Abstract. Objectives. Unicompartmental and total knee arthroplasty (UKA and TKA) are successful treatments for osteoarthritis, but monolithic implants disrupt the natural homeostasis of bone which leads to bone loss over time. This can cause problems if the implant needs to be revised. This study aimed to demonstrate that tibial implants made from titanium lattice could replace the tibial condyle surface while minimising disruption of the bone's natural mechanical loading environment. A secondary aim was to determine whether implants perform better if they replicate more closely bone's mechanical modulus, anisotropy and spatial heterogeneity. This study was conducted in a human cadaveric model. Methods. In a cadaveric model, UKA and TKA procedures were performed on 8 fresh-frozen knee specimens by a board-certified consultant orthopaedic surgeon, using tibial implants made from conventional monolithic material and titanium lattice structures. Stress at the bone-implant interfaces was measured with pressure film and compared to the native knee. Results. Titanium lattice implants were able to restore the mechanical environment seen in the native tibia for both UKA and TKA designs. Maximum stress at the bone-implant interface ranged from 1.2–3.3MPa compared to 1.3–2.7MPa for the native tibia. The conventional UKA and TKA implants reduced the maximum stress in the bone by a factor of 10 and 9.7 respectively. The conventional UKA and TKA implants caused 71% and 77% of bone surface area to be underloaded compared to the native tibia. Conclusions. Titanium lattice implants can maintain the natural mechanical loading in the proximal tibia after UKA and TKA. This may help maintain normal bone homeostasis throughout the life of the implant. These encouraging data indicate normal bone homeostasis can be maintained after arthroplasty using manufacturing methods already in widespread use. This would maintain bone quality throughout the life of the implant and alleviate complications at revision surgery

µCT images are commonly analysed to assess changes in bone density and architecture in preclinical murine models. Several platforms provide automated analysis of bone architecture parameters from volumetric regions of interest (ROI). However, segmentation of the regions of subchondral bone to create the volumetric ROIs remains a manual and time-consuming task. This study aimed to develop and evaluate automated pipelines for trabecular bone architecture analysis of mouse proximal tibia subchondral bone. A segmented dataset involving 62 knees (healthy and arthritic) from 10-week male C57BL/6 mice were used to train a U-Net type architecture, with µCT scans (downsampled) input that output segmentation and bone volume density (BV/TV) of the subchondral trabecular bone. Segmentations were upsampled and used in tandem with the original scans (10µ) as input for architecture analysis along with the thresholded trabecular bone. The analysis considered the manually and U-Net segmented ROIs using two available pipelines: the ITKBoneMorphometry library and CTan (SKYSCAN). The analyses included: bone volume (BV), total volume (TV), BV/TV, trabecular number (TbN), trabecular thickness (TbTh), trabecular separation (TbSp), and bone surface density (BSBV). There was good agreement for bone measures between the manual and U-Net pipelines utilizing ITK (R=0.88-0.98) and CTan (R=0.91-0.98). ITK and CTan showed good agreement for BV, TV, BV/TV, TbTh and BSBV (R=0.9-0.98). However, a limited agreement was seen between TbN (R=0.73) and TbSb (R=0.59) due to methodological differences in how spacing is evaluated. This U-Net/ITK pipeline seamlessly automated both segmentation and quantification of the proximal tibia subchondral bone. This automated pipeline allows the analysis of large volumes of data, and its open-source nature may enable the standardization of stereologic analysis of trabecular bone across different research groups

