Optical　information　and　communication　technologies　are　essentially　based　on　the　ability　to　shape　the　light　field,　either　at　the　transmission　or　at　the　reception　of　the　optical　signal.　Nowadays,　wavelength　and　polarization　state　are　already　implemented　in　current　telecom　architectures　and　adding　the　spatial　structuring　of　the　light　field　as　a　novel　degree　of　freedom　to　enhance　data　rate　is　desirable.　In　this　context,　the　development　of　optical　devices　to　shape　optical　modes　belonging　to　orthogonal　basis　remains　challenging.　Here,　in　the　context　of　singular　optics,　this　work　reports　on　the　design,　fabrication,　and　characterization　of　modal　optical　vortex　beam　shaping　of　paraxial　light　in　the　visible　domain,　in　the　framework　of　the　Laguerre-Gauss　basis.　Both　the　azimuthal　and　radial　degrees　of　freedom　are　univocally　shaped　via　optical　spin-orbit　interaction　mediated　by　dielectric　metasurfaces　by　combining　the　spatial　modulation　of　amplitude,　geometric　phase,　and　dynamic　phase.　These　results　not　only　demonstrate　the　realization　of　new　optical　components,　but　also　highlight　how　metasurface-based　technologies　can　contribute　to　optical　information　processing　in　the　classical　or　quantum　regime.