toes. Aim: reconstruct left distal tibia to enable full weight-bearing. Method: Lower leg debrided. LRS applied, using proximal ring with Sheffield clamp and two rings around foot. Corticotomy of proximal tibia. Bone transport, 10 days later. Heel debridement, to clear necrotic bone. Two months later transported bone was 2cm from ankle. Sepsis controlled. Distal tibia beveled, bone transport continued. Docking procedure performed. Ex-fix adjusted, attaining compression of hindfoot and midfoot. Distal tibia and foot transported 4cm, to correct disproportion. Osteoset used for bone growth. During the following two years, length discrepancy resolved, sepsis manageable. X-rays showed two cortices between proximal tibia and transported tibia. Fixator removed two months later. Received orthotic boot. Results: In September 2003 the patient came for follow-up. There was no evidence of sepsis in the leg. He was full weight-bearing using an orthotic shoe and rocker bottom sole. There was no pain. He had left the army and was now working as a builder in his country of origin and putting in a whole day’s work. The length of the transported segment is approximately 14cm. It is now fully consolidated and four cortices are visible on x-ray. The fusion of the distal tibia into the foot is solid and no pain is experienced from that. Conclusion: Big defects in the distal tibia can be managed with a straight rail reconstruction system, using unifocal bone transport with proximal corticotomy

Introduction and Objectives: Release of the A1 pulley in trigger finger can be done by an open method or by a percutaneous technique using an intramuscular needle. The percutaneous technique results in resolution of trigger finger. However, a higher recurrence rate has been reported in adults as compared to the conventional open technique. To our knowledge no one has shown the efficacy of the percutaneous technique for release of the A1 pulley in children. For this reason, we have decided to study the efficacy and safety of the procedure. Materials and Methods: Since November 2002, two senior surgeons from the paediatric orthopaedic unit have treated 10 patients with trigger finger using the percutaneous technique. Study subjects were not selected. Rather, the study included the first 10 cases of fingers with this condition that presented for medical consultation. In all cases, the operation consisted of two surgical stages. The first stage consisted of percutaneous cutting of the pulley using the bevel of an intramuscular needle. The second stage immediately following involved open examination of the pulley, tendon, and adjacent neurovascular structures. Results: In the first surgical stage (percutaneous surgery) we were able to resolve clinical locking or tendinous nodules in all cases. In the second surgical stage (surgical examination), we observed the following: incomplete release of the pulley in 70% of cases, one case of flexor tendon laceration, and one case of minor lacerations of the neurovascular bundle. The condition did not recur in any of the patients. Discussion and Conclusions: In our hands, percutaneous surgery provides less control over release of the pulley and less control over possible iatrogenic damage to adjacent structures and does not allow us to forgo the use of general anaesthesia

Purpose: Suture anchors used for reinserting soft tissue on bony structures have been studied with the purpose of evaluating hold in bone. There has not however been any work on the influence of the eye design on suture resistance. The purpose of this work was to examine this aspect of the question. Material and methods: The following anchors were tested: Statak 4 (Zimmer, Warsaw, IN, USA), Corkscrew 3.5, Fastak 2.4 (Arthrex, Naples, FL, USA), PeBA C 6.5 (OBL, Scottsdale, AZ, USA), Mitek GII 5Mitek, Norwood, MA, USA), Harpoon 2 (Arthrotek, Warsaw, IN? USA), Ultrafix (Linvatec, Largo, FL, USA), Vitis 3.5 AND 5 (Tornier, St Isnier, France). The following suture threads were used: Vicryl dec 5, Flexidene dec 5, PDS dec 4. Three types of tests were performed on an Instron 8500+. To study loading at thread rupture, a loop with a constant length was placed under traction in the axis of the anchor until thread rupture. Two measurement modalities were used. For the first, static tension was applied to increase the linear load at the rate of 1.25 mm/s. In the second, cyclic traction applied tension five times at a frequency of 1 Hz with 10N loading increments. To study thread weakening in relation to each anchor, we imposed a back and forth movement on the strand running through the eye using a sinusoidal 10 mm movement at a frequency of 0.03 Hz, one end of the thread being fixed and the other supporting a constant 20 N load. Each thread was tested in each anchor and each type of test was run three times. Results: Load at rupture of each thread was not affected significantly by the design of the anchor eyes. Rupture generally occurred at the knot level, sometimes at the eye (Harpoon, Fastak, Vitis) for the Flexidene dec 5 thread. Conversely, there were important differences in the thread weakness tests: a knitted thread such as Vicryl was much stronger than the two other threads tested, irrespective of the anchor. Furthermore, resistance for the dynamic test was very variable for the different anchors: 100±20 cycles for corkscrew 3.5 and 3±1 cycles for Vitis 3.5 with Vicryl or 6+/1 cycles for Harpoon 2 with Flexidene. Conclusion: The design and finishing of each eye had an effect on the resistance of thread moving through the eye. For anchors which weakened thread after a few back and forth movements, it can be assumed that simple knotting damages the thread to a point where early failure occurs at reinsertion. The best results were obtained when the anchor eye had a bevelled groove

Aims

Restoration of proximal medial femoral support is the keystone in the treatment of intertrochanteric fractures. None of the available implants are effective in constructing the medial femoral support. Medial sustainable nail (MSN-II) is a novel cephalomedullary nail designed for this. In this study, biomechanical difference between MSN-II and proximal femoral nail anti-rotation (PFNA-II) was compared to determine whether or not MSN-II can effectively reconstruct the medial femoral support.

Aims

The aim of this study was to establish the diagnostic accuracy of culture of joint aspirate with and without saline injection-reaspiration.

Objectives

We studied subchondral intraosseous pressure (IOP) in an animal model during loading, and with vascular occlusion. We explored bone compartmentalization by saline injection.