RESUMO
The aim of this study was to design and investigate solid lipid nanoparticles (SLN) providing an intestinal alkaline phosphatase (IAP) triggered charge reversion. SLN containing the monophosphate ester bearing surfactant P-PEG-9-lauryl ether and the cationic surfactant benzalkonium chloride were prepared via step-wise hot microemulsion method enabling P-PEG-9-lauryl ether to accumulate the phosphate moiety on the surface of the particles accessible for IAP. Charge reversal SLN were characterized in vitro and ex vivo. SLN containing 10% of P-PEG-9-lauryl ether and 1% of cationic surfactant displayed a z-average of 92 nm and a PDI of 0.33 remaining stable over one year stored at 2-8 °C. An enzyme induced charge reversion from -18.4 mV to +16.5 mV correlated with the cleavage of 82% of the incorporated phosphate. SLN maintained their size during charge reversion, as no significant difference in z-average was observed. Mucin interaction studies revealed a higher interaction between SLN and mucins in the presence of IAP causing an increase in z-average from 190 nm to 2500 nm as well as a decrease in zeta potential from -26 mV to -17 mV. No significant change in z-average and zeta potential was observed when IAP was absent indicating lower mucin interaction of negatively charged particles. In contrast, higher interaction with cell membrane was evidenced by 85% hemolysis when SLN were pretreated with IAP, whereas control SLN without IAP resulted in 16% hemolysis. To investigate the phosphate cleavage by membrane bound IAP, SLN were incubated on excised rat intestinal mucosa and a significant higher release of phosphate was observed in comparison to samples treated with an enzyme inhibitor. Charge reversal SLN might be promising drug delivery systems for alkaline phosphatase bearing membranes that are covered by a mucus gel layer such as the intestine.