Introduction. Autologous Matrix Induced Chondrogenesis (AMIC) for surgical treatment of osteochondral lesions of the talus (OCLT) has shown excellent clinical and radiological results at short term follow up two years after surgery. However, no mid-term follow up data is available. Aim. 1. To evaluate the clinical outcome after AMIC-aided reconstruction of osteochondral lesions of the talus at a minimum follow up time of five years. 2. To evaluate the morphology and quality of the regenerated cartilage by magnetic resonance imaging (MRI) at on at a minimum follow up time of five years. Methods. Seventeen patients prospectively underwent surgery receiving a AMIC-aided repair of OCLT consisting of debridement, autologous grafting, and sealing of the defect with a collagen scaffold (Chondro-Gide, Geistlich Surgery, Wolhusen, Switzerland). Clinical and radiological assessment was performed before and after a minimum of 60 months after surgery (average 78 months, range, 60–120). Clinical examination included the American Orthopaedic Foot & Ankle Society (AOFAS) ankle score and the Visual Analogue Scale (VAS). Radiological imaging consisted of MRI. The Magnetic Resonance Observation of Cartilage Repair Tissue (MOCART) score was applied. Results. The AOFAS ankle score improved significantly from a mean of 60 points preoperatively (range, 17–79) to 91 points (range, 70–100) postoperatively (p< 0.01). The preoperative pain score averaged a VAS of 5 (range, 2–8), improving to an average of 1.1 (range 0–8) (p< 0.01). The MOCART score for cartilage repair tissue on postoperative MRI averaged 71 points (range, 50–90). Conclusion. The AMIC-procedure is safe for the treatment of OCLT with overall good clinical and magnetic resonance imaging results at five years follow up

The reliable production of _in vitro_ chondrocytes that faithfully recapitulate _in vivo_ development would be of great benefit for orthopaedic disease modelling and regenerative therapy(1,2). Current efforts are limited by off-target differentiation, resulting in a heterogeneous product, and by the lack of comparison to human tissue, which precludes detailed evaluation of _in vitro_ cells(3,4).

We performed single-cell RNA-sequencing of long bones dissected from first-trimester fetal limbs to form a detailed ‘atlas’ of endochondral ossification. Through 100-gene in-situ sequencing, we placed each sequenced cell type into its anatomical context to spatially resolve the process of endochondral ossification. We then used this atlas to perform deconvolution on a series of previously published bulk transcriptomes generated from _in vitro_ chondrogenesis protocols to evaluate their ability to accurately produce chondrocytes.

We then applied single-nuclear RNA-sequencing to cells from the best performing protocol collected at multiple time points to allow direct comparison between the differentiation of _in vitro_ and _in vivo_ cells.

We captured 275,000 single fetal cells, profiling the development of chondrocytes from multipotent mesenchymal progenitors to hypertrophic cells at full transcriptomic breadth. Using this atlas as the ground truth for evaluating _in vitro_ cells, we found substantial variability in cell states produced by each protocol, with many showing little similarity to _in vivo_ cells, and all exhibiting off-target differentiation.

Trajectory alignment between _in vivo_ and _in vitro_ single-cell data revealed key differences in gene expression dynamics between _in vitro_ and _in vivo cells,_ with several osteoblastic transcription factors erroneously unregulated _in vitro,_ including _FOXO1._

Using this information, we inhibited _FOXO1_ in culture to successfully increase chondrocyte yield _in vitro._

This study presents a new framework for evaluating tissue engineering protocols, using single-cell data to drive improvement and bring the prospect of true engineered cartilage closer to reality.

