Rotator cuff tears are common, with failure rates of up to 94% for large and massive tears¹. For such tears, reattachment of the musculotendinous unit back to bone is problematic, and any possible tendon-bone repair heals through scar tissue rather than the specially adapted native enthesis. We aim to develop and characterise a novel soft-hard tissue connector device, specific to repairing/bridging the tendon-bone injury in significant rotator cuff tears, employing decellularised animal bone partially demineralised at one end for soft tissue continuation.

Optimisation samples of 15×10×5mm³, trialled as separate cancellous and cortical bone samples, were cut from porcine femoral condyles and shafts, respectively. Samples underwent 1-week progressive stepwise decellularisation and a partial demineralisation process of half wax embedding and acid bathing. Characterisations were performed histologically for the presence/absence of cellular staining in both peripheral and central tissue areas (n=3 for each cortical/cancellous, test/PBS control and peripheral/central group), and with BioDent reference point indentation (RPI) for pre- and post-processing mechanical properties.

Histology revealed absent cellular staining in peripheral and central cancellous samples, whilst reduced in cortical samples compared to controls. Cancellous samples decreased in wet mass after decellularisation by 45.3% (p<0.001). RPI measurements associated with toughness (total indentation depth, indentation depth increase) and elasticity (1st cycle unloading slope) showed no consistent changes after decellularisation. X-rays confirmed half wax embedding provided predictable control of the mineralised-demineralised interface position.

Initial optimisation trials show proof-of-concept of a soft-hard hybrid scaffold as an immune compatible xenograft for irreparable rotator cuff tears. Decellularisation did not appreciably affect mechanical properties, and further biological, structural and chemical characterisations are underway to assess validity before in vivo animal trials and potential clinical translation.

Sarcopenia is an age-related geriatric syndrome which is associated with subsequent disability and morbidity. Currently there is no promising therapy approved for the treatment of sarcopenia. The receptor activator of nuclear factor NF-κB ligand (RANKL) and its receptor (RANK) are expressed in bone and skeletal muscle. Activation of the NF-κB pathway mainly inhibits myogenic differentiation, which leads to skeletal muscle dysfunction and loss. LYVE1 and CD206 positive macrophage has been reported to be associated with progressive impairment of skeletal muscle function with aging. The study aims to investigate the effects of an anti-RANKL treatment on sarcopenic skeletal muscle and explore the related mechanisms on muscle inflammation and the polarization status of macrophages.

Sarcopenic senescence-accelerated mouse P8 (SAMP8) mice at month 8 were treated intraperitoneally with 5mg/kg anti-RANKL (IK22/5) or isotype control (2A3; Bio X Cell) antibody every 4 weeks and harvested at month 10. Senescence accelerated mouse resistant-1 (SAMR1) were collected at month 10 as the age-matched non-sarcopenic group. Ex-vivo functional assessment, grip strength and immunostaining of C/EBPa, CD206, F4/80, LYVE1 and PAX7 were performed. Data analysis was done with one-way ANOVA, and the significant level was set at p≤0.05.

At month 10, tetanic force/specific tetanic force, twitch force/specific twitch force in anti-RANKL group were significantly higher than control group (all p<0.01). The mice in the anti-RANKL treatment group also showed significantly higher grip strength than Con group (p<0.001). The SAMP8 mice at month 10 expressed significantly more C/EBPa, CD206 and LYVE1 positive area than in SAMR1, while anti-RANKL treatment significantly decreased C/EBPa, CD206 and LYVE1 positive area.

The anti-RANKL treatment protected against skeletal muscle dysfunctions through suppressing muscle inflammation and modulating M2 macrophages, which may represent a novel therapeutic approach for sarcopenia.

Acknowledgment: Collaborative Research Fund (CRF, Ref: C4032-21GF)

Abstract

Intraosseous Transcutaneous Amputation Prosthesis (ITAP) is a new generation of limb replacements that can provide to amputees, an alternative solution to the main problems caused by the most common used external prosthesis such as pressure sores, infections and unnatural gait. ITAP is designed as one pylon osteointegrated into the bone and protruding through the skin, allowing both the mechanical forces to be directly transferred to the skeleton and the external skin being free from frictions and infections. The skin attachment to the implant is fundamental for the success of the ITAP, as it prevents the implant to move and consequently fail.

In this study we wanted to test if cell viability and attachment was improved using TiO2 nanotubes.

Human keratinocytes and human dermal fibroblasts were seeded for three days on TiO2 nanotubes with different sizes (18–30nm, 40–60nm and 60–110nm), compared with controls (smooth titanium) and tested for viability and attachment. A Mann-Whitney U test was used to compare groups where p values < 0.05 were considered significant. The results showed that the viability and cell attachment for keratinocytes were significantly higher after three days on controls comparing with all nanotubes (p=0.02), while attachment was higher on bigger nanotubes and controls. Cell viability for fibroblasts was significantly higher on nanotubes between 40 and 110nm comparing with smaller size and controls (p=0.03), while investigation of cell attachment is ongoing.

From these early results, we can say that TiO2 nanotubes can improve the soft tissue attachment on ITAP. Further in-vitro and ex-vivo experiments on cell attachment will be carried out.

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*10⁵ cells per scaffold) were statically seeded for 4 hours on to the scaffolds (7×3.5×3 mm³, 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.

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 mechanical stimulation as a result of bone-bone direct contact with less protection of cartilage in cartilage defect regions.

This study showed an association between cartilage defect and subchondral bone mineral density distribution. Cysts were observed in all osteoarthritic samples and they are located close to cartilage defects in the weight-bearing regions. Cartilage defect altered the loading pattern of the joints, this leading to the bone remodelling and resultant bone structural changes as compared to the normal bone tissues.

This work was financially supported by The ARUK Proof of Concept Award (grant no: 21160).

Summary Statement

OA knee with subchondral cyst formation presented differential microstructure and mechanical competence of trabecular bone. This finding sheds light on the pivot role of subchondral cyst in OA bone pathophysiology.