Abstract. Approximately 20% of primary and revision Total Knee Arthroplasty (TKA) patients require multiple revisions, which are associated with poor survivorship, with worsening outcomes for subsequent revisions. For revision surgery, either endoprosthetic replacements or metaphyseal sleeves can be used for the repair, however, in cases of severe defects that are deemed “too severe” for reconstruction, endoprosthetic replacement of the affected area is recommended. However, endoprosthetic replacements have been associated with high complication rates (high incidence rates of prosthetic joint infection), while metaphyseal sleeves have a more acceptable complication profile and are therefore preferred. Despite this, no guidance exists as to the maximal limit of bone loss, which is acceptable for the use of metaphyseal sleeves to ensure sufficient axial and rotational stability. Therefore, this study assessed the effect of increasing bone loss on the primary stability of the metaphyseal sleeve in the proximal tibia to determine the maximal bone loss that retains axial and rotational stability comparable to a no defect control. Methods. to determine the pattern of bone loss and the average defect size that corresponds to the clinically defined defect sizes of small, medium and large defects, a series of pre-operative x-rays of patients with who underwent revision TKA were retrospectively analysed. Ten tibiae sawbones were used for the experiment. To prepare the bones, the joint surface was resected the typical resection depth required during a primary TKA (10mm). Each tibia was secured distally in a metal pot with perpendicular screws to ensure rotational and axial fixation to the testing machine. Based on X-ray findings, a fine guide wire was placed 5mm below the cut joint surface in the most medial region of the plateau. Core drills (15mm, 25mm and 35mm) corresponding to small, medium and large defects were passed over the guide wire allowing to act at the centre point, before the bone defect was created. The test was carried out on a control specimen with no defect, and subsequently on a Sawbone with a small, medium or large defect. Sleeves were inserted using the published operative technique, by trained individual using standard instruments supplied by the manufacturers. Standard axial pull-out (0 – 10mm) force and torque (0 – 30°) tests were carried out, recording the force (N) vs. displacement (mm) curves. Results. A circular defect pattern was identified across all defects, with the centre of the defect located 5mm below the medial tibial base plate, and as medial as possible. Unlike with large defects, small and medium sized defects reduced the pull-out force and torque at the bone-implant interface, however, these reductions were not statistically significant when compared to no bony defect. Conclusions. This experimental study demonstrated that up to 35mm radial defects may be an acceptable “critical limit” for bone loss below which metaphyseal sleeve use may still be appropriate. Further clinical assessment may help to confirm the findings of this experimental study. This study is the first in the literature to aim to quantify “critical bone loss” limit in the tibia for revision knee arthroplasty. Declaration of Interest. (a) fully declare any financial or other potential conflict of interest

Purpose. Addressing posterior tibial plateau fractures is increasingly recognized as an important prognostic factor for functional outcome. The treatment of posterior tibial plateau fractures is rather demanding and the implants are still standard, off-the-shelf implants. This emphasizes the need for a more thorough morphological study of the posterior tibial plateau, in order to treat these posterior fractures more adequately. We aimed to demonstrate anatomical variations of the tibia in order to develop better implants. Method. After approval of the ethical committee 22 historically available CT scans of intact left tibia”s were segmented using Mimics (Materialise, Belgium). In order to perform principal component analysis, corresponding meshes are necessary. Mesh correspondence was achieved by deforming one selected source tibia to every other target tibia, through non rigid registration. The non-rigid registration algorithm was based on the algorithm described by Amberg et al (ref). After performing the non-rigid registration, principal component analysis was performed in Matlab (Mathworks, USA). Results. The first 3 components account for 98,1% of the anatomical shape variation of the tibia. The first principal component accounts for 95,4, the second accounts for 1,6% and the third component accounts for the remaining 1,1% of variation. In the first principal component the most marked variation was the length and the shaft width. Shorter tibia”s have a steeper and more angled posterior medial and lateral plateau as where longer tibia”s have a more rounded posterior tibia plateau. On the distal end, the tip of the medial malleolus is more prominent in shorter tibia”s than in longer tibia”s. The orientation of the tibiofibular joint is directed more posteriorly in larger tibias where it is orientated more laterally in smaller tibia”s. The slope of the medial and lateral tibia plateau is not related to the length or width of the plateau. The second principal component shows a relationship between a valgus shaped tibia shaft and its relation to a relatively smaller medial plateau”s compared with straight tibia”s of the same length. Valgus shaped, small tibia shafts have more posteriorly tilted lateral plateau”s compared with straight, broad shafted tibias. The third principal component shows that an angular shaped posterior tibia plateau is related to a more increased anterior bowing. The increase in the posterior tilt is mostly marked in the medial tibia plateau. Conclusion. The majority of tibia shape variations is directly related to the length of the shaft. The clinically known varus and valgus deformations represent only a small percentage of the total variation. Nevertheless, their variation within the second component is large and has a direct relation to the morphology of the tibia plateau. This data coud furthermore be used to improve implant design

