Objectives. Cortical and cancellous bone healing processes appear to be histologically different. They also respond differently to anti-inflammatory agents. We investigated whether the leucocyte composition on days 3 and 5 after cortical and cancellous injuries to bone was different, and compared changes over time using day 3 as the baseline. Methods. Ten-week-old male C56/Bl6J mice were randomized to either cancellous injury in the proximal tibia or cortical injury in the femoral diaphysis. Regenerating tissues were analyzed with flow cytometry at days 3 and 5, using panels with 15 antibodies for common macrophage and lymphocyte markers. The cellular response from day 3 to 5 was compared in order to identify differences in how cancellous and cortical bone healing develop. Results. Between day 3 and 5, the granulocytes increased in the cancellous model, whereas the lymphocytes (T cells, B cells, NK cells) and monocytes (CD11b+, F4/80+, CD206+, CD14+) increased in the cortical model. Conclusion. These results suggest an acute type of inflammation in cancellous bone healing, and a more chronic inflammation in cortical healing. This might explain, in part, why cancellous healing is faster and more resistant to anti-inflammatory drugs than are diaphyseal fractures. Cite this article: L. Tätting, O. Sandberg, M. Bernhardsson, J. Ernerudh, P. Aspenberg. Different composition of leucocytes in cortical and cancellous bone healing in a mouse model. Bone Joint Res 2018;7:620–628. DOI: 10.1302/2046-3758.712.BJR-2017-0366.R2

Autologous cancellous bone graft is the gold standard in large bone defect repair. However, studies using autologous bone grafting in rats are rare and donor sites as well as harvesting techniques vary. The aim of this study was to determine the feasibility of autologous cancellous bone graft harvest from 5 different anatomical sites in rats and compare their suitability as donor sites for autologous bone graft. 13 freshly euthanised rats were used to describe the surgical approaches for autologous bone graft harvest from the humerus, iliac crest, femur, tibia and tail vertebrae (n=4), determine the cancellous bone volume and microstructure of those five donor sites using µCT (n=5), and compare their cancellous bone collected qualitatively by looking at cell outgrowth and osteogenic differentiation using an ALP assay and Alizarin Red S staining (n=4). It was feasible to harvest cancellous bone graft from all 5 anatomical sites with the humerus and tail being more surgically challenging. The microstructural analysis showed a significantly lower bone volume fraction, bone mineral density, and trabecular thickness of the humerus and iliac crest compared to the femur, tibia, and tail vertebrae. The harvested volume did not differ between the donor sites. All donor sites apart from the femur yielded primary osteogenic cells confirmed by the presence of ALP and Alizarin Red S stain. Bone samples from the iliac crest showed the most consistent outgrowth of osteoprogenitor cells. The tibia and iliac crest may be the most favourable donor sites considering the surgical approach. However, due to the differences in microstructure of the cancellous bone and the consistency of outgrowth of osteoprogenitor cells, the donor sites may have different healing properties, that need further investigation in an in vivo study

Objectives. Meropenem may be an important drug in the treatment of open tibial fractures and chronic osteomyelitis. Therefore, the objective of this study was to describe meropenem pharmacokinetics in plasma, subcutaneous adipose tissue (SCT), and cancellous bone using microdialysis in a porcine model. Methods. Six female pigs were assigned to receive 1000 mg of meropenem intravenously over five minutes. Measurements of meropenem were obtained from plasma, SCT, and cancellous bone for eight hours thereafter. Microdialysis was applied for sampling in solid tissues. The meropenem concentrations were determined using ultra-high-performance liquid chromatography. Results. The penetration of meropenem into cancellous bone, expressed as the ratio of plasma to cancellous bone area under the concentration-curve from zero to the last measured value, was incomplete and delayed. The time with concentration above the minimal inhibitory concentration (T. >MIC. ), for an MIC of 0.5 μg/ml, was shorter for cancellous bone in comparison with both plasma and SCT. For MICs above 0.5 μg/ml, T. >MIC. in cancellous bone was only shorter than SCT. Considering an MIC of 4 μg/ml, no animals achieved the target of 40% T. >MIC. in plasma and cancellous bone, while less than 20% achieved it in SCT. Conclusion. The main finding of this study was short T. >MIC. in cancellous bone after intravenous administration of 1000 mg meropenem. Consequently, in order to achieve sufficient tissue concentration in the cases of open tibial fractures and chronic osteomyelitis, supplemental application of meropenem may be necessary. Cite this article: P. Hanberg, A. Lund, K. Søballe, M. Bue. Single-dose pharmacokinetics of meropenem in porcine cancellous bone determined by microdialysis: An animal study. Bone Joint Res 2019;8:342–348. DOI: 10.1302/2046-3758.87.BJR-2018-0308.R1

Introduction. Bone fracture toughness is an important parameter in resistance of bone to monotonic and fatigue failure. Earlier studies on bone fracture toughness were focused on either cortical or cancellous bone, separately [1, 2]. Reported fracture toughness values indicated that cortical bone is tougher to break as compared to cancellous bone. In order to understand complete fracture of a whole bone, the interface between cortical and cancellous bone (named as corticellous bone) might play a crucial role and is interesting topic of research. The goal of this study was to identify fracture toughness in terms of J integral and fracture mechanism of the corticellous bone. Material and Methods. Corticellous bone samples (single edge notch bend specimen or SENB) were prepared from bovine proximal femur according to ASTM E399-90 standard (Fig.1). For corticellous bone, samples were prepared in such way that approximately half of the sample width consist of cortical bone and another half is cancellous bone. Precaution was taken while giving notch and pre-crack to corticellous bone that pre-crack should not enter from cortical to cancellous portion. All specimens were tested using a universal testing machine (Tinius Olsen, ± 100 N) under displacement rate of 100 µm/min until well beyond yield point. The fracture toughness parameter in terms of critical stress intensity (K. IC. ) was calculated according to ASTM E399-90 as given by, . (1). K. IC. =. PS. /. BW. 1.5. *. f. (. a. /. W. ). …. Where, P = applied load in kN, S = loading span in cm, B = specimen thickness in cm, W = specimen width in cm, a = total crack length, f(a/W) = geometric function. After the fracture test the J integral of each specimen was calculated using following equation. [ASTM E1820]. . (2). J. total. =. J. el. +. J. pl. =. K. IC. 2. /. E. ′. +. 2. A. pl. /. Bb. 0. …. Where, J. el. is J integral of the elastic deformation, J. pl. is J integral of the plastic deformation, E′=E for plane stress condition and E′= E/(1−ν. 2. ) for plane strain condition (E is elastic modulus; ν is Poisson's ratio), b. o. = W−a. o. , height of the un-cracked ligament, and A. pl. is the area of the plastic deformation part in the load–displacement curve. Result and Discussion. The fracture toughness in terms of critical stress intensity (K. IC. ) of corticellous bone was found to be 2.45 MPa.m. 1/2. The plastic part of J integral, J. pl. value of corticellous specimen was 9310 Jm. −2. , and shown to be 27 times of the J. el. value, 341 Jm. −. 2. Total J integral of corticellous bone was found to be 9651 Jm. −2. When crack travels through cortical portion and reaches at the interface, crack branching occurred and further it slows down (Fig.2). Indeed, more energy is required in plastic than elastic deformation. Conclusion. J integral of corticellous bone is found to higher which is due to plastic deformation and crack branches at the interface between cortical and cancellous bone. For any figures or tables, please contact the authors directly

Remodeling of the cancellous bone is more active than that of the cortical bone. It is known that the remodeling is governed by the intracancellous fluid pressure. Particularly, the lacunocanalicular pore (PLC) fluid pressure (FP) is essential for survival of the osteocyte and communication of remodeling signals between the PLC and intertrabecular pore (PIT). As a result, knowledge about the PLCFP generation of trabeculae is required to understand human cancellous bone biology. At this moment, the PLCFP measurement of human trabeculae is not reported. The purpose of this study was a direct measurement of PLCFP generation of human proximal femoral trabeculae in the direction of superior-to-fovea. Twenty one microscopic cylindrical trabecular specimens from trabeculae of five fresh human proximal femur (75 to 77 years) were fabricated using a micro-milling machine composed of the laser (Teemphotonics: 532nm), 3-dimensional PZT stage (PI Gmbh, resolution: 0.5nm), and microscope (lens: Navitar, and CCD: Hitachi) with the image processor. The fabrication resolution of the micro-milling machine was 0.4 um. Based on the trabecular trajectory of femoral head, the specimens were obtained in the direction of superior-to-fovea. The cylindrical specimen size had 120 um in diameter and 240 um in length. The test methods described in the previous study were utilized. The used undrained uniaxial strain condition could induce the maximum PLCFP within the trabecular elastic limit. The measured trabecular PLCFP (±SD) at the strain of 0.4% was 693.7±79.1 kPa. Since this experiment is equivalent to the instantaneous response of PLCFP with free flow boundaries after application of an extremely fast loading speed such an ideal step loading, a PLCFP generation in the physiological condition will be much less than the results obtained in this study. Base on the linear isotropic poroelasticity, the obtained Skempton's coefficient is almost 0. Thus, the load bearing capability by trabecular PLC fluid is negligible. The Biot coefficient is 0.35 which is higher than that of the cortical tissue (0.14). As a result, the intraosseous fluid communication through trabecular surfaces is active compared to that through Haversian canal surfaces. This imply that mass transports from the trabecular PLC into the PIT and from the PIT into the trabecular PLC could be significantly affected by the PITFP (the physiological blood systolic and diastolic pressure: 16 and 11 kPa, respectively) that acts as the FP boundary condition for the PLC flow. It is known that the PLC flow generates the electrical charges on the trabecular surface (‘+’ for being spouted into the PIT and ‘−’ for being flown into the PLC), which control differentiation and proliferation of the osteoblast and mesenchymal stem cell. Thus, significant changes in the PITFT could cause changes in the intra-trabecular PLC flow characteristics, mass transports between the PLC and PIT, and electrical charges on the trabeculae. Eventually, these could result in pathologies related to the trabecular remodeling

