Background

High re-rupture rates following repairs of rotator cuff tears (RCTs) have resulted in the increased use of repair grafts to act as temporary scaffolds to support tendon healing. It has been estimated that thousands of extracellular matrix repair grafts are used annually to augment surgical repair of rotator cuff tears. The only mechanical assessment of the suitability of these grafts for rotator cuff repair has been made using tensile testing only, and compared grafts to canine infraspinatus. As the shoulder and rotator cuff tendons are exposed to shearing as well as uniaxial loading, we compared the response of repair grafts and human rotator cuff tendons to shearing mechanical stress. We used a novel technique to study material deformation, dynamic shear analysis (DSA).

The aim of this study is to print 3D polycaprolactone (PCL) scaffolds at high and low temperature (HT/LT) combined with salt leaching to induced porosity/larger pore size and improve material degradation without compromising cellular activity of printed scaffolds. PCL solutions with sodium chloride (NaCl) particles either directly printed in LT or were casted, dried, and printed in HT followed by washing in deionized water (DI) to leach out the salt. Micro-Computed tomography (Micro-CT) and scanning electron microscope (SEM) were performed for morphological analysis. The effect of the porosity on the mechanical properties and degradation was evaluated by a tensile test and etching with NaOH, respectively. To evaluate cellular responses, human bone marrow-derived mesenchymal stem/stromal cells (hBMSCs) were cultured on the scaffolds and their viability, attachment, morphology, proliferation, and osteogenic differentiation were assessed. Micro-CT and SEM analysis showed that porosity induced by the salt leaching increased with increasing the salt content in HT, however no change was observed in LT. Structure thickness reduced with elevating NaCl content. Mass loss of scaffolds dramatically increased with elevated porosity in HT. Dog bone-shaped specimens with induced porosity exhibited higher ductility and toughness but less strength and stiffness under the tension in HT whereas they showed decrease in all mechanical properties in LT. All scaffolds showed excellent cytocompatibility. Cells were able to attach on the surface of the scaffolds and grow up to 14 days. Microscopy images of the seeded scaffolds showed substantial increase in the formation of extracellular matrix (ECM) network and elongation of the cells. The study demonstrated the ability of combining 3D printing and particulate leaching together to fabricate porous PCL scaffolds. The scaffolds were successfully printed with various salt content without negatively affecting cell responses. Printing porous thermoplastic polymer could be of great importance for temporary biocompatible implants in bone tissue engineering applications

This study aims to assess the fracture mechanics of type-2 diabetic (T2D) femoral bone using innovative site-specific tests, whilst also examining the cortical and trabecular bone microarchitecture from various regions using micro-computed tomography (CT) of the femur as the disease progresses. Male [Zucker Diabetic Fatty (ZDF: fa/fa) (T2D) and Zucker Lean (ZL: fa/+) (Control)] rats were euthanized at 12-weeks of age, thereafter, right and left femora were dissected (Right femora: n = 6, per age, per condition; Left femora: n=8-9, per age, per condition). Right femurs were notched in the posterior of the midshaft. Micro-CT was used to scan the proximal femur, notched and unnotched femoral midshaft (cortical) of the right femur and the distal metaphysis (trabecular) of the left femur to investigate microarchitecture and composition. Right femurs were fracture toughness tested to measure the stress intensity factor (Kic) followed by a sideways fall test using a custom-made rig to investigate femoral neck mechanical properties. There was no difference in trabecular and cortical tissue material density (TMD) between T2D and control rats. Cortical thickness was unchanged, but trabeculae were thinner (p<0.01) in T2D rats versus controls. However, T2D rats had a greater number of trabeculae (p<0.05) although trabecular spacing was not different to controls. T2D rats had a higher connectivity distribution (p<0.05) and degree of anisotropy (p<0.05) in comparison to controls. There was no difference in the mechanical properties between strains. At 12-weeks of age, rats are experiencing early-stage T2Ds and the disease impact is currently not very clear. Structural and material properties are unchanged between strains, but the trabecular morphology shows that T2D rats have more trabecular struts present in order to account for the thinner trabeculae

Rotator cuff tears are common, with failure rates of up to 94% for large and massive tears. 1. For such tears, reattachment of the musculotendinous unit back to bone is problematic, and any possible tendon-bone repair heals through scar tissue rather than the specially adapted native enthesis. We aim to develop and characterise a novel soft-hard tissue connector device, specific to repairing/bridging the tendon-bone injury in significant rotator cuff tears, employing decellularised animal bone partially demineralised at one end for soft tissue continuation. Optimisation samples of 15×10×5mm. 3. , trialled as separate cancellous and cortical bone samples, were cut from porcine femoral condyles and shafts, respectively. Samples underwent 1-week progressive stepwise decellularisation and a partial demineralisation process of half wax embedding and acid bathing. Characterisations were performed histologically for the presence/absence of cellular staining in both peripheral and central tissue areas (n=3 for each cortical/cancellous, test/PBS control and peripheral/central group), and with BioDent reference point indentation (RPI) for pre- and post-processing mechanical properties. Histology revealed absent cellular staining in peripheral and central cancellous samples, whilst reduced in cortical samples compared to controls. Cancellous samples decreased in wet mass after decellularisation by 45.3% (p<0.001). RPI measurements associated with toughness (total indentation depth, indentation depth increase) and elasticity (1st cycle unloading slope) showed no consistent changes after decellularisation. X-rays confirmed half wax embedding provided predictable control of the mineralised-demineralised interface position. Initial optimisation trials show proof-of-concept of a soft-hard hybrid scaffold as an immune compatible xenograft for irreparable rotator cuff tears. Decellularisation did not appreciably affect mechanical properties, and further biological, structural and chemical characterisations are underway to assess validity before in vivo animal trials and potential clinical translation

In this study, we developed biocompatible adhesive which enables implanted chondrogenic-enhanced hASCs being strongly fixed to the lesion site of defected cartilage. The bioengineered mussel adhesive protein (MAP) was produced and purified using a bacterial expression system as previously reported. The cell encapsulated coacervate was formulated with two polyelectrolyte, the MAP and 723kDa hyaluronic acid (HA). MAP formed liquid microdroplets with HA and subsequently gelated into microparticles, which is highly viscous and strongly adhesive. The MAP with chondro-induced hASCs were implanted on the osteochondral defect created in the patellar groove/condyle of OA-induced rabbits. Rabbits were allocated to three different groups as follows: Group1 – Fibrin only; Group2 – Fibrin with hASCs (1.5×10. 6. chondro-induced hASCs); Group3; MAP with hASCs. The implanted cells were labeled with a fluorescent dye for in vivo visualization. After 35 days, fluorescent signals were more potently detected for MAP with hASCs group than Fibrin with hASCs group in osteochondral defect model. Moreover, histological assessment showed that MAP with hASCs group had the best healing and covered with hyaline cartilage-like tissue. The staining image shows that MAP with hASCs group were filled with perfectly differentiated chondrocytes. Although Fibrin with hASCs group had better healing than fibrin only group, it was filled with fibrous cartilage which owes its flexibility and toughness. As MAP with hASCs group has higher possibility of differentiating to complete cartilage, Fibrin only group and Fibrin with hASCs group have failed to treat OA by rehabilitating cartilage. In order to clarify the evidence of remaining human cell proving efficacy of newly developed bioadhesive, human nuclear staining was proceeded with sectioned rabbit cartilage tissue. The results explicitly showed MAP with hASCs group have retained more human cells than Fibrin only and Fibrin with hASCs groups. We investigated the waterproof bioadhesive supporting transplanted cells to attach to defect lengthily in harsh environment, which prevents cells from leaked to other region of cartilage. Collectively, the newly developed bio-adhesive, MAP, could be successfully applied in OA treatment as a waterproof bioadhesive with the capability of the strong adhesion to target defect sites

