Enriching a cellulose hydrogel with a biologically active marine exopolysaccharide for cell-based cartilage engineering.

The development of biologically and mechanically competent hydrogels is a prerequisite in cartilage engineering. We recently demonstrated that a marine exopolysaccharide, GY785, stimulates the in vitro chondrogenesis of adipose stromal cells. In the present study, we thus hypothesized that enriching our silated hydroxypropyl methylcellulose hydrogel (Si-HPMC) with GY785 might offer new prospects in the development of scaffolds for cartilage regeneration. The interaction properties of GY785 with growth factors was tested by surface plasmon resonance (SPR). The biocompatibility of Si-HPMC/GY785 towards rabbit articular chondrocytes (RACs) and its ability to maintain and recover a chondrocytic phenotype were then evaluated in vitro by MTS assay, cell counting and qRT-PCR. Finally, we evaluated the potential of Si-HPMC/GY785 associated with RACs to form cartilaginous tissue in vivo by transplantation into the subcutis of nude mice for 3 weeks. Our SPR data indicated that GY785 was able to physically interact with BMP-2 and TGFß. Our analyses also showed that three-dimensionally (3D)-cultured RACs into Si-HPMC/GY785 strongly expressed type II collagen (COL2) and aggrecan transcripts when compared to Si-HPMC alone. In addition, RACs also produced large amounts of extracellular matrix (ECM) containing glycosaminoglycans (GAG) and COL2. When dedifferentiated RACs were replaced in 3D in Si-HPMC/GY785, the expressions of COL2 and aggrecan transcripts were recovered and that of type I collagen decreased. Immunohistological analyses of Si-HPMC/GY785 constructs transplanted into nude mice revealed the production of a cartilage-like extracellular matrix (ECM) containing high amounts of GAG and COL2. These results indicate that GY785-enriched Si-HPMC appears to be a promising hydrogel for cartilage tissue engineering. Copyright © 2015 John Wiley & Sons, Ltd.

Influence of pegylation and hapten location at the surface of radiolabelled liposomes on tumour immunotargeting using bispecific antibody.

INTRODUCTION: This paper proposes liposomes as a potential new tool for radioimmunotherapy in solid tumours with a two step targeting system. Tumour pretargeting is obtained by using a monoclonal bispecific antibody (BsmAb, anti CEA x anti-DTPA-In) and pegylated liposomes containing lipid-hapten (DSPE-DTPA-In or DSPE-PEG-DTPA-In). To optimise at the same time in vivo behaviour and specific targeting, the study focuses on the liposome formulation in order to determine more precisely the role of pegylation on both the blood half-life and the specific recognition with the BsmAb. METHODS: Different liposome formulations containing two PEG length (1000 and 2000) in varying amount (1.5-6 mol%) were prepared with DTPA directly coupled to DSPE or at the end of the PEG chain (DSPE-DTPA or DSPE-PEG-DTPA). Liposomes were immobilized on an L1 chip to measure by SPR (Surface Plasmon Resonance) the effect of pegylation on the BsmAb recognition of the DTPA-In hapten. Pharmacokinetic studies were performed in mice. Tumour targeting was studied in nude mice xenografted with human colorectal adenocarcinoma cells that express CEA, and doubly radiolabelled liposomes (with (111)In and (125)I) injected 24h after the BsmAb. RESULTS: The best in vitro apparent dissociation constant was obtained with liposomes bearing DTPA at the end of the PEG chain (KD=6.3 nM), which showed significant specific tumour uptake after BsmAb injection (8.6 ± 2.4% ID/g at 24h versus 4.5 ± 0.5%ID/g for passive targeting, α=0.01). All tumour/organ ratios were superior to 1 at 24h for this formulation, except for the spleen. CONCLUSION: The feasibility of specific tumour targeting in mice with a BsmAb and radiolabelled liposomes was demonstrated and the interest of SPR to predict their targeting performance in vivo was highlighted. This original and new approach provides promising prospects for the radioimmunotherapy of solid tumours.

Effects of a sulfated exopolysaccharide produced by Altermonas infernus on bone biology.

The growth and differentiation of bone cells is controlled by various factors, which can be modulated by heparan sulfates. Here, we investigated the effects of an oversulfated exopolysaccharide (OS-EPS) on the bone. We compared the effect of this compound with that of a native EPS. Long-term administration of OS-EPS causes cancellous bone loss in mice due, in part, to an increase in the number of osteoclasts lining the trabecular bone surface. No significant difference in cancellous bone volume was found between EPS-treated mice and age-matched control mice, underlying the importance of sulfation in trabecular bone loss. However, the mechanism sustaining this osteoporosis was unclear. To clarify OS-EPS activities, we investigated the effect of OS-EPS on osteogenesis. Our results demonstrated that OS-EPS inhibited osteoclastogenesis in two cell models. Using the surface plasmon resonance technique, we revealed that OS-EPS can form a hetero-molecular complex OS-EPS/receptor activator of NF-κB ligand (RANKL)/RANK and that RANK had a higher affinity for RANKL pre-incubated with OS-EPS than for RANKL alone, which would be in favor of an increase in bone resorption. However, in vitro, OS-EPS inhibited the early steps of osteoclast precursor adhesion and therefore inhibited the cell fusion step. In addition, we showed that OS-EPS reduced proliferation and accelerated osteoblastic differentiation, leading to strong inhibition of mineralized nodule formation, which would be in favor of an increase in bone resorption. Taken together, these data show different levels of bone resorption regulation by EPSs, most of them leading to proresorptive effects.