More and more evidences showed that cartilage harbored local progenitor cells that could differentiate toward osteoblast, chondrocyte, and adipocyte. However, our previous results showed that osteoarthritis derived chondroprogenitor cells (OA-CPC) exhibited strong osteogenic potential even in chondrogenic condition. How to promote their chondrogenic potential is the key for cartilage repair and regeneration in osteoarthritis. Recently, lipid availability was proved to determine skeletal progenitor fate. Therefore, we aim to determine whether lipid inhibition under 3D culture condition could enhance OA-CPC chondrogenesis. Moreover, glucose concentration was also evaluated for chondrogenic capacity. Although there are many researches showed that lower glucose promotes chondrogenesis, in our results, we found that OA-CPC in high concentration of glucose (4.5g/L) with lipid inhibitor (GW1100) showed strongest chondrogenic potential, which could form largest cell pellet with strong proteoglycan staining, COL II expression and no COL I expression. Besides, COL2A1 was increased and COL10A1 was decreased significantly by GW1100 under high glucose condition in 2D culture. Interestingly, although the expression level of MMP13 was not changed by GW1100 at RNA and protein level, less MMP13 protein secreted out of cell nuclear. In summary, we estimated that higher glucose and lower lipid supplies benefit OA-CPC chondrogenesis and cartilage repair.

Tissue repair is believed to rely on tissue-resident progenitor cell populations proliferating, migrating, and undergoing differentiation at the site of injury. During these processes, the crosstalk between mesenchymal stromal/stem cells (MSCs) and macrophages has been shown to play a pivotal role. However, the influence of extracellular matrix (ECM) remodelling in this crosstalk, remains elusive. Human MSCs cultured on tissue culture plastic (TCP) and encased within fibrin in vitro were treated with/without TNFα and IFNγ. Human monocytes were cocultured with untreated/pretreated MSCs on TCP or within fibrin. After seven days, the conditioned media (CM) were collected. Human chondrocytes were exposed to CM in a migration assay. The impact of TGFβ was assessed by adding an inhibitor (TGFβRi). Cell activity was assessed using RT-qPCR and XL-protein-profiler-array. Previously, we demonstrated that culturing human MSCs within 3D-environments significantly enhances their immunoregulatory activity in response to pro-inflammatory stimuli. In this study, monocytes were co-cultured with MSCs within fibrin, acquiring a distinct M2-like repair macrophage phenotype in contrast to TCP co-cultures. MSC/macrophage CM characterization using a protein array demonstrated differences in release of several factors, including chemokines, growth factors and ECM components. Chondrocyte migration was significantly reduced in CM from untreated MSC/monocytes co-cultures in fibrin compared to CM of untreated MSCs/monocytes on TCP. This impact on migration was not seen with chondrocytes cultured in CM of monocytes co-cultured with pretreated MSCs in fibrin. The CM of monocytes co-cultured with pretreated MSCs in fibrin up-regulates COL2A1 and SOX9 compared to TCP. Chondrogenesis and migration were TGFβ dependent. MSC/macrophage crosstalk and responsiveness to cytokines are influenced by the ECM environment, which subsequently impacts tissue-resident cell migration and chondrogenesis. The direct effects of ECM on MSC/macrophage secretory phenotype is complemented by the dynamic ECM binding and release of growth factors such as TGFβ

Photobiomodulation (PBM), the use of light for regenerative purposes, has a long history with first documentations several thousand years ago in ancient Egypt and a Nobel Price on this topic at the beginning of last century (by Niels Finsen). Nowadays, it is in clinical use for indications such as wound healing, pain relief and anti-inflammatory treatment. Given the rising numbers of in vitro studies, there is increasing evidence for the underlying mechanisms such as wavelength dependent reactive oxygen production and adenosine triphosphate generation. In cartilage regeneration, the use of PBM is controversially discussed with divergent results in clinics and insufficient in vitro studies. As non-invasive therapy, PMB is, though, of particular importance, since a general regenerative stimulus would be of great benefit in the otherwise only surgically accessible tissues. We therefore investigated the influence of different wavelengths - blue (475 nm), green (516 nm) or red (635 nm) of a low-level laser (LLL) - on the chondrogenic differentiation of chondrocytes and adipose derived stromal cells of different human donors and applied the light in different settings (2D, 3D) with cells in a proliferative or differentiating stage. All assessed parameters (spheroid growth, histology, matrix quantification and gene expression) revealed an influence of LLL on chondrogenesis in a donor-, wavelength- and culture-model-dependent manner. Especially encouraging was the finding, that cells with poor chondrogenic potential could be improved by one single 2D treatment. Amongst the three wave lengths, red light was the most promising one with the most positive impact. Although in vivo data are still missing, these in vitro results provide evidence for a proper biofunctional effect of LLL.

Abstract. Objectives. Tissue repair is believed to rely on tissue-resident progenitor cell populations proliferating, migrating, and undergoing differentiation at the site of injury. During these processes, the crosstalk between mesenchymal stromal/stem cells (MSCs) and macrophages has been shown to play a pivotal role. However, the influence of extracellular matrix (ECM) remodelling in this crosstalk, remains elusive. Methods. Human MSCs cultured on tissue culture plastic (TCP) and encased within fibrin in vitro were treated with/without TNFα and IFNγ. Human monocytes were cocultured with untreated/pretreated MSCs on TCP or within fibrin. After seven days, the conditioned media (CM) were collected. Human chondrocytes were exposed to CM in a migration assay. The impact of TGFβ was assessed by adding an inhibitor (TGFβRi). Cell activity was assessed using RT-qPCR and XL-protein-profiler-array. Results. Previously, we demonstrated that culturing human MSCs within 3D-environments significantly enhances their immunoregulatory activity in response to pro-inflammatory stimuli. In this study, monocytes were co-cultured with MSCs within fibrin, acquiring a distinct M2-like repair macrophage phenotype in contrast to TCP co-cultures. MSC/macrophage CM characterization using a protein array demonstrated differences in release of several factors, including chemokines, growth factors and ECM components. Chondrocyte migration was significantly reduced in CM from untreated MSC/monocytes co-cultures in fibrin compared to CM of untreated MSCs/monocytes on TCP. This impact on migration was not seen with chondrocytes cultured in CM of monocytes co-cultured with pretreated MSCs in fibrin. The CM of monocytes co-cultured with pretreated MSCs in fibrin up-regulates COL2A1 and SOX9 compared to TCP. Chondrogenesis and migration were TGFβ dependent. Conclusion. MSC/macrophage crosstalk and responsiveness to cytokines are influenced by the ECM environment, which subsequently impacts tissue-resident cell migration and chondrogenesis. The direct effects of ECM on MSC/macrophage secretory phenotype is complemented by the dynamic ECM binding and release of growth factors such as TGFβ. Declaration of Interest. (b) declare that there is no conflict of interest that could be perceived as prejudicing the impartiality of the research reported:I declare that there is no conflict of interest that could be perceived as prejudicing the impartiality of the research project

Femoroacetabular impingement is a prearthritic deformity frequently associated with early chondral damage. Several techniques exist for restoring larger cartilage defects. While AMIC proved to be an effective treatment in knee and ankle, there are only short-term data available in hip. This study aimed to investigate the mid-term clinical outcome of patients with chondral lesions treated by AMIC and evaluate the quality of repair tissue via MRI.

This retrospective, single center study includes 18 patients undergoing surgical hip dislocation for FAI between 2013 and 2016. Inclusion criteria were: cam or pincer-type FAI, femoral or acetabular chondral lesions > 1 cm², (IRCS III-IV). Due to exclusion criteria and loss-to-follow-up 9 patients (10 hips) could be included. Patient reported outcome measures included Oxford Hip Score (OHS) & Core Outcome Measure Index (COMI)). MRIs were evaluated using the Magnetic Resonance Observation of Cartilage Repair Tissue (MOCART) score.

None of the patients underwent revision surgery except screw removals from the greater trochanter. Followup data indicate a satisfactory to good hip function at 5 years: PROMS improved from pre- to postop at 5 years: OHS from 38.1 to 43.4, COMI from to 1.8 and UCLA from 4 to 8.1 respectively. MOCART score was 67.5 postoperatively. Subgrouping showed slightly better results for acetabular defects (Ø 69.4) compared femoral defects (Ø 60).

Based on the reported mid-term results, we consider AMIC as a valuable treatment option for larger chondral defects of the hip.