Osteoporosis (OP) results in a reduction in the mechanical competence of the bone tissue of the sufferers. In skeletal sites such as the proximal femur and the vertebrae, OP manifests itself in low trauma fragility fractures which are debilitating for the patient. The relationships between the compressive strength of cancellous tissue and its apparent density are well established in studies of the past. Recently the authors have presented a method able to assess the fracture toughness properties of cancellous bone (1), a challenging cellular material which can exhibit large elasto-plastic deformations. The in-vitro measurement of fracture toughness alongside the customary compressive strength can provide a comprehensive assessment of the mechanical capacity of cancellous bone, which will reflect closer its ability to resist crack initiation. The aims of the present study were: (1) to examine whether the observed fracture toughness deterioration can also be detected by non-invasive quantitative ultrasound (QUS); and (2) to provide rational evidence for the well proven ability of QUS to predict directly ‘risk of fracture’. 20 femoral heads were obtained from donors undergoing emergency surgery for a fractured neck of femur. QUS investigations of the calcaneus, proximal phalanx and distal radius were undertaken within 72 hours of surgery. 128 fracture toughness samples and 20 compression cores were manufactured and tested. Two clinical QUS systems were used to obtain in-vivo scan data and then directly compared those to the density, porosity and the fracture mechanics of tissue extracted from the same individuals. The results demonstrated not only that there was a significant link between in-vivo determined QUS values for the calcaneus and finger to the density of the density of the femoral head; but that there was also a significant link between the QUS results from the calcaneus and the fracture toughness of the cancellous bone from the femoral head. These results point towards a systemic effect of osteoporosis which affects similarly different parts of the skeleton and supports the use of clinical QUS systems as a diagnostic tool for the prediction of fracture risk

Complex spinal deformities can cause pain, neurological symptoms and imbalance (sagittal and/or coronal), severely impairing patients’ quality of life and causing disability. Their treatment has always represented a tough challenge: prior to the introduction of modern internal fixation systems, the only option was an arthrodesis to prevent worsening of the deformity. Then, the introduction of pedicle screws allowed the surgeons to perform powerful corrective manoeuvres, distributing forces over multiple levels, to which eventually associate osteotomies. In treating flexible coronal deformities, in-ternal fixation and corrective manoeuvres may be sufficient: the combination of high density pedicle screws and direct vertebral rotation revolutionized surgical treatment of scoliosis. However, spinal osteotomies are needed for correcting complex rigid deformities; the type of osteot-omy must be chosen according to the aetiology, type and apex of the deformity. When dealing with large radius deformities, spread over multiple levels and without fusion, multiple posterior column os-teotomies such as Smith-Petersen and Ponte (asymmetric, when treating scoliosis) can be performed, dissipating the correction over many levels. Conversely, the management of a sharp, angulated de-formity that involves a few vertebral levels and/or with bony fusion, requires more aggressive 3 col-umn osteotomies such as Pedicle Subtraction Osteotomies (PSO), Bone Disc Bone Osteotomies (BDBO) or Vertebral Column Resection (VCR). Sometimes the deformity is so severe that cannot be corrected with only one osteotomy: in this scenario, multilevel osteotomies can be performed

Tendon regeneration is complex since the scaffold has to bear high loads and stress concentrations, while providing suitable deformability. Previous studies demonstrated a physiological orientation of the fibers and good cell adhesion on electrospun polymeric scaffolds [1]. The aims of this work were to: (i) prepare and characterize electrospun resorbable scaffolds with different compositions and (ii) develop a process to produce a multiscale bundle assembly to mimic the hierarchical structure and biomechanical properties of a real tendon. We produced fibrous scaffolds made of blends of poly-L-lactic acid (PLLA) and collagen (Coll):. Pure PLLA;. PLLA/Coll 75/25 w/w;. PLLA/Coll 50/50 w/w. In order to prepare 3D bundles made of aligned fibres, we used a high-speed rotating collector. The electrospun nanofibers were deposited tangentially onto the drum, the electrospun layer was manually rolled transversely along the drum and then removed. The bundles were approximately 150 mm long and 300–450 mm in diameter. Five specimens were prepared and tested for each blend. To evaluate the mechanical properties of the bundles a tension test was applied with capstan grips on a testing machine with a 100N load cell, under the following conditions:. Gauge length: 20 mm. Monotonic ramp to break detection. Actuator speed 5 mm/min. For all the bundles, the stress-strain curve showed an initial non-linear part (toe region), similar to the laxity of the tendon at rest. The mechanical analysis confirmed the outstanding ductility and toughness of pure PLLA. Increasing the percentage of collagen resulted in a reduction of ductility. The PLLA/Coll 50/50 had a rather brittle behaviour. The values of mechanical properties found for the different compositions were slightly lower but of the same order of magnitude as tendon fibers (Failure stress: 33.7±19.2 MPa; Failure strain: 21.0±9.1 %; Young Modulus: 257±101 MPa [2]). The bundles made of pure PLLA had a failure stress of 13.2±0.8 MPa; failure strain of 84.7±9.4%; Young Modulus of 78.6±7.5 MPa. The bundles made of PLLA/Coll 50/50 had: failure stress of 10.5±1.5 MPa; failure strain of 21.4±2.7%, Young Modulus of 65.7±9.8 MPa. The most promising composition was the PLLA/Coll 75/25, with a failure stress of 14.0±0.7 MPa; failure strain of 40.3±2.2 %, Young Modulus of 98.6±12 MPa. We also tested bundles mechanical properties after aging samples in phosphate buffer at 37 °C for 48 hours, 7 and 14 days. After ageing, stress and strain values were progressively lower, while the toughness increased, compared to the dry samples. The promising results found in this work for the electrospun PLLA-collagen blends confirm their potential use for tendon tissue regeneration. This is a starting point for developing multiscale scaffolds mimicking the structure of tendon tissue, which can potentially be used in human regenerative medicine both as bioresorbable prosthesis, or inserted in a bioreactor for in vitro production of tendon tissue