Intro. Calcium sulphate (CS) is a recent alternative for antibiotic elution in infected bones and joints. The purpose of this study is to evaluate the use of antibiotic impregnated calcium sulphate (AICS) beads in the management of infected tibia and femur, with regards to patient outcomes and complication rates (including reinfection rate, remission rate and union rate). Methods. Searches of AMED, CINAHL, EMBASE, EMCARE, Medline, PubMed and Google Scholar were conducted in June 2020, with the mesh terms: “Calcium sulphate beads” or “Calcium sulfate beads” or “antibiotic beads” or “Stimulan” AND “Bone infection” or “Osteomyelitis” or “Debridement” AND “Tibia” or “Femur”. Risk of bias was assessed using the Risk of Bias in Non-randomised Studies of interventions (ROBINS-i) tool, and quality assessed via the Grading of Recommendations, Assessment, Development and Evaluation (GRADE) criteria. Results. Out of 105 relevant papers, 11 met the inclusion criteria for data extraction. Total infection recurrence rate was 6.8% (range 3.2 – 11.9%, n = 295), which was significantly lower (p < 0.001) than that of polymethylmethacrylate (PMMA; 19.6%, n = 163). Complication rates varied. The main issue regarding AICS use was wound drainage (7.9 – 33.3%), which was considerably higher in studies involving treatment of the tibia only. Studies using PMMA did not experience this issue, but there were a few incidences of superficial pin tract infection following surgery. Conclusions. AICS was consistently effective at infection eradication, despite variation in causative organism and location of bead placement. Additionally, PMMA has many inconvenient properties. AICS is therefore an attractive alternative as an adjunct in treatment of infected tibia and femur. Wound drainage rate varied and was higher in studies regarding tibial cases alone

Introduction and Objective. The geometry of the proximal tibia and distal femur is intimately linked with the biomechanics of the knee and it is to be considered in total knee arthroplasty (TKA) component positioning. The aim of the present study was to evaluate the proximal tibial torsion in relation to the flexion-extension axis of the knee in healthy and pathological cohort affected by knee osteoarthritis (OA). Materials and Methods. We retrospectively analyzed computed tomography scans of OA knee of 59 patients prior to TKA and non-arthritic knee of 39 patients as control. Posterior condylar angle (PCA), femoral tibial torsion (TEAs-PTC and TEAs-PTT), proximal tibial torsion (PTC-PTT and PCAx-PTC) and distance between tibial tuberosity and the trochlear groove (TT-TG) were measured. Results. No differences were found for gender, age, TG-TT and PCAn angles. Statistically significant differences were found for all the other angles considered. Significant relation was found between Tibial Torsion and TEA-PTT angles, between PCAx-PTC and TEA-PTC, between TEA-PTT and TEA-PTC and between PCAx-PTC and TEA-PTT. All measures, except TG-TT and PCAn angles, showed high validity (AUC > 75%) in detecting OA, with TEA-PTT displaying the highest validity with an AUC of 94.38%. Conclusions. This is the first study to find significant differences in terms of proximal tibia geometry and anatomy between non arthritic and OA knees. It is conceivable that such anatomy could be implicated in the development of OA. Based on our data, the TEAs is a valid reference for correct positioning of tibial component in TKA. Indeed, setting the tibial component parallel to TEAs makes the prosthetic knee more similar to the native non-arthritic knee

Abstract. Introduction. Ankle arthritis is estimated to affect approximately 72 million people worldwide. Treatment options include fusion and total ankle replacement (TAR). Clinical performance of TAR is not as successful as other joint replacement and failure is poorly understood. Finite element analysis offers a method to assess the strain in bone implanted with a TAR. Higher strain has been associated with microfracture and alters the bone-implant interface. The aim of this study was to explore the influence of implant fixation on strain within the tibia when implanted with a TAR through subject-specific models. Methods. Five cadaveric ankles were scanned using a Scanco Xtreme CT. The Tibia and Talus were segmented from each scan and virtually implanted with a Zenith TAR (Corin, UK) according to published surgical technique. Patient specific models were created and run at five different positions of the gait cycle corresponding to peak load and flexion values identified from literature. Bone material properties were derived from CT greyscale values and all parts were meshed with linear tetrahedral elements. The implant-bone interface was adjusted to fully-fixed or frictionless contact, representing different levels of fixation post-surgery. Strain distributions around the tibial bone fixation were measured. Results. Initial results showed clear differences in strain distributions both between different ankle specimens and fixation levels, with highest strain occurring within the bone at the tip of the tibial stem. Frictionless contact gave higher strain outputs than fully-fixed for all specimens with a range 0.12–0.3% and 0.07%–0.13% respectively. Conclusions. In all specimens, strain was higher in the frictionless contact, which may be considered representative of no bony ingrowth, highlighting fixation may be a critical factor in TAR failure. Differences observed between specimens highlights that TAR may not be a suitable intervention for all patients, due to variation in bone quality and anatomy. Declaration of Interest. (b) declare that there is no conflict of interest that could be perceived as prejudicing the impartiality of the research reported:I declare that there is no conflict of interest that could be perceived as prejudicing the impartiality of the research project

Objectives. This study aims to evaluate if micro-CT can work as a method for the 3D assessment and analysis of cancellous bone by comparing micro-CT with undecalcified histological sections in OVX rats. Methods. The mandible and tibia of sham, ovariectomised (OVX) and zoledronate-injected ovariectomised (OVX-ZOL) rats were assessed morphometrically. Specimens were scanned by micro-CT. Undecalcified histological sections were manufactured from the specimen scanned by micro-CT and stained with haematoxylin and eosin. Bivariate linear regressions and one-way analysis of variance were undertaken for statistics using SPSS 16.0.1 software. Results. There were highly significant correlations between undecalcified histological sections and micro-CT for all parameters (bone volume density (BV/TV), bone surface density (BS/BV), trabecular thickness (Tb.Th), trabecular number (Tb.N), and trabecular separation (Tb.Sp))in the mandible and tibia. Bone histomorphometric parameters analysed by both methods exhibited significant differences among sham, OVX, and OVX-ZOL groups. There were significant correlations between mandible and tibia in BV/TV, BS/BV, and Tb.Sp. Conclusions. Micro-CT is a complementary tool to histological sections in basic research that could improve our understanding of bone histomorphometry. The mandible can be used as an effective site to assess bone morphometry of OVX or metabolic bone disease rat models. Cite this article: H. Liu, W. Li, Y. S. Liu, Y. S. Zhou. Bone micro-architectural analysis of mandible and tibia in ovariectomised rats: A quantitative structural comparison between undecalcified histological sections and micro-CT. Bone Joint Res 2016;5:253–262

Introduction and Objective. Management of gap non-union of the tibia, the major weight bearing bone of the leg remains controversial. The different internal fixation techniques are often weighed down by relatively high complication rates that include fractures which fail to heal (non-union). Minimally invasive techniques with ring fixators and bone transport (distraction osteogenesis) have come into picture as an alternative allowing alignment and stabilization, avoiding a graduated approach. This study was focused on fractures that result in a gap non-union of > 6 cm. Ilizarov technique was employed for management of such non-unions in this case series. The Ilizarov apparatus consists of rings, rods and kirschner wires that encloses the limb as a cylinder and uses kirschner wires to create tension allowing early weight bearing and stimulating bone growth. Ilizarov technique works on the principle of distraction osteogenesis, that is, pulling apart of bone to stimulate new bone growth. Usually, 4–5 rings are used in the setup depending on fracture site and pattern for stable fixation. In this study, we demonstrate effective bone transport and formation of gap non-union more than 6 cm in 10 patients using only 3 rings construct Ilizarov apparatus. Materials and Methods. This case study was conducted at Dr. D. Y. Patil Medical Hospital, Navi Mumbai, Maharashtra, India. The study involved 10 patients with a non-union or gap > 6 cm after tibial fracture. 3 rings were used in the setup for the treatment of all the patients. Wires were passed percutaneously through the bone using a drill and the projecting ends of the wires were attached to the metal rings and tensioned to increase stability. The outcome of the study was measured using the Oxford Knee scoring system, Functional Mobility Scale, the American Foot and Ankle Score and Visual Analog Scale. Further, follow up of patients was done upto 2 years. Results. All the patients demonstrated good fixation as was assessed clinically and radiologically. 9 patients had a clinical score of > 65 which implied fair to excellent clinical rating. The patients showed good range of motion and were highly satisfied with the treatment as measured by different scoring parameters. Conclusions. In this case study, we demonstrate that the Ilizarov technique using 3 rings is equally effective in treating non-unions > 6 cm as when using 4–5 rings. Obtaining good clinical outcome and low complication rate in all 10 patients shows that this modified technique can be employed for patients with such difficulties in the future

