Neurotoxic properties of the anabolic androgenic steroids nandrolone and methandrostenolone in primary neuronal cultures.

Anabolic-androgenic steroid (AAS) abuse is associated with multiple neurobehavioral disturbances. The sites of action and the neurobiological sequels of AAS abuse are unclear at present. We investigated whether two different AASs, nandrolone and methandrostenolone, could affect neuronal survival in culture. The endogenous androgenic steroid testosterone was used for comparison. Both testosterone and nandrolone were neurotoxic at micromolar concentrations, and their effects were prevented by blockade of androgen receptors (ARs) with flutamide. Neuronal toxicity developed only over a 48-hr exposure to the steroids. The cell-impermeable analogues testosterone-BSA and nandrolone-BSA, which preferentially target membrane-associated ARs, were also neurotoxic in a time-dependent and flutamide-sensitive manner. Testosterone-BSA and nandrolone-BSA were more potent than their parent compounds, suggesting that membrane-associated ARs were the relevant sites for the neurotoxic actions of the steroids. Unlike testosterone and nandrolone, toxicity by methandrostenolone and methandrostenolone-BSA was insensitive to flutamide, but it was prevented by the glucocorticoid receptor (GR) antagonist RU-486. Methandrostenolone-BSA was more potent than the parent compound, suggesting that its toxicity relied on the preferential activation of putative membrane-associated GRs. Consistently with the evidence that membrane-associated GRs can mediate rapid effects, a brief challenge with methandrostenolone-BSA was able to promote neuronal toxicity. Activation of putative membrane steroid receptors by nontoxic (nanomolar) concentrations of either nandrolone-BSA or methandrostenolone-BSA became sufficient to increase neuronal susceptibility to the apoptotic stimulus provided by ß-amyloid (the main culprit of AD). We speculate that AAS abuse might facilitate the onset or progression of neurodegenerative diseases not usually linked to drug abuse.

Synthesis, characterization and in vitro evaluation of dimethyl-beta-cyclodextrin-4-biphenylylacetic acid conjugate.

Biphenylylacetic acid (BPAA) was linked to the free hydroxyl group of 2,6-di-O-methyl-beta-Cyclodextrin (DM-beta-CyD) through an ester linkage to obtain the site specific release of the drug to the colon. The conjugate at 1:1 mole ratio was separated from the reaction mixture by semipreparative reverse-phase HPLC and characterized by 1H-NMR, 13C-NMR, IR spectroscopy, mass spectrometry and elemental analysis. Chemico-physical characteristics, such as water solubility and dissolution rate, were evaluated comparatively to the BPAA-DM-beta-CyD inclusion complex. Hydrolysis rates were investigated in media simulating gastro-intestinal fluids and at pH 7.4 in the presence of porcine liver esterase. A rapid release of the drug was observed at acid pH value. In all cases a first order kinetic was observed, characterized by t1/2 value of 1.19, 19 and 4 h for chemical hydrolysis at pH 1.1, at pH 7.4 and enzymatic hydrolysis, respectively. In vitro permeation studies through caco-2 cells confirmed the ability of DM-beta-CyD to increase the absorption of included BPAA. A slow permeation was observed for the drug conjugate to DM-beta-CyD due to the slow release of BPAA.

Lipoamino acid prodrugs of paclitaxel: synthesis and cytotoxicity evaluation on human anaplastic thyroid carcinoma cells.

Lipophilic derivatives of the anticancer drug paclitaxel (PTX) were prepared by means of its conjugation to lipoamino acid (LAA) residues, with the aim of increasing drug accumulation in tumor cells. PTX was linked to the methyl esters of norleucine (C6) or 2-aminodecanoic acid (C10). A succinic acid group was used as a spacer to link the 2'-hydroxyl group of PTX and the LAA residue, respectively by means of an ester and an amide bond. The in vitro anticancer activity of the prodrugs was tested on a human thyroid anaplastic cancer cell line (ARO). The intracellular uptake kinetics of free PTX and its prodrugs was assessed by HPLC. PTX-LAA prodrugs showed a noticeable cytotoxic activity against ARO cells at shorter incubation time (12 h) and lower doses (0.01-0.1 microM) than PTX. Intracellular accumulation experiments indicated an improvement of drug concentration inside these cells, related to the block of the cellular expulsion by means of multi drug resistance efflux complex and improved physicochemical features that allowed the greater passive cellular membrane permeation. The enhanced activity of PTX-LAA prodrugs, in terms of potency and onset of the effect, as well as the interesting intracellular accumulation data suggest that these compounds can be further tested as possible alternatives to PTX for the treatment of resistant cancer cells.