Aim. To investigate the effects of strain rate and mineral level on the stress at failure, stiffness and toughness of whole bones. Methods. 40 ovine femurs were harvested and subjected to either slow [8.56 × 10−3 s−1 (± 1.42 × 10−3 SD)] or dynamic [17.14 s−1 (± 8.20 SD)] loading. Half the bones were demineralised by 20% compared to the original mineral content. These were allocated evenly between the high and low strain rate groups. Dynamic loading was achieved by custom designed comminution device. Slow rate testing was carried out on a Zwick/Roell z005 testing machine. Results. Strain rate was found to increase the Young's modulus in both the normal and demineralised bone. Additionally the toughness of the bones at failure was found to reduce with increasing strain rate. When comparing bone of normal quality the stress at failure was found to increase with strain rate. However, this effect was greatly reduced when comparing the effect of strain rate on the stress occurring in demineralised bones. Discussion. These results show that bone has an ability to withstand higher than normal stresses if these are applied quickly and for a short duration (such as would occur in a traumatic event). This ability is greatly reduced when the bone is of reduced mineral content, such as is found in aged or diseased bone

Compartment syndrome of the foot requires urgent surgical treatment. Currently, there is still no agreement on the number and location of the myofascial compartments of the foot. The aim of this cadaver study was to provide an anatomical basis for surgical decompression in the event of compartment syndrome. We found that there were three tough vertical fascial septae that extended from the hindfoot to the midfoot on the plantar aspect of the foot. These septae separated the posterior half of the foot into three compartments. The medial compartment containing the abductor hallucis was surrounded medially by skin and subcutaneous fat and laterally by the medial septum. The intermediate compartment, containing the flexor digitorum brevis and the quadratus plantae more deeply, was surrounded by the medial septum medially, the intermediate septum laterally and the main plantar aponeurosis on its plantar aspect. The lateral compartment containing the abductor digiti minimi was surrounded medially by the intermediate septum, laterally by the lateral septum and on its plantar aspect by the lateral band of the main plantar aponeurosis. No distinct myofascial compartments exist in the forefoot. Based on our findings, in theory, fasciotomy of the hindfoot compartments through a modified medial incision would be sufficient to decompress the foot

Total joint replacement (TJR), such as hip and knee replacement, is commonly used for the treatment of end stage arthritis. The use of Poly (methylmethacrylate) bone cement is a gold standard in such replacement, where it fixes the implant in place and transfer stresses between bone and implant, and frequently used for local delivery of drugs such as antibiotics. The use of antibiotic loaded bone cement is considered a well-established standard in the treatment and prophylaxis of Prosthetic joint infections (PJI). PJIs is a serious problem that decreases success rate of surgery and can be life threatening to patients, where the incidence can reach up 2% in total and hip replacements and up to 40% for revision surgery. Currently used antibiotic loaded bone cements have many limitations, including burst release of < 10% of antibiotic added. This burst release falls rapidly below inhibitory level within few days, which leads to selection of resistant antimicrobial strains and does not provide prophylaxis from early and delayed stage infection. This study aims to provide a controlled release for gentamicin when loaded on Silica nanoparticles (NP) using layer-by-layer technique (LbL) to provide prophylaxis and treatment from postsurgical infections. The gentamicin loaded NPs were incorporated into PMMA bone cement and the new nanocomposite is characterized for gentamicin release, antimicrobial and mechanical properties. Our results showed that the nanocomposite gentamicin release continued for 30 days at concentration 3 times higher than the commercial formulation containing the same amount of gentamicin, where burst release for few days were observed. Moreover, the nanocomposite showed superior antimicrobial inhibition for bacterial growth and good cytocompatibility without adversely affecting the cement compressive strength, bending and fracture toughness properties

