Novel G-CSF conjugated anionic globular dendrimer: Preparation and biological activity assessment.

The most crucial role of granulocyte colony-stimulating factor (G-CSF) in the body is to increase the strength of immune system. In recent years, research on the use of nanoparticles in pharmaceuticals has been considered, most of which have been for drug-loading purposes. In this study, a novel G-CSF conjugated dendrimer was synthesized and characterized using different techniques. In vitro cytotoxicity was assessed on A549 and L929 cells, while abnormal toxicity was studied in mice. In vitro and in vivo biological activities were assessed in NFS60 cells and rats, respectively. In addition, in vivo distribution, plasma half-life, and histopathological effect were studied in rat. The characterization tests confirmed the successful conjugation. There was no difference between G-CSF cytotoxicity before and after conjugation, and no difference with the control group. No mice showed abnormal toxicity. Although in vitro biological activity revealed both conjugated and free G-CSF promote proliferation cells, biological activity decreased significantly after conjugation about one-third of the unconjugated form. Nonetheless, in vivo biological activity of conjugated G-CSF increased by more than 2.5-fold relative to the unconjugated form, totally. Fortunately, no histopathologic adverse effect was observed in vital rat tissues. Also, in vivo distribution of the conjugate was similar to the native protein with an enhanced terminal half-life. Our data revealed that G-CSF conjugated dendrimer could be considered as a candidate to improve the in vivo biological activity of G-CSF. Moreover, multivalent capability of the dendrimer may be used for other new potentials of G-CSF in future perspectives.

Ligand anchored poly(propyleneimine) dendrimers for brain targeting: Comparative in vitro and in vivo assessment.

The present investigation was aimed at developing various ligands-anchored dendrimers and comparing their brain targeting potential at one platform. Sialic acid (S), glucosamine (G) and concanavalin A (C) anchored poly(propyleneimine) (PPI) dendritic nanoconjugates were developed and evaluated for delivery of anti-cancer drug, paclitaxel (PTX) to the brain. MTT assay on U373MG human astrocytoma cells indicated IC50 values of 0.40, 0.65, 0.95, 2.00 and 3.50µM for PTX loaded SPPI, GPPI, CPPI, PPI formulations, and free PTX, respectively. The invivo pharmacokinetics and biodistribution studies in rats showed significantly higher accumulation of PTX in brain as compared to free PTX. The order of targeting potential of various ligands under investigation was found as sialic acid>glucosamine>concanavalin A. Thus, it can be concluded that sialic acid, glucosamine and Con A can be used as potential ligands to append PPI dendrimers for enhanced delivery of anticancer drugs to the brain for higher therapeutic outcome.

PAMAM dendrimer-baculovirus nanocomplex for microencapsulated adipose stem cell-gene therapy: in vitro and in vivo functional assessment.

The present study aims to develop a new stem cell based gene delivery system consisting of human adipose tissue derived stem cells (hASCs) genetically modified with self-assembled nanocomplex of recombinant baculovirus and PAMAM dendrimer (Bac-PAMAM) to overexpress the vascular endothelial growth factor (VEGF). Cells were enveloped into branched PEG surface functionalized polymeric microcapsules for efficient transplantation. In vitro analysis confirmed efficient transduction of hASCs expressing 7.65 ± 0.86 ng functionally active VEGF per 10(6) microencapsulated hASCs (ASC-VEGF). To determine the potential of the developed system, chronically infarcted rat hearts were treated with either empty microcapsules (MC), microencapsulated hASCs expressing MGFP reporter protein (MC+ASC-MGFP), or MC+ASC-VEGF, and analyzed for 10 weeks. Post-transplantation data confirmed higher myocardial VEGF expressions with significantly enhanced neovasculature in the MC+ASC-VEGF group. In addition, the cardiac performance, as measured by percentage ejection fraction, also improved significantly in the MC+ASC-VEGF group (48.6 ± 6.1%) compared to that in MC+ASC-MGFP (38.8 ± 5.3%) and MC groups (31.5 ± 3.3%). Collectively, these data demonstrate the feasibility of this system for improved stem cell therapy applications.

Biological assessment of triazine dendrimer: toxicological profiles, solution behavior, biodistribution, drug release and efficacy in a PEGylated, paclitaxel construct.

The physicochemical characteristics, in vitro properties, and in vivo toxicity and efficacy of a third generation triazine dendrimer bearing approximately nine 2 kDa polyethylene glycol chains and twelve ester linked paclitaxel groups are reported. The hydrodynamic diameter of the neutral construct varies slightly with aqueous solvent ranