Summary. Objective assessment of tendon histomorphology, particularly in the context of tissue repair, requires comprehensive analyses of both cellular distribution and matrix architecture. Fourier Transform analyses of histological images collected with second harmonic generation (SHG-FT) technique provide objective, quantitative assessment of collagen fiber organization with high specificity. Concurrent nuclear staining allows simultaneous analyses of cell morphology and distribution. Introduction. Tendon injuries can be career-limiting in human and equine athletes, since the architectural organization of the tissues are lost in the course of fibrotic repair. Objective assessment of tendon repair is problematical, particularly in research addressing potential therapies. Fourier Transform analyses of histological images collected with second harmonic generation (SHG-FT) technique can provide objective, quantitative assessments of collagen fiber organization with high specificity. This study describes the use of SHG-FT with fluorescently-labelled tendon-derived cells (TDC) in an in-vivo model of equine tendinitis to assess the temporal and spatial effects of cell delivery on collagen fiber organization. Materials and methods. Collagenase-induced tendinitis was created in the mid-metatarsal region of one hindlimb superficial digital flexor tendons (SDFT) in two horses. SDFTs from two clinically normal adult horses and were also used as controls. Autogenous TDCs were isolated from the lateral digital extensor tendon of the contralateral hind limb. Four weeks post-collagenase injection, 10×10. 6. DiI-labeled TDCs were injected into the tendon lesions. Tendon samples were obtained for histologic evaluation following euthanasia, 2-weeks after cell injections. Tendon samples were cryo-sectioned to 25–30μ exposed to nuclear counter stains (DAPI and PI) and imaged immediately through a confocal microscope (Zeiss LSM 710) with a 2-photon laser source, to obtain backward SHG (bSHG) and forward SHG (fSHG) images. In addition, images with DiI and DAPI fluorescence were acquired using 500–550 nm (green) or 565–615 nm (orange) emission filters, respectively. Fourier analysis of the SHG images was carried out using imageJ software. Results. DiI-labeled TDCs could be imaged successfully under two-photon fluorescence concurrently with SHG imaging. This was possible because the excitation wavelength of the two-photon laser (780nm) and detection of emissions above 565nm do not interfere with the bSHG band (380–400nm). Images collected with bSHG included signals from DAPI-stained nuclei. In contrast, emissions from PI-labeled nuclei were acquired independently of SHG signals. The contrast generated by individual collagen fibers was higher in images collected with fSHG than bSHG. SHG-FT of fSHG images provided accurate assessment of collagen fiber orientation in repair tissue and normal tendon. Discussion/Conclusions. Objective assessment of collagen orientation, along with spatial distribution of cells within healing tendon serves as useful indices of healing. Injected DiI-labeled TDCs could be imaged successfully under two-photon fluorescence concurrently with SHG imaging. However, DiI fluorescence is susceptible to photo-bleaching during SHG acquisition. Use of an alternative nuclear counter stains, such as PI, that do not emit along with SHG signal should be considered to optimise data acquisition and support simultaneous analyses of collagen structure, cellular morphology and cell distribution. SHG-FT histologic analysis along with biochemical and biomechanical indices collectively provide comprehensive assessment of therapies for tendon repair

Osteoporosis is a mineral bone disease arising from the predominance of osteoclastic bone resorption. Bisphosphonates which inhibit osteoclasts are commonly used in osteoporosis treatment, but are not without severe adverse effects like osteonecrosis of the jaw. The mechanisms behind the development of such phenomena is not well understood. Bone homeostasis is achieved through an intimate cross-talk between osteoclasts and osteoblasts. Thus, it is important to visualise activities of these cells simultaneously in situ. Currently, there are means to visualise osteoclast shape and numbers with tartrate-resistant alkaline phosphatase (TRAP) staining but no practical and accurate methods to quantify osteoclast activity in situ. This investigation aims to establish the use of ELF97, a substrate of TRAP, to visualise and quantify osteoclast activity. This provides vital clues to mechanisms of various bone disorders. TRAP dephosphorylation of ELF97 results in a detectable fluorescent product at areas of osteoclast activity. Osteoclastic activity was initiated in zebrafish by inducing crush injuries in tail fin rays. Colocalisation of ELF97 fluorescence with osteoclast-specific DsRed in transgenic zebrafish, visualised under confocal microscopy, is used to further establish the specificity of ELF97 to sites of osteoclastic activity. Quantification is established by comparing fluorescence between wild type, osteoclast-deficient mutants and bisphosphonate-treated zebrafish. The utility of ELF97 will also be investigated in terms of the stability of the florescent product. The investigation revealed that ELF97 and DsRed fluorescence were found commonly at crush sites with osteoclastic activity. Wild type zebrafish had greater fluorescence compared to osteoclast-deficient (p<0.0001) and bisphosphonate-treated zebrafish (p<0.0001) after 7 and 14 days post-crush, revealing that fluorescence from ELF97 corresponds to expected osteoclastic activity. Fluorescence of tail fins treated with ELF97 did not diminish over a period of 21 days of storage, demonstrating its stability. ELF97 is thus a useful means to visualise osteoclast activity, potentially crucial in more advanced investigations to understand bone disorders. It could be used in combination with other cellular markers in whole biological samples to study and experimentally manipulate bone remodelling

Osteoarthritis (OA) is a degenerative joint disease affecting millions worldwide. Early detection of OA and monitoring its progression is essential for effective treatment and for preventing irreversible damage. Although sensors have emerged as a promising tool for monitoring analytes in patients, their application for monitoring the state of pathology is currently restricted to specific fields (such as diabetes). In this study, we present the development of an optical sensor system for real-time monitoring of inflammation based on the measurement of nitric oxide (NO), a molecule highly produced in tissues during inflammation. Single-walled carbon nanotubes (SWCNT) were functionalized with a single-stranded DNA (ssDNA) wrapping designed using an artificial intelligence approach and tested using S-nitroso-N-acetyl penicillamine (SNAP) as a standard released-NO marker. An optical SWIR reader with LED excitation at 650 nm, 730 nm and detecting emission above 1000 nm was developed to read the fluorescence signal from the SWCNTs. Finally, the SWCNT was embedded in GelMa to prove the feasibility of monitoring the release of NO in bovine chondrocyte and osteochondral inflamed cultures (1–10 ng/ml IL1β) monitored over 48 hours. The stability of the inflammation model and NO release was indirectly validated using the Griess and DAF-FM methods. A microfabricated sensor tag was developed to explore the possibility of using ssDNA-SWCNT in an ex vivo anatomic set-up for surgical feasibility, the limit of detection, and the stability under dynamic flexion. The SWCNT sensor was sensitive to NO in both in silico and in vitro conditions during the inflammatory response from chondrocyte and osteochondral plug cultures. The fluorescence signal decreased in the inflamed group compared to control, indicating increased NO concentration. The micro-tag was suitable and stable in joints showing a readable signal at a depth of up to 6 mm under the skin. The ssDNA-SWCNT technology showed the possibility of monitoring inflammation continuously in an in vitro set-up and good stability inside the joint. However, further studies in vivo are needed to prove the possibility of monitoring disease progression and treatment efficacy in vivo. Acknowledgments: The project was co-financed by Innosuisse (grant nr. 56034.1 IP-LS)

3D Printed polyether-ether-ketone (PEEK) has gained widespread use in clinical practice due to its excellent biocompatibility, biomechanical compatibility, and personalization. However, pre-printed PEEK implants are not without their flaws, including bioinert, optimization distortion of 3D printing digital model and prosthetic mismatching. Recent advancements in mechanical processing technology have made it possible to print bone implants with PEEK fused deposition, allowing for the construction of mechanically adaptable implants. In this study, we aimed to synthesize silanized polycitrate (PCS) via thermal polymerization and in situ graft it to PEEK surface to construct an elastomer coating for 3D printed PEEK implants (PEEK-PCS). This incorporation of PCS allows the implant to exhibit adaptive space filling ability and stress dispersal. In vivo and in vitro results, PEEK-PCS exhibited exceptional osseointegration and osteogenesis properties along with macrophage M2 phenotypic polarization, inflammatory factors reducing, promotion of osteogenic differentiation in bone marrow mesenchymal stem cells (BMSCs). Additionally, PEEK-PCS displays good autofluorescence properties in vitro and in vivo, with stable fluorescence for 14 days, suggesting potential bioimaging applications. The study confirms that PEEK in situ grafting with thermo-polymerized PCS elastomers is a viable approach for creating multifunctional (bone defect adaptation, bioimaging, immune regulation, and osseointegration) implants for bone tissue engineering

While high-performance ceramics like alumina and zirconia exhibit excellent wear resistance, they provide poor osseointegration capacity. As osseointegration is crucial for non-cemented joint prostheses, new techniques have been successfully developed for biofunctionalizing high-performance ceramic surfaces. Stable cell adhesion can be achieved by covalently bound specific peptides. In this study we investigate the effect of sterilization processes on organo-chemically functionalized surfaces. To enhance the performance of alumina-toughened zirconia ceramics (ATZ), a 3-aminopropyldiisopropylethoxysilane (APDS) monolayer was applied and coupled with cyclo-RGD peptides (cRGD) by using bifunctional crosslinker bis(sulfosuccinimidyl)suberat (BS³). The samples were sterilized using e-beam or gamma-sterilization at 25 kGy, either before or after biofunctionalization with cRGD. Functionalization stability was investigated by contact angle measurements. The functionality of cRGD after sterilization was demonstrated using proliferation tests and cytotoxicity assays. Immunofluorescence staining (pFAK, Actin, DAPI) was conducted to evaluate the adhesion potential between the samples and human mesenchymal stem cells (hMSCs). Functionalized samples before and after sterilization showed no significant difference regarding their contact angles. A proliferation test demonstrated that the cells on functionalized samples proliferate significantly more than on untreated samples before and after sterilization. hMSCs showed a significant higher proliferation on gamma sterilized samples compared to all other groups after 14 days. It was confirmed that the samples did not exhibit cytotoxic behavior before or after sterilization. Fluorescence microscopy demonstrated that both, cells on sterilized and on non-sterilized samples, expressed high levels of pFAK-Y397. The investigated functionalization enables improved adhesion and proliferation of hMSCs and is stable against the investigated sterilization processes. This is of importance as the option of having a sterile product enables the start of the translation of this biofunctional coating towards preclinical and subsequently first-in-man applications. Acknowledgments: We acknowledge the financial support of the Federal Ministry of Education and Research, BMBF (13GW0452A-C)

The development of cytoplasmic processes from in situ chondrocytes is a characteristic feature of early osteoarthritis in human cartilage. The processes involve cytoskeletal elements and are distinct from the short primary cilia described in human chondrocytes. Vimentin is an intermediate filament playing an essential structural and signal-transduction role. We determined cellular levels and distribution of vimentin in chondrocytes of different morphologies in non-degenerate and mildly osteoarthritic cartilage. Femoral heads were obtained after consent from patients undergoing hip arthroplasty following femoral neck fracture. Cartilage explants were graded as non-degenerate (grade 0;G0) or mildly osteoarthritic (grade 1;G1) and labelled with the cytoplasmic dye CMFDA (5-chloromethylfluorescein-diacetate) for cell shape. Explants were cryosectioned and labelled for vimentin by fluorescence immunohistochemistry. In situ chondrocyte morphology was identified by confocal microscopy as either normal (rounded/elliptical) or abnormal (with one or more cytoplasmic process of ≥2µm) and vimentin levels and distribution determined semi-quantitatively and related to chondrocyte morphology. When all cells in G0 and G1 cartilage were compared, there was no difference between average levels of vimentin per cell (P=0.144)[6(261)];femoral heads:cells). When cells were separated on the basis of morphology, there was no difference between vimentin levels in cells with one or more cytoplasmic process compared to those of normal morphology (P>0.05;[6(261)]). However vimentin levels were much greater at the base of cytoplasmic processes compared to distant areas of the same cells (P=0.021)[5(29)]). Although overall levels of chondrocyte vimentin do not change in these early stages of osteoarthritis, the formation and structure of these substantial chondrocyte cytoplasmic processes involves changes to its distribution. These morphological changes are similar to those occurring during chondrocyte de-differentiation to fibroblasts reported in osteoarthritis which results in the formation of mechanically-inferior fibro-cartilage. Alterations to chondrocyte vimentin distribution either directly or indirectly may play a role in cartilage degeneration

To investigate temporal changes in synovial lymphatic system (SLS) drainage function after Anterior cruciate ligament (ACL) injury, a non-invasive ACL rupture model was used to induce the PTOA phenotype without altering the SLS structure. We have created a non-invasive ACL rupture model in the right knee (single overload impact) of 12- week-old C57bl/6 male mice to mimic the ACL rupture-induced PTOA development. 70 kDa-TxRedDextran were injected into the right knee of the mice at 0, 1, 2, and 4 wks post modeling (n=5/group), and the fluorescence signal distribution and intensity were measured by the IVIS system at 1 and 6 hrs post-injection. After 24 hrs, the drainage lymph nodes and whole knee joint were harvested and subjected to ex vivo IVIS imaging and immunofluorescence detection respectively. Manual ACL rupture was induced by 12N overloaded force and validated by a front drawer test. Intraarticular clearance of TxRed-Dextran detected by the IVIS was significantly reduced at 1, and 2 wks at a level of 43% and 55% respectively but was not significantly different from baseline levels at 4 wks (89%). TxRed-Dextran signal in draining lymph nodes was significantly reduced at 1 week at the level of but not for 2 and 4 wks compared to baseline levels (week 1–29%, week 2–50%, week 4–94%). TxRed-Dextran particle was significantly enriched in the synovium at 1, 2 wks but was not significantly different from baseline levels at 4 wks rupture-post ACL rupture (Particle numbers: Sham Ctrl-34 ±14, week 1, 113 ± 17; week 2, 89 ± 13; week 4, 46 ± 18; mean ± SD). We observed the drainage function of SLS significantly decreased at 1 and 2 wks after the ACL rupture, and was slowly restored at 4 wks post-injury in a non-invasive ACL rupture model. Early impairment of SLS drainage function may lead to accumulation of inflammatory factors and promote PTOA progression

Early changes within articular cartilage during human idiopathic osteoarthritis are poorly understood. However alterations to chondrocyte morphology occur with the development of fine cytoplasmic processes and cell clusters, potentially playing a role in cartilage degeneration. The aggrecanase ADAMTS-4 (A disintegrin and metalloproteinase with thrombospondin motifs-4) has been implicated as an important factor in cartilage degradation, so we investigated the relationship between chondrocyte morphology and levels of ADAMTS-4 in both non-degenerate and mildly osteoarthritic human cartilage. Human femoral heads were obtained following consent from patients undergoing hip arthroplasty following femoral neck fracture. Cartilage explants of normal (grade 0; G0) and mildly osteoarthritic (grade 1; G1) cartilage were labelled with the cytoplasmic dye CMFDA (5-chloromethylfluorescein-diacetate). Explants were cryosectioned (30μm sections), and labelled for ADAMTS-4 by fluorescence immunohistochemistry. Sections were imaged with confocal microscopy, allowing the semi-quantitative analysis of ADAMTS-4 and 3D visualisation of in situ cell morphology. With cartilage degeneration from G0 to G1, there was a decrease in the proportion of chondrocytes with normal rounded morphology (P<0.001) but an increase in the proportion of cells with processes (P<0.01) and those in clusters (P<0.001;[4(1653)]; femoral heads:cells). Although average levels of ADAMTS-4 for all cells was the same between G0 and G1 (P>0.05), a change was evident in the distribution curves for cell-specific ADAMTS-4 labelling. Cell-by-cell analysis showed that ADAMTS-4 levels were higher in chondrocytes with cytoplasmic processes compared to normal cells (P=0.044) however cells in clusters had lower levels than normal cells (P=0.003;[3(436)]). Preliminary data suggested that ADAMTS-4 levels increased with larger chondrocyte clusters. These results suggest complex heterogeneous changes to levels of cell-associated ADAMTS-4 with early cartilage degeneration – increasing in cells with processes and initially decreasing in clusters. Increased levels of ADAMTS-4 are likely to produce focal areas of matrix weakness potentially leading to early cartilage degeneration

Joint tissues release extracellular vesicles (EVs) that potentially sustain joint homeostasis and contribute to osteoarthritis (OA) pathogenesis. EVs are putative novel therapeutics for OA, and transport biologically active molecules (including small non-coding RNAs (SNCRNAs)) between cells. This study identified altering SNCRNA cargo in EVs in OA which may act as early diagnostic markers and treatment targets. OA was surgically induced in four skeletally mature Standardbred horses using an osteochondral fragment model in the left middle carpal joint. The right joint underwent sham surgery. Synovial fluid (SF) and plasma were obtained weekly throughout the 70-day study. EVs were isolated using size exclusion chromatography and characterised using nanoparticle tracking (Nanosight), and exosome fluorescence detection and tetraspanin phenotyping (Exoview). RNA was extracted from EVs derived from SF (sham and OA joints) and plasma collected at days 10, 35, 42, 49, 56, 63, and subjected to small RNA sequencing on a NovaSeq SP100 flow cell (Illumina). Nanosight-derived EV characteristics of size and concentration were not significantly different following disease induction. The diameter of the temporal population of plasma and SF-derived exosomes changed significantly for CD9 and CD81 following OA induction with significant temporal, and disease-related changes in CD63 and CD81 protein expressin in plasma and SF. In SF and plasma-derived EVs snoRNAs, snRNAs, tRNAs, lncRNA, y-RNA, piRNAs and scRNA were found. Following pairwise analysis of all-time points we identified 27 miRs DE in plasma and 45 DE miRs in SF. Seven were DE in plasma and SF; miR-451, miR-25, miR-215, miR-92a, miR-let-7c, miR-486-5p, miR-23a. In plasma and SF 35 and 21 snoRNAs were DE with four DE in plasma and SF; U3, snord15, snord46, snord58. This work has identified alterations to OA EV sncRNAs in plasma and SF providing a greater understanding of the role of EVs in early OA

Preventing infections in joint replacements is a major ongoing challenge, with limited effective clinical technologies currently available for uncemented knee and hip prostheses. This research aims to develop a coating for titanium implants, consisting of a supported lipid bilayer (SLB) encapsulating an antimicrobial agent. The SLB will be robustly tethered to the titanium using self-assembled monolayers (SAMs) of octadecylphosphonic acid (ODPA). The chosen antimicrobial is Novobiocin, a coumarin-derived antibiotic known to be effective against resistant strains of Staphylococcus aureus. ODPA SAMs were deposited on TiO. 2. -coated quartz crystal microbalance (QCM) sensors using two environmentally friendly non-polar solvents (anisole and cyclopentyl methyl ether, CPME), two concentrations of ODPA (0.5mM and 1mM) and two processing temperatures (21°C and 60°C). QCM, water contact angle measurements, X-ray photoelectron spectroscopy (XPS), atomic force microscopy (AFM) and temperature-programmed desorption mass spectrometry (TPD-MS) were used to characterise the ODPA SAM. A SLB with encapsulated Novobiocin was subsequently developed on the surface of the ODPA SAM using fluorescent lipids and a solvent assisted method. The prototype implant surface was tested for antimicrobial activity against S. aureus. A well-ordered, uniform ODPA SAM was rapidly formed using 0.5 mM ODPA in CPME at 21°C during 10 min, as confirmed by high Sauerbrey mass (≍285-290 ng/cm. 2. ), high atomic percentage phosphorus (detected using XPS) and high water contact angles (117.6±2.5°). QCM measurements combined with fluorescence microscopy provided evidence of complete planar lipid bilayer formation on the titanium surface using a solvent assisted method. Incorporation of Novobiocin into the SLB resulted in reduced attachment and viability of S. aureus. Key parameters were established for the rapid, robust and uniform formation of an ODPA SAM on titanium (solvent, temperature and concentration). This allowed the successful formation of an antimicrobial SLB, which demonstrated potential for reducing attachment and viability of pathogens associated with joint replacement infections

Stem cells are known to have low levels of intracellular reactive oxygen species (ROS) and high levels of glutathione. ROS are thought to interact with several pathways that affect the transcription machinery required for stem cell differentiation, and are critical for maintaining stem cell function. In this study, we are developing a new fluorescent probe that rapidly and reversibly reacts with glutathione (GSH), the most abundant non-protein thiol in living cells that acts as an antioxidant and redox regulator. Multipotent perivascular progenitor cells derived from human ESCs (hESC-PVPCs): Differentiated ESCs as embryoid bodies in the presence of BMP4 to induce mesoderm differentiation followed by a simple cell selection strategy using attachment of single cells onto collagen-coated dishes. Differential gene expression profiling was performed among H9 hESCs, EBs induced by BMP4 and naturally selected CD140B+CD44+ population at Day 7 (PVPCs). Colony-forming assay: GSHhigh and GSHlow PVPCs were plated on 10-cm tissue culture-treated polystyrene dishes in triplicate in growth medium and cultured for 14 days. Transwell migration assay: GSHhigh and GSHlow PVPCs at passage 4 were resuspended at 1 × 10. 6. /mL in the migration medium and seeded in the upper chamber. The following human recombinant SDF-1 and PDGF-AA proteins were used as chemoattractants in the lower compartment. Probe-GSH conjugate shows shifts in fluorescence excitation and emission spectra that enables ratiometric measurement of GSH levels. Using these properties, stem cells can be purified by FACS-based technology according to intracellular GSH level. We are developing a protocol both for comparing GSH level in stem cell from different culture conditions and for preparing stem cells with high-GSH level . Our results reveal that GSHhigh PVPC purified by FACS show increased colony forming ability compared with that GSHlow PVPC, indicating that intracellular GSH contributes to the maintenance of stemness. Moreover, transplantation of GSHlow PVPC is more effective than that of GSHlow PVPC for cartilage regeneration in osteochondral defect. This technique enable FACS-based sorting of stem cells according to intracellular GSH levels and thus investigation of functional role of GSH (high antioxidant capacity) in the stem cell maintenance and chondrogenic differentiation

A substantial body of evidence supports the use of extracorporeal shock wave therapy (ESWT) for fracture non-unions in human medicine. However, the success rate (i.e., radiographic union at six months after ESWT) is only approximately 75%. Detailed knowledge regarding the underlying mechanisms that induce bio-calcification after ESWT is limited. The aim of the present study was to analyse the biological response within mineralized tissue of a new invertebrate model organism, the zebra mussel Dreissena polymorpha, after exposure with extracorporeal shock waves (ESWs). Mussels were exposed to ESWs with positive energy density of 0.4 mJ/mm. 2. or were sham exposed. Detection of newly calcified tissue was performed by concomitantly exposing the mussels to fluorescent markers. Two weeks later, the fluorescence signal intensity of the valves was measured. Mussels exposed to ESWs showed a statistically significantly higher mean fluorescence signal intensity within the shell zone than mussels that were sham exposed. Additional acoustic measurements revealed that the increased mean fluorescence signal intensity within the shell of those mussels that were exposed to ESWs was independent of the size and position of the focal point of the ESWs. These data demonstrate that induction of bio-calcification after ESWT may not be restricted to the region of direct energy transfer of ESWs into calcified tissue. The results of the present study are of relevance for better understanding of the molecular and cellular mechanisms that induce formation of new mineralized tissue after ESWT. Specifically, bio-calcification following ESWT may extend beyond the direct area of treatment

Summary. A novel in vivo animal model to establish new surgical interventions for patients with ACL insufficiency. Introduction. After ACL reconstruction, recruited cells from surrounding tissues play crucial roles in ligamentization to obtain adequate structural properties. To allow athletes to return sports activity sooner, these remodeling processes should be elucidated and be accelerated. However, in conventional animal models, it has been difficult to differentiate donor and recipient cells. Here we introduce the transgenic Kusabira-Orange pigs, in which cells produce fluorescence systemically, as in vivo model to trace cell recruitment after ACL reconstruction. Methods. After the approval by the Institutional Animal Care and Used Committee, a transgenic pig that carries and produces red fluorescent Kusabira-Orange (KO) was established. Skeletally immature transgenic pigs (n=12) (20 wks old, 76.0 ± 17.5 kg) and wild type (WT) pigs were used as recipient and donor, respectively. For validation of the pigs as in vivo model, the ACL histological structure, cell shape, mitogenic activity, and migration activity were assessed and were compared to those of wild type pigs. The sensitivity and specificity of KO fluorescence under microscopy were analyzed. Histological analyses were conducted with HE, Masson trichrome (MT), and DAPI staining. The length change pattern in our ACL reconstruction was evaluated to validate the surgical procedure. After allograft ACL reconstruction with fresh-frozen flexor digital tendon of WT pigs, pigs were euthanised at 3, 6, 12, and 24 weeks postoperatively (3 pigs each) for the histological analyses. Results. The histological analyses, and mitogenic/migration assays did not show any apparent differences between KO and WT pigs. The sensitivity and specificity of KO fluorescence revealed to be 98%. Maximal length change of the reconstructed ACL was less than 3.5 mm. Three weeks postoperatively, host cells producing KO fluorescence repopulated mainly at the peripheral part of the graft, while, interestingly, cells also located in inter-territorial space of collagen fascicles. More cells migrated towards the mid of the graft in 6–12 week. Cell distribution became homogeneous in parallel to matrix remodeling in 12–24 week. Discussion. As far as we know, this is the first study to apply the genetically engineered pig producing a fluorescent protein as in vivo model to analyze biological remodeling processes after ACL reconstruction. ACL fibroblasts in KO pigs could be detected under fluorescence with high sensitivity and specificity. In addition, structural organization, mitogenic and migration activity were not different from those in WT. As for histological experiments, the recipient cells could be easily and effectively differentiated from donor cells especially 3 weeks postoperatively. Cells migrated in the inter-territorial region among collagen fascicles earlier than we expected. We are going to investigate angiogenesis, matrix remodeling, and structural properties in parallel to the cell migration

Recapitulating tissue elasticity can direct mesenchymal stromal cell (MSC) differentiation; however, it is unclear how substrate elasticity affects MSC metabolism. It is hypothesized MSCs subjected to stiffnesses, atypical of standard tissue culture plastic, display altered metabolic phenotypes during differentiation. In this study, such alterations in MSC metabolic profiles, based on the fluorescence lifetime of NAD(P)H, a critical co-factor in energy production, were monitored using Fluorescence lifetime imaging microscopy (FLIM) as an evaluation tool. Polyacrylamide substrates with varying stiffnesses were fabricated to model the native elasticity of cartilage and bone. MSCs cultured on these substrates exhibited potent alterations in their metabolic status over a 14-day period that were detectable as early as day 3 using FLIM. Overall, soft substrates induced a more glycolytic response after 10 days of culture that persisted at day 14 (as measured by protein-bound NAD(P)H contributions to the lifetime decay). Similarly, by day 10; MSCs on intermediate-stiffness substrates favoured glycolysis. MSCs on stiffer substrates initially displayed a glycolytic phenotype followed by a transition to oxidative phosphorylation by day 10. Staining for mineralised nodules and glycosaminoglycans verified MSCs on stiffer substrates differentiating towards an osteogenic lineage, while MSCs on intermediate substrates showed similarities with differentiated chondrocytes. Overall, it can be concluded that matrix stiffness can induce metabolic perturbations in MSCs for up to 14 days. From this research, ideal culture conditions in which the metabolics of MSCs could be manipulated to promote maximum potency could potentially be defined in the future