To date there has been no material for endoprosthetics providing excellent resistance to abrasion and corrosion combined with great tensile strength, fracture toughness, and bending strength, as well as adequate biocompatibility. Carbon-fiber-reinforced silicon carbide (C/SiC, C/C-SiC or C/SiSiC) is as a ceramic compound a potentially novel biomaterial offering higher ductility and durability than comparable oxide ceramics. Aim of this investigation was to test the suitability of C/SiC ceramics as a new material for bearing couples in endoprosthetics. One essential quality that any new material must possess is biocompatibility. For this project the in-vitro biocompatibility was investigated by using cuboid like scaffolds made of CMC. To determine whether the material is suited as a lubricant partner in endoprosthetics, we measured its abrasion coefficient and wear tolerance against various antibodies. The C/SiC samples tested were produced via the Liquid Silicon Infiltration (LSI) of pyrolized porous fiber preforms made by warm-flow pressing free-flowing granulates on a hydraulic downstroking press with a heated die of the type HPS-S, 1000 kN. After preparation of the composites, the tribological characteristics are determined. Flexural strength was determined at room temperature according to DIN685-3 with an universal testing machine Z100 and the Young”s -modulus was carried out via resonant frequency-damping analysis RFDA. The samples”surface as well as cell adhesion and cell morphology were assessed via ESEM. The human osteoblast-like cell line MG-63 and human ostoeblast were used for cel culture ecperiments (WST, Live/dead, Cytotoxicity, cell morphology). Based on the raw data the mean value and the standard deviation were calculated. The Mann-Whitney-U-Test was used to evaluate the differences between experiment and control samples. The flexural strength at room temperature is approx. 180 MPa, while the elongation at break is about 0.13%. The Young”s modulus is detected between 120 and 150 GPa. The density lies between 2.5 and 3.0 g/cm. 3. We noted a friction coefficient µ between 0.31. The cell lines exhibited no morphological alterations, and adhered well to the C/SiC samples. Vitality was not impaired by contact with the ceramic composite. Cell growth was observed evenly distributed over a 21-day period. In the future, investigators aiming to apply this composite in endoprosthetics will have to focus on its efficacy in conjunction with sudden, strong demands, and long-term performance in bodily fluids within joint simulators, etc. In conclusion: C/SiC can definitely be considered a new material with genuine potential for use in endoprosthetics

This edition of the Cochrane Corner looks at the three reviews that were published in the second half of 2023: surgical versus non-surgical interventions for displaced intra-articular calcaneal fractures; cryotherapy following total knee arthroplasty; and physical activity and education about physical activity for chronic musculoskeletal pain in children and adolescents.

The management of maxillofacial injuries requires restoring the contours of the facial skeleton to achieve an aesthetic outcome. When fractures are simple, open reduction and rigid fixation with stock titanium osteosynthesis plates is usually sufficient. However, when the damage is more substantial (when the fracture is comminuted or in case of a bone defect) anatomical landmarks are lost and the reconstruction requires the use of titanium meshes. These meshes are usually modelled intraoperatively to restore the contours of the bone. This can be a tough and time consuming task in case of minimal invasive approach and intraoperative edema. When the injury is unilateral, printing a 3D anatomical model of the mirrored unaffected side is an easy way to accurately pre-bend the mesh preoperatively. With the emergence of “low cost” consumer 3D printers, the aim of our study was to evaluate the cost of this technique in a department of maxillofacial surgery. The first part of the study was to evaluate free software solutions available online to determine which of these could be used to create 3D virtual models from the patients' volume imaging data, mirror the model and export an STL file suitable for 3D-printing with a consumer 3D-printer. The second part was to identify the desktop 3D-printers commercially available according to the different technology used, their prices and that of consumables required. Five free software solutions were identified to create STL meshes of the patient's anatomy from thin slice CT scan DICOM data. Two more were available to repair, segment and mirror them to provide a clean STL file suitable for 3D printing with a desktop 3D printer. The prices of 2 different printers were then listed for each of the 3 additive manufacturing technologies available to date. Prices ranged from 2,299 € for the Ultimaker 2+© (Fuse Deposition Modeling, FDM), to 4,999 € for the Sintratec© printer (Selective Laser Sintering, SLS), the Formlabs 2© (stereolithography) being at an intermediate price of 3,299 €. Finally, the cost of the manufacture of a model was calculated for each of these printers. Considering a model of a supraorbital ridge printed to restore the anterior wall of the frontal sinus, the volume of the mesh is around 20 cm. 3. This represents a cost of less than 1 € with the FDM technology, 4.70 € with stereolithography and 1.50 € with the SLS printer. Since patents of additive manufacturing have become part of the public domain, the cost of 3D printing technology has fallen drastically. Desktop printers are now an investment accessible to a surgery department and the cost of the material is low. This allows the surgeons, by the mean of free software, to directly create 3D models of their patients' anatomy, mirror them if needed and manufacture a template to pre-bend titanium meshes that will be subsequently sterilized for the surgery. Having the printer in the department reduces manufacturing lead times and makes this technique possible even for urgent cases