Abstract. Objectives. This study aids the control of remodelling and strain response in bone; providing a quantified map of apparent modulus and strength in the proximal tibia in 3 anatomically relevant directions in terms of apparent density and factor groups. Methods. 7 fresh-frozen cadaveric specimens were quantified computed tomography (qCT) scanned, segmented and packed with 3 layers of 9mm side length cubic cores aligned to anatomical mechanical axes. Cores were removed with printed custom cutting and their densities found from qCT. Cores (n = 195) were quasi-statically compression tested. Modulus was estimated from a load cycle hysteresis loop, between 40% and 20% of yield stress. Sequential testing order in 3 orthogonal directions was randomised. Group differences were identified via an analysis of variance for the factors density, age, gender, testing order, subchondral depth, condyle and sub-meniscal location. Regression models were fit for significant factor sub-groups, predicting properties from density. Results. Axial modulus was 1.5 times greater than the two transverse directions (p<0.001), between which no difference was found. For all test directions, differences were quantified for density and modulus across all subchondral depths (p<0.001). 60% of transverse modulus variation was explained by density within subgroups for each subchondral depth. Medial axial modulus was 1.3 times greater than the lateral side (p = 0.011). Lateral axial modulus halved over a 25mm depth whilst remaining constant for the medial side. Density explained 75% of variation when grouped by subchondral depth and condyle. Yield strength was well predicted across all test directions, with density explaining 81% of axial strength variation and no differences over subchondral depth. Conclusions. The quantification of bone multiaxial modulus based on condyle and subchondral depth has been shown for the first time in a clinically viable protocol using conventional CT. Accounting for spatial variation improves upon literature property prediction models. Declaration of Interest. (b) declare that there is no conflict of interest that could be perceived as prejudicing the impartiality of the research reported:I declare that there is no conflict of interest that could be perceived as prejudicing the impartiality of the research project

Although osteoporosis reduces overall bone mass causing bone fragility, our recent studies have shown that bone tissue composition is altered at the microscopic level, which is undetectable by conventional diagnostic techniques (DEXA) but may contribute to bone fracture. However, the time sequence of changes in bone microarchitecture, mechanical environment and mineral distribution are not yet fully understood. This study quantified the longitudinal effects of estrogen deficiency on the trabecular microarchitecture and mineral distribution in the tibia of Female Wistar rats (6 months) that underwent ovariectomy (OVX, n=10) or sham surgery (SHAM, n=10). Weekly micro-CT scans of the proximal tibia were conducted at 15µm resolution for the first month of estrogen deficiency. Morphometric analysis was conducted to characterise the trabecular bone microarchitecture. The bone mineral composition was characterised with analysis of bone mineral density distributions (BMDD). There was significantly reduced trabecular bone volume fraction at 2 weeks in OVX rats compared to controls (p<0.01). There was no difference in mineral distribution between the OVX and control animals. This study provides the first evidence in uncovering the temporal nature of changes in bone microarchitecture and mineral distribution, showing that structure changes before composition. In-vivo µCT analysis for later time points (week 8, 14 and 34) is ongoing to comprehensively examine these longitudinal compositional changes. Moreover, we are conducting ex-vivo mechanical analysis (nanoindentation), and together these will uncover the time-sequence and respective contribution of changes in bone mass and composition to the integrity of the bone tissue at these stages of estrogen deficiency

