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Research

DESIGN AND DEVELOPMENT OF A 3D FLUIDIC BIOREACTOR PLATFORM FOR A COMBINED MECHANICAL/PERFUSING STIMULATION OF ARTICULAR SUBSTITUTES

European Orthopaedic Research Society (EORS) 24th Annual Meeting, 14–16 September 2016. Part 2.



Abstract

Due to its avascular nature, articular cartilage exhibits a very limited capacity to regenerate and to repair. Although much of the engineered cartilage grafts so far proposed have successfully shown to mimic the morphological and biochemical appearance of hyaline cartilage, they are generally mechanically inferior to the natural tissue1. In this study a new bioreactor device was realized to test innovative scaffolds under physiological stimulation (i.e. perfusion fluid flow and dynamic compression), with the aim to produce a more functional engineered tissue construct for articular applications.

The computer-controlled bioreactor system has been properly designed to simultaneously provide static or dynamic compression and/or continuous perfusion to 3D engineered constructs, reproducing the physiological loads to which the articular cartilage is subjected. The specifically designed bioreactor comprises a chamber where the grafts are accommodated, a porous piston connected to a linear stepper motor (Dings, Model 34-2080-4-300), which controls its movement to provide mechanical stimulation and a peristaltic pump (Watson-Marlow, Model 323S), connected by joints and pipes to the culture chamber to ensure a continuous media perfusion. As piston for compression, a sintered stainless steel filter (43% of porosity) was adopted to allow the perfusion of the culture media during physical stimulation. The culture chamber is composed by a hollow cylinder (30 mm × 40,5 mm) and a base realized as a single object. They are made in polycarbonate for its characteristics of transparency and infrangibility and linked to a Nylon cover through four brass tie rods unscrewable from above. The chamber has been designed to accommodate simultaneously different constructs of any size and shape and stimulate them with perfusion and/or dynamic compression. A finites elements program was used to mimic the effects of perfusion and compression regime on the scaffolds cultured within the bioreactor chamber.

The bioreactor was properly designed and developed. Particular attention has been paid to the implementation of a simple, compact and economical system. It was then tested by using different polymeric porous scaffolds (PVA, collagen, Gelatin grafts, both porous and not) cultured with mesenchymal cells up to two weeks. The system has been validated in terms of sterility, experimental reproducibility and ease to use. The structural stability of grafts over time has been observed; moreover cells adhesion, proliferation and matrix production under different chemical-physical stimuli conditions is under investigation.

We have realized a novel bioreactor system representing an artificial articular niche, where a dynamic compression combined with fluid perfusion allows to functionally and mechanically validate tissue substitutes, besides investigating the response of engineered cartilaginous tissues to physical stimuli mimicking the natural cartilage micro-environment. Such bioreactor may be in fact adopted as a sort of articular simulator for promoting and standardizing the new tissue formation in vitro, preconditioning cell fate through the application of proper artificial stimuli. Moreover, they can be valid tools to investigate physiological processes and novel therapeutic approaches avoiding controversial animal models.