The purposes of this study were to define the range of laxity of the interosseous ligaments in cadaveric wrists and to determine whether this correlated with age, the morphology of the lunate, the scapholunate (SL) gap or the SL angle. We evaluated 83 fresh-frozen cadaveric wrists and recorded the SL gap and SL angle. Standard arthroscopy of the wrist was then performed and the grades of laxity of the scapholunate interosseous ligament (SLIL) and the lunotriquetral interosseous ligament (LTIL) and the morphology of the lunate were recorded. Arthroscopic evaluation of the SLIL revealed four (5%) grade I specimens, 28 (34%) grade II, 40 (48%) grade III and 11 (13%) grade IV. Evaluation of the LTIL showed 17 (20%) grade I specimens, 40 (48%) grade II, 28 (30%) grade III and one (1%) grade IV.

On both bivariate and multivariate analysis, the grade of both the SLIL and LTIL increased with age, but decreased with female gender. The grades of SLIL or LTIL did not correlate with the morphology of the lunate, the SL gap or the SL angle. The physiological range of laxity at the SL and lunotriquetral joints is wider than originally described. The intercarpal ligaments demonstrate an age-related progression of laxity of the SL and lunotriquetral joints. There is no correlation between the grades of laxity of the SLIL or LTIL and the morphology of the lunate, the SL gap or the SL grade. Based on our results, we believe that the Geissler classification has a role in describing intercarpal laxity, but if used alone it cannot adequately diagnose pathological instability.

We suggest a modified classification with a mechanism that may distinguish physiological laxity from pathological instability.

Conventional computer navigation systems using bone fixation have been validated in measuring anteroposterior (AP) translation of the tibia. Recent developments in non-invasive skin-mounted systems may allow quantification of AP laxity in the out-patient setting.

We tested cadaveric lower limbs (n=12) with a commercial image free navigation system using passive trackers secured by bone screws. We then tested a non-invasive fabric-strap system. The lower limb was secured at 10° intervals from 0° to 60° knee flexion and 100N of force applied perpendicular to the tibial tuberosity using a secured dynamometer. Repeatability coefficient was calculated both to reflect precision within each system, and demonstrate agreement between the two systems at each flexion interval. An acceptable repeatability coefficient of ≤3 mm was set based on diagnostic criteria for ACL insufficiency when using other mechanical devices to measure AP tibial translation.

Precision within the individual invasive and non-invasive systems measuring AP translation of the tibia was acceptable throughout the range of flexion tested (repeatability coefficient ≤1.6 mm). Agreement between the two systems was acceptable when measuring AP laxity between full extension and 40° knee flexion (repeatability coefficient ≤2.1 mm). Beyond 40° of flexion, agreement between the systems was unacceptable (repeatability coefficient >3 mm).

These results indicate that from full knee extension to 40° flexion, non-invasive navigation-based quantification of AP tibial translation is as accurate as the standard invasive system, particularly in the clinically and functionally important range of 20° to 30° knee flexion. This could be useful in diagnosis and post-operative follow-up of ACL pathology.

A cavovarus foot deformity was simulated in cadaver specimens by inserting metallic wedges of 15° and 30° dorsally into the first tarsometatarsal joint. Sensors in the ankle joint recorded static tibiotalar pressure distribution at physiological load. The peak pressure increased significantly from neutral alignment to the 30° cavus deformity, and the centre of force migrated medially. The anterior migration of the centre of force was significant for both the 15° (repeated measures analysis of variance (ANOVA), p = 0.021) and the 30° (repeated measures ANOVA, p = 0.007) cavus deformity. Differences in ligament laxity did not influence the peak pressure. These findings support the hypothesis that the cavovarus foot deformity causes an increase in anteromedial ankle joint pressure leading to anteromedial arthrosis in the long term, even in the absence of lateral hindfoot instability