The treatment of fractures of the proximal tibia is complex and makes great demands on the implants used. Our study aimed to identify what levels of primary stability could be achieved with various forms of osteosynthesis in the treatment of diaphyseal fractures of the proximal tibia. Pairs of human tibiae were investigated. An unstable fracture was simulated by creating a defect at the metaphyseal-diaphyseal junction. Six implants were tested in a uniaxial testing device (Instron) using the quasi-static and displacement-controlled modes and the force-displacement curve was recorded. The movements of each fragment and of the implant were recorded video-optically (MacReflex, Qualysis). Axial deviations were evaluated at 300 N. The results show that the nailing systems tolerated the highest forces. The lowest axial deviations in varus and valgus were also found for the nailing systems; the highest axial deviations were recorded for the buttress plate and the less invasive stabilising system (LISS). In terms of rotational displacement the LISS was better than the buttress plate. In summary, it was found that higher loads were better tolerated by centrally placed load carriers than by eccentrically placed ones. In the case of the latter, it appears advantageous to use additive procedures for medial buttressing in the early phase

Summary Statement. Tibia plateau split fracture fixation with two cancellous screws is particularly suitable for non-osteoporotic bone, whereas four cortical lag screws provide a comparable compression in both non-osteoporotic and osteoporotic bone. Angle-stable locking plates maintain the preliminary compression applied by a reduction clamp. Introduction. Interfragmentary compression in tibia plateau split fracture fixation is necessary to maintain anatomical reduction and avoid post-traumatic widening of the plateau. However, its amount depends on the applied fixation technique. The aim of the current study was to quantify the interfragmentary compression generated by a reduction clamp with subsequent angle-stable locking plate fixation in an osteoporotic and non-osteoporotic synthetic human bone model in comparison to cancellous or cortical lag screw fixation. Methods. Adult synthetic human tibiae with hard or soft cancellous bone were osteotomised at the lateral tibia plateau creating a split fracture (AO type 41-B1) and fixed with either two 6.5 mm cancellous, four 3.5 mm cortical lag screws or 3.5 mm LCP proximal lateral tibia plate, preliminary compressed by a reduction clamp (n = 5 per group). Interfragmentary compression was measured by a pressure sensor film after instrumentation. One-way analysis of variance (ANOVA) with Bonferroni post hoc correction was performed for statistical analysis (p < 0.05). Results. Applying a reduction clamp, interfragmentary compression was 0.6 MPa ± 0.1 in non-osteoporotic and osteoporotic bone. The locking plate was able to maintain the compression (0.5 MPa ± 0.1) in non-osteoporotic and osteoporotic bone, but it was significantly lower compared to four cortical lag screws (non-osteoporotic p = 0.01; osteoporotic p = 0.03). Comparing four 3.5 mm cortical lag screws, compression was not significantly different between the non-osteoporotic (1.7 MPa ± 0.7) and osteoporotic bone (1.4 MPa ± 0.5). Two 6.5 mm cancellous lag screws achieved significantly higher compression in non-osteoporotic (2.1 MPa ± 0.6) compared to osteoporotic (0.8 MPa ± 0.2, p = 0.01) bone. Conclusion. Preliminary compression applied by a reduction clamp was maintained by angle-stable locking plates. The two 6.5 mm cancellous screw technique would especially be appropriate for young human non-osteoporotic bone, whereas the four 3.5 mm cortical screw configuration could also be applied in osteoporotic bone

