Objectives. The present study describes a novel technique for revitalising allogenic intrasynovial tendons by combining cell-based therapy and
The study objective was to prospectively assess clinical outcomes for a pilot cohort of tibial shaft fractures treated with a new tibial nailing system that produces controlled axial interfragmentary micromotion. The hypothesis was that axial micromotion enhances fracture healing compared to static interlocking. Patients were treated in a single level I trauma centre over a 2.5-year period. Group allocation was not randomized; both the micromotion nail and standard-of-care static locking nails (control group) were commercially available and selected at the discretion of the treating surgeons. Injury risk levels were quantified using the Nonunion Risk Determination (NURD) score. Radiological healing was assessed until 24 weeks or clinical union. Low-dose CT scans were acquired at 12 weeks and virtual mechanical testing was performed to objectively assess structural bone healing.Aims
Methods
We have determined whether somatosensory evoked potentials (SEPs) were detectable after direct
Aims. It has been established that
Regulation of articular cartilage homeostasis is a complex process in which biologic and mechanical factors are involved. Hyperactivation of Wnt signaling, associated with osteoarthritis (OA), could jeopardize the protective anabolic effect of physiological loading. Here, we investigated the role of excessive Wnt signalling in cartilage molecular responses to loading. Human cartilage explants were harvested from hips of donors without OA. The Wnt agonist CHIR99021 was used to activate Wnt signalling 24 hours before cartilage explants were subjected to a loading protocol consisting of 2 cycles of 1 hour of 10% compression at 1 Hz, followed by 1-hour free swelling. Mechano-responsiveness was evaluated using the expression of type II collagen, aggrecan and MMP-13. Expression of known target genes TCF-1 and c-JUN was evaluated as positive control for Wnt and
Secondary bone healing is impacted by the extent of interfragmentary motion at the fracture site. It provides mechanical stimulus that is required for the formation of fracture callus. In clinical settings, interfragmentary motion is induced by physiological loading of the broken bone – for example, by weight-bearing. However, there is no consensus about when mechanical stimuli should be applied to achieve fast and robust healing response. Therefore, this study aims to identify the effect of the immediate and delayed application of mechanical stimuli on secondary bone healing. A partial tibial osteotomy was created in twelve Swiss White Alpine sheep and stabilized using an active external fixator that induced well-controlled interfragmentary motion in form of a strain gradient. Animals were randomly assigned into two groups which mimicked early (immediate group) and late (delayed group) weight-bearing. The immediate group received daily stimulation (1000 cycles/day) from the first day post-op and the delayed group from the 22nd day post-op. Healing progression was evaluated by measurements of the stiffness of the repair tissue during
Aims.
Bone is a dynamic tissue that undergoes continuous mechanical forces. Mechanical stimuli applied on scaffolds resembling a part of the human bone tissue affects the osteogenesis [1]. Poly(3,4-ethylenedioxythiophene) (PEDOT) is a piezoelectric material that responds to
Introduction and Objective. Traditionally, osteoarthritis (OA) has been associated mostly with degradation of cartilage only. More recently, it has been established that other joint tissues, in particular bone, are also centrally involved. However, the link between these two tissues remains unclear. This relationship is particularly evident in post-traumatic OA (PTOA), where bone marrow lesions (BMLs), as well as fluctuating levels of inflammation, are present long before cartilage degradation begins. The process of bone-cartilage crosstalk has been challenging to study due to its multi-tissue complexity. Thus, the use of explant model systems have been crucial in advancing our knowledge. Thus, we developed a novel patellar explant model, to study bone cartilage crosstalk, in particular related to subchondral bone damage, as an alternative to traditional femoral head explants or cylindrical core specimens. The commonly used osteochondral explant models are limited, for our application, since they involve bone damage during harvest. The specifics aim of this study was to validate this novel patellar explant model by using IL-1B to stimulate the inflammatory response and
In the course of uneventful secondary bone healing, a fracture gap is progressively overgrown by callus which subsequently calcifies and remodels into new bone. It is widely accepted that callus formation is promoted by