Introduction and Objective. The meniscus is composed of two distinct regions, a vascular outer zone and an avascular inner zone. Due to vascularization, tears within the vascular zone can be treated by suturing. However, tears in the avascular zone have a poor healing capacity and partial meniscectomy is used to prevent further pain, although this leads to early osteoarthritis. Previous studies have demonstrated that the vascular zone contains a progenitor population with multilineage differentiation potential. Isolation and propagation of these progenitors can be used to develop cell-based therapies for treating meniscal defects. In vivo, the meniscus resides under a low oxygen environment, also known as physioxia (2–7% oxygen) and previous work suggests that it promotes the meniscal phenotype. The objective of the study was to isolate progenitor populations from both meniscus regions and to examine their clonogenecity and differentiation potential under both hyperoxia (20% oxygen) and physioxia (2% oxygen). We hypothesize that physioxia will have a beneficial effect on colony formation and trilineage differentiation of meniscal cells. Materials and Methods. Human meniscus (n =4; mean age: 64 + 6) tissue was split into vascular and avascular regions, finely cut into small pieces and then sequentially digested in pronase (70U/mL) and collagenase (200U/mL) at 37. 0. C. Avascular and vascular meniscus cells were counted and split equally for expansion under hyperoxia and physioxia at a seeding density of 5 × 10. 3. cells/cm. 2. At passage 1, cells were seeded at 2, 5 and 20 cells/cm. 2. in 10cm dishes for observing colony formation using crystal violet assay. At passage 3, vascular and avascular meniscus cells were differentiated towards the chondrogenic, osteogenic and adipogenic lineage. Chondrogenesis was evaluated using DMMB staining for GAG deposition, osteogenesis was assessed using Alizarin Red staining for calcium deposition, whilst adipogenesis was observed using Oil-Red-O staining for fat droplets. Results. Expansion of vascular and avascular meniscus cells showed no difference in doubling time between hyperoxic or physioxic culture. However, physioxia significantly increased the number of colonies compared to hyperoxia for both meniscus cell types (p < 0.05). Both vascular and avascular meniscus cells differentiated towards the chondrogenic, osteogenic and adipogenic lineage under both oxygen tensions. Interestingly, we observed greater DMMB, alizarin red and oil-red-o staining for vascular meniscal cells under physioxia compared to corresponding hyperoxic cultures and avascular meniscal cells. Conclusions. Physioxia enhances the clonogenecity of vascular and avascular meniscus cells. Trilineage differentiation potential was observed from both regions with increased capacity detected under physioxia for vascular meniscal cells. Physioxic isolation of meniscal cells for the propagation of these progenitors can used be for the treatment of meniscal tears/defects

To unravel the relation between mechanical loading and biological response, cell-seeded hydrogel constructs can be used in bioreactors under multi-axial loading conditions that combines compressive with torsional loading. Typically, considerable biological variation is observed. This study explores the potential confounding role of mechanical factors in multi-directional loading experiments. Indeed, depending on the material properties of the constructs and characteristics of the mechanical loading, the mechanical environment within the constructs may vary. Consequently, the local biological response may vary from chondrogenesis in some parts to proteoglycan loss in others.

This study uses the finite element method to investigate the effects of material properties of cell-seeded constructs and multiaxial loading characteristics on local mechanical environment (stresses and strains) and relate these to chondrogenesis (based on maximum compressive principal strain (MCPS) - Zahedmanesh et al., 2014) and proteoglycan loss (based on fluid velocity (FV) - Orozco et al., 2018).

The construct was modelled as a homogenized poro-hyperelastic (using a Neohookean model and Darcys law) cylinder of 8mm diameter and equal height using Abaqus. The bottom surface was fully constrained and dynamic unconfined compression and torsion loading were applied to the top surface. Free fluid flow was allowed through the lateral surface. We studied the sensitivity of the maximum values of the target parameters at 9 key locations to the material parameters and loading characteristics. Six input parameters were varied in preselected ranges: elastic modulus (E=[20,80]kPa), Poissons ratio (nu=[0.1,0.4]), permeability (k=[1,4]e-12m4/Ns), compressive strain (Comp=[5,20]%), rotation (Rot=[5,20]°) and loading frequency (Freq=[1,4]Hz). A full-factorial design of experiment method was used and a first-order polynomial surface including the interactions fitted the responses.

MCPS varies between 7.34% and 33.52% and is independent of the material properties (E, nu and k) and Freq but has a high dependency on Comp and a limited dependency on Rot. The maximum value occurs centrally in the construct, except for high values of Rot and low Comp where it occurs at the edges. FV vary between 0.0013mm/sec and 0.1807mm/sec and dominantly depends on E, k and Comp, while its dependency on Rot and Freq is limited. The maximum value usually occurs at the edges, although at high Freq it may move towards the center of the superficial and deep zones. This study can be used as a guideline for the optimized selection of mechanical parameters of hydrogel for cell-seeded constructs and loading conditions in multi-axial bioreactor studies. In future work, we will study the effect in intact and injured cartilage explants.

SOX genes comprise a family of transcription factors characterised by a conserved HMG-box domain that confer pleiotropic effects on cell fate and differentiation through binding to the minor groove of DNA. Paracrine regulation and contact-dependant Notch signalling has been suggested to modulate the induction of SOX gene expression. The objective of this study is to investigate the crosstalk between and preconditioning of mesenchymal stem cells (MSCs) with chondrocytes through comparing SOX gene expression in their co-culture and respective monocultures.

Our study adopted an in vitro autologous co-culture of p0 adipose-derived MSCs (AMSCs) and articular chondrocytes derived from Kellgren-Lawrence Grade III/IV osteoarthritic knee joints (n=7). Samples were handled according to the 2004 UK Human Tissue Act. Cells were purified and co-cultured with one AMSC for every chondrocyte at 5000 cells/cm². The AMSCs were characterised by a panel of MSC surface markers in flow cytometry and were allowed to undergo trilineage differentiation for subsequent histological investigation. SOX5, SOX6, and SOX9 expression of co-cultures and monoculture controls were quantified by TaqMan quantitative real-time PCR. Experiments were performed in triplicate.

AMSC phenotype was evidenced by the expression of CD105, CD73, CD90 & heterogenous CD34 but not CD45, CD14, CD19 & HLA-DR in flow cytometry, and also differentiation into chondrogenic, osteogenic and adipogenic lineages with positive Alcian blue, Alizarin Red and Oil Red O staining. The expression of SOX5, SOX6, and SOX9 were greater in observed co-cultures than would be expected from an expression profile modelled from monocultures.

The findings provides evidence for the upregulation of SOX family transcription factors expression during the co-culture of MSCs and chondrocytes, suggesting an active induction of chondrogenic differentiation and change of cell fate amidst a microenvironment that facilitates cell-contact and paracrine secretion. This provides insight into the chondrogenic potential and therapeutic effects of MSCs preconditioned by the chondrocyte secretome (or potentially chondrocytes reinvigorated by the MSC secretome), and ultimately, cartilage repair.

Cartilage injuries often represent irreversible tissue damage because cartilage has only a low ability to regenerate. Thus, cartilage loss results in permanent damage, which can become the starting point for osteoarthritis. In the past, bioactive glass scaffolds have been developed for bone replacement and some of these variants have also been colonized with chondrocytes. However, the hydroxylapaptite phase that is usually formed in bioglass scaffolds is not very suitable for cartilage formation (chondrogenesis). This interdisciplinary project was undertaken to develop a novel slowly degrading bioactive glass scaffold tailored for cartilage repair by resembling the native extracellular cartilage matrix (ECM) in structure and surface properties. When colonized with articular chondrocytes, the composition and topology of the scaffolds should support cell adherence, proliferation and ECM synthesis as a prerequisite for chondrogenesis in the scaffold.

To study cell growth in the scaffold, the scaffolds were colonized with human mesenchymal stromal cells (hMSCs) and primary porcine articular chondrocytes (pACs) (27,777.8 cells per mm³) for 7 – 35 d in a rotatory device. Cell survival in the scaffold was determined by vitality assay. Scanning electron microscopy (SEM) visualized cell ultramorphology and direct interaction of hMSCs and pACs with the bioglass surface. Cell proliferation was detected by CyQuant assay. Subsequently, the production of sulphated glycosaminoglycans (sGAGs) typical for chondrogenic differentiation was depicted by Alcian blue staining and quantified by dimethylmethylene blue assay assay. Quantitative real-time polymerase chain reaction (QPCR) revealed gene expression of cartilage-specific aggrecan, Sox9, collagen type II and dedifferentiation-associated collagen type I. To demonstrate the ECM-protein synthesis of the cells, the production of collagen type II and type I was determined by immunolabelling.

The bioactive glass scaffold remained stable over the whole observation time and allowed the survival of hMSCs and pACs for 35 days in culture. The SEM analyses revealed an intimate cell-biomaterial interaction for both cell types showing cell spreading, formation of numerous filopodia and ECM deposition. Both cell types revealed initial proliferation, decreasing after 14 days and becoming elevated again after 21 days. hMSCs formed cell clusters, whereas pACs showed an even distribution. Both cell types filled more and more the pores of the scaffold. The relative gene expression of cartilage-specific markers could be proven for hMSCs and pACs. Cell associated sGAGs deposition could be demonstrated by Alcian blue staining and sGAGs were elevated in the beginning and end of the culturing period. While the production of collagen type II could be observed with both cell types, the synthesis of aggrecan could not be detected in scaffolds seeded with hMSCs.

hMSCs and pACs adhered, spread and survived on the novel bioactive glass scaffolds and exhibited a chondrocytic phenotype.

Aims

The hypothesis of this study was that bone peg fixation in the treatment of osteochondral lesions of the talus would show satisfactory clinical and radiological results, without complications.

Adult articular cartilage mechanical functionality is dependent on the unique zonal organization of its tissue. Current mesenchymal stem cell (MSC)-based treatment has resulted in sub-optimal cartilage repair, with inferior quality of cartilage generated from MSCs in terms of the biochemical content, zonal architecture and mechanical strength when compared to normal cartilage. The phenotype of cartilage derived from MSCs has been reported to be influenced by the microenvironmental biophysical cues, such as the surface topography and substrate stiffness. In this study, the effect of nano-topographic surfaces to direct MSC chondrogenic differentiation to chondrocytes of different phenotypes was investigated, and the application of these pre-differentiated cells for cartilage repair was explored.

Specific nano-topographic patterns on the polymeric substrate were generated by nano-thermal imprinting on the PCL, PGA and PLA surfaces respectively. Human bone marrow MSCs seeded on these surfaces were subjected to chondrogenic differentiation and the phenotypic outcome of the differentiated cells was analyzed by real time PCR, matrix quantification and immunohistological staining. The influence of substrate stiffness of the nano-topographic patterns on MSC chondrogenesis was further evaluated. The ability of these pre-differentiated MSCs on different nano-topographic surfaces to form zonal cartilage was verified in in vitro 3D hydrogel culture. These pre-differentiated cells were then implanted as bilayered hydrogel constructs composed of superficial zone-like chondro-progenitors overlaying the middle/deep zone-like chondro-progenitors, was compared to undifferentiated MSCs and non-specifically pre-differentiated MSCs in a osteochondral defect rabbit model.

Nano-topographical patterns triggered MSC morphology and cytoskeletal structure changes, and cellular aggregation resulting in specific chondrogenic differentiation outcomes. MSC chondrogenesis on nano-pillar topography facilitated robust hyaline-like cartilage formation, while MSCs on nano-grill topography were induced to form fibro/superficial zone cartilage-like tissue. These phenotypic outcomes were further diversified and controlled by manipulation of the material stiffness. Hyaline cartilage with middle/deep zone cartilage characteristics was derived on softer nano-pillar surfaces, and superficial zone-like cartilage resulted on softer nano-grill surfaces. MSCs on stiffer nano-pillar and stiffer nano-grill resulted in mixed fibro/hyaline/hypertrophic cartilage and non-cartilage tissue, respectively. Further, the nano-topography pre-differentiated cells possessed phenotypic memory, forming phenotypically distinct cartilage in subsequent 3D hydrogel culture. Lastly, implantation of the bilayered hydrogel construct of superficial zone-like chondro-progenitors and middle/deep zone-like chondro-progenitors resulted in regeneration of phenotypically better cartilage tissue with higher mechanical function.