Summary Statement. The implantation of scaffold-free CTE from suspension culture into growth-plate defects resulted in a significant reduction in growth arrest of the rabbit tibia. Introduction. In childhood and adolescence, the growth plate injury can cause partial premature arrest of growth plate, which can make problems such as leg length discrepancy and angular deformity. Bone bridge resection and variable implantation materials such as fat, bone wax, silastic and craniopalst has been investigated. However, those procedures may show limitations including the control of bone growth and long term safety of implant materials in vivo. As an alternative, homogeneous or heterogeneous cartilage cells and stem cell transplants have been tried. In this method, scaffold for cell transplantation is needed. But, so far the most suitable scaffold has not been established. Recently, some authors generated a cartilage tissue equivalent (CTE) using a suspension culture with biophysical properties similar to native hyaline cartilage. Therefore we are able to transplant the CTE without scaffold to the physeal defect. The purpose of this study was to investigated the effects of a transplantation of a vitro-generated scaffold-free tissue-engineered cartilage tissue equivalent (CTE) using a suspension chondrocyte culture in a rabbit growth arrest model. Material and Method. Cartilage tissue equivalent culture. The CTE was generated by the suspension culture of chondrocytes (2 × 10. 7. /well/1 mL) which was isolated from articular cartilage of 5 weeks New Zealand white rabbit on a 24-well plate (2.4 cm. 2. /well) treated with poly HEMA (nunc, Roskide, Denmark) for up to 8 and 16 weeks. (2)Partial growth arrest animal model. An experimental model for growth arrest was created by excising the growth plate at the proximal medial side of tibia with the 4 mm in diameter and 4 mm in depth from 6-week-old New Zealand white rabbits. Two experimental groups were set to evaluate CTE implantation; group I, no implantation as controls; group II, implantation of CTE. (3) Evaluation of effect of the transplantation of CTE. Serial plain radiographs were performed at one week. The medial proximal tibial angle (MPTA) was measured for assessing the degree of angular deformity. Histologic examination using HE stain, Alcian bule and immunohistochemistry was done at 4 and 8 weeks after surgery. Results. Radiographic results: In group I, all damaged growth plates were arrested and angular deformities appeared 4 weeks later. In groups II, angular deformities were much less than in the control group. Histologic result: In group I, bone bridge formation was shown at the damaged growth plate at 4 weeks after surgery. In group II, regeneration of growth plates was recognised at 4 and 8 week after surgery. However, the thickness of regenerated growth plate at 8 weeks specimen was thinner than that of 4 weeks specimen. Discussion and Conclusion. The implantation of scaffold-free CTE from suspension culture into growth-plate defects resulted in a significant reduction in growth arrest of the rabbit tibia

Due to the increasing life expectancy the incidence of gonarthrosis, the degeneration of articular cartilage and bone in the knee joint, is increasing worldwide. Although the success rate of knee arthroplasties is high, complications like the loosening of the implant necessitate subsequent treatments. Moreover, the morphology and microstructure of the knee joint varies considerably between patients, therefore the anatomical expertise of orthopedic surgeons is essential. In this analysis we therefore investigate the variation and micro-architectural alterations in subchondral bone in osteoarthritis (OA) patients undergoing a knee replacement surgery. We investigate OA bone degenerations using clinical X-rays and micro-computed tomography (micro-CT). Tibial bone samples are collected from 100 patients undergoing a total knee arthroplasty at the Klinikum Wels-Grieskirchen. Images are obtained using an industrial micro-CT scanner RayScan 250E. Microstructural parameters include bone volume fraction and cortical thickness of the subcondral bone and are obtained from micro-CT images with isometric voxel sizes of 50 µm. Using micro-CT, we show a high morphological variation in relation to cortical thickness, both within the respective condyle as well as between the medial and lateral condyle. Cortical thickness seems to correlate with cartilage thickness and knee joint alignment. The results are incorporated into a gonarthrosis database that integrates microstructural parameters via a combined analysis of X-ray and micro-CT data. This database aims to facilitate the assessment of osteoarthritis, i.e. in relation to cartilage degeneration, in future patients on the basis of the investigated patient collective

Osteoarthritis (OA) is traditionally believed to affect the osteochondral unit by wear-and-tear from the superficial zone to the deep zone of cartilage and extended to subchondral plate. Obesity is commonly considered as a risk of OA development and hence total knee replacement (TKR), but the mechanism remains unclear. We hypothesized that obesity accelerated OA development by deteriorating tidemarks and increasing bone remodelling. 616,495 cases of TKR for OA from Australia and British joint replacement registries were collected, and data indicated that patients with higher BMI had TKR at earlier age. Specifically, patients with BMI ≤25kg/m. 2. showed 8 years younger than patients with BMI ≥40kg/m. 2. (P<0.0001) when they received TKR. We next examined tibia plateaus of 88 knee OA patients by micro-CT and histomorphometry. Linear regression showed that less cartilage degradation was associated with increased BMI in the load-bear compartment (p<0.05), while 58.3% of patients with BMI≥40kg/m. 2. demonstrated a clear anatomical separation close to tidemarks filled with fibrosis, erythrocytes and bone fragments (compared to BMI ≤25kg/m. 2. group: 7.7%, p<0.01). In subchondral bone, elevated bone formation was associated with increased BMI, as higher thickness of osteoid (p<0.01), percent osteoid volume (p<0.01), percent osteoid surface (p<0.01) were found in obese patients. However, no alteration of bone resorption and microstructural parameters was found to be associated with BMI. We suspected that the abnormal loading in knee joint due to high BMI led to the direct deterioration of binding site of osteochondral unit, which might be the mechanism of the rapid progression in obesity-related OA

In six unloaded cadaver knees we used MRI to determine the shapes of the articular surfaces and their relative movements. These were confirmed by dissection. Medially, the femoral condyle in sagittal section is composed of the arcs of two circles and that of the tibia of two angled flats. The anterior facets articulate in extension. At about 20° the femur ‘rocks’ to articulate through the posterior facets. The medial femoral condyle does not move anteroposteriorly with flexion to 110°. Laterally, the femoral condyle is composed entirely, or almost entirely, of a single circular facet similar in radius and arc to the posterior medial facet. The tibia is roughly flat. The femur tends to roll backwards with flexion. The combination during flexion of no antero-posterior movement medially (i.e., sliding) and backward rolling (combined with sliding) laterally equates to internal rotation of the tibia around a medial axis with flexion. About 5° of this rotation may be obligatory from 0° to 10° flexion; thereafter little rotation occurs to at least 45°. Total rotation at 110° is about 20°, most if not all of which can be suppressed by applying external rotation to the tibia at 90°

Introduction. Bending tests are commonly used to evaluate the mechanical behaviour of small animal bones. To test whole bones, it is normal that soft tissue should be removed before testing. However, cleaning the specimens might disturb the callus, interfering with the mechanical properties. This study compares mechanical properties of rat tibia between specimen with and without muscle cleaning. Materials and methods. 12 male Wistar rats aged 3–4 months were used. Soft tissues including skin and muscle were removed from right tibias (Group A), whereas muscles on the left tibia were left intact (Group B). 4-point bending was used to find the ultimate load, stress and Young's modulus. Results. All specimens displayed a basic failure pattern from load-displacement graph. Mean ultimate load of 105.2N (S.E.M.=7.60, n=12) for group A and 101.6N (S.E.M.=7.32, n=12) group B. Mean stress at failure of 281.50MPa (S.E.M.=34.98, n=12) was found for group A 288.70MPa (S.E.M.=20.83, n=12) for group B. Mean Young's modulus was 8.97GPa (S.E.M.=1.44, n=12) for group A and 10.05GPa (S.E.M=0.69, n=12) for group B. No statistical differences for any mechanical properties were found between groups for either t-test(p>0.05) or Bland-Altman plot. Discussion. No differences in mechanical properties were found with or without soft tissue. Therefore, biomechanical testing of small specimen bending without removing muscle can be used. The advantages of this technique are reduced specimen preparation time and decreasing risk of creating a stress raiser at the callus

Mechanical loading during physical activity produces strains within bones. It is thought that these forces provide the stimulus for the adaptation of bone. Tibial strains and rates of strain were measured in vivo in six subjects during running, stationary bicycling, leg presses and stepping and were compared with those of walking, an activity which has been found to have only a minimal effect on bone mass. Running had a statistically significant higher principal tension, compression and shear strain and strain rates than walking. Stationary bicycling had significantly lower tension and shear strains than walking. If bone strains and/or strain rates higher than walking are needed for tibial bone strengthening, then running is an effective strengthening exercise for tibial bone

Objectives

The purpose of this study was to compare the results and complications of tibial lengthening over an intramedullary nail with treatment using the traditional Ilizarov method.