Introduction and Objective. Exosomal miRNA have been shown to regulate many myogenic and osteogenic pathways involved in injury repair and healing. It is also known that rehabilitation and exercise can improve muscle mass and bone growth. The mechanisms by which this occurs in vivo are well studied, but the impact exosomes and their associated miRNA cargo have is unclear. With this knowledge and question in mind, we hypothesized that C2C12 myoblasts subjected to in vitro mechanical stimulus (“exercise”) would exhibit improved exosome production and differentially expressed miRNA cargo when compared to their static (“unexercised”) counterparts. Materials and Methods. C2C12 myoblasts were cultured using the FlexCell FX-5000TT bioreactor. Two exercise regimens were programmed: 1) low intensity regimen (LIR) (0–15% strain at 0.5 Hz for 24 hours) 2) high intensity interval regimen (HIIR) (12–22% strain at 1 Hz for 10 minutes followed by 50 minutes of rest repeated for 24 hours). Unexercised (static) cells were cultured in parallel. Exosomes were isolated using the Invitrogen Total Exosome Isolation Reagent. The Pierce BCA Protein Assay, System Bioscience's ExoELISA-ULTRA CD81 Kit and, SBI's ExoFlow-ONE EV labeling kit were used to confirm and quantify exosome number and protein concentration. The SBI Exo-NGS service was used to perform miRNA sequencing on isolated exosomes. Results. All exercise regimens resulted in increased exosome concentrations as determined by CD81 exosome ELISA and flow-cytometry based exosome quantification. The LIR interestingly produced significantly more exosomes than static and HIIR. Within the exosomes from
Introduction and Objective. It is widely accepted that interfragmentary strain stimulus promotes callus formation during secondary bone healing. However, the impact of the temporal variation of
The course of secondary fracture healing typically consists of four major phases including inflammation, soft and hard callus formation, and bone remodeling. Callus formation is promoted by
Osteoporotic fracture has become a major problem in ageing population and often requires prolonged healing time. Low Intensity Pulsed Ultrasound (LIPUS) can significantly enhance fracture healing through alteration of osteocyte lacuno-canalicular network (LCN). DMP1 in osteocytes is responsible for maintaining LCN and mineralisation. This study aims to investigate osteocyte-specific DMP1's role in enhanced osteoporotic fracture healing in response to
Post-traumatic osteoarthritis (PTOA) is a subset of osteoarthritis, which occurs secondary to traumatic joint injury which is known to cause pathological changes to the osteochondral unit. Articular cartilage degradation is a primary hallmark of OA, and is normally associated with end-stage disease. However, subchondral bone marrow lesions are associated with joint injury, and may represent localized bone microdamage. Changes in the osteochondral unit have been traditionally studied using explant models, of which the femoral-head model is the most common. However, the bone damage caused during harvest can confound studies of microdamage. Thus, we used a novel patellar explant model to study osteochondral tissue dynamics and mechanistic changes in bone-cartilage crosstalk. Firstly, we characterized explants by comparing patella with femoral head models. Then, the patellar explants (n=269) were subjected to either mechanical or inflammatory stimulus. For mechanical stimulus 10% strain was applied at 0.5 and 1 Hz for 10 cycles. We also studied the responses of osteochondral tissues to 10ng/ml of TNF-α or IL-1β for 24hrs. In general the findings showed that patellar explant viability compared extremely well to the femoral head explant. Following IL-1β or TNF-α treatment, MMP13, significantly increased three days post exposure, furthermore we observed a decrease in sulfate glycoaminoglycan (sGAG) content. Bone morphometric analysis showed no significant changes. Contrastingly,
In the native articular cartilage microenvironment, chondrocytes are constantly subjected to dynamic physical stimuli that maintains tissue homeostasis. They produce extra cellular matrix (ECM) components such as collagens (type II mainly, 50-75%), proteoglycans (10-30%) and other type of proteins. 1. . While collagen offers a large resistance in tension, proteoglycans are the responsible of the viscoelastic response under compression due to the negative charge they confer to the ECM allowing it to entrap a large amount of interstitial fluid. In pathologic states (e.g. osteoarthritis), this ECM is degenerated and the negative charge becomes unbalanced, losing the chondroprotective properties and resulting on an overloaded chondrocytes that further degenerate the matrix. Low-Intensity Pulsed Ultrasound Stimulation (LIPUS) has been used to generate acoustic (pressure) waves that create bubbles that collapse with cells, inducing a stimulus that can modulate cell response. 2. This
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
To clarify the pathomechanisms of discogenic low back pain, the sympathetic afferent discharge originating from the L5-L6 disc via the L2 root were investigated neurophysiologically in 31 Lewis rats. Sympathetic afferent units were recorded from the L2 root connected to the lumbar sympathetic trunk by rami communicantes. The L5-L6 discs were
Physical activity is a key determinant of bone mass and health, however during adulthood and ageing there appears to be a decrease in the ability to respond positively to exercise which is variable between individuals. While exercise is known to protect against the osteopo-rotic process with modest increases in BMD the exact cellular and molecular responses are poorly understood. We have studied the effect of
Summary. These data suggest that PTH treatment for stimulation of bone healing after trauma is not much dependent on
3D cell culture studies more accurately represent the complex in vivo mechanical environment of human bone and are, thus, superior to 2D studies when testing the efficacy of osteoporosis therapies. As such, the objective of this study was to use a 3D model to investigate the effect of sclerostin antibodies. Sclerostin is a protein, which inhibits osteoblasts and is downregulated under
It is well known that environmental cues such as mechanical loading and/or cell culture medium composition affect tissue-engineered constructs resembling natural bone. These studies are mostly based on an initial setting of the influential parameter that will not be further changed throughout the study. Through the growth of the cells and the deposition of the extracellular matrix (ECM) the initial environmental conditions of the cells will change, and with that also the loads on the cells will change. This study investigates how changes of mechanical load or media composition during culture influences the differentiation and ECM production of mesenchymal stromal cells seeded on porous 3D silk fibroin scaffolds. ECM formation, ECM mineralization and cell differentiation in 3D tissue-engineered bone were analyzed using microscopic tools. Our results suggest that mechanical stimuli are necessary to differentiate human mesenchymal stromal cells of both bone marrow and adipose tissue origin into ECM producing osteoblasts which ultimately become ECM-embedded osteocytes. However, the influence of this stimulus seems to fade quickly after the onset of the culture. Constructs which were initially cultured under mechanical loading continued to deposit minerals at a similar growth rate once the
Introduction and Objective. Anterior cruciate ligament reconstruction (ACLR) with tendon autografts is the “gold standard” technique for surgical treatment of ACL injuries. Common tendon graft choices include patellar tendon (PT), semitendinosus/gracilis “hamstring” tendon (HT), or quadriceps tendon (QT). Healing of the graft after ACLR may be affected by graft type since the tissue is subjected to mechanical stresses during post-operative rehabilitation that play important roles in graft integration, remodeling and maturation. Abnormal mechanical loading can result in high inflammatory and degradative processes and altered extracellular matrix (ECM) synthesis and remodeling, potentially modifying tissue structure, composition, and function. Because of the importance of load and ligamentization for tendon autografts, this study was designed to compare the differential inflammatory and degradative metabolic responses to loading by three tendon types commonly used for autograft ACL reconstruction. Materials and Methods. With IRB approval (IRB # 2009879) and informed patient consent, portions of 9 QT, 7 PT and 6 HT were recovered at the time of standard of care ACLR surgeries. Tissues were minced and digested in 0.2 mg/ml collagenase solution for two hours and were then cultured in 10% FBS at 5% CO. 2. , 37°C, and 95% humidity. Once confluent, cells were plated in Collagen Type I-coated BioFlex® plates (1 × 10. 5. cells/well) and cultured for 2 days prior to the application of strain. Then, media was changed to supplemented DMEM with 2% FBS for the application of strain. Fibroblasts were subjected to continuous
Abstract. Objectives. Osteoporosis of the pelvis and femur is diagnosed in a high proportion of lower-limb amputees which carries an increased fracture risk and subsequently serious implications on mobility, physical dependency and morbidity. Through the development of biofidelic musculoskeletal and finite element (FE) models, we aim to determine the effect of lower-limb amputation on long-term bone remodelling in the hip and to understand the potential underpinning mechanisms for bone degradation in the younger amputee population. Methods. Our models are patient specific and anatomically accurate. Geometries are derived from MRI-scans of one bilateral, above-knee, amputee and one body-matched control subject. Musculoskeletal modelling enables comparison of muscle and joint reaction-forces throughout gait. This provides the loading scenario implemented in FE. FE modelling demonstrates the effect of loading on the amputated limb via a prosthetic socket by comparing bone
We examined cultured osteoblasts derived from paired samples from the greater tuberosity and acromion from eight patients with large chronic tears of the rotator cuff. We found that osteoblasts from the tuberosity had no apparent response to
In a healthy joint, mechanical loading increases matrix synthesis and maintains cell phenotype, while reducing catabolic activities. It activates several pathways, most of them yet largely unknown, with integrins, TGF-β, canonical (Erk 1/2) and stress-activated (JNK) MAPK playing a key role. Degenerative joint diseases are characterized by Wnt upregulation and by the presence of proteolytic fibronectin fragments (FB-fs). Despite they are known to impair some of the aforementioned pathways, little is known on their modulatory effect on cartilage mechanoresponsiveness. This study aims at investigating the effect of mechanical loading in healthy and in vitro diseased cartilage models using pro-hypertrophic Wnt agonist CHIR99021 and the pro-catabolic FB-fs 30 kDa. Human primary chondrocytes from OA patients have been grown in alginate hydrogels for one week, prior to be incubated for 4 days with 3μM CHIR99021 or 1 μM FB-fs. Human cartilage explants isolated from OA patients have incubated 4 days with 3 μM CHIR99021 or 1 μM FB-fs. Both groups have then been
The development of functional biomaterials scaffolds for bone tissue engineering applications includes the control of specific biological and mechanical parameters that are involved in the growth of bone tissue in a way that mimics the physiological process of healing bone defects. Here, we report on the development of composite scaffolds made from biodegradable natural and synthetic biomaterials with characteristic architectural features, functionalized with the osteoinductive growth factor bone morphogenetic protein BMP-2, and evaluating their osteogenic response in static and dynamic cell culture systems. The results show that scaffold designing with advanced technologies combined with appropriate biochemical and
Objectives. The need for bone tissue supplementation exists in a wide range
of clinical conditions involving surgical reconstruction in limbs,
the spine and skull. The bone supplementation materials currently
used include autografts, allografts and inorganic matrix components;
but these pose potentially serious side-effects. In particular the
availability of the autografts is usually limited and their harvesting
causes surgical morbidity. Therefore for the purpose of supplementation
of autologous bone graft, we have developed a method for autologous
extracorporeal bone generation. Methods. Human osteoblast-like cells were seeded on porous granules of
tricalcium phosphate and incubated in osteogenic media while exposed
to
Significant challenges remain to accomplishing the development of fully functional tendon tissue substitutes that can lead to clinically effective and successful applications. Scaffolding materials must meet demanding requirements such i) mimic the hierarchical and anisotropically aligned structure of tendon tissues from the nano- up to the macroscale, ii) meet tendon mechanical requirements and non-linear biomechanical behaviour, iii) provide the necessary biophysical/biochemical cues and mechanical responsiveness to induce the tenogenic differentiation of stem cells and potentiating the effects of biochemical supplementation. On the other side, tenogenic differentiation of stem cells is still to be established, as well as the role of such cells (either naïve or pre-differentiated) in promoting tissue regeneration. We have recently found evidences that magnetic actuation can provide means of
The unique properties of mesenchymal stem cells (MSCs) and their natural presence within the bone marrow make them an attractive source of cells for novel cartilage repair strategies. As mechanics play a critical role in vivo, a more physiological loading regime in vitro would be more appropriate to test novel therapies, and this can be achieved using bioreactors. Using a multiaxial load bioreactor system, we have investigated the effect of
Current cell-based tissue engineering strategies have limited clinical applicability due to the need for large cell numbers and prolonged culture periods that lead to phenotypic drift. In vitro microenvironmental modulators have been proposed to mimic the native tendon. Standard in vitro culture conditions result in delayed extracellular matrix (ECM) deposition, impairing the development of scaffold-free approaches. ECM deposition can be enhanced by macromolecular crowding (MMC), a biophysical phenomenon that governs the milieu of multicellular organisms. We assessed a multifactorial biophysical approach, using MMC and mechanical loading, on different cell sources to determine their suitability for in vitro fabrication of tendon-like tissue. Human dermal fibroblasts (DFs), tenocytes (TCs) and bone marrow mesenchymal stem cells (BMSCs) were cultured with MMC under static and uniaxial strain culture conditions. TCs and DFs exhibited alignment perpendicular to the load, whilst BMSCs did not show preferential alignment. When MMC was used, DFs and BMSCs showed increased deposition of collagen I, the main component in tendon ECM. DFs presented ECM composition similar to TCs with collagen types III, V and VI present. Gene expression analysis revealed upregulation of tenogenic markers by TCs and DFs, such as scleraxis and thrombospondin-4, under both loading and MMC. The combined use of MMC and
Background: Greater tuberosity disuse osteoporosis is a consequence of rotator cuff tear. This is a significant problem as the tendon is implanted into a trough within the greater tuberosity during repair. Failure of the repair is a common complication (up to 50%). We hypothesise that failure in re-implantation is due to deficient bone cell response to
Disuse osteoporosis of the greater tuberosity is a consequence of rotator cuff tear. This is a significant problem as the tendon is implanted into a trough within the greater tuberosity during repair. Failure of the repair is a common complication (up to 50%). We hypothesized that failure in re-implantation is due to deficient bone cell response to
Anterior cruciate ligament (ACL) reconstruction is the current standard of care for ACL tears. However, the results are not consistently successful, autografts or allografts have certain disadvantages, and synthetic grafts have had poor clinical results. The aim of this study was to determine the efficacy of tissue engineering decellularized tibialis tendons by recellularization and culture in a dynamic tissue bioreactor. To determine if recellularization of decellularized tendons combined with
Objective. In order to effectively utilize mechanical signals in the clinic as a non-drug-based intervention to improve cartilage defect regeneration after surgical treatment, it is essential to identify crucial components of the cellular response that are typical to the anabolic process. The mechanisms behind the effect of
Cell-based tissue engineering strategies for tendon repair have limited clinical applicability due to delayed extracellular matrix (ECM) deposition and subsequent prolonged culture periods, which lead to tenogenic phenotypic drift. Deposition of ECM in vitro can be enhanced by macromolecular crowding (MMC), a biophysical phenomenon that governs the intra- and extra-cellular milieu of multicellular organisms, which has been described to accelerate ECM deposition in human tenocytes. A variety of cell sources have been studied for tendon repair including tenocytes, dermal fibroblasts (DFs) and mesenchymal stem cells (MSCs) and various biophysical, biochemical and biological tools have been used to mimic tendon microenvironment. Therefore, we propose to assess the combined effect of MMC and mechanical loading on different cell sources to determine their suitability for the in vitro fabrication of tendon-like tissue. The uniaxial strain induced differential cell orientation based on the differentiation state of the cells: tenocytes and DFs, both permanently differentiated cells exhibited alignment perpendicular to the direction of the load, similarly to what is seen in native tendon environment. Immunocytochemistry showed that, when MMC is used, the DFs and MSCs showed increased deposition of collagen type I, one of the main components in tendon ECM. It is also seen that the ECM deposited follows the alignment of the cell cytoskeleton. However, for tenocytes, deposition of collagen type I is only seen when MMC is used in combination with mechanical loading, indicating that mechanical loading led to increased synthesis of collagen I, suggesting maintenance of the tenogenic phenotype. Other collagen types relevant to native tendon composition were also analysed, including types III, V and VI, and their deposition was also shown to be modulated by the use of MMC and mechanical loading. This appears to recreate the events of tendon tissue formation during development, where these collagen types are involved in regulation of collagen I fibrillogenesis and fibril diameter. Preliminary data also indicates that, under mechanical loading and MMC, expression of tenogenic genes is upregulated whilst chondrogenic and osteogenic markers are downregulated. This indicates the suitability of the combination of MMC and
Background. Osteoarthritis (OA), a common degenerative disorder of synovial joints, is characterized by disruption of the extracellular matrix (ECM) homeostasis with an overall misbalance towards cartilage catabolism. Integrins are alpha/beta heterodimeric transmembrane proteins transmitting chemical and biomechanical signals into the cells. There is a growing consensus that changes of ECM composition by proteolytic degradation of matrix constituents, or alteration of the biomechanical microenvironment of chondrocytes caused by chronic stress or injury significantly increase the risk of OA through the perturbation of integrin signaling. In order to further investigate the role of the b1 integrin subfamily in OA, we have challenged hip cartilage explants dissected for mice lacking beta1 integrins in chondrocytes by cytokines, ECM degradation products or
Circular RNA (circRNA) is involved in the regulation of articular cartilage degeneration induced by inflammatory factors or oxidative stress. In a previous study, we found that the expression of Minus RNA sequencing, fluorescence in situ hybridization, and quantitative real-time polymerase chain reaction (qRT-PCR) were used to detect the expression of Aims
Methods