Introduction and Objective. Individuals with type 2 diabetes (T2D) have a 3-fold increased risk of bone fracture compared to non-diabetics, with the majority of fractures occurring in the hip, vertebrae and wrists. However, unlike osteoporosis, in T2D, increased bone fragility is generally not accompanied by a reduction in bone mineral density (BMD). This implies that T2D is explained by poorer bone quality, whereby the intrinsic properties of the bone tissue itself are impaired, rather than bone mass. Yet, the mechanics remain unclear. The objective of this study is to (1) assess the fracture mechanics of bone at the structural and tissue level; and (2) investigate for changes in the composition of bone tissue along with measuring total fluorescent advanced glycation end products (fAGEs) from the skin, as T2D progresses with age in Zucker diabetic fatty (ZDF (fa/fa)) and lean Zucker (ZL (fa/+)) rats. Materials and Methods. Right ulnae and skin sections were harvested from ZDF (fa/fa) (T2D) and ZL (fa/+) (Control) rats at 12 and 46 weeks (wks) of age (n = 8, per strain and age) and frozen. Right ulnae were thawed for 12 hrs before micro-CT (μCT) scanning to assess the microstructure and measure BMD. After scanning, ulnae were loaded until failure via three-point bending. Fourier transform-infrared microspectroscopy (FTIR) was used to measure various bone mineral- and collagen-related parameters such as, mineral-to-matrix ratio and nonenzymatic cross-link ratio. Finally, fAGEs were measured from skin sections using fluorescence spectrometry and an absorbance assay, reported in units of ng quinine/ mg collagen. Results. At 12 and 46 wks bone size was significantly smaller in length (p < 0.01), cortical area (p < 0.001) and cross-sectional moment of inertia (p < 0.001) in T2D rats compared to age-matched controls. A slight reduction in BMD was observed in T2D rats compared to controls at both ages, however, this was not significant. Structural properties of T2D bone were significantly altered at 12 and 46 wks, with bending rigidity increasing approximately 2.5-fold and 1.5-fold in control and T2D rats with age, respectively (p < 0.0001). Similarly, yield and ultimate moment significantly reduced in T2D rats with age in comparison to controls (p < 0.0001). Energy absorbed to failure was significantly reduced in T2D rats at 46 weeks of age compared to controls (p < 0.01). The amount of energy absorbed to failure increased approximately 1.4-fold from 12 to 46 wks in control rats, however, in T2D rats a reduction was seen with age, although not significant. At 12 wks, there was no significant deficits in tissue material properties, whereas, at 46 wks a significant reduction in yield stress, yield strain and ultimate stress was observed for T2D rats in comparison to controls (p < 0.05). Conclusions. These findings show that longitudinal growth is impaired as early as 12 wks of age and by 46 wks bone size is significantly reduced in T2D rats compared to controls. The reduction in T2D structural properties is likely attributed to the bone geometry deficits. At 12 wks of age, the tissue material properties are not altered in T2D bone versus controls. However, at 46 wks, bone strength is reduced in T2D, leading to the conclusion that tissue properties are altered as the disease progresses

Abstract. Objectives. Musculoskeletal injuries are the leading contributor to disability globally, yet current treatments do not offer complete restoration of the tissue. This has resulted in the exploration of novel interventions based on tissue engineering as a therapeutic solution. This study aimed to explore novel collagen sponges as scaffolds for bone tissue engineering as an initial step in the construction of tendon-bone co-culture constructs in vitro. Methods. Collagen sponges (Jellagen, UK), manufactured from Jellyfish collagen were seeded with 10,000 rat osteoblast cells (dROBs) and maintained in culture for 6 days (37°C, 5% CO. 2. ). Qualitative viability was assessed by a fluorescent Calcein-AM live cell stain and quantitively via the CYQUANT cell viability assay (Invitrogen, UK) on days 0, 1, 4 and 6 in culture (n=3 per time point). Digital imaging was also used to assess size and shape changes to the collagen sponge in culture. Results. The collagen sponge biomaterial supported dROB adhesion, viability and proliferation with an abundance of viable cells detected by fluorescent microscopy on day 6. Indeed, the quantitative assessment confirmed that cellular proliferation was evident with increases in fluorescence detected from 517 (± 88) RFU to 8730 ± (2228) RFU from day 0 to 6. In addition, the size of the collagen sponges appeared to decrease over time, indicating contraction of the collagen sponges in culture. Conclusions. This preliminary study has demonstrated that the novel collagen sponges support cellular attachment and proliferation of osteoblasts, and is an important first step in building a bone-tendon construct in vitro. Our future work is focussed on using the osteoblast-seeded sponges in combination with tendon cells, to build a co-culture to represent the bone-tendon interface in vitro. This work has the potential to advance the clinical translation of tissue-engineered tendons to the clinic. 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