Summary. Increased lateral ulnotrochlear joint space due to improper sizing in radial head arthroplasty may result in medial collateral ligament laxity, leading to increased osteophytes and arthritis. Introduction. Radial head (RH) arthroplasty is a common response to comminuted RH fractures. Typical complications include improper sizing, leading to changes in joint kinematics. Evidence of these changes should be visible through fluoroscopic images of affected joints. The two examined changes in this study are the ulnar deviation from distal radial translation (DRT), and the widening of the lateral ulnotrochlear joint space (LUT). Methods. Eight fresh-frozen cadaver arms were used. Initial images were taken with the native RH intact. The Kocher approach exposed the radiocapitellar (RC) joint capsule, preserving all ligaments. The RH was excised and Integra Katalyst CoCr (Plainsboro, NJ) telescoping, bipolar, RH inserted. Images were taken with implant sizings: −2mm, 0mm, +2mm, and +4mm, (from native) using 1mm washers preventing implant bipolarity. AP fluoroscopic images of the elbow were taken at full extension. Joint spaces were measured using image analysis, normalised using known radio-opaque lengths. Four LUT measurements were made, two medially and two laterally, and normalised by measuring the RH implant diameter. Each set (medial and lateral) were averaged together and the resulting value used for all comparisons. Images of distal ulnar deviation at the wrist were taken with the wrist in supination, the hand rotated medially. Measurements were from the distal medial radial tip to the distal lateral ulnar tip. Images were normalised by placing a scalpel in the same plane as measurement. Results. DRT values were difference paired for each arm using the 0mm values as baselines. One-way ANOVA of the paired values resulted in significant DT with sizing increases (p<0.01). The quotient of DRT and sizing determined comparative impact with the LUT increase. LUT joint gap measurements were percentage paired, with natives as the baseline, and One-way ANOVA used. A significant increase in LUT spacing occurred with increased sizings (p<0.01). Discussion. Increased ulnar deviation can increase loading on the TFCC, leading to possible TFCC tear, increased articular cartilage wear from carpal misalignment, and eventual wrist instability and arthritis. The percentage of the radial lengthening is represented in DRT. Over-sizing results in small percentages of increased radial length at the wrist, therefore deviation at the elbow must take place, either through rotation of the ulna, or translation. Either of these can be seen through LUT measurements. Previous measurements of the LUT space were made by Frank (2009), with similar results. This was being used as a method of improper sizing detection using radiographs. The percentage difference of LUT space for corresponding sizing: there is an increase in LUT space for every sizing; maybe due to loosening of the soft tissue from arthroplasty. Increased LUT space indicates the medial translation of proximal ulna. This can result in Medial Collateral Ligament laxity, leading to increased osteophytes, and arthritis. Use and non-treatment, can create a chronic, painful, disorder

The function of the knee joint is to allow for locomotion and is comprised of various bodily structures including the four major ligaments; medial collateral ligament (MCL), lateral collateral ligament (LCL), anterior cruciate ligament (ACL) and posterior cruciate ligament (PCL). The primary function of the ligaments are to provide stability to the joint. The knee is prone to injury as a result of osteoarthritis as well as ligamentous and meniscal lesions. Furthermore, compromised joint integrity due to ligamentous injury may be a result of direct and indirect trauma, illness, occupational hazard as well as lifestyle. A device capable of non-invasively determining the condition of the ligaments in the knee joint would be a useful tool to assist the clinician in making a more informed diagnosis and prognosis of the injury. Furthermore, the device would potentially reduce the probability of a misdiagnosis, timely diagnosis and avoidable surgeries. The existing Laxmeter prototype (UK IPN: GB2520046) is a Stress Radiography Device currently limited to measuring the laxity of the MCL and LCL at multiple fixed degrees of knee flexion. Laxity refers to the measure of a ligament's elasticity and stiffness i.e. the condition of the ligament, by applying a known load (200N) to various aspects of the proximal tibial and thereby inducing tibial translation. The extent of translation would indicate the condition of the ligament. The Laxmeter does not feature a load applying component as of yet, however, it allows for the patient to be in the most comfortable and ideal position during radiographic laxity measurement testing. The entire structure is radiolucent and attempts to address the limitations of existing laxity measurement devices, which includes: excessive radiation exposure to the radiographic assistant, little consideration for patient ergonomics and restrictions to cruciate or collateral ligament laxity measurements. The study focusses on further developing and modifying the Laxmeter to allow for: the laxity measurement of all four major ligaments of the knee joint, foldability for improved storage and increased structural integrity. Additionally, a load applicator has been designed as an add-on to the system thereby making the Laxmeter a complete Stress Radiography Device. Various materials including Nylon, Polycarbonate, Ultra High Molecular Weight Polyethylene (UHMWPE) – PE 1000, and Acetal/ POM were tested, using the Low Dose X-ray (Lodox) scanner, to determine their radiolucency. All materials were found to be radiolucent enough for the manufacture of the Laxmeter structure as well as the load applicator in order to identify and measure the translation of the tibia with respect to the stationary femur. The Laxmeter allows for the measurement of the laxity of the MCL and LCL at multiple fixed degrees of flexion by providing the ideal patient position for testing. The next iteration of the device will present an affordable and complete Stress Radiography Device capable of measuring the laxity of all four major ligaments of the knee joint at multiple fixed degrees of flexion. Future work would include aesthetic considerations as well as an investigation into carbon-fibre-reinforced plastics

