Extensive annulus fibrosus (AF) radial tears lead to intervertebral disc (IVD) herniation. While unrepaired defects in the AF are associated with postoperative reherniation and high IVD degeneration prevalence, current surgical strategies are limited to symptomatic treatment of pain and disregard the structural integrity of the AF. For all these reasons, this study is focused on i) designing polycaprolactone (PCL) electrospun implants that mimic the multi-lamellar fibrous structure of the native tissue and ii) assessing their ability to properly close and repair an AF defect in a sheep in vivo model. Oriented PCL mats were produced by electrospinning with average fiber diameters of 1.3µm and a tensile modulus (55±1MPa) matching the one of a native human AF lamella (∼47MPa). In vitro experiments demonstrated a spontaneous colonization of PCL mats by human and ovine AF cells. In vivo study was carried out on 6 sheep in which 5 lumbar discs were exposed using a left retroperitoneal approach. Defects (2×5mm, 2mm depth) were created in the outer annulus, with randomized distribution of conditions including 10-layer oriented or non-oriented mats, untreated and healthy groups. X-ray and MRI examinations were performed every month until explantations at 1, 3 and 6 months, followed by immuno-histological analysis. Data showed no dislocation of the implants, cell infiltration between the PCL mats and within the mats, and a continuous type I collagen tissue formation between the implants and the surrounding AF tissue. These results highlight that multi-layer PCL electrospun mat is a promising biomaterial for AF repair.

Osteoarthritis (OA) is a degenerative and inflammatory joint disease that affects the whole joint. Mesenchymal stem cells ability to secrete anti-inflammatory and immuno-modulatory factors represents an attractive tool in the treatment of OA. Considering the risk of cell leakage and the massive cell death upon intra-articular injection, we developed a micromolding protocol of encapsulation that allows to obtain particles that (i) could be injected with a 26G needle into a mouse joint and (ii) could provide a 3D microenvironment supporting cell biological activity. Polydimethylsiloxane (PDMS) chips containing circular micromolds were manufactured and a solution of alginate (2% w/v) containing human adipose stem cells (3 millions/mL) was deposited on the chips. Cell loading into the micromolds was performed either by sedimentation or by centrifugation. Following Ca2+ crosslinking, alginate particles (diameter 150±0.7μm) were obtained. The number of cells per particle was 5 times higher when the micromolds were loaded by centrifugation. Cell number and metabolic activity remained stable for 7 days after encapsulation and injection through a 26G needle had no impact on cell viability. When cells were stimulated with TNF-alpha and INF-gamma, prostaglandin E2 (PGE2) concentration in the supernatant was multiplied by 13 and 7 and indoleamine2,3-dioxygenase (IDO) activity was 2 and 4 times higher when cell loading was performed by sedimentation or centrifugation, respectively. We have demonstrated that encapsulated cells were able to sense and respond to an inflammatory stimulus and their therapeutic potential will be evaluated in a murine model of osteoarthritis.