Introduction. Tendon disease and rupture are common in patients with diabetes and these are exacerbated by poor healing. although nanoscale changes in diabetic tendon are linked to increased strength and stiffness. The resistance to mechanical damage of a tissue may be measured using fatigue testing but this has not been carried out in diabetic tendon, although the toughness of diabetic bone is known to be reduced. The aim of this study was to measure the static fatigue behaviour of tendons from a streptozotocin (STZ)-induced rat model of diabetes, hypothesising that diabetes causes tendon to show lower resistance to mechanical damage than healthy tendon. Materials and Methods. Diabetic (n=3, 12 weeks post-STZ) and age-matched control (n=3) adult male Sprague Dawley rats were culled, tails harvested and stored at −80ºC. Following defrosting, fascicles (5 per animal) were carefully dissected, mean diameter measured using an optical micrometer and mounted in a Bose Biodynamics test machine using custom grips in a PBS bath. Static fatigue testing at 30 MPa to failure enabled both elastic modulus (initial ramp) and steady state creep rate (gradient at creep curve inflexion) to be measured. Data are reported as median ± interquartile range and pw0.05 using a Mann-Whitney U test was taken as significant. Results. Confirming previous reports, tendon from diabetic rats showed significantly higher elastic modulus (201 ± 68 MPa) than healthy (151 ± 62 MPa). Strain at failure showed no differences between groups. Tendon from diabetic rats showed significantly slower steady state creep (71 ± 44 μstrain s. −1. ) than healthy (691 ± 1000 μstrain s. −1. ). Discussion. These preliminary data show an order of magnitude larger resistance to mechanical damage in diabetic tendons, possibly associated with the previously reported increased packing and decreased fibril diameters. Energy-storing flexor tendons, the most commonly affected in diabetics, and the positional tendons tested here show similar fatigue behaviour when tested at the same fraction of “stress-in-life”. Further investigation is required into the cell tissue repair response in diabetes in order to link reduced rates of mechanical damage with the clinically increased risk of disease and rupture in diabetic patients

In this study we explore the hypothesis that there is a correlation between the ratio of the intensities of specific peaks of the Raman spectrum of bone tissue and the material properties of that particular type of bone. Raman spectroscopy is a powerful analytical technique capable of providing rich chemical information on the composition of skeletal tissue matrices and it has been used extensively to interrogate bone in the past. Spectra are presented of a selection of animal bones, each having greatly differing material properties, the differences having been produced by evolution in response to their greatly differing functions. The main examples described are deer antler (a bone naturally selected for toughness), tympanic bulla from a fin whale (naturally selected for stiffness) and the intermediate ‘standard’ bone from adult mammalian limbs which must be both tough enough to resist fracture and stiff enough to resist deformation during physiological loading (from an ovine femur in our case). In order to illustrate the specific relationship between material properties and Raman spectra additional mineralized tissues also with differing functions and of known Young's moduli are also introduced. The results show that a strong correlation exists between the mineral to collagen ratio of these different bone tissues as measured with Raman spectroscopy and their (previously published) Young's moduli. Raman spectra have been retrieved through skin and tissue in other studies in the past, an amalgamation of refined versions of those in vivo techniques with the work introduced here paves the way for the emergence of novel systems for assessing the material properties of bone tissue at specific anatomical sites in vivo in the future