Our results demonstrate the potential of nano-topographic cues, coupled with substrate stiffness, in guiding the differentiation of MSCs to chondrocytes of a specific phenotype. Implantation of these chondrocytes in a bilayered hydrogel construct yielded cartilage with more normal architecture and mechanical function. Our approach provides a potential translatable strategy for improved articular cartilage regeneration using MSCs.

Objectives

The long head of the biceps (LHB) is often resected in shoulder surgery and could therefore serve as a cell source for tissue engineering approaches in the shoulder. However, whether it represents a suitable cell source for regenerative approaches, both in the inflamed and non-inflamed states, remains unclear. In the present study, inflamed and native human LHBs were comparatively characterized for features of regeneration.

Objectives

The aim of this study was to provide a comprehensive understanding of alterations in messenger RNAs (mRNAs), long noncoding RNAs (lncRNAs), and circular RNAs (circRNAs) in cartilage affected by osteoarthritis (OA).

Objectives

Re-rupture is common after primary flexor tendon repair. Characterization of the biological changes in the ruptured tendon stumps would be helpful, not only to understand the biological responses to the failed tendon repair, but also to investigate if the tendon stumps could be used as a recycling biomaterial for tendon regeneration in the secondary grafting surgery.

Joint injuries often result in inflammation and cartilage defects. When inflamed, the synovium secretes factors that prevent successful cartilage repair by inhibiting chondrogenic differentiation of progenitor cells. In particular the pro-inflammatory macrophages in the synovium are indicated to contribute to this anti-chondrogenic effect. Thus, we aimed to counteract the anti-chondrogenic effect of inflamed synovium by modulating synovial inflammation and its macrophages. Synovium tissue obtained from osteoarthritic patients undergoing a total knee replacement was cut into explants and cultured for 72 hours +/− 1 µM of the anti-inflammatory drug triamcinolone acetonide (TAA) (Sigma Aldrich). TAA significantly decreased gene expression of TNFA, IL1β and IL6, and increased expression of CCL18, IL1RA in synovial explants (all with p < 0.001). On the other hand, TAA significantly decreased the percentages of pro-inflammatory CD14+/CD80+ and CD14+/CD86+ macrophages in the synovium (both p < 0.001) as assessed by flow cytometry analyses. The percentages of anti-inflammatory CD14+/CD163+ macrophages, is significantly increased (p < 0.001) in TAA treated synovium. Conditioned medium (CM) from synovium explants downregulated the gene expression of cartilage matrix components collagen type-2 and aggrecan expression in chondrogenic MSCs. This chondrogenesis inhibiting effect was reduced by treating synovium with TAA during the production of the CM. Our findings indicate that reducing synovial inflammation might improve the joint environment for better cartilage repair, possibly by modulation of macrophage phenotypes.

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 mechanical stimulation on human stem cell differentiation in the absence of growth factors, specifically transforming growth factor β (TGFβ). Our bioreactor system allows for the application of shear, compression or a combination of both stimuli to establish the phenotypic changes induced within MSCs. Neither compression alone, nor shear alone induces a change in MSC phenotype with a fibrin-based scaffold. However, we have demonstrated that a combination of compression and shear is able to induce chondrogenic differentiation and this is due to increased endogenous expression and activation of TGFβ. Using this multiaxial load bioreactor system, we can search for novel markers and potential therapeutic targets that only occur under physiological loads. In addition, potential rehabilitation protocols to be used after cell therapy in cartilage repair can also be investigated.

Mesenchymal Stem Cells (MSCs) are a candidate cell type for treating osteoarthritic focal defects. In vivo, cartilage and bone marrow reside under a low oxygen tension, between 2–7% oxygen or physioxia, that has been shown to enhance MSC chondrogenesis. However, chondrogenesis is inhibited in the presence of IL-1. Here, it was hypothesized that physioxia reduces IL-1 inhibited chondrogenesis. Human MSCs (Mean age, 32 years; n = 9) were split equally for expansion under either 2% (physioxia) or 20% (hyperoxia) oxygen. Chondrogenic pellets (2 × 10⁵ MSCs/pellet) were formed and cultured in the presence of 10 ng/ml TGF-b₁ and in combination with either 0.1 or 0.5 ng/ml IL-1 under their respective expansion conditions. Pellets were assessed for their wet weight, GAG and collagen II content and evaluated histologically (Collagen X and MMP-13). Statistical analysis was performed using a Two-way ANOVA with Tukey post-hoc test, significant differences stated when p < 0.05. A significant dose-dependent IL-1 inhibition in chondrogenesis was observed for pellet wet weight and GAG content under hyperoxia (p < 0.05). Physioxia alone significantly increased wet weight, GAG and collagen II content (p < 0.05) compared to hyperoxia. A donor-dependant response was observed, whereby 80% of donors responded to physioxia and their analysis showed significant increases in wet weight and GAG content in the presence IL-1(p < 0.05). Furthermore, reduced hypertrophy marker expression (Collagen X and MMP-13) was observed under physioxia in the presence of IL-1. The molecular signalling mechanisms controlling these responses are to be investigated.

To overcome the severely limited regenerative capacity of cartilage, bone marrow mesenchymal stromal cells (MSCs) are an attractive cell source that is accessible less invasively and in higher quantity than articular chondrocytes (ACs). However, current in vitro chondrogenic protocols induce MSCs to form transient cartilage reminiscent of growth plate cartilage that becomes hypertrophic and is remodeled into bone. In contrast, under the same conditions, ACs form stable articular-like cartilage. Developmental studies in mice have revealed that TGF-beta/BMP, Wnt, and Hedghog/PTHrP signaling are the major regulators of both, articular cartilage and endochondral bone formation. While the differential regulation of TGF-beta/BMP and Hedgehog/PTHrP in endochondral MSC versus AC chondral differentiation is established knowledge, little is known about Wnt in these cells. Aim of this study was therefore to compare in vitro levels of Wnt network components in MSC-derived endochondral versus AC-derived articular cartilage.

Whole genome expression data comparing human MSCs and ACs at days 0 and 28 of in vitro chondrogenesis were screened for differential expression of Wnt ligands, receptors, co-receptors, activators/inhibitors and signaling molecules. Expression of the most strongly differentially regulated Wnt network genes was studied in detail during in vitro chondrogenesis of MSCs vs ACs via qPCR at days 0, 7, 14, 21, 35, and 42.

During early chondrogenesis, most Wnt components were expressed at low levels in both MSCs and ACs, with two exceptions. MSCs started into chondrogenesis with significantly higher levels of the non-canonical ligand WNT5A. ACs on the other hand expressed significantly higher levels of the canonical antagonist FRZB on day 0. During advancing and late chondrogenesis, MSCs downregulated WNT5A but still expressed it at significantly higher levels at day 42 than ACs. Strong regulation was also evident for WNT11 and the receptor PTK7 which were both strongly upregulated in MSCs. Unlike MSCs, ACs barely regulated these non-canonical Wnt genes. With regard to canonical signaling, only the transcription factor LEF1 showed strong upregulation in MSCs, while FZD9 and FRZB were only slightly upregulated in late MSC chondrogenesis. Again, these genes remained unregulated in ACs.

Our data suggest that a dynamic Wnt network regulation may be a unique characteristic of endochondral MSC differentiation while during AC chondral differentiation Wnt expression remained rather low and stable. Overall, mRNA of the non-canonical Wnt network components were stronger regulated than canonical factors which may indicate that primarily non-canonical signaling is dynamic in endochondral differentiation. Next step is to assess levels of active and total beta-catenin, the canonical Wnt mediator, and to use Wnt antagonists to establish a causal relationship between Wnt signaling and endochondral differentiation.