In 2021 the bone grafting market was worth €2.72 billion globally. As allograft bone has a limited supply and risk of disease transmission, the demand for synthetic grafting substitutes (BGS) continues to grow while allograft bone grafts steadily decrease. Synthetic BGS are low in mechanical strength and bioactivity, inspiring the development of novel grafting materials, a traditionally laborious and expensive process. Here a novel BGS derived from sustainably grown coral was evaluated. Coral-derived scaffolds are a natural calcium carbonate bio-ceramic, which induces osteogenesis in bone marrow mesenchymal stem cells (MSCs), the cells responsible for maintaining bone homeostasis and orchestrating fracture repair. By 3D printing MSCs in coral-laden bioinks we utilise high throughput (HT) fabrication and evaluation of osteogenesis, overcoming the limitations of traditional screening methods. MSC and coral-laden GelXA (CELLINK) bioinks were 3D printed in square bottom 96 well plates using a CELLINK BIO X printer with pneumatic adapter Samples were non-destructively monitored during the culture period, evaluating both the sample and the culture media for metabolism (PrestoBlue), cytotoxicity (lactose dehydrogenase (LDH)) and osteogenic differentiation (alkaline phosphatase (ALP)). Endpoint, destructive assays used included qRT-PCR and SEM imaging. The inclusion of coral in the printed bioink was biocompatable with the MSCs, as reflected by maintained metabolism and low LDH release. The inclusion of coral induced osteogenic differentiation in the MSCs as seen by ALP secretion and increased RUNX2, collagen I and osteocalcin transcription. Sustainably grown coral was successfully incorporated into bioinks, reproducibly 3D printed, non-destructively monitored throughout culture and induced osteogenic differentiation in MSCs. This HT fabrication and monitoring workflow offers a faster, less labour-intensive system for the translation of bone substitute materials to clinic.
Bone tissue experiences continued remodelling in response to changes in its biochemical and biophysical environment. Given the finite lifespan of osteoblasts, this continued bone formation requires replenishment from a progenitor population. Although this is largely believed to be from a skeletal stem cell population, given the limitation in in-vivo markers for this cell type, progress in demonstrating this mechanism is limited. Therefore, we characterized the LepR-Cre mouse strain and evaluated whether LepR positive cells are the progenitor population and if they contribute to the osteoblast population over time and in mechanically-induced bone formation in-vivo. Transgenic mouse strains; B6.129(Cg)-Leprtm2(cre)Rck/J to study LepR-expressing cells and B6.Cg-Gt(ROSA)26Sortm9(CAG-tdTomato)Hze/J as a reporter strain were obtained from Jackson Laboratories. Characterization studies were performed on LepR:tdTomato mice at embryonic stage (19.5dpc), 8 and 12 weeks old. Mice (12 weeks old) were subjected to compressive tibia loading with a 11N peak load for 40 cycles, every other day for 2 weeks. Histological analysis reveal that LepR is expressed from the embryonic stage in various organs including bones. LepR positive cells are found around blood vessels and on bone surfaces. Flow cytometry analysis show the amount of LepR positive cells negative for CD45 and Ter-119 markers inside the bone marrow increases over time and following tibial loading. Mechanical loading induces an increase in bone mass and bone parameters. This model allows us to track and evaluate the role of LepR positive cells as bone forming cells, and to decipher the role of these cells in mechanically-induced bone formation.
To investigate the new theory of hydroneurolysis and hydrodissection in the treatment of carpal tunnel syndrome (CTS). Independently of the fluid hydrodissolution works due to mechanical forces and it may have some positive effects in patients with ischemic damage caused by scar tissue pressure at the nerve's surface. A prospective blind clinical study of 31 patients suffering from carpal tunnel syndrome, established by nerve conduction studies and clinical tests. 14 patients (out of 29), who refused to undergo an open operation as a treatment to their disease at this point of time, were treated with a simple ultrasound-guided injection at the proximal carpal tunnel. In order to exclude the biochemical influence of the fluid in the treating disease we choosed to infiltrate 3 cc. of normal saline 0,9%. In the follow-up period our group was asked to answer to a new Q-DASH score and visual analogue scale (VAS) 100/100 in 2, 4 and 8 weeks.Background
Methods
The findings demonstrate that culture expanded human mesenchymal stem cells (MSCs) incorporated and proliferated in clinically relevant cell scaffolds better than freshly isolated bone marrow mononucleated cells (MNCs); in fact, only in MSC cultures were cells present for longer term chondrogenic inductions. The treatment of chondral defects poses a significant clinical problem and a variety of cell sources and techniques have been studied and practiced to regenerate cartilage. Preclinical and clinical evidence suggests that MSCs can help regenerate cartilage when transplanted into cartilage lesions. However, the uptake of MSCs for cell therapies is limited due to the need for their culture expansion to generate subsequent numbers for transplantation. An alternative is to use minimally manipulated MNCs, which avoids the costs and regulatory implications of culture expansion and would enable the treatment of cartilage defects in a one-step procedure. Therefore, this study has focused on comparing these two cell types within three different scaffolds that can currently be used as cell delivery systems.Summary
Introduction
Wear of polymeric glenoid components has been identified as a cause of loosening and failure of shoulder implants1,2 in vivo. A small number of shoulder joint simulators have been built for in vitro wear testing, however none have been capable of testing with physiological motion patterns in three axes and with physiological loading. The Newcastle Shoulder Wear Simulator was designed with three axes of motion, which are programmable so that different activities of daily living might be replicated. The simulator uses three pneumatic cylinders with integral position encoders to move five shoulder prostheses simultaneously in the flexion-extension, abduction-adduction, and internal-external rotation axes. Axial loading is applied with pneumatic cylinders supplied from a pneumatic proportional valve via a manifold, which also supplies a sixth static control station. In order to establish if that the machine can actually perform as intended, commissioning trials were conducted replicating lifting a 0.5 Kg weight to head height as a daily living activity. During the commissioning trials JRI Orthopaedics Reverse VAIOS shoulder prostheses were tested in 50% bovine serum at ambient temperature. The results show that the shoulder joint wear simulator can satisfactorily reproduce a daily living activity deliberately selected for having a large range of motion and loading. Other daily activities, such as drinking from a mug, are less demanding in the ranges of motion and loading and represent no difficulty in being reproduced on the simulator. Now successfully commissioned, this new multi-station shoulder wear simulator can wear test current and new designs of shoulder prosthesis in vitro
Degree of early integration of titanium alloy implants into bone is an important predictor of long term implant success in arthroplasty. The correlation between observations on early cell adhesion and the ability of modified surfaces to affect osseointegration of implants in in vivo models is unclear. We hypothesised that observation of increased focal adhesion complexes in early cultures of osteoblasts would correlate with increased osseointegration of treated implants in an animal model. Longer term culture of rat osteoblasts for alkaline phosphatase activity indicated that cells cultured on the 9V treated surfaces were displaying greater alkaline phosphatase activity at 14 days. Bone nodule formation at 28 days demonstrated a trend towards smaller area of bone nodules on the surfaces treated at 9V then those treated at 3V and 5V. A rat model was employed for testing mechanical push-out strength of experimental implants and demonstrated a trend towards increased yield strength of the bone-implant interface for implants treated at 3V180s and 5V180s. Histomorphometry was performed and no statistically significant differences in percentage area of contact with mineralised bone matrix were seen, although there was a trend for greater mineralised matrix contact on the polished and 9V180s treated implants. Previous experiments demonstrated cells on the 9V treated surfaces were well spread and had significantly increased size and number of focal adhesions. This was regarded as indicating more successful cell adhesion. The above results demonstrate that this early trend disappeared in longer term culture did not persist in experiments in an animal model.
To review the current best surgical practice and detail a multi-disciplinary
approach that could further reduce joint replacement infection. Review of relevant literature indexed in PubMed.Objectives
Methods
Uncemented implants are an important part of the arthroplasty armamentarium. Risk of aseptic loosening and failure of these components is related to initial osseointegration - the formation of a seamless bone-implant interface without interposition of fibrous tissue. Modification of the surface properties of titanium alloy, to enhance suitability for early osseointegration.Background
Aim
Bone marrow derived mesenchymal stem cells are a potential source of cells for the repair of articular cartilage defects. Hypoxia has been shown to improve chondrogenesis in adult stem cells. In this study we characterised bone marrow derived stem cells and investigated the effects of hypoxia on gene expression changes and chondrogenesis. Adherent colony forming cells were isolated and cultured from the stromal component of bone marrow. The cells at passage 2 were characterised for stem cell surface epitopes, and then cultured as cell aggregates in chondrogenic medium under normoxic (20% oxygen) or hypoxic (5% oxygen) conditions for 14 days. Gene expression analysis, glycosoaminoglycan and DNA assays, and immunohistochemical staining were determined to assess chondrogenesis.INTRODUCTION
MATERIALS AND METHODS
To control the growth and function of osteoblasts on Titanium alloy surfaces produced by electrochemical patterning. Samples of Ti6Al4V were prepared with three different finishes; no surface preparation following machining, polishing on a grinding wheel with sequential grit papers up to 4000 to achieve a mirror finish and treatment in a flat electrochemical cell with a 3M sulphuric acid in methanol using 9V supplied over 60 seconds to produce a surface with defined nano/microscale roughness. Glass coverslips were used as control surfaces. Surfaces were seeded with primary rat calvarial osteoblasts and incubated in Dulbecco's Modified Eagle Medium with 10% (v/v) sera for 24 hours before fixing and performing immunofluorescence staining with anti-vinculin antibody. Photomicrographs of the surfaces were analysed with Image J and analySIS FIVE programs. Results for cell number, cell area, focal adhesion area and polarity (lack of roundness) were analysed (using the Mann Whitney test) for ANOVA using SPSS.Aim
Methods
Mesenchymal stem cells are a potential source of cells for the repair of articular cartilage defects. We have previously demonstrated that the infrapatellar synovial fat pad is a rich source of mesenchymal stem cells and these cells are able to undergo chondrogenic differentiation. Although synovial fat pad derived mesenchymal stem cells may represent a heterogenous population, clonal populations derived from the synovial fat pad have not previously been studied. Mesenchymal stem cells were isolated from the infrapatellar synovial fat pad of a patient undergoing total knee arthroplasty and expanded in culture. Six clonal populations were also isolated before initial plating using limiting dilution and expanded. The cells from the mixed parent population and the derived clonal populations were characterised for stem cell surface epitopes, and then cultured as cell aggregates in chondrogenic medium for 14 days. Gene expression analyses; glycosoaminoglycan and DNA assays; and immunohistochemical staining were determined to assess chondrogenic responses.Introduction
Materials and Methods
Currently, there are no generally accepted treatments for the prevention of osteonecrosis. To compound this further, despite considerable research efforts, the natural history of this disease remains poorly understood. The disease process appears to be initially asymptomatic, but after symptoms appear, the course becomes rapidly progressive. Clinical studies have shown that, if left untreated, collapse of the femoral head will occur in 80 per cent of the cases or greater within four years. As our knowledge of the etiology and pathogenesis of osteonecrosis improves, new treatments to halt, or at least impede, the progression of the disease may be possible. Achieving the best outcomes in the treatment of osteonecrosis depends on early, accurate diagnosis, and prompt treatment appropriate for the stage of the disease. In many cases, if treated early, long-term preservation of the native joint is possible. Magnetic resonance imaging allows accurate diagnosis in even the earliest asymptomatic stages of the disease. Non-surgical treatments such as pharmacological agents have shown promise in experimental studies, although further work remains before they are appropriate for widespread use. Various hip salvaging procedures such as core decompression, percutaneous drilling, non-vascularized and vascularized bone grafting, and various osteotomies have been successful in the majority of properly selected patients over follow-up times of a decade or more. Advances in arthroplasty technologies and techniques, including hip resurfacing and modern cementless total hip arthroplasty have allowed patients to return to pain-free, active lifestyles with excellent long-term prosthesis survival. Current treatments for osteonecrosis, while generally successful, focus on halting or delaying the progression of symptomatic disease. Recent discoveries concerning the relationship between genetic factors and the development of osteonecrosis, as well as the pathophysiologic effects of various indirect and direct risk factors such as corticosteroid use and sickle cell disease, continue to improve our understanding of the underlying disease process. While these discoveries are promising, we must continue to work towards the goal of being able to identify and treat the precursors of osteonecrosis before it progresses to symptomatic disease and threatens the survival of native joints.
This study compared the effect of a computer-assisted and a traditional surgical technique on the kinematics of the glenohumeral joint during passive abduction after hemiarthroplasty of the shoulder for the treatment of fractures. We used seven pairs of fresh-frozen cadaver shoulders to create simulated four-part fractures of the proximal humerus, which were then reconstructed with hemiarthroplasty and reattachment of the tuberosities. The specimens were randomised, so that one from each pair was repaired using the computer-assisted technique, whereas a traditional hemiarthroplasty without navigation was performed in the contralateral shoulder. Kinematic data were obtained using an electromagnetic tracking device. The traditional technique resulted in posterior and inferior translation of the humeral head. No statistical differences were observed before or after computer-assisted surgery. Although it requires further improvement, the computer-assisted approach appears to allow glenohumeral kinematics to more closely replicate those of the native joint, potentially improving the function of the shoulder and extending the longevity of the prosthesis.
