Elucidating raw material variability--importance of surface properties and functionality in pharmaceutical powders

The purpose of this study is to illustrate, with a controlled example, the influence of raw material variability on the excipient's functionality during processing. Soluble starch was used as model raw material to investigate the effect of variability on its compaction properties. Soluble starch used in pharmaceutical applications has undergone a purification procedure including washing steps. In this study, a lot of commercially available starch was divided into two parts. One was left intact and the other was subjected to an extra washing step. The two resulting lots were subjected to a series of physical characterization tests typical of those used to qualify raw materials. The two resulting lots gave virtually identical results from the tests. From the physical testing point of view, the two lots can be considered as two equivalent lots of the same excipient. However, when tested for their functionality when subjected to a compaction process, the two lots were found to be completely different. The compaction properties of the two lots were distinctly different under all environmental and processing conditions tested. From the functionality point of view, the two lots are two very different materials. The similar physical testing results but different functionality can be reconciled by considering the surface properties of the powders. It was found that the washing step significantly altered the surface energetic properties of the excipient. The washed lot consistently produced stronger compacts. These results are attributable to the measurably higher surface energy of induced by the additional washing step.

Gene delivery to dendritic cells facilitated by a tumor necrosis factor alpha-competing peptide

Efficient gene delivery systems tailor-designed for dendritic cells (DCs) would allow the possibility of therapeutic manipulation of a wide spectrum of immune functions. Toward achieving this goal, we have identified a novel heptameric peptide (YTYQGKL) that functions as a localization moiety to mediate gene transfer in murine DCs. The sequence was identified by screening a phage display library against a DC cell line (JAWSII) using mouse TNFalpha as the eluting ligand. Alignment analysis reveals YTYQGKL resembles a solvent accessible region in mouse and human TNFalpha structures. A cyclized synthetic peptide bearing the sequence CYTYQGKLC binds to DCs in a concentration-dependent manner. Appending the cyclic peptide to a DNA binding domain (16 consecutive lysine residues) enhances transfection of reporter gene-encoding plasmids in JAWSII cells and in bone marrow derived primary DCs (BMDC). Further enhancement of gene transfer was observed when the peptide-DNA construct was anchored onto polymeric microspheres, with up to 25% of BMDC expressing the transgene. Exposing cells to the free peptide prior to transfection significantly diminished transgene expression. These results demonstrate that YTYQGKL can be used to facilitate gene transfer in DCs.