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Beilstein J. Nanotechnol. 2019, 10, 2152–2162, doi:10.3762/bjnano.10.208
Figure 1: Simple representation of the structure of SmartLipids. The mixture of structurally very different s...
Figure 2: Maximum loading reported for SLNs, NLCs and SmartLipids for the dermal active agents retinol [11-13] (left...
Figure 3: X-ray diffraction patterns of SLNs (pink curve) and SmartLipids mixture (red curve) determined dire...
Figure 4: Fast degradation of lipophilic active agents (R) in fluid carriers (blue), such as oil/water emulsi...
Figure 5: Storage study with retinol loaded SmartLipids particles over six months. Remaining retinol content ...
Figure 6: Left: Nile red-labeled lipid nanoparticle suspension (right arm) and nanoemulsion (left arm) applie...
Figure 7: Determination of the relative film thickness by measuring the dielectric constant D on skin. Probe ...
Figure 8: Penetration of curcumin into pig ear skin, vertical pig ear slices, fluorescence microscopy images ...
Figure 9: Models of cosmetic active agents or drugs (green) incorporated into lipid nanoparticles, from left ...
Figure 10: Examples of release profiles from lipid nanoparticles: very fast release of cyclosporine within min...
Figure 11: In vitro release of the sunscreen oxybenzone from a nanoemulsion (grey) and from a SLN suspension (...