The disaccharide trehalose is a well-established autophagy inducer, but its therapeutic application is severely hampered by its low potency and poor pharmacokinetic profile. Thus, we targeted the rational design and synthesis of trehalose-based small molecules and nano objects to overcome such issues. Among several rationally designed trehalose-centered putative autophagy inducers, we coupled trehalose via suitable spacers with known self-assembly inducer squalene to yield two nanolipid-trehalose conjugates. Squalene is known for its propensity, once linked to a bioactive compound, to assemble in aqueous media in controlled conditions, internalizing its payload and forming nanoassemblies with better pharmacokinetics. We assembled squalene conjugates to produce the corresponding nanoassemblies, characterized by a hydrodynamic diameter of 188 and 184 nm and a high stability in aqueous media as demonstrated by the measured Z-potential. Moreover, the nanoassemblies were characterized for their toxicity and capability to induce autophagy in vitro.
Squalene-Based Nano-Assemblies Improve the Pro-Autophagic Activity of Trehalose / Frapporti, Giulia; Colombo, Eleonora; Ahmed, Hazem; Assoni, Giulia; Polito, Laura; Randazzo, Pietro; Arosio, Daniela; Seneci, Pierfausto; Piccoli, Giovanni. - In: PHARMACEUTICS. - ISSN 1999-4923. - 14:4(2022). [10.3390/pharmaceutics14040862]
Squalene-Based Nano-Assemblies Improve the Pro-Autophagic Activity of Trehalose
Frapporti, Giulia;Assoni, Giulia;Seneci, Pierfausto;Piccoli, Giovanni
2022-01-01
Abstract
The disaccharide trehalose is a well-established autophagy inducer, but its therapeutic application is severely hampered by its low potency and poor pharmacokinetic profile. Thus, we targeted the rational design and synthesis of trehalose-based small molecules and nano objects to overcome such issues. Among several rationally designed trehalose-centered putative autophagy inducers, we coupled trehalose via suitable spacers with known self-assembly inducer squalene to yield two nanolipid-trehalose conjugates. Squalene is known for its propensity, once linked to a bioactive compound, to assemble in aqueous media in controlled conditions, internalizing its payload and forming nanoassemblies with better pharmacokinetics. We assembled squalene conjugates to produce the corresponding nanoassemblies, characterized by a hydrodynamic diameter of 188 and 184 nm and a high stability in aqueous media as demonstrated by the measured Z-potential. Moreover, the nanoassemblies were characterized for their toxicity and capability to induce autophagy in vitro.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione