Journal of pharmaceutical sciences
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Aerosolized medicine is one of the fastest growing areas in the pharmaceutical industry. Dry powder aerosols of pharmaceutical compounds are particularly attractive for the prevention and treatment of respiratory diseases but are also emerging as a treatment option for systemic diseases. Engineering particles in dry powder formulations can overcome many of the limitations of traditional inhaled pharmaceuticals. ⋯ Parameters such as milling time and drug concentration were investigated, and the aerosol performance of dried budesonide NanoClusters was characterized. The wet milling process was able to produce aerosol particles composed entirely of budesonide. High emitted fraction and a large fine particle fraction suggested that the NanoCluster budesonide formulation would offer highly efficient delivery of drug throughout the lung.
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The physical and chemical stability of dry powder aerosol formulations is an essential component in the development of an inhaled therapeutic. The pharmaceutical processing methods and storage conditions are primary determinants of the stability of a dry powder inhaler (DPI) formulation. Wet milling was used to produce budesonide NanoClusters (NCs), which are agglomerates of drug nanoparticles (≈ 300 nm) with a mean aerodynamic diameter between 1 and 3 µm, capable of deep lung penetration. ⋯ The physical stability of a selected budesonide NC formulation was investigated using industry standard dose content uniformity and cascade impaction techniques. The chemical stability of the lead formulation was also determined as a function of processing parameters and storage conditions. This study confirms the reproducibility and robust stability of NC powders as a novel means to turn drug particles into high-performance aerosols.
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Previously, our laboratory reported that cyclic peptide prodrugs of the opioid peptide H-Tyr-D-Ala-Gly-Phe-D-Leu-OH (DADLE) are metabolized by cytochrome P450 (CYP450) enzymes, which limits their systemic exposure after oral dosing to animals. In an attempt to design more metabolically stable cyclic prodrugs of DADLE, we synthesized analogs of DADLE cyclized with a coumarinic acid linker (CA; CA-DADLE), which contained modifications in the amino acid residues known to be susceptible to CYP450 oxidation. Metabolic stability and metabolite identification studies of CA-DADLE and its analogs were then compared using rat liver microsomes (RLM), guinea pig liver microsomes (GPLM), and human liver microsomes (HLM), as well as recombinant human recombinant cytochrome P450 3A4 (hCYP3A4). ⋯ When CA-DADLE was incubated with hCYP3A4, similar oxidative metabolism of the peptide was observed. In contrast, incubation of the CA-DADLE analogs with hCYP3A4 showed that these amino-acid-modified analogs are not substrates for this CYP450 isozyme. These results suggest that the amino-acid-modified analogs of CA-DADLE prepared in this study could be stable to metabolic oxidation by CYP3A4 expressed in human intestinal mucosal cells.
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The biopharmaceutical and physicochemical properties of two new cyclic prodrugs (CA-[cychexalanine (Cha(4)), D-Leu(5) ]-Enkephalin (Enk) and coumarinic acid (CA)-[Cha(4), D-Ala(5)]-Enk) of opioid peptides that were designed to be stable to oxidative metabolism by cytochrome P-450 enzymes in the intestinal mucosa are described in this paper. Two-dimensional nuclear magnetic resonance studies and molecular dynamics simulations showed that these cyclic prodrugs exhibit unique solution conformations (i.e., type I β-turns), which are favorable for transcellular permeation. ⋯ Permeability studies using an in situ rat intestinal perfusion model confirmed the poor intestinal permeation characteristics of CA-[Cha(4), D-Leu(5) ]-Enk and CA-[Cha(4), D-Ala(5)]-Enk as well as the stability of these two new cyclic prodrugs of opioid peptides to oxidative metabolism. In conclusion, these data clearly show that oral absorption of cyclic prodrugs of opioid peptides can only be achieved by designing molecules devoid of substrate activity for both cytochrome P-450 enzymes and efflux transporters in the intestinal mucosa.
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Biography Historical Article
Professor Valentino J. Stella: scientist, mentor, entrepreneur, family man, and giant in pharmaceutical chemistry.