There is an increasing concern of osteoporotic fractures in the ageing population. Low-magnitude high-frequency vibration (LMHFV) was shown to significantly enhance osteoporotic fracture healing through alteration of osteocyte lacuno-canalicular network (LCN). Dentin matrix protein 1 (DMP1) in osteocytes is known to be responsible for maintaining the LCN and mineralization. This study aimed to investigate the role of osteocyte-specific DMP1 during osteoporotic fracture healing augmented by LMHFV. A metaphyseal fracture was created in the distal femur of ovariectomy-induced osteoporotic Sprague Dawley rats. Rats were randomized to five different groups: 1) DMP1 knockdown (KD), 2) DMP1 KD + vibration (VT), 3) Scramble + VT, 4) VT, and 5) control (CT), where KD was performed by injection of short hairpin RNA (shRNA) into marrow cavity; vibration treatment was conducted at 35 Hz, 0.3 g; 20 minutes/day, five days/week). Assessments included radiography, micro-CT, dynamic histomorphometry and immunohistochemistry on DMP1, sclerostin, E11, and fibroblast growth factor 23 (FGF23). In vitro, murine long bone osteocyte-Y4 (MLO-Y4) osteocyte-like cells were randomized as in vivo groupings. DMP1 KD was performed by transfecting cells with shRNA plasmid. Assessments included immunocytochemistry on osteocyte-specific markers as above, and mineralized nodule staining.Aims
Methods
Osteoarthritis (OA) affects bone cartilage and underlying bone. Mechanically, the underlying bone provides support to the healthy growth of the overlying cartilage. However, with the progress of OA, bone losses and cysts occur in the bone and these would alter the biomechanical behaviour of the joint, and further leading to bone remodelling adversely affect the overlying cartilage. Human femoral head and femoral condyle were collected during hip or knee replacement operation due to the end stage of osteoarthritis (age 50–70), and the cartilage patches were graded and marked. A volunteer patient, with minor cartilage injury in his left knee while the right knee is intact, was used as control. Peripheral quantitative computed tomography (pQCT) was used to scan the bone and to determine the volumetric bone mineral density (vBMD) distribution. The examination of retrieved tissue explants from osteoarthritic patients revealed that patches of cartilage were worn away from the articular surface, and patches of intact cartilage were left. The cysts, ranging from 1 to 10mm were existed in all osteoarthritic bones, and were located close to cartilage defects in the weight-bearing regions, and closely associated with the grade of cartilage defect as measured by pQCT. The bone mineral density (vBMD) distribution demonstrated that the bones around cysts had much higher vBMD than the trabecular bone away from the cysts. Compared to the subchondral bone under thicker cartilage, subchondral bone within cartilage defect has higher vBMD. This may result from the
Osteoarthritis (OA) is a common degenerative joint disease. The osteocyte transcriptome is highly relevant to osteocyte biology. This study aimed to explore the osteocyte transcriptome in subchondral bone affected by OA. Gene expression profiles of OA subchondral bone were used to identify disease-relevant genes and signalling pathways. RNA-sequencing data of a bone loading model were used to identify the loading-responsive gene set. Weighted gene co-expression network analysis (WGCNA) was employed to develop the osteocyte mechanics-responsive gene signature.Aims
Methods
Due to its avascular nature, articular cartilage exhibits a very limited capacity to regenerate and to repair. Although much of the engineered cartilage grafts so far proposed have successfully shown to mimic the morphological and biochemical appearance of hyaline cartilage, they are generally mechanically inferior to the natural tissue. 1. In this study a new bioreactor device was realized to test innovative scaffolds under physiological stimulation (i.e. perfusion fluid flow and dynamic compression), with the aim to produce a more functional engineered tissue construct for articular applications. The computer-controlled bioreactor system has been properly designed to simultaneously provide static or dynamic compression and/or continuous perfusion to 3D engineered constructs, reproducing the physiological loads to which the articular cartilage is subjected. The specifically designed bioreactor comprises a chamber where the grafts are accommodated, a porous piston connected to a linear stepper motor (Dings, Model 34-2080-4-300), which controls its movement to provide
Introduction. Primary cilia are organelles found singularly on almost every cell in the body, including tenocytes. Tendon is a hierarchical, composite structure, and previous work from our group has suggested that the cell populations in the inter-fascicular matrix (IFM) may be different from those within the fascicle matrix (FM). This study investigated how stress deprivation influenced the primary cilia of both cell types, and the mechanics of the IFM and the FM. Materials and Methods. Rat tail tendons were dissected and then either tested immediately (fresh), or maintained in media for 1 week, either stress deprived or at 4% static strain. Fascicles and IFM were then either, fixed and imaged to determine cilia length (n = 80–160 cilia per group from across 3 rats), or mechanically tested to determine the static and viscoelastic properties of both the fascicles and the IFM (n = 6–8 per group). Results. Cilia length in the IFM and FM of fresh samples were not significantly different. After 1 week of stress deprivation, the cilia had significantly increased in length in both the IFM and FM, however the increase in length in the IFM was significantly greater than that in the FM. Cilia in tissue maintained at 4% static strain were significantly shorter than those in stress deprived tissue, however they remained longer than those in fresh tissue. The tensile strength of the fascicles was not affected by stress deprivation or static strain conditions. However, the viscoelastic properties of the stress deprived fascicles were significantly reduced. By contrast, the tensile strength of the IFM was significantly reduced in the stress deprived samples, indicative of greater degradation in this region. Discussion. This is the first time differences in the cilia have been observed between tendon regions. Their different response to stress deprivation provides further evidence that these populations of cells respond differently to changes in
Bone metastases are common and severe complications of cancers. It is estimated to occur in 65–75% of breast and prostate cancer patients and cause 80% of breast cancer-related deaths. Metastasised cancer cells have devastating impacts on bone due to their ability to alter bone remodeling by interacting with osteoblasts and osteoclasts. Exercise, often used as an intervention for cancer patients, regulates bone remodeling via osteocytes. Therefore, we hypothesise that bone mechanical loading may regulate bone metastases via osteocytes. This provides novel insights into the impact of exercises on bone metastases. It will assist in designing cancer intervention programs that lowers the risk for bone metastases. Investigating the mechanisms for the observed effects may also identify potential drug targets. MLO-Y4 osteocyte-like cells (gift of Dr. Bonewald, University of Missouri-Kansas City) on glass slides were placed in flow chambers and subjected to oscillatory fluid flow (1Pa; 1Hz; 2 hours). Media were extracted (conditioned media; CM) post-flow. RAW264.7 osteoclast precursors were conditioned in MLO-Y4 CM for 7 days. Migration of MDA-MB-231 breast cancer cells and PC3 prostate cancer cells towards CM was assayed using Transwell. Viability, apoptosis, and proliferation of the cancer cells in the CM were measured with Fixable Viability Dye eFluor 450, APOPercentage, and BrDu, respectively. P-values were calculated using Student's t-test. Significantly more MDA-MB-231 and PC3 cells migrated towards the CM from MLO-Y4 cells with exposure to flow in comparison to CM from MLO-Y4 cells not exposed to flow. The preferential migration is abolished with anti-VEGF antibodies. MDA-MB-231 cells apoptosis rate was slightly lower in CM from MLO-Y4 cells exposed to flow, while proliferation rate was slightly higher. The current data showed no difference in cancer cells viability and adhesion to collagen between any two groups. On the other hand, it was observed that less MDA-MB-231 cells migrated towards CM from RAW264.7 cells conditioned in CM from MLO-Y4 cells stimulated with flow in comparison to those conditioned in CM from MLO-Y4 cells not stimulated with flow. TRAP staining results confirmed that there were less differentiated osteoclasts when RAW264.7 cells were cultured in CM from MLO-Y4 cells exposed to flow. Overall, this study suggests that when only osteocytes and cancer cells are involved, osteocytes subjected to mechanical loading can promote metastases due to the increased secretion of VEGF. However, with the incorporation of osteoclasts, mechanical loading on osteocytes seems to reduce MDA-MB-231 cell migration. This is likely because osteocytes reduce osteoclastogenesis in response to
Arthroscopic microfracture is a conventional form of treatment for patients with osteochondritis of the talus, involving an area of < 1.5 cm2. However, some patients have persistent pain and limitation of movement in the early postoperative period. No studies have investigated the combined treatment of microfracture and shortwave treatment in these patients. The aim of this prospective single-centre, randomized, double-blind, placebo-controlled trial was to compare the outcome in patients treated with arthroscopic microfracture combined with radial extracorporeal shockwave therapy (rESWT) and arthroscopic microfracture alone, in patients with ostechondritis of the talus. Patients were randomly enrolled into two groups. At three weeks postoperatively, the rESWT group was given shockwave treatment, once every other day, for five treatments. In the control group the head of the device which delivered the treatment had no energy output. The two groups were evaluated before surgery and at six weeks and three, six and 12 months postoperatively. The primary outcome measure was the American Orthopaedic Foot and Ankle Society (AOFAS) Ankle-Hindfoot Scale. Secondary outcome measures included a visual analogue scale (VAS) score for pain and the area of bone marrow oedema of the talus as identified on sagittal fat suppression sequence MRI scans.Aims
Methods
Background. Residual stress remains in bone tissues after press-fit-fixation of a joint prosthesis, recently employed for joint arthroplasty. The response of bone tissues to the residual stress is, however, unknown because it is not physiological. This unnatural stimulus may have adverse effects on bone tissues, including causing thigh pain or bone resorption. In the present study, we designed an experimental method to apply a stationary load from inside an animal femur using a loop spring of titanium alloy with super elasticity. The femoral response was assessed based on the migration of the wire into bone twelve weeks after implantation. As the results, wire migration was noted in 10 of 11 cases. Methods. We developed a method using a loop spring made of super elastic titanium alloy, which can maintain sufficient stress in a rat femur for a prolonged period. This titanium alloy, which contains 43.94% titanium and 56.06% nickel, was supplied as a wire (WDL1, Actment Co., Ltd., Kasukabe, Japan). In the present study, an experimental method was designed to apply a stationary load from inside a rat femur by inserting a loop spring made of super elastic wire. Results. Ten weeks after implantation, migration of the spring wire into the cortical bone was noted in 10 of 11 cases. To assess spring migration in cortical bone, we measured the distance from the endocortical surface to the tip of springs on micro-CT images. The line of the endocortical surface was extrapolated from the adjacent to the wire contact area. The estimated load was distributed from 1.19 to 3.28 N. The migration depth on anterior and posterior sides was not associated with the estimated load. Discussion. In the present study, we developed a method of generating a stationary stress field in a rat femur using a loop spring made from Ni-Ti alloy with super ermore, implantation of the pin was presumed to be able to interpretation by the thelasticity. The load that originated from elastic deformation was large enough to apply
Osteoarthritis (OA) is mainly caused by ageing, strain, trauma, and congenital joint abnormalities, resulting in articular cartilage degeneration. During the pathogenesis of OA, the changes in subchondral bone (SB) are not only secondary manifestations of OA, but also an active part of the disease, and are closely associated with the severity of OA. In different stages of OA, there were microstructural changes in SB. Osteocytes, osteoblasts, and osteoclasts in SB are important in the pathogenesis of OA. The signal transduction mechanism in SB is necessary to maintain the balance of a stable phenotype, extracellular matrix (ECM) synthesis, and bone remodelling between articular cartilage and SB. An imbalance in signal transduction can lead to reduced cartilage quality and SB thickening, which leads to the progression of OA. By understanding changes in SB in OA, researchers are exploring drugs that can regulate these changes, which will help to provide new ideas for the treatment of OA. Cite this article:
To investigate the risk factors for unsuccessful radial head reduction (RHR) in children with chronic Monteggia fractures (CMFs) treated surgically. A total of 209 children (mean age 6.84 years (SD 2.87)), who underwent surgical treatment for CMFs between March 2015 and March 2023 at six institutions, were retrospectively reviewed. Assessed risk factors included age, sex, laterality, dislocation direction and distance, preoperative proximal radial metaphysis width, time from injury to surgery, reduction method, annular ligament reconstruction, radiocapitellar joint fixation, ulnar osteotomy, site of ulnar osteotomy, preoperative and postoperative ulnar angulation, ulnar fixation method, progressive ulnar distraction, and postoperative cast immobilization. Independent-samples Aims
Methods
This review provides a concise outline of the advances made in the care of patients and to the quality of life after a traumatic spinal cord injury (SCI) over the last century. Despite these improvements reversal of the neurological injury is not yet possible. Instead, current treatment is limited to providing symptomatic relief, avoiding secondary insults and preventing additional sequelae. However, with an ever-advancing technology and deeper understanding of the damaged spinal cord, this appears increasingly conceivable. A brief synopsis of the most prominent challenges facing both clinicians and research scientists in developing functional treatments for a progressively complex injury are presented. Moreover, the multiple mechanisms by which damage propagates many months after the original injury requires a multifaceted approach to ameliorate the human spinal cord. We discuss potential methods to protect the spinal cord from damage, and to manipulate the inherent inhibition of the spinal cord to regeneration and repair. Although acute and chronic SCI share common final pathways resulting in cell death and neurological deficits, the underlying putative mechanisms of chronic SCI and the treatments are not covered in this review.
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].