Summary Statement. The chemistry, amount, morphology, and size distribution of wear debris from silicon nitride coatings generated in the bearing surface can potentially reduce the negative biological response and increase the longevity compared to conventional materials in joint replacements. Introduction. Total hip implants have a high success rate at 15 years of implantation, but few survive over 25 years. At present, revisions are mostly due to aseptic loosening, believed to mainly be caused by the biological response to wear debris generated in the joint bearing. For the polymer liners the size of the wear debris determines the biological response, while for metal bearing surfaces a limitation is the metal ion release. When ceramics are used, the wear debris is in general small and mechanical factors may be the main cause for failure. A more recent, experimental alternative is to let the well-known metallic substrate serve as the soft, tough bulk, and additionally apply a hard and smooth ceramic coating. In this way a lower wear rate and reduced metal ion release could be obtained. Furthermore, the chosen composition, silicon nitride (SixNy), contains no detrimental ions, and silicon nitride debris has been shown to slowly dissolve in aqueous medium. Altogether, it can potentially increase the longevity of the implant. However, the debris from SixNy coatings has not yet been characterised. In this study, a wear model test was performed to generate wear debris from SixNy coatings. The debris was characterised using scanning electron microscopy (SEM) and energy-dispersive X-ray spectroscopy (EDS) in combination with computational calculations. Methods. Silicon nitride coatings deposited on flat cobalt chromium alloy (ASTM F75) were worn in a reciprocating ball on disc setup in a 25% serum solution at 37°C against an alumina ball with a load of 1.5 N. Wear debris was separated using serum digestion with hydrochloric acid (ISO 17853:2011) and examined in SEM in combination with EDS. As reference polyethylene (PE) was used to verify that relevant particles sizes were achieved. The SEM images were processed using a modified MATLAB-script originating from Cervera Gontard et al. [1], identifying the particles and calculating their size. Results. Particles generated from SixNy coatings (n=62) a size distribution D50 [D10-D90] of 0.29 µm [0.16–0.69] and were round to oval in shape. The PE particles (n=70) had a size distribution of 0.29 µm [0.13–1.3], shaped similar to the SixNy particles or with a more elongated shape. Discussion and conclusions. PE wear debris has been reported to lie in the size range of nm up to several μm in vivo, with a large proportion within the critical size for macrophage activation (0.2 to 0.8 μm). The model test reports relevant sizes and shape of PE debris, confirming the validity of the method. Particles generated from the SixNy coatings showed a smaller size range than PE, however most particles were within the critical size range for biological activation. In conclusion, this model test could be used to generate what we believe are relevant sizes and shapes of PE and SixNy wear debris and to learn more at an early stage of prediction of wear debris. Further dissolution studies as well as studies on the in vitro and in vivo cell response to these types of particles will be performed. The authors thank the Swedish Foundation for Strategic Research (SSF) through MS2E and FP7 NMP project LifeLongJoints for financial support, as well as Linköping University for the coating facilities and expertise

Objectives

Microindentation has the potential to measure the stiffness of an individual patient’s bone. Bone stiffness plays a crucial role in the press-fit stability of orthopaedic implants. Arming surgeons with accurate bone stiffness information may reduce surgical complications including periprosthetic fractures. The question addressed with this systematic review is whether microindentation can accurately measure cortical bone stiffness.

In a rabbit model we investigated the efficacy of a silk fibroin/hydroxyapatite (SF/HA) composite on the repair of a segmental bone defect. Four types of porous SF/HA composites (SF/HA-1, SF/HA-2, SF/HA-3, SF/HA-4) with different material ratios, pore sizes, porosity and additives were implanted subcutaneously into Sprague-Dawley rats to observe biodegradation. SF/HA-3, which had characteristics more suitable for a bone substitite based on strength and resorption was selected as a scaffold and co-cultured with rabbit bone-marrow stromal cells (BMSCs). A segmental bone defect was created in the rabbit radius. The animals were randomised into group 1 (SF/HA-3 combined with BMSCs implanted into the bone defect), group 2 (SF/HA implanted alone) and group 3 (nothing implanted). They were killed at four, eight and 12 weeks for visual, radiological and histological study.

The bone defects had complete union for group 1 and partial union in group 2, 12 weeks after operation. There was no formation of new bone in group 3. We conclude that SF/HA-3 combined with BMSCs supports bone healing and offers potential as a bone-graft substitute.