Aim. Pyogenic spondylodiscitis is associated with prolonged antimicrobial therapy and high relapse rates. Nevertheless, tissue pharmacokinetic studies of relevant antimicrobials in both prophylactic and therapeutic situations are still sparse. Previous approaches based on bone biopsy and discectomy exhibit important methodological limitations. The objective of this study was therefore to assess the concentration of cefuroxime in intervertebral disc (IVD), vertebral body cancellous bone, subcutaneous adipose tissue (SCT) and plasma pharmacokinetics after single dose administration by use of microdialysis (MD) in a large animal model. Method. Ten female pigs were assigned to receive 1,500 mg of cefuroxime intravenously over 15 min. Measurements of cefuroxime were obtained from plasma, SCT, the vertebral cancellous bone and the IVD for 8 hours thereafter. MD was applied for sampling in solid tissues. The cefuroxime concentration in both the MD and plasma samples was determined using ultra-high performance liquid chromatography. Results. For both the IVD and the vertebral cancellous bone, the area under the concentration-curve from zero to the last measured value was significantly lower than that of free plasma. Tissue penetration of cefuroxime was incomplete for the IVD, whereas for vertebral cancellous bone and SCT it was not. Furthermore, the penetration of cefuroxime from plasma to IVD was delayed. Additionally, a noticeable prolonged elimination rate of cefuroxime in the IVD was found. The maximal concentration and the elimination of cefuroxime were reduced in IVD compared to both SCT and vertebral cancellous bone. Due to this delay in elimination of cefuroxime, the time with concentrations above the minimal inhibitory concentration (T>MIC) was significantly higher in IVD than in SCT, vertebral cancellous bone and free plasma for MICs up to 6 μg/ml. Conclusions. MD was successfully applied for serial assessment of the concentration of cefuroxime in the IVD and the vertebral cancellous bone. Penetration of cefuroxime from plasma to IVD was found to be incomplete and delayed, but due to a prolonged elimination, the best results regarding T>MIC was found in IVD

Purpose. To evaluate the radiographic long-term result of femoral revision hip arthroplasty using impacted cancellous allograft combined with cemented, collarless, polished and tapered stem. Materials and methods. Among 28 patients with impacted cancellous allograft with a cemented stem, 28 hips from 26 consecutive patients were analyzed retrospectively. The average patient age was 59 years. The follow-up period ranged 9 years 6 months to 14 years 5 months (mean, 12, 5 years). Radiographic parameters analyzed in this study included subsidence of the stem in the cement, subsidence of the cement mantle in the femur, bone remodeling of the femur, radiolucent line, and osteolysis. Results. Radiographic analysis showed very stable stem initially. 27 stems showed minimal subsidence (less than 5 mm) and 1 stem showed moderate subsidence (about 10 mm) in the cement. But there was no mechanical failure and subsidence at the composit-femur interface. Evidence of cortical and trabecular remodeling were observed in all cases. No radiolucent line or osteolysis were found in the follow-up period. There were 4 proximal femoral cracks and 1 distal femoral splitting during operation. Conclusion. The result of cemented stem revision with the use of impacted cancellous allograft was good long-terand femoral bone stock deficiency may be reconstructed successfully

Aim. Cefuroxime is a time-dependent antibiotic widely used as intravenous perioperative prophylaxis in spine surgery. A previous study has indicated that a single dose of cefuroxime provided insufficient spine tissue concentrations for spine procedures lasting more than 2–3 hours. Due to the fact that postoperative pyogenic spondylodiscitis is associated with prolonged antimicrobial therapy and high relapse rates, we aimed to evaluate if a twofold increase of standard dosage of 1.5g cefuroxime given as one double dose or two single doses with 4-hours intervals will lead to sufficient cefuroxime spine tissue concentrations throughout the dosing interval. Method. This is preliminary data for 8 out of 16 female pigs. Data from all 16 pigs will be included for the conference. Eight pigs were randomized into two groups: Group A received one double dose of cefuroxime (3g) as a bolus, and Group B received two single doses of cefuroxime (2×1.5g) with 4-hours intervals. Measurements were obtained from plasma, subcutaneous tissue (SCT), vertebral cancellous bone and the intervertebral disc (IVD) for 8-hours thereafter. Microdialysis was applied for sampling in solid tissues. The cefuroxime concentrations were determined using ultra-high performance liquid chromatography. Results. The time with concentrations above the minimal inhibitory concentration (T>MIC) for the clinical breakpoint MIC for Staphylococcus aureus of 4 μg/ml, was superior in all compartments when administering cefuroxime as two single doses with 4-hours intervals. For the target MIC of 4 μg/ml, the mean T>MIC in all compartments ranged between 53–73% and 85–95% for Group A and B, respectively. For both groups the area under the concentration-curve (AUC) was higher for plasma compared to the remaining compartments, and the lowest AUCs were found in the vertebral cancellous bone and the IVD. There were no differences in AUC between the two groups. Furthermore, the maximal concentrations were lower for both vertebral cancellous bone and IVD compared to both SCT and plasma. When comparing the two groups, higher maximal concentrations were found in all compartments for Group A. Tissue penetration was incomplete and delayed for all compartments and comparable between the two groups. Conclusions. Despite comparable pharmacokinetic results between the two groups, Group B exhibited superior T>MIC in all compartments for the clinical breakpoint MIC for Staphylococcus aureus of 4 μg/ml. As such administration of cefuroxime as two single doses with 4-hours intervals provided sufficient cefuroxime spine tissue concentrations for a minimum of 85% of an 8-hour dosing interval, which may be acceptable for most spine procedures

Total shoulder arthroplasty is a well-established and widely accepted method of treatment for a variety of shoulder disorders, loosening of the glenoid prosthesis is the main complication in total shoulder arthroplasty, it is highly dependent on the quality of the glenoid cancellous bone. Very little is known about mechanical properties of this cancellous bone. The objectives of this study were to determine the mechanical properties (elastic modulus and strength) of glenoid cancellous bone in the axial, coronal and sagittal planes including regional variation using a uniaxial compression test. To our knowledge, this kind of study was not done before. Eleven scapulas were obtained from six fresh-frozen, unembalmed human cadavers (mean age eighty-eight years). Eighty-two cubic cancellous bone specimens of 6×6×6mm3 were used for mechanical testing in the three planes. The test was a uniaxial compression along each direction, Elastic modulus and strength were determined from the stress-strain curve. Apparent density was also calculated. The study showed significant differences in the mechanical properties with anatomic location and directions of loading. Young modulus and strength were found to be significantly higher at the posterior part of the glenoid with the weakest properties at the antero-inferior part. Cancellous bone was found to be anisotropic with higher mechanical properties in the latero-medial direction (perpendicular to the articular surface of the glenoid). The apparent density was on average equal to 0.29 g/cm3 with the higher values at the posterior and superior part of the glenoid. Good correlation between apparent density and elastic modulus was found only in the sagittal plane but not in the coronal and axial plane, the overall correlation was low (r2 = 0.22, p< 0.0001) which emphasizes the role of trabecular bone architecture in predicting mechanical properties. The mechanical properties determined in this study provide input data for finite element method analyses and may help to assist in uncemented shoulder prosthesis design

INTRODUCTION. Appropriate, well characterized animal models remain essential for preclinical research. This study investigated a relevant animal model for cancellous bone defect healing. Three different defect diameters of fixed depth were compared in both skeletally immature and mature sheep. This ovine model allows for the placement of four confined cancellous defects per animal. METHODS. Defects were surgically created and placed in the cancellous bone of the medial distal femoral and proximal tibial epiphyses (See Figure 1). All defects were 25 mm deep, with defect diameters of 8, 11, and 14 mm selected for comparison. Defects sites were flushed with saline to remove any residual bone particulate. The skeletally immature and mature animals corresponded to 18 month old and 5 year old sheep respectively. Animals were euthanized at 4 weeks post-operatively to assess early healing. Harvested sites were graded radiographically. The percentage of new bone volume within the total defect volume (BV/TV) was quantified through histomorphometry and μ-CT bone morphometry. Separate regions of interest were constructed within the defect to assess differences in BV/TV between periosteal and deep bone healing. Defect sites were PMMA embedded, sectioned, and stained with basic fuschin and methylene blue for histological evaluation. RESULTS. The animals tolerated the surgery well, with no incidence of fractures within the four weeks. Healing of the defects progressed via endochondral ossification, with none of the defects being completely healed within the 4 week time point. Bone volume fraction (BV/TV) significantly decreased with an increasing defect diameter. Actual bone volume (BV), however, increased with defect diameter, suggesting a correlation between biological response and severity of injury. Three distinct healing regions were found to exist within the defect and along the axis of the defect, with significant differences detected in the BV/TV between adjacent regions. Histologically, the 5 year old animals appeared to have decreased osteoblast activity, and lower osteocyte density within the newly formed woven bone. On occasion, the defects were found to intersect the tibial growth plate in the 18 month old animals, with bone replacing the proliferating chondrocyte zone (See Figure 2). Additionally, the 14 mm defect was not able to be placed in the tibia of sheep due to the possibility of the defect entering the tibial intramedullary (IM) canal, and the lack of cancellous bone between the tibial plateau and IM canal. Both these issues considerably affect this model and should be avoided. CONCLUSION. The surgical placement of 11 mm diameter defects in the proximal tibial and distal femoral epiphyses of skeletally mature sheep presents a suitable large animal model to study early healing of cancellous bone defects. This refined model allows for the placement of four separate non-healing defects within a single sheep, and allows for the possibility to reduce animal numbers required to obtain information

