The present work is an experimental study of the generation and the maturation of vortex rings, in order to characterize their structure and their global dynamics for small to moderate Reynolds numbers (between 5 and 500) in Newtonian and non-Newtonian fluids. The experimental set-up consists of a vertical cylindrical piston-tube system with the lower part immersed in a filled tank. Measurement campaigns have been carried out using dye visualization and Particle Image Velocimetry (PIV). A first part of the work is focussed on Newtonian fluid and allows the dynamics at low Reynolds numbers to be investigated qualitatively and quantitatively. This dynamics turns out to be more complex than the one classically observed at high Reynolds numbers, and is characterized by the production of a counter-rotating secondary vortex ring. The results obtained for shear thinning fluids show the influence of the power-law index on the development and the propagation of the ring. The computation of the shear rate field allows the results to be analyzed in terms of shear thinning and Newtonian regions. Finally a preliminary investigation for viscoplastic and viscoelastic fluids has been performed. In both cases, it is shown that one (for viscoplastic fluids) or several (for viscoelastic fluids) counter-rotating secondary vortex rings are generated, a phenomenon that can be associated with the intrinsic physical properties of the fluid. All these results provide several perspectives of study in the field of vortex rings dynamics in the weakly inertial regimes.