Bone remodelling is mediated through the synchronism of bone resorption (catabolism) by osteoclasts and bone formation (anabolism) by osteoblasts. Imbalances in the bone remodelling cycle represent an underling cause of metabolic bone diseases such as osteoporosis, where bone resorption exceeds formation (1). Current therapeutic strategies to repair osteoporotic bone fractures focus solely in targeting anabolism or supressing catabolism (2). However, these therapeutics do not reverse the structural damage present at the defect site, ultimately leading to impaired fracture healing, making the repair of osteoporotic fractures particularly challenging in orthopaedics. Herein, we focus on investigating a combined versatile pro-anabolic and anti-catabolic effect of Magnesium (Mg. 2+. ) to modulate bone cell behaviour (3), to develop an engineered biomimetic bio-instructive biomaterial scaffold structurally designed to enhance bone formation while impeding pathological osteoclast resorption activities to facilitate better bone healing and promote repair. Pre-osteoblasts MC3T3-E1 (OBs) and osteoclasts progenitors RAW 264.7 (OCs) cell lines were cultured in growth media exposed to increasing concentrations of MgCl. 2. (0, 0.5, 1, 10, 25 and 50mM) and the optimal concentration to concurrently promote the differentiation of OBs and inhibit the differentiation or funtion of RANKL-induced OCs was assessed. We next used Fluorescence Lifetime Imaging Microscopy to investigate changes in the metabolic pathways during OBs and OCs differentiation when exposed to increasing MgCl. 2. concentrations. We developed a range of magnesium-incorporated collagen scaffolds to permit the spatiotemporal release of Mg. 2+. within the established therapeutic window, and to investigate the behaviour of bone cells in a 3D environment. In our results, we reported an increase in the expression of the bone formation markers osteocalcin and osteopontin for OBs exposed to 10mM MgCl. 2. , and a significant downregulation of the osteoclast-specific markers TRAP and cathepsin K in RANKL-induced OCs differentiation when exposed to 25mM MgCl. 2. Moreover, 25mM MgCl. 2. induced changes in the energy metabolism of OCs from a predominantly oxidative phosphorylation towards a more glycolytic pathway suggesting a regulatory effect of Mg. 2+. in the underlying mechanisms of osteoclasts formation and function. The developed porous collagen-magnesium scaffolds significantly reduced the expression of early osteoclastogenic markers RANK and NFkB, and an elevated expression of the osteogenic markers Runx2 and Col1A1 was reported after 7 days. Our research to date has provided evidences to demonstrate the potential of Mg. 2+. to concurrently enhance osteogenesis while inhibiting osteoclastogenesis in vitro, potentially introducing new targets for developing therapies to repair osteoporotic bone fractures

Summary. This study helps to elucidate how ColVI and Dcn within the pericellular matrix (PCM) of differentiating hMSCs directly impacts dynamic cytoskeletal response to load, and demonstrates an important role for the PCM in mechanotransduction during chondrogenesis. Introduction. Mechanosignaling events in differentiating human mesenchymal stem cells (hMSCs) are dependent on their temporally changing micromechanical environment and their dynamic cytoskeleton. During chondrogenic differentiation, hMSCs develop a matrix composed of type VI collagen (ColVI) and proteoglycans such as decorin (Dcn). We have previously demonstrated that this developing PCM is important in cellular mechanotransduction. The aim of this study was to determine the functional roles of ColVI and Dcn in modulating load-induced changes in the organization of vimentin intermediate filaments (VIF), actin microfilaments (AM), and vinculin. Methods. hMSCs were transduced with shRNA targeting either col6a1 (shColVI) or dcn (shDcn) and then cultured in 2% alginate beads for 14 days in chondrogenic media. GFP-transduced hMSCs were cultured in parallel. Cells with their intact PCM were isolated with 100mM sodium citrate, 30mM EDTA, and re-embedded in alginate discs. These hMSC-alginate constructs underwent unconfined compression at 0.1Hz for 1 hour from 0–10% strain. Free Swelling (FS) and loaded discs were fixed either immediately following (0hr) or 4 hours post-load. Discs were cryosectioned and fluorescently labeled for VIF, AM, or vinculin with DAPI counterstain. Confocal image-stacks were collected and corrected total cell fluorescence (CTCF) per area was calculated using ImageJ (NIH) to quantify cytoskeletal organization. Results. VIF fluorescence showed a dynamic cytoskeletal response to load in non-infected and GFP-transduced controls with an increase in intensity. In both ColVI and Dcn knockdown groups, VIF exhibited higher fluorescence in FS, which then didn't significantly change following load, possibly due to its higher baseline concentration. AM showed a similar response to load in shColVI knockdown samples, with a significantly higher intensity in FS samples, which wasn't affected by loading and remained cortically localised in all samples. In shDcn samples, there was a significant increase in actin content immediately following load, similar to control. Vinculin staining showed significantly lower staining intensity in shColVI knockdown samples than non-infected and GFP-transduced samples at all timepoints, and exhibited a different trend in response to loading. Following loading, vinculin was diffusely stained across the cytoskeleton in all samples. Discussion. This study demonstrates through targeted shRNA knockdown that the involvement of ColVI and Dcn in mechanosignaling events of differentiating hMSCs could be due to their interactions with and control over the dynamic cytoskeleton. Vimentin and actin have previously been shown to contribute to the viscoelastic mechanical properties of hMSCs and are important in the ability for cells to resist load. Our experiments indicate that specific components in the PCM can affect cytoskeletal dynamics, with knockdown samples lacking the significantly dynamic response to load seen in control samples. Actin cytoskeletal intensity and vinculin intensity show an inverse relationship to load. Since vinculin mediates interactions between actin cytoskeleton and integrins at focal adhesions, these data suggest that ColVI and Dcn regulation of cytoskeletal response may be governed more by the changing external micromechanical environment, rather than altered cell-matrix interactions. Further studies are needed to elucidate the roles of ColVI and Dcn in downstream intracellular mechanosignaling events of differentiating hMSCs