Summary. The effect of the geometry of the tibial polyethylene insert was investigated in vivo loaded conditions. Introduction. The decision to choose CR (cruciate retaining) insert or CS (condylar stabilised) insert during TKA remains a controversial issue. Triathlon CS type has a condylar stabilised insert with an increased anterior lip that can be used in cases where the PCL is sacrificed but a PS insert is not used. The difference of the knee kinematics between CR and CS insert remains unclear. This study measured knee kinematics of deep knee flexion under load in two insert designs using 2D/3D registration technique. Patients and Methods. We investigated the in vivo knee kinematics of 20 knees (18 patients) implanted with Triathlon CR components (Stryker Orthopedics, Mahwah, NJ), 10 knees in the CR insert with retaining PCL, and 10 knees in the CS insert with sacrificing PCL. All TKAs were judged clinically successful (Knee Society knee scores >90), with no ligamentous laxity or pain. Mean patient age at the time of operation was 72±12 years in CR and 69±9 years in CS. Mean period between operation and surveillance was 20±11 months in CR and 11±5 months in CS. Under fluoroscopic surveillance, each patient did a wight-bearing deep knee bending motion. Femorotibial motion including tibial polyethylene insert was analyzed using 2D/3D registration technique, which uses computer-assisted design (CAD) models to reproduce the spatial position of the femoral, tibial components from single-view fluoroscopic images. We evaluated the range of motion, femoral axial rotation, and antero-posterior (AP) translation of the nearest points. Results. The average range of motion between femoral component and tibial component was 113.3±22.3° in CR and 107.4±13.1° in CS. The amount of femoral axial rotation from 0° to 110° flexion was 8.6±2.9° in CR insert, and 7.6±2.6° in CS insert, respectively. No significant difference was observed in the amount of femoral external rotation (p=0.71). In CR insert, the medial contact point moved 4.0±2.9mm anteriorly from 0° to 100° flexion. The lateral contact point moved 2.0±1.1mm anteriorly from 60° to 90° flexion. In CS insert, the medial contact point moved 6.4±2.1mm anteriorly from 20° to 100° flexion. The lateral contact point moved 1.9±1.7mm anteriorly from 50° to 110° flexion. There was significant differences were observed in the amount of medial anterior translation between the two insert (medial; p=0.04, lateral; p=0.94). Discussion and Conclusion. Triathlon CR and CS insert had a similar kinematics pattern. However, there was significant differences were observed in the amount of medial anterior translation between the two insert. These results indicated that the increased anterior lip could not control medial anterior sliding. The posterior part of the two insert were almost same, so the kinematics are similar

Objectives

Ligaments which heal spontaneously have a healing process that is similar to skin wound healing. Menopause impairs skin wound healing and may likewise impair ligament healing. Our purpose in this study was to investigate the effect of surgical menopause on ligament healing in a rabbit medial collateral ligament model.

We evaluated two reconstruction techniques for a simulated posterolateral corner injury on ten pairs of cadaver knees. Specimens were mounted at 30° and 90° of knee flexion to record external rotation and varus movement. Instability was created by transversely sectioning the lateral collateral ligament at its midpoint and the popliteus tendon was released at the lateral femoral condyle. The left knee was randomly assigned for reconstruction using either a combined or fibula-based treatment with the right knee receiving the other. After sectioning, laxity increased in all the specimens. Each technique restored external rotatory and varus stability at both flexion angles to levels similar to the intact condition. For the fibula-based reconstruction method, varus laxity at 30° of knee flexion did not differ from the intact state, but was significantly less than after the combined method.

Both the fibula-based and combined posterolateral reconstruction techniques are equally effective in restoring stability following the simulated injury.