Introduction. Osteoporosis (OP), osteoarthrosis (OA), and rheumatoid arthritis (RA) are the most common age-related degenerative bone diseases, and major public health problems in terms of enormous amount of economic cost. RA is considered as a major cause of secondary osteoporosis. At late stage, OP often leads to skeletal fractures, and OA and RA result in severe joint disability. Over the last a few decades, much significant research on the properties has been carried out on these diseases, however, a detailed comparison of the microarchitecture of cancellous bones of these diseases is not available. In this study, we investigated three-dimensional (3-D) microarchitectural properties of OP, OA and RA cancellous bone. We hypothesized that there were significant differences in microarchitecture among OP, OA and RA bone tissues that might lead to different bone quality. Materials and Method. Twenty OP, fifty OA, and twelve RA femur heads were harvested from patients undergone total hip replacement surgery. Cubic cancellous bone samples (8∗8∗8 mm3) were prepared and scanned with a high resolution microtomographic system (vivaCT 40, Scanco Medical AG., Brüttisellen, Switzerland). Then micro-CT images were segmented using individual thresholds to obtain accurate 3-D data sets. Detailed microarchitectural properties were evaluated based on novel unbiased, model-free 3-D methods. For statistical analysis, one-way ANOVA was used, and a p<0.05 was considered significant. Results. Significant differences in the microarchitecture of cancellous bone were observed among the OP, OA and RA groups. Compared with the other groups, OP cancellous bone had lowest density, thinner, typical rod-like structure and less connectivity (all p<0.01). Interestingly, there were no significant differences in the microarchitectural properties measured between the OA and RA cancellous bones. Both OA and RA cancellous bones had significant higher bone volume fraction and were thicker, typical plate-like structure compared with the OP group (all p<0.01), even though there was clearly bone erosion observed in RA cancellous bone. Discussion. Quantification of the alterations in bone properties and quality will help to gain more insights into the pathogenesis of degenerative bone diseases and to target and develop novel approaches for the intervention and treatment, and for the design, fixation and durability of total joint prosthesis. Our study demonstrated that there were significant differences in the microarchitecture of the OP, OA and RA femur head cancellous bone. The OA and RA cancellous bone had similar bone density and microarchitecture despite apparent bone erosion in the RA cancellous bone. These results from femur head did not support the traditional notion that RA and OP had similar low bone density. Thus, whether femur head bone tissues from these diseases have similar bone collagen, mineral and mechanical properties, more importantly bone quality, should be clarified in the future

Three 3mm transverse slices were sectioned from the distal cancellous region of seven fresh-frozen cadaveric humerii. Each slice was marked with a 3x3mm grid, and subjected to compressive testing using a flat cylindrical indenter (1.6mm diameter). Indentation modulus and strength were calculated for each site, and pooled into nine anatomically-defined regions. The most distal slice had higher moduli values (p< 0.05), and the posterior capitellar region had lower moduli values (p< 0.05). There were no slice or regional differences in strength. This suggests that surgical procedures requiring cancellous fixation utilize the most distal aspect of the humerus while avoiding the posterior capitellum. To quantify the indentation strength and modulus of distal humeral cancellous bone, and identify any regional variations. Cancellous bone modulus in the distal humerus decreases from distal to proximal. The posterior capitellum has a lower modulus than the other regions of the distal humerus. The influence of slice depth emphasizes the importance of minimizing the amount of bone removed during prosthetic replacement. Regional variations in modulus suggest that the posterior capitellum should be avoided during fixation of implants or placement of screws. Three 3mm transverse cancellous bone slices obtained from the distal end of each of seven fresh-frozen cadaveric specimens were subjected to compressive testing using a materials testing machine with a 1.6mm flat cylindrical indenter. Testing was performed in a 3x3mm grid. The indentation modulus and local strength were calculated for each test site, and then averaged into nine regions defined by the capitellum, medial and lateral trochlea, and anterior, central and posterior sections for each slice. Mean modulus was found to be 309.8±242.0 MPa (range: 2.9–1041.7 MPa). Yield strength averaged 4.4±2.5 MPa (range: 0.6–16.3 MPa). The highest modulus was found in the distal-most slice (p< 0.05). The lowest modulus region was the posterior capitellum (p< 0.05). There were no differences in strength between slices or across the nine regions. A comparison with proximal tibial cancellous bone properties suggests the distal humerus may carry loads approaching 30% of those at the knee, assuming that bone adapts to stress magnitudes. Funding: Natural Sciences and Engineering Research Council; University of Western Ontario

Introduction: In postmenopausal female patients with hip osteoarthritis, osteoporosis as well as altered local trabecular bone architecture may lead to a increased migration of uncemented hip prostheses. 1. ,. 2. The aim of this study was to determine whether 3D bone architecture and mechanical properties of intertrochanteric cancellous bone in the proximal femur predict RSA migration of uncemented femoral stems. Materials and Methods: The study population consisted of 61 female patients with primary hip osteoarthritis. Informed consent was obtained prior to any study-related procedures. The Ethical Committee approved the study protocol. All patients underwent a total hip replacement (ABG II, Stryker) with uncemented proximally hydroxyapatite-coated femoral stem with tantalum RSA markers. Ceramicceramic bearing surfaces were used. A uniplanar type of RSA setup was applied. The RSA examinations were performed postoperatively and at 3, 6, and 12 months. During surgery, cancellous bone biopsy was taken from the proximal femur from the site of stem implantation. The specimens were scanned with micro-CT. 3D analysis of trabecular bone geometry and BMD was performed using CTAn software. After micro-CT imaging, the trochanteric cancellous bone specimens were subjected to a destructive compression test. Maximum force and stiffness were calculated. Linear regression analysis was applied to study correlations between different parameters investigated. Results: The patients exhibited major differences in the density and structural quality of intertrochanteric cancellous bone. Significant correlations were found between the measured biomechanical parameters and the structural parameters calculated from micro-CT data. Unexpectedly, the quality of intertrochanteric cancellous bone did not predict RSA migration of the femoral stems. The femoral stems reached high stability within 3 months and there were no significant differences in the axial and rotational migration of the femoral stems between the patients with normal or poor quality of the intertrochanteric cancellous bone. Discussion: The 3D bone architecture, mineral density and mechanical properties of the local intertrochanteric cancellous bone do not seem to serve as predictors of femoral stem migration. The observation suggests that the significance of cancellous bone quality for the initial stability of uncemented femoral stems has been over-emphasized

Osteoarthrosis (OA) stands alongside cancer and heart disease as one of the major causes of suffering and disability amongst the elderly. Changes related to OA occur in all elements of the joint, and there are indications that sub-chondral cancellous bone plays a primary role in the cartilage degeneration in OA. Most previous investigations have been focused on moderate and late OA, whereas little is known about the changes in cancellous bone microstructure in human early OA. This study quantified cancellous bone microstructure in early-stage OA using three-dimensional (3D) methods. Subchondral cancellous bone specimens, produced from 10 human post-mortem early-stage osteoarthrotic (OA) proximal tibiae and 10 normal age- and gender-matched proximal tibiae, were allocated to 4 groups: medial OA, lateral control, normal medial control, and normal lateral control. OA initiates mostly at the medial condyle, and histological analysis was done to confirm this change. The cylindrical specimens were micro-computed tomography (micro-CT) scanned. From accurate 3D data sets, structural parameters were determined by means of true, unbiased and assumption-free 3D methods. The data were assessed statistically, and a p< 0.05 was considered significant. Our data supported the hypothesis that significant microstructural changes – other than density changes – occur in early-stage OA cancellous bone. OA cancellous bone is markedly plate-like, less anisotropic, less interconnected, but lower in mechanical properties which suggests a disorganisation in the microstructure as OA initiation. Structure model type best explains the mechanical properties for the OA and the normal controls. However, the determination coefficients (R2) for the OA group are largely reduced. These results indicate significant property and quality deterioration in early-stage OA subchondral cancellous bone