Uncemented implants combining antimicrobial properties with osteoconductivity would be highly desirable in revision surgery due to periprosthetic joint infection (PJI). Silver coatings convey antibacterial properties, however, at the cost of toxicity towards osteoblasts. On the other hand, topological modifications such as increased surface roughness or porosity support osseointregation but simultaneously lead to enhanced bacterial colonization. In this study, we investigated the antibacterial and osteoconductive properties of silver-coated porous titanium (Ti) alloys manufactured by electron beam melting, rendering a macrostructure that mimics trabecular bone. Trabecular implants with silver coating (TR-Ag) or without coating (TR) were compared to grit-blasted Ti6Al4V (GB) and glass cover slips as internal controls. Physicochemical characterization was performed by X-ray diffraction (XRD) and energy dispersive X-rays (EDX) together with morphological characterization through electron scanning microscopy (SEM). Bacterial adherence after incubation of samples with Staphylococcus (S.) aureus and S. epidermidis strains harvested from PJI patients was quantitatively assessed by viable count after detachment of adherent bacteria by collagenase/dispase treatment. Primary human osteoblasts (hOB) were used to investigate the osteoconductive potential by lactate dehydrogenase (LDH) and alkaline phosphatase (ALP) activity. Cell morphology was investigated by fluorescence microscopy after staining with carboxifluorescein diacetate succinimidyl ester (CFDA-SE) and 4′,6-diamidino-2-phenylindole (DAPI). The trabecular implants depicted a porosity of 70% with pore sizes of 600µm. The amount of silver analyzed by EDX accounted for 35%wt in TR-Ag but nil in TR. Silver-coated TR-Ag implants had 24% lower S. aureus viable counts compared to non-coated TR analogues, and 9% lower compared to GB controls. Despite trabecular implants, both with and without silver, had higher viable counts than GB, the viable count of S. epidermidis was 42% lower on TR-Ag compared to TR. The percentage of viable hOB, measured by LDH and normalized to controls and area at 1 day, was lower on both TR-Ag (18%) and on TR (13%) when compared with GB (89%). However, after 1 week, cell proliferation increased more markedly on trabecular implants, with a 5-fold increase on TR-Ag, a 3.4-fold increase on TR, and a 1.7-fold increase on GB. Furthermore, after 2 weeks of hOB culture, proliferation increased 20-fold on TR-Ag, 29-fold on TR, and 3.9-fold for GB, compared to 1 day. The osteoconductive potential measured by ALP illustrated slightly higher values for TR-Ag compared to TR at 1 day and 2 weeks, however below those of GB samples. Cell morphology assessed by microscopy showed abundant growth of osteoblast-like cells confined to the pores of TR-Ag and TR. Overall, our findings indicate that the silver coating of trabecular titanium exerts limited cytotoxic effects on osteoblasts and confers antimicrobial effects on two PJI-relevant bacterial strains. We conclude that improving material design by mimicking the porosity and architecture of cancellous bone can enhance osteoconductivity while the deposition of silver confers potent antimicrobial properties

Poly-lactic acid (PLA) scaffolds are widely used in bone tissue engineering. The introduction of 3D printing has greatly increased the ability for tailoring different geometrical designs of these scaffolds for improved cellular attachment, growth and differentiation. This study aimed to investigate the effect of PLA fibre angle in 3D printed PLA scaffolds on hDPSC attachment and growth in vitro. Two types of PLA scaffolds were prepared via 3D printing containing fibres angled at either 45° or 90°. hDPSCs (P4, 2*10. 5. cells per scaffold) were statically seeded for 4 hours on to the scaffolds (7×3.5×3 mm. 3. , n=3). Cellular attachment was checked using fluorescence microscopy and the number of unattached cells was counted using a haemocytometer (HCM). The cell-scaffold constructs were then cultured in osteogenic medium for up to 5 weeks. ALP staining and SEM were performed for one construct from each group at week 3. Cellular viability was determined using CMFDA/EHD1 live/dead labelling at week 4. After 5 weeks, constructs were processed for histology. Fluorescence micrographs showed high numbers of hDPSCs attached to scaffold surfaces in both groups after seeding irrespective of fibre angle. However, HCM cell count revealed that the 45° angled PLA scaffolds had significantly greater cell attachment compared to the 90° angled PLA group (p<0.0001). After 3 weeks in osteogenic culture, both types of construct showed strong ALP staining. SEM showed that in the 45° angled PLA group, almost all macro-pores were fully closed with newly formed cell sheets. In comparison, in the 90° angled group, most of the macro-pores remained open although a limited amount of cellular bridging was present. SEM also detected crystal deposits in different areas within the cell sheets for both construct groups. Most hDPSCs were alive in both groups at week 4 of culture with few dead cells present. After 5 weeks, histology showed marked cellular growth and new matrix formation, with detectable Van Kossa +ve crystal deposits in different areas within all constructs irrespective of PLA fibre angle. This study showed that 45° angled PLA 3D printed scaffolds enhanced hDPSC attachment and cellular bridging, which may help to rapidly close the macro-pores within the scaffold compared to the 90° angled group. This illustrates the potential of 45° angled 3D printed PLA scaffolds as good candidates for bone tissue engineering