The uptake mechanism of PEGylated DNA polyplexes by the liver influences gene expression.

Two uptake mechanisms were identified for PEGylated DNA polyplex biodistribution to the liver. At a low polyplex dose, a rapid-uptake mechanism dominates, resulting in 60% capture by liver in 5 min, due to a saturable receptor-mediated process. Rapid-uptake led to the fast metabolism of polyplexes by liver (t1/2 = 2.1 h), correlating with a 1-µg pGL3 polyplex dose losing full transfection competency after 4 h in the liver. Dose escalation of either polyplex or poly(ethylene glycol) (PEG) peptide led to the saturation of rapid-uptake and revealed a delayed-uptake mechanism for polyplexes by liver. Delayed-uptake was characterized by the slower liver accumulation of 40% of the polyplex dose over 40 min, followed by slow metabolism (t1/2 = 15 h) and an extended time (12 h) for a 1-µg pGL3 polyplex dose, remaining fully transfection competent in the liver. The delayed-uptake mechanism is consistent with polyplexes crossing liver fenestrated endothelial cells to reach steady state in the space of Disse. The results describe how to control polyplex biodistribution to liver to avoid rapid-uptake and metabolism, in favor of delayed-uptake, to preserve polyplex transfection competency in the liver for up to 12 h.

High-affinity PEGylated polyacridine peptide polyplexes mediate potent in vivo gene expression.

Polyethylene glycol (PEG)ylated polyacridine peptides bind to plasmid DNA with high affinity to form unique polyplexes that possess a long circulatory half-life and are hydrodynamically (HD)-stimulated to produce efficient gene expression in the liver of mice. We previously demonstrated that acridine-modified lysine (Acr) in (Acr-Lys)(6)-Cys-PEG(5kDa) stabilizes a 1-µg pGL3 dose for up to 1 h in the circulation, resulting in HD-stimulated (saline only) gene expression in the liver, equivalent in magnitude to direct-HD dosing of 1 µg of pGL3. In this study, we report that increasing the spacing of Acr with either four or five Lys residues markedly increases the stability of PEGylated polyacridine peptide polyplexes in the circulation allowing maximal HD-stimulated expression for up to 5 h post DNA administration. Co-administration of a decoy dose of 9 µg of non-expressing DNA polyplex with 1 µg of pGL3 polyplex further extended the HD-stimulated expression to 9 h. This structure-activity relationship study defines the PEGylated polyacridine peptide requirements for maintaining fully transfection competent plasmid DNA in the circulation for 5 h and provides an understanding as to why polyplexes or lipoplexes prepared with polyethylenimine, chitosan or Lipofectamine are inactive within 5 min following intravenous dosing.

Metabolically stabilized long-circulating PEGylated polyacridine peptide polyplexes mediate hydrodynamically stimulated gene expression in liver.

A novel class of PEGylated polyacridine peptides was developed that mediate potent stimulated gene transfer in the liver of mice. Polyacridine peptides, (Acr-X)(n)-Cys-polyethylene glycol (PEG), possessing 2-6 repeats of Lys-acridine (Acr) spaced by either Lys, Arg, Leu or Glu, were Cys derivatized with PEG (PEG(5000 kDa)) and evaluated as in vivo gene transfer agents. An optimal peptide of (Acr-Lys)(6)-Cys-PEG was able to bind to plasmid DNA (pGL3) with high affinity by polyintercalation, stabilize DNA from metabolism by DNAse and extend the pharmacokinetic half-life of DNA in the circulation for up to 2 h. A tail vein dose of PEGylated polyacridine peptide pGL3 polyplexes (1 µg in 50 µl), followed by a stimulatory hydrodynamic dose of normal saline at times ranging from 5 to 60 min post-DNA administration, led to a high level of luciferase expression in the liver, equivalent to levels mediated by direct hydrodynamic dosing of 1 µg of pGL3. The results establish the unique properties of PEGylated polyacridine peptides as a new and promising class of gene delivery peptides that facilitate reversible binding to plasmid DNA, protecting it from DNase in vivo resulting in an extended circulatory half-life, and release of transfection-competent DNA into the liver to mediate a high-level of gene expression upon hydrodynamic boost.

Disposition kinetics of sparfloxacin in healthy, hepatopathic, and nephropathic conditions in chicken after single intravenous administration.

OBJECTIVE: To study the variation of disposition kinetic values of sparfloxacin in healthy, hepatopathic, and nephropathic chickens after a single intravenous administration. MATERIALS AND METHODS: Hepatotoxicity was induced by the administration of paracetamol (500 mg / kg / day, p.o. for seven days) and nephrotoxicity by uranyl nitrate (2.0 mg / kg / day dissolved in distilled water, i.v. for four days) in chickens. Disposition kinetic studies of sparfloxacin were investigated in healthy as well as hepatopathic and nephropathic birds after a single intravenous administration at 40 mg / kg body weight. RESULTS: Maximum plasma concentration detected at 0.16 hour was 31.25 +/- 2.95, 61.95 +/-1.85, and 99.86 +/- 2.21 mug / ml in healthy, hepatopathic, and nephropathic group, respectively. The drug could not be detected in the plasma of healthy birds beyond 12-hour period, while the same was detectable for 72 hour in the plasma of hepatopathic and nephropathic birds. The concentration of sparfloxacin was significantly (P < 0.01) higher in all the samples of hepathopathic and nephropathic birds compared to healthy birds. All the kinetic values were increased (P < 0.01) in the hepatopathic and nephropathic birds, except Vd(area) and Cl(B) values in hepatopathic Birds; while beta and Cl(B) values nephropathic birds were decreased significantly than that of healthy birds. CONCLUSIONS: The dose of sparfloxacin may be reduced in hepatopathic as well as nephropathic birds.