Introduction. Osteoporosis is a metabolic disease of the bone responsible for a loss of bone resistance and an increase in fracture risk. World Health Organization (WHO) estimations are about 6.3 millions of femoral neck fractures in the world by 2050. These estimations make osteoporosis a real problem in term of public health. Knowledge in biological tissues mechanical behaviour and its evolution with age are important for the design of diagnosis and therapeutic tools. From the mechanical aspect, bone resistance is dependent on bone density, bone architecture and bone tissue quality. If the importance of bone density and bone architecture has been well explored, the bone tissue quality still remains unstudied because of the lack of biomechanical tools suitable for testing bone at this microscopic dimension. Therefore the goal of this study is to estimate the osteoporotic cancellous bone tissue mechanical behaviour at its microscopic scale, using an approach coupling mechanical assays and digital reconstruction. Materials and methods. The experimental study is based on cancellous bone tissue extracted from human femoral head. Forty 8mm diameters bone cylinders have been removed from femoral head explanted after a femoral neck fracture treated by arthroplasty. These cylinders have been submitted to a digitally controlled compressive trial. Before and after the trials, microscanner analyses with an 8 μm spatial resolution have been realized in order to determine the micro structural parameters. The cylinders have been rebuilt with the digital model-building in order to estimate the mechanical behaviour and the bone quality. Results. The results will be presented from a macroscopic and microscopic point of view and will show the relationship between gender and age of the patients. At the macroscopic scale, we will look at that apparent young modulus heterogeneity and the cracking strength. At the microscopic scale, we will confirm that the cancellous bone tissue mechanical behaviour is close to the Haversian bone tissue mechanical behaviour. Finally, the parametric study will permit us to point out the main microstructural components influencing cancellous bone tissue quality. Conclusion. This study allows a precise estimation of the osteoporotic cancellous bone tissue mechanical behaviour. It seems to be a great step in the understanding of this disease and it could probably lead to great improvements in the diagnosis, prognostic, medical and surgical approaches of osteoporosis

The influence of controlled mechanical loading on osseointegration was investigated using an in vivo device implanted in the distal lateral femur of five male rabbits. Compressive loads (1 MPa, 1 Hz, 50 cycles/day, 4 weeks) were applied to a porous coated titanium cylindrical implant (5mm diameter, 2mm width, 75% porosity, 350ìm average pore diameter) and the underlying cancellous bone.. The contralateral limb served as an unloaded control. MicroCT scans at 28 μm resolution were taken of a 4 × 4mm cylindrical region of interest that included cancellous bone below the implant. A scanning electron microscope with a backscattered electron (BSE) detector was used to quantify the percent bone ingrowth and periprosthetic bone in undecalcified sections through the same region of interest. A mixed effects model was used to account for the correlation of the outcome measures within rabbits.. The percent bone ingrowth was significantly greater in the loaded limb (19 +/− 4%) compared to the unloaded control limb (16 +/− 4%, p=0.016) as measured by BSE imaging. The underlying cancellous periprosthetic tissue bone volume fraction was not different between the loaded (0.26 +/− 0.06) and unloaded control limb (0.27 +/− 0.07, p=0.81) by microCT. BSE imaging also showed no difference in the percent area of periprosthetic bone (27 +/− 10% loaded vs. 23 +/− 10% unloaded, p=0.25). Cyclic mechanical loading significantly enhanced bone ingrowth into a titanium porous coated surface compared to the unloaded controls

The cancellous bone adjacent to major load-bearing joints such as the hip and knee has complex architecture. The loading patterns across these joints influence the architecture of the cancellous bone, which varies according to the magnitude and direction of these forces. Articular lesions are associated with alterations in the loading patterns and hence change to the cancellous architecture. The fractal dimension, as a numerical descriptor of complex shapes, enables these changes to be quantitated. The fractal analysis was performed by a box counting method. The perimeter of binary profiles of cancellous bone samples was measured for different box sizes. The fractal dimension is 1-D (where D is the slope of the straight-line segments from the plot of log of perimeter versus of log box size). Samples of cancellous bone were taken at autopsy from three subchondral regions, superior to the fovea in the femoral head (n=56) and the tibial (n=25) and femoral (n=25) condyles of the knee. There were three straight-line segments identified on the log-log plot, for each subject, indicating a fractal dimension over three different ranges of scale. Fractal 1 describes the complexity of bone surface detail influenced by osteoclast and osteoblast activity, fractal 2 describes the shape or form of individual trabeculae and fractal 3 describes the overall spatial complexity of the cancellous structure. The results show that for fractal 1, all three regions are the same. For fractal 2, the femoral head is greater than the condyles (1.40±0.07 versus 1.36±0.05 and 1.36±0.05) and for fractal 3, the femoral head is significantly greater than the condyles (1.76±0.06 versus 1.73±0.04 and 1.70±0.05). These data show that cancellous bone architecture differs between skeletal sites. In particular, the fine surface detail influenced by bone cell activity and described by fractal 1 is the same in each region, while the shape of individual trabeculae as described by fractal 2 is more complex in the femoral head. The overall spatial complexity of the cancellous structure as described by fractal 3 is the same in each condyle of the knee while in the femoral head it is significantly greater. The fractal dimension, as a descriptor of complexity, enables the effect of differences in the mechanical micro-environment on cancellous bone architecture to be quantified so that pathology affecting these regions can be studied

Summary. These data suggest that PTH treatment for stimulation of bone healing after trauma is not much dependent on mechanical stimulation and therefore, roughly equal treatment effects might be expected in the upper and lower extremities in humans. Introduction. Stimulation of bone formation by PTH is known to, in part, act via increased mechanosensitivity. Therefore, unloading should decrease the response to PTH treatment in uninjured bone. This has served as a background for speculations that PTH might be less efficacious for human fracture treatment in unloaded limbs, e.g. for distal radial fractures. We analyzed if the connection with mechanical stimulation also pertains to bone formation after trauma in cancellous bone. Methods. 20 male SD rats, 8 weeks old, had one hind leg immobilised via Botox injections. At 10 weeks of age the rats received bilateral screw implants into their proximal tibiae. Half of the rats were given daily injections of 5µg/kg PTH(1–34). After two weeks of healing, the tibias and femurs were harvested. Mechanical testing of screw fixation (pull-out) and µCT of the cancellous bone of the distal femurs was performed. Results. The pull-out forces served as a read-out for cancellous bone formation after trauma. PTH more than doubled the pull-out force in the unloaded limbs (from 14 to 30 N), but increased it by less than half in the loaded (from 30 to 44 N). These force values are not limited by a ceiling effect, and the difference in relative effect of PTH was significant (p = 0.03). Discussion/Conclusion. PTH appeared to exert a greater effect on bone healing in the unloaded limbs, compensating for the lack of mechanical stimulation. These data suggest that PTH treatment for stimulation of bone healing after trauma is not much dependent on mechanical stimulation. Therefore, roughly equal treatment effects might be expected in the upper and lower extremities in humans

The treatment of undisplaced femoral neck fracture in the elderly population is still controversial. We analysed the outcome of cancellous screw fixation for undisplaced femoral neck fracture in patients over 70 years. Materials and methods. From 1998 to 2003, ninety-seven patients with undisplaced femoral neck fracture, aged over 70 and treated with cancellous screw fixation were retrospectively identified. Full clinical data was available for 79 of the 97 patients identified. All patients had in situ fracture fixation. Results. Of the 79 patients, M:F was 22:57, average age was 81.3 years. The average inpatient stay was 13.2 days. The mean follow-up was 12 months. 24 patients had Garden type I and 55 type II fractures. 26 (32.9%) patients did not return to their pre-morbid mobility status, 5 (6.3%) did not return to their preadmission dwelling (2 went to residential homes and 3 to nursing homes). We had documented radiographic details in 46 patients: 41 patients had a healed fracture on radiographs (89.1%), 5 patients had AVN, 4 patients had non-union and 1 patient had AVN with non-union. The radiographic failure rate was 22%. 15 patients had evidence of screw back out with healed fracture. 12 of the 46 complained of pain post-operatively of which 9 (19.6%) patients had re-operation; 6 (13%) underwent revision surgery and 3 (6.5%) required screw removal. 30-day mortality was 3.7%. 1-year mortality was 23.2% of which 16 died within the first 6 months (19.5%). Conclusion. This study shows that, in our unit, cancellous screw fixation of undisplaced femoral neck fractures in patients over the age 70 had a good outcome with a 20% re-operation rate and 22% radiographic failure rate. One third of the patients did not return to their preadmission mobility level/dwelling

To evaluate the radiographic mid-to long-term result of femoral revision hip arthroplasty using impacted cancellous allograft combined with cemented, collarless, polished and tapered stem. Among 27 patients with impacted cancellous allograft with a cemented stem, 28 hips from 26 consecutive patients were analyzed retrospectively. The average patient age was 59 years. The follow-up period ranged 36 months to 10 years, 3 months (mean, 76.6 months). Radiographic parameters analyzed in this study included subsidence of the stem in the cement, subsidence of the cement mantle in the femur, bone remodeling of the femur, radiolucent line, and osteolysis. Radiographic analysis showed very stable stem initially. 27 stems showed minimal subsidence (less than 0.005m) and 1 stem showed moderate subsidence (about 0.008m) in the cement. But there was no mechanical failure and subsidence at the composite-femur interface. Evidence of cortical and trabecular remodeling were observed in all cases. No radiolucent line or osteolysis were found in the follow-up period. There were 4 proximal femoral cracks and 1 distal femoral splitting during operation. The result of cemented stem revision with the use of impacted cancellous allograft was good mid-to long-term. And femoral bone stock deficiency may be reconstructed successfully