We used a rabbit model to investigate the mechanism by which the angulation of fractures is corrected in children. We produced a transverse proximal tibial fracture in one leg of 12 eight-week-old New Zealand white rabbits and measured bone alignment and length and the patterns of bone growth and remodelling. The angle between the joint surfaces changed rapidly to correct the alignment of the limb as a result of asymmetrical growth of epiphyseal plates. In an adult with closed plates, the angle between the joint surfaces cannot therefore improve. The angle at the fracture itself showed slow improvement because of bone drift and the asymmetrical growth of the epiphyseal plates. Remodelling corrected the shape of the bone in the region of the fracture. Periosteal division on the convex side increased the growth of the epiphyseal plate on that side, thus slowing the correction. The effect was relatively small, providing an indication that factors other than the periosteum are important in inducing correction. External torsional deformities developed because of helical growth at the plate. This was probably caused by abnormal posture which induced a torque at the growth plate. Helical growth is the mechanism by which rotational deformities can occur and correct

Metabolic bone diseases, such as osteoporosis and osteopetrosis, result from an imbalanced bone remodeling process. In vitro bone models are often used to investigate either bone formation or resorption independently, while in vivo, these processes are coupled. Combining these processes in a co-culture is challenging as it requires finding the right medium components to stimulate each cell type involved without interfering with the other cell type's differentiation. Furthermore, differentiation stimulating factors often comprise growth factors in supraphysiological concentrations, which can overshadow the cell-mediated crosstalk and coupling.

To address these challenges, we aimed to recreate the physiological bone remodeling process, which follows a specific sequence of events starting with cell activation and bone resorption by osteoclasts, reversal, followed by bone formation by osteoblasts. We used a mineralized silk fibroin scaffold as a bone-mimetic template, inspired by bone's extracellular matrix composition and organization. Our model supported osteoclastic resorption and osteoblastic mineralization in the specific sequence that represents physiological bone remodeling.

We also demonstrated how culture variables, such as different cell ratios, base media, and the use of osteogenic/osteoclast supplements, and the application of mechanical load, can be adjusted to represent either a high bone turnover system or a self-regulating system. The latter system did not require the addition of osteoclastic and osteogenic differentiation factors for remodeling, therefore avoiding growth factor use.

Our in vitro model for bone remodeling has the potential to reduce animal experiments and advance in vitro drug development for bone remodeling pathologies like osteoporosis. By recreating the physiological bone remodeling cycle, we can investigate cell-cell and cell-matrix interactions, which are essential for understanding bone physiology and pathology. Furthermore, by tuning the culture variables, we can investigate bone remodeling under various conditions, potentially providing insights into the mechanisms underlying different bone disorders.

Abstract

Extracellular matrix (ECM) mechanical cues guide healing in tendons. Yet, the molecular mechanisms orchestrating the healing processes remain elusive. Appropriate tissue tension is essential for tendon homeostasis and tissue health. By mapping the attainment of tensional homeostasis, we aim to understand how ECM tension regulates healing. We hypothesize that diseased tendon returns to homeostasis only after the cells reach a mechanically gated exit from wound healing.

We engineered a 3D mechano-culture system to create tendon-like constructs by embedding patient-derived tendon cells into a collagen I hydrogel. Casting the hydrogel between posts anchored in silicone allowed adjusting the post stiffness. Under this static mechanical stimulation, cells remodel the (unorganized) collagen representing wound healing mechanisms. We quantified tissue-level forces using post deflection measurements. Secreted ECM was visualized by metabolic labelling with non-canonical amino acids, click chemistry and confocal microscopy. We blocked cell-mediated actin-myosin contractility using a ROCK inhibitor (Y27632) to explore the involvement of the Rho/ROCK pathway in tension regulation.

Tissue tension forces reached the same homeostatic level at day 21 independent of post compliance (p = 0.9456). While minimal matrix was synthesized in early phases of tissue formation (d3-d5), cell-deposited ECM was present in later stages (d7-d9). More ECM was deposited by tendon constructs cultured on compliant (1Nm) compared to rigid posts (p = 0.0017). Matrix synthesized by constructs cultured on compliant posts was less aligned (greater fiber dispersion, p = 0.0021). ROCK inhibition significantly decreased tissue-level tensional forces (p < 0.0001).

Our results indicate that tendon cells balance matrix remodeling and synthesis during tissue repair to reach an intrinsically defined “mechanostat setpoint” guiding tension-mediated exit from wound healing towards homeostasis. We are identifying specific molecular mechanosensors governing tension-regulated healing in tendon and investigate the Rho/ROCK system as their possible downstream pathway.

The effect of high-fat diet and testosterone replacement therapy upon bone remodelling was investigated in orchiectomised male APOE-/- mice.

Mice were split in to three groups: sham surgery + placebo treatment (control, n=9), orchiectomy plus placebo treatment (n=8) and orchiectomy plus testosterone treatment (n=10). Treatments were administered via intramuscular injection once a fortnight for 17 weeks before sacrifice at 25 weeks of age. Tibiae were scanned ex-vivo using µCT followed by post-analysis histology and immunohistochemistry.

Previously presented µCT data demonstrated orchiectomised, placebo treated mice exhibited significantly reduced trabecular bone volume, number, thickness and BMD compared to control mice despite no significant differences in body weight. Trabecular parameters were rescued back to control levels in orchiectomised mice treated with testosterone. No significant differences were observed in the cortical bone.

Assessment of TRAP stained FFPE sections revealed no significant differences in osteoclast or osteoblast number along the endocortical surface. IHC assessment of osteoprotegerin (OPG) expression in osteoblasts is to be quantified alongside markers of osteoclastogenesis including RANK and RANKL.

Results support morphological analysis of cortical bone where no change in cortical bone volume or density between groups is in line with no significant change in osteoblast or osteoclast number and percentage across all three groups.

Future work will include further IHC assessment of bone remodelling and adiposity, as well as utilisation of mechanical testing to establish the effects of observed morphological differences in bone upon mechanical properties. Additionally, the effects of hormone treatments upon murine-derived bone cells will be investigated to provide mechanistic insights.

Introduction and Objective

Bone remodelling is a continuous process whereby osteocytes regulate the activity of osteoblasts and osteoclasts to repair loading-induced microdamage. While many in vitro studies have established the role of paracrine factors (e.g., RANKL/OPG) and cellular pathways involved in bone homeostasis, these techniques are generally limited to two-dimensional cell culture, which neglects the role of the native extracellular matrix in maintaining the phenotype of osteocyte. Recently, ex vivo models have been used to understand cell physiology and mechanobiology in the presence of the native matrix. Such approaches could be applicable to study the mechanisms of bone repair, whilst also enabling exploration of biomechanical cues. However, to date an ex vivo model of bone remodelling in cortical bone has not been developed. In this study, the objective was to develop an ex vivo model where cortical bone was subjected to cyclic strains to study the remodelling of bone.

Introduction

Chondrocytes are enveloped within the pericellular matrix (PCM), a structurally intricate network primarily demarcated by the presence of collagen type VI microfibrils and perlecan, resembling a protective cocoon. The PCM serves pivotal functions in facilitating cell mechanoprotection and mechanotransduction. The progression of osteoarthritis (OA) is associated with alterations in the spatial arrangement of chondrocytes, transitioning from single strings to double strings, small clusters, and eventually coalescing into large clusters in advanced OA stages. Changes in cellular patters coincide with structural degradation of the PCM and loss of biomechanical properties. Here, we systematically studied matrix metalloproteinases (MMPs), their distribution, activity, and involvement in PCM destruction, utilizing chondrocyte arrangement as an OA biomarker.

Introduction and Objective

Global prevalence of obesity has risen almost three-fold between 1975 and 2016. Alongside the more well-known health implications of obesity such as cardiovascular disease, cancer and type II diabetes, is the effect of male obesity on testosterone depletion and hypogonadism. Hypogonadism is a well-known contributor to the acceleration of bone loss during aging, and obesity is the single biggest risk factor for testosterone deficiency in men. Understanding the micro and macro structural changes to bone in response to testosterone depletion in combination with a high fat ‘Western’ diet, will advance our understanding of the relationship between obesity and bone metabolism. This study investigated the impact of surgically induced testosterone depletion and subsequent testosterone treatment upon bone remodelling in mice fed a high fat diet.

Background

Implant stability and is an important factor for adequate bone remodelling and both are crucial in the long-term clinical survival of total hip arthroplasty (THA). Assessment of early bone remodelling on X-rays during the first 2 years post-operatively is mandatory when stepwise introduction of a new implant is performed. Regardless of fixation type (cemented or cementless), early acetabular component migration is usually the weakest link in THA, eventually leading to loosening. Over the past years, a shift towards uncemented cup designs has occurred. Besides the established hydroxyapatite (HA) coated uncemented cups which provide ongrowth of bone, new uncemented implant designs stimulating ingrowth of bone have increased in popularity. These cups initiate ingrowth of bone into the implant by their open metallic structure with peripheral pores, to obtain a mechanical interlock with the surrounding bone, thereby stabilising the prosthesis in an early stage after implantation. This retrospective study assessed bone remodelling, osseointegration and occurrence of radiolucency around a new ingrowth philosophy acetabular implant.

Background

Children suffering from primary bone cancer necessitating resection of growth plates, may suffer progressive leg length discrepancy, which can be attenuated with extendable prostheses. A serious complication is catastrophic implant failure. Over time, bone will remodel, altering the stress pattern in the implant. By using finite element analysis we can model different bone remodeling conditions to ascertain the effect that this will have on stress distribution and magnitude.

A finite element analysis was performed. Simplified computer generated models were designed of a cemented femoral Stanmore growing massive endoprosthesis. Three scenarios were designed, modelled on post-operative radiographs. Scenario 1 had a gap between the end of the femur and the implant collar, scenario 2 had no gap, but with no bone attachment into the collar, and scenario 3 had growth of the bone over the length of the collar with attachment. Physiological loading conditions were applied. The resultant stress in the implant for each scenario was measured, and compared to the strength of the material. Peak stresses were recorded at the stem-collar junction.

The maximum stress recorded in the implant in scenario 1 was 3104.2Mpa, compared to 1054.4Mpa in scenario 2, and 321.2Mpa in scenario 3.

Most of researches related to osteoporosis emphasized on trabecular bone loss. However, cortical bone has a prominent role on bone strength determined by bone quality, such as 2D or 3D geometry and microstructure of bone, not only density.[1] The focal thinning of cortical bone associated with aging in post-menopausal osteoporotic bone in the proximal femur may predispose a hip to fracture.[2, 3] As the trabecular bone is lost with progression of osteoporosis, the remaining cortical bone take more predominant role on bone strength.[4] To date, no effective osteoporotic agent was demonstrated to enhance both cortical geometric change and bone strength. Herein, we investigate the effect of Teriparatide (rhPTH(1–34)) on cortical bone at femoral diaphysis in OVX rat model.

Twenty 12-week-old, female Sprague Dawley rats were used in this study. Bilateral ovariectomies were performed in 16 animals and randomly divided to three groups as control (N=6), OVX (N=6) and treatment group after OVX (OVX+F) by teriparatide (N=8). After twelve weeks of intervention, all rats were euthanized and right femurs and L5 vertebrae were extracted for further tests. All bone specimens were subjected to dual-energy X-ray absorptiometer (DXA) to evaluate areal bone mineral density (aBMD) of L5 vertebrae and femurs, micro-computed tomography (micro-CT) to analyze cortical bone parameters of femoral diaphysis, including cortical cross section area (CSA), cortical thickness and cross-sectional moment of inertia (CSMI). A three-point bending test was applied to determine fracture load of each femurs.

Compare to OVX group, increase of aBMD by 14.6 % at L5 vertebrae and 13.3% at femoral diahpysis in treatment group. The cortical parameters of femoral diaphysis, CSA and cortical thickness, analyzed by micro-CT were significantly increased but the increasing tendency of CSMI did not have significant changes statistically after teriparatide intervention for 3 months duration. The increase of cortical bone strength (OVX vs OVX+F group, 120.72±2.72 vs 137.93±5.02, p < 0.05) at femoral diaphysis after treatment were also noticed.

This study has point out a deeper look at geometric change of cortical bone after teriparatide treatment. This finding imply teirparatide has the ability to change the geometry of cortical bone and increase bone strength at femoral diaphysis.

The exact pathways of collagen remodeling in tendon tissue are not well understood. Therefore, we have established an ex vivo 3D collagen gel-based system and we studied the remodeling capacity of two different TSPC lines from young, Y-TSPC and aged/degenerative, A-TSPC donors. Here, we specifically focused on investigating the involvement of integrin receptors in the remodeling process. Integrins are transmembrane receptors consisting of alpha (a) and beta (b) subunits, which form cell-to-matrix bonds, activate various pathways and thereby control cell proliferation, differentiation and survival.

Y- and A-TSPC were derived from human Achilles tendons and are fully described in Kohler et al. 2013. RT-PCR was used to assess the expression of collagen-binding integrins in the TSPC cultivated in collagen gels. Next, a1 and a11 integrins were silenced by stable lentiviral delivery of target-specific shRNA in the Y-TSPC. Control (con-shRNA), integrin (a1-shRNA) and integrin a11 (a11-shRNA) virus-containing supernatant was given for 24h and then cells were selected with 50 microg./ml zeocin for 10 days. The integrin knockdown (KD) efficiency was assessed by quantitative PCR and western blotting. Last, functional tests were carried out by time-lapse recording gel contraction of four cell groups (Y-TSPC+con, Y-TSPC+a1KD, Y-TSPC+a11KD, and A-TSPC).

Among the screened integrins we found that integrin a1 and a11 were significantly downregulated in A-TSPC with 3.8 and 5.6 folds, correspondingly. Therefore, to mimic the A-TSPC we carried out a gene KD of a1 and a11 in Y-TSPC. PCR and western blot clearly validated the efficient KD. Analyses of collagen contraction, revealed that Y-TSPC+a11KD significantly reduced collagen contractability comparable to A-TSPC. This indicated the indispensable role of this integrin in the signaling pathway of collagen matrix remodeling. In respect to integrin a1, we found that this receptor did not affect the contraction rate of Y-TSPC, which was similar to Y-TSPC+con.

To our knowledge we have now identified for the first time the critical role of a11 integrin receptor in tendon collagen remodeling, and a follow up analysis of its exact downstream cascade is on the way. Future efforts in deciphering how tendon matrix makeover is regulated can lead to innovation in preventive strategies for tendon degeneration.

In a prospective study of 14 patients undergoing total hip replacement we have used dual-energy X-ray absorptiometry (DEXA) to investigate remodelling of the bone around two different designs of cementless femoral prosthesis. The bone mineral density (BMD) was measured at 12-weekly intervals for a year. Eight patients (group A) had a stiff, collarless implant and six (group B) a flexible isoelastic implant.

Patients in group A showed a decrease in BMD from 14 weeks after operation. By 12 months, the mean loss in BMD was 27%, both medially and laterally to the proximal part of the implant. Those in group B showed an overall increase in BMD which reached a mean of 12.6% on the lateral side of the distal portion of the implant.

Our results support the current concepts of the effects of stem stiffness and flexibility on periprosthetic remodelling.

Recent studies have shown that random disorder nanotopography increases osteoblast differentiation and bone formation. This has great potential merit in producing surfaces where osteointegration is required such as spinal fusion surgery and arthroplasty. However, the long-term failure of orthopaedic implants is often related to osteoclast mediated osteolysis and loosening. It is vitally important that we understand the effect of nanotopography on osteoclast formation and bone remodeling.

We developed an unique osteoblast/osteoclast co-culture system derived from human mesenchymal and haematopoetic stem cells. This was co-cultured on both nanopatterned and unpatterned polycarbonate substrates. We assessed the co-culture using electron microscopy (SEM), protein expression using immunofluorescence and histochemical staining and gene expression using polymerase chain reaction (PCR).

Co-culture of both osteoclasts and osteoblasts was confirmed with mature bone nodules and resorption pits identified on both surfaces. Significantly increased osteoblast differentiation and bone formation was noted on disordered nanotopography. Antagonistic genes controlling osteoclast activity were both upregulated with no significant difference in osteoclast marker gene expression.

Our results confirm successful co-culture of osteoblasts and osteoclasts using an unique method closely resembling the in vivo environment encountered by orthopaedic implants. Nanotopography increases osteoblast differentiation and bone formation as previously identified, with possible subsequent increase in osteoclast mediated bone turnover.

Introduction

Low back pain is a major public health problem in our society. Degeneration of intervertebral disc (IVD) appears to be the leading cause of chronic low-back pain [1]. Mechanical stimulations including compressive and tensional forces are directly implicated in IVD degeneration. Several studies have implicated the cytoskeleton in mechanotransduction [2, 3], which is important for communication and transport between the cells and extracellular matrix (ECM). However, the potential roles of the cytoskeletal elements in the mechanotransduction pathways in IVD are largely unknown.

We developed a 3D vascularized bone remodeling model embedding human osteoblast and osteoclast precursors and endothelial cells in a mineralized matrix. All the cells included in the model exerted their function, resulting in a vascularized system undergoing mineralized matrix remodeling.

Bone remodeling is a dynamic process relying on the balance between the activity of osteoblasts and osteoclasts which are responsible for bone formation and resorption, respectively. This process is also characterized by a tight coupling between osteogenesis and angiogenesis, indicating the existence of a complex cross-talk between endothelial cells and bone cells. We have recently developed microscale in vitro hydrogel-based models, namely the 3D MiniTissue models, to obtain bone-mimicking microenvironments including a 3D microvascular network formed by endothelial cell self-assembly [1–2]. Here, we generated a vascularized 3D MiniTissue bone remodeling model through the coculture of primary human cells in a 3D collagen/fibrin (Col/Fib) matrix enriched with CaP nanoparticles (CaPn) to mimic bone mineralized matrix.

Human umbilical vein endothelial cells (HUVECs), bone marrow mesenchymal stem cells (BMSCs), osteoblast (OBs) and osteoclast (OCs) precursors were cocultured in plain and CaPn-enriched Col/Fib according to the following experimental conditions: a) HUVECs-BMSCs; b) OBs-OCs; c) HUVECs-BMSCs-OBs-OCs. Undifferentiated BMSCs were used to support HUVECs in microvascular network formation. BMSCs and peripheral blood mononuclear cells were respectively pre-differentiated into OB and OC precursors through 7 days of culture in osteogenic or osteoclastogenic medium. Needle-shaped CaPn (Ø ∼20 nm, length ∼80 nm) were added to a collagen/fibrinogen solution. Cells were resuspended in a thrombin solution and then mixed with plain or CaPn-enriched collagen/fibrinogen. The cell-laden mix was injected in U-shaped PMMA masks and let to polymerize to generate constructs of 2×2×5 mm³. Samples were cultured for 10 days. Microvascular network formation was evaluated by confocal microscopy. OB differentiation was analyzed by quantification of Alkaline Phosphatase (ALP) and cell-mediated mineralization. OC differentiation was assessed by Tartrate-Resistant Acid Phosphatase (TRAP) and cell-mediated phosphate release quantification.

HUVECs developed a robust 3D microvascular network and BMSCs differentiated into mural cells supporting vasculogenesis. The presence of CaPn enhanced OB and OC differentiation, as demonstrated by the significantly higher ALP and TRAP levels and by the superior cell-mediated mineralization and phosphate release measured in CaPn-enriched than in plain Col/Fib. The coculture of OBs and OCs with HUVECs and BMSCs further enhanced ALP and TRAP levels, indicating that the presence of HUVECs and BMSCs positively contributed to OB and OC differentiation. Remarkably, higher values of ALP and TRAP activity were measured in the tetraculture in CaPn-enriched Col/Fib compared to plain Col/Fib, indicating that also in the tetraculture the mineralized matrix stimulated OB and OC differentiation.

The 3D MiniTissue bone remodeling model developed in this study is a promising platform to investigate bone cell and endothelial cell cross-talk. This system allows to minimize the use of cells and reagents and is characterized by a superior ease of use compared to other microscale systems, such as microfluidic models. Finally, it represents a suitable platform to test drugs for bone diseases and can be easily personalized with patient-derived cells further increasing its relevance as drug screening platform.

Long term, secondary implant fixation of Total Disc Replacements (TDR) can be enhanced by hydroxyapatite or similar osseo-conductive coatings. These coatings are routinely applied to metal substrates. The objective of this in vivo study was to investigate the early stability and subsequent bone response adjacent to an all polymer TDR implant over a period of six months in an animal model.

Six skeletally mature male baboons (Papio annubis) were followed for a period of 6 months. Using a transperitoneal exposure, a custom-sized Cadisc L device was implanted into the disc space one level above the lumbo-sacral junction in all subjects. Radiographs of the lumbar spine were acquired prior to surgery, and post-operatively at intervals up to 6 months to assess implant stability. Flourochrome markers (which contain molecules that bind to mineralization fronts) were injected at specified intervals in order to investigate bone remodeling with time.

Animals were humanely euthanized six months after index surgery. Test and control specimens were retrieved, fixed and subjected to histological processing to assess the bone-implant-bone interface. Fluorescence microscopy and confocal scanning laser microscopy were utilized with BioQuant image analysis to determine the bone mineral apposition rates and gross morphology.

Radiographic evaluation revealed no loss of disc height at the operative level or adjacent levels. No evidence of subsidence or significant migration of the implant up to 6 months. Heterotopic ossification was observed to varying degrees at the operated level.

Histology revealed the implant primary fixation features embedded within the adjacent vertebral endplates. Flourochrome distribution revealed active bone remodeling occurring adjacent to the polymeric end-plate with no evidence of adverse biological responses. Mineral apposition rates of between 0.7 and 1.7 microns / day are in keeping with literature values for hydroxyapatite coated implants in cancellous sites of various species.

Radiographic assessment demonstrates that the Cadisc L implant remains stable in vivo with no evidence of subsidence or significant migration. Histological analysis suggests the primary fixation features are engaged, and in close apposition with the adjacent vertebral bone. Flourochrome markers provide evidence of a positive bone remodelling response in the presence of the implant.

After anterior cruciate ligament (ACL) rupture, reconstructive surgery with a hamstring tendon autograft is often performed. Despite overall good results, ACL re-rupture occurs in up to 10% of the patient population, increasing to 30% of the cases for patients aged under 20 years. This can be related to tissue remodelling in the first months to years after surgery, which compromises the graft's mechanical strength. Resident graft fibroblasts secrete matrix metalloproteinases (MMPs), which break down the collagen I extracellular matrix. After necrosis of these fibroblasts, myofibroblasts repopulate the graft, and deposit more collagen III rather than collagen I. Eventually, the cellular and matrix properties converge towards those of the native ACL, but full restoration of the ACL properties is not achieved. It is unknown how inter-patient differences in tissue remodelling capacity contribute to ACL graft rupture risk. This research measured patient-specific tissue remodelling-related properties of human hamstring tendon-derived cells in an in vitro micro-tissue platform, in order to identify potential biological predictors for graft rupture. Human hamstring tendon-derived cells were obtained from remnant autograft tissue after ACL reconstructions. These cells were seeded in collagen I gels on a micro-tissue platform to assess inter-patient cellular differences in tissue remodelling capacity. Remodelling was induced by removing the outermost micro-posts, and micro-tissue compaction over time was assessed using transmitted light microscopy. Protein expression of tendon marker tenomodulin and myofibroblast marker α-smooth muscle actin (αSMA) were measured using Western blot. Expression and activity of remodelling marker MMP2 were determined using gelatin zymography. Cells were obtained from 12 patients (aged 12–51 years). Patient-specific variations in micro-tissue compaction speed or magnitude were observed. Up to 50-fold differences in αSMA expression were found between patients, although these did not correlate with faster or stronger compaction. Surprisingly, tenomodulin was only detected in samples obtained from two patients. Total MMP2 expression varied between patients, but no large differences in active fractions were found. No correlation of patient age with any of the remodelling-related factors was detected. Remodelling-related biological differences between patient tendon-derived cells could be assessed with the presented micro-tissue platform, and did not correlate with age. This demonstrates the need to compare this biological variation in vitro - especially cells with extreme properties - to clinical outcome. Sample size is currently increased, and patient outcome will be determined. Combined with results obtained from the in vitro platform, this could lead to a predictive tool to identify patients at risk for graft rupture

Objectives

To explore the therapeutic potential of combining bone marrow-derived mesenchymal stem cells (BM-MSCs) and hydroxyapatite (HA) granules to treat nonunion of the long bone.

We used a biodegradable mesh to convert an acetabular defect into a contained defect in six patients at total hip replacement. Their mean age was 61 years (46 to 69). The mean follow-up was 32 months (19 to 50). Before clinical use, the strength retention and hydrolytic in vitro degradation properties of the implants were studied in the laboratory over a two-year period. A successful clinical outcome was determined by the radiological findings and the Harris hip score.

All the patients had a satisfactory outcome and no mechanical failures or other complications were observed. No protrusion of any of the impacted grafts was observed beyond the mesh. According to our preliminary laboratory and clinical results the biodegradable mesh is suitable for augmenting uncontained acetabular defects in which the primary stability of the implanted acetabular component is provided by the host bone. In the case of defects of the acetabular floor this new application provides a safe method of preventing graft material from protruding excessively into the pelvis and the mesh seems to tolerate bone-impaction grafting in selected patients with primary and revision total hip replacement.