Azobenzene derivatives with activity against drug-resistant Candida albicans and Candida auris.

Increasing resistance against antimycotic drugs challenges anti-infective therapies today and contributes to the mortality of infections by drug-resistant Candida species and strains. Therefore, novel antifungal agents are needed. A promising approach in developing new drugs is using naturally occurring molecules as lead structures. In this work, 4,4'-dihydroxyazobenzene, a compound structurally related to antifungal stilbene derivatives and present in Agaricus xanthodermus (yellow stainer), served as a starting point for the synthesis of five azobenzene derivatives. These compounds prevented the growth of both fluconazole-susceptible and fluconazole-resistant Candida albicans and Candida auris strains. Further in vivo studies are required to confirm the potential therapeutic value of these compounds.

Controlling Supramolecular Structures of Drugs by Light.

Controlling physicochemical properties of light-unresponsive drugs, by light, prima facie, a paradox approach. We expanded light control by ion pairing light-unresponsive salicylate or ibuprofen to photoswitchable azobenzene counterions, thereby reversibly controlling supramolecular structures, hence the drugs' physicochemical and kinetic properties. The resulting ion pairs photoliquefied into room-temperature ionic liquids under ultraviolet light. Aqueous solutions showed trans-cis-dependent supramolecular structures under a light with wormlike aggregates decomposing into small micelles and vice versa. Light control allowed for permeation through membranes of cis-ibuprofen ion pairs within 12 h in contrast to the trans ion pairs requiring 72 h. In conclusion, azobenzene ion-pairing expands light control of physicochemical and kinetic properties to otherwise light-unresponsive drugs.

Antibacterial Anacardic Acid Derivatives.

We report on the antibacterial activity of five phenolic lipids derived from anacardic acid characterized by increasing alkyl chain lengths with 6, 8, 10, 12, or 14 carbon atoms. The compounds were profiled for their physicochemical properties, transport across epithelial monolayers, cytotoxicity, and antibacterial activity as compared to common antibiotics. No cytotoxicity was reported in cell lines of fibroblast, hepatic, colorectal, or renal origin. C10 and C12 significantly increased the survival in a Galleria mellonella model infected with multi-drug-resistant Staphylococcus aureus (MRSA) or vancomycin-resistant Enterococci (VRE) as compared to the untreated control group. Future studies are required to corroborate these findings in relevant animal model systems of infection.

Investigations into neuroprotectivity, stability, and water solubility of 7-O-cinnamoylsilibinin, its hemisuccinate and dehydro derivatives.

Derivatives of the recently described potent neuroprotective 7-O-cinnamoylsilibinin ester were prepared: its hemisuccinate to improve water solubility and the dehydrosilibinin ester that was shown to form in assay media to investigate its role in overall neuroprotective effects. 7-O-Cinnamoyl-2,3-dehydrosilibinin is less neuroprotective than 7-O-cinnamoylsilibinin in a murine hippocampal cell line (HT-22) and we conclude that the dehydrosilibinin derivatives are not the actual carriers of neuroprotective properties, at least in the assay applied. Solubility of the test compounds was determined in shake-flask experiments and the ester's solubility was greatly improved by introduction of a hemisuccinate at the 23-position of silibinin. Time-stability curves in assay media were recorded. The hemisuccinate ester did not act as a prodrug to release 7-O-cinnamoylsilibinin but is the second ester bond to be cleaved. Nevertheless, it still exhibits significant neuroprotection. Therefore, its greatly increased solubility might effectively counterbalance lower in vitro neuroprotection.

Geometrical and Structural Dynamics of Imatinib within Biorelevant Colloids.

Solubilization of lipophilic drugs is essential for efficient uptake. We detail the solubilization of imatinib in simulated gastrointestinal fluids containing taurocholate (TC) and lecithin (L) and reflecting fasted versus fed states using NMR spectroscopy, X-ray diffractometry, transmission electron microscopy, and dynamic light scattering analysis. Imatinib concentration impacted colloidal geometries and molecular dynamics in a fasted state. At drug substance concentrations up to 250 µM, imatinib was mainly engulfed within the core of >110 nm in diameter vesicles. At higher drug concentrations, the colloids collapsed to <40 nm, and imatinib migrated into the shell of the micelles, mainly being associated with the lipophilic face of TC but not with L. Simulating the fed state resulted in the formation of small micelles independent of the drug concentration. Furthermore, a hydrogel was formed, effectively keeping the drug substance in an amorphous state even when stressed by drying. In conclusion, this study detailed the fascinating dynamics of colloidal structures and molecular assembly as a function of imatinib concentration in biorelevant conditions. This approach may provide a blueprint for the rational development of future pharmaceutical formulations, taking the molecular interactions with bile salts/phospholipids into account.

Bioinspired co-crystals of Imatinib providing enhanced kinetic solubility.

Realizing the full potential of co-crystals enhanced kinetic solubility demands a comprehensive understanding of the mechanisms of dissolution, phase conversion, nucleation and crystal growth, and of the complex interplay between the active pharmaceutical ingredient (API), the coformer and co-existing forms in aqueous media. One blueprint provided by nature to keep poorly water-soluble bases in solution is the complexation with phenolic acids. Consequently, we followed a bioinspired strategy for the engineering of co-crystals of a poorly water-soluble molecule - Imatinib - with a phenolic acid, syringic acid (SYA). The dynamics of dissolution and solution-mediated phase transformations were monitored by Nuclear Magnetic Resonance (NMR) spectroscopy, providing mechanistic insights into the 60 fold-increased long lasting concentrations achieved by the syringate co-crystals as compared to Imatinib base and Imatinib mesylate. This lasting effect was linked to SYA's ability to delay the formation and nucleation of Imatinib hydrate - the thermodynamically stable form in aqueous media - through a metastable association of SYA with Imatinib in solution. Results from permeability studies evidenced that SYA did not impact Imatinib's permeability across membranes while suggesting improved bioavailability through higher kinetic solubility at the biological barriers. These results reflect that some degree of hydrophobicity of the coformer might be key to extend the kinetic solubility of co-crystals with hydrophobic APIs. Understanding how kinetic supersaturation can be shaped by the selection of an interactive coformer may help achieving the needed performance of new forms of poorly water-soluble, slowly dissolving APIs.

Mapping the pharmaceutical design space by amorphous ionic liquid strategies.

Poor water solubility of drugs fuels complex formulations and jeopardizes patient access to medication. Simplifying these complexities we systematically synthesized a library of 36 sterically demanding counterions and mapped the pharmaceutical design space for amorphous ionic liquid strategies for Selurampanel, a poorly water soluble drug used against migraine. Patients would benefit from a rapid uptake after oral administration to alleviate migraine symptoms. Therefore, we probed the ionic liquids for the flux, supersaturation period and hygroscopicity leading to algorithms linking molecular counterion descriptors to predicted pharmaceutical outcome. By that, 30- or 800-fold improvements of the supersaturation period and fluxes were achieved as were immediate to sustained release profiles through structural counterions' optimization compared to the crystalline free acid of Selurampanel. Guided by ionic liquid structure, in vivo profiles ranged from rapid bioavailability and high maximal plasma concentrations to sustained patterns. In conclusion, the study outlined and predicted the accessible pharmaceutical design space of amorphous ionic liquid based and excipient-free formulations pointing to the enormous pharmaceutical potential of ionic liquid designs.

Cytotoxic properties of the alkaloid rutaecarpine and its oligocyclic derivatives and chemical modifications to enhance water-solubility.

The alkaloid rutaecarpine and its derivatives have been described as cytotoxic and hold potential as antitumor agents. Nevertheless, their synthesis is demanding and compounds display poor water solubility. Herein, we describe the synthesis of two sets of rutaecarpine derivatives with amine functions to improve solubility. Using a classic shake-flask experiment and a potentiometric titration platform, the water solubility of the compounds was determined. Solubility improved significantly with the amine functions connected over the indole-N atom. Reduction of metabolic activity and cell viability on HeLa cells was in the same range or better for these derivatives compared to the chemically unaltered parent compounds prepared in a new synthetic procedure established in our group.