Hot melt-extrusion improves the properties of cyclodextrin-based poly(pseudo)rotaxanes for transdermal formulation.

This study aimed to investigate whether hot-melt extrusion (HME) processing can modify the interactions between drugs, cyclodextrins and polymers, and in turn alter the microstructure and properties of supramolecular gels. Mixtures composed of amphiphilic polymer (Soluplus), cyclodextrin (HPßCD or αCD), plasticizer (PEG400 or PEG6000) and colloidal silicon dioxide were processed by HME. Carvedilol (CAR) was added to the formulation aiming its transdermal delivery. Extrudates were characterized by HPLC, XRPD, FTIR, DSC, and solid-state NMR. Gels prepared from extrudates (HME gels) or the corresponding physical mixtures (PM gels) in PBS were analyzed regarding components ordering (NMR, SEM), rheology, and CAR diffusion rate. HME led to the loss of the crystalline lattice of CAR and αCD, without causing any drug degradation. Solid NMR indicated that HME promoted the interaction of α-CD and HPßCD with the other components. HME gels had no coarsely disperse particles in their structure and behaved as weak gels (G' ~ G″). In contrast, PM gels contained drug crystals and showed elastic behavior (G' > G″). In general, HME gels were less viscous than PM ones and led to higher drug flux, especially those prepared using HPßCD. Moreover, the association of HPßCD and PEG6000 provided faster drug flux from supramolecular gels regardless the higher gel viscosity. The results evidenced that HME processing can decisively modify the arrangement of the components in the supramolecuar gels and, consequently, their properties, notably increasing drug release rate.

Cyclodextrin-based poly(pseudo)rotaxanes for transdermal delivery of carvedilol.

This work aimed to design supramolecular gels combining Soluplus or Solutol and alfa- and hydroxypropyl-ß-cyclodextrin (α-CD, HPß-CD) for carvedilol (CAR) transdermal delivery. Poly(pseudo)rotaxane formation (appearance, SEM, 1H NMR), drug solubilization, rheological properties and in vitro release were investigated. CAR-CD complexes were prepared in situ or by spray drying. For Solutol, poly(pseudo)rotaxanes were formed immediately after mixing with α-CD and did not influence CAR solubility. Differently, Soluplus poly(pseudo)rotaxanes took 24-48 h to be formed and CAR solubility decreased compared to Soluplus micelles. Soluplus 20% + α-CD (5-10%) showed higher G' and G'' but also faster CAR release than Solutol poly(pseudo)rotaxanes, which is explained by the different location of PEG chains in the two amphiphilic polymers. Faster drug release was achieved incorporating HPß-CD or CAR-HPß-CD spray-dried complexes. The results evidenced the versatility of the formulations in terms of rheological behavior and drug release patterns, which can be adjusted for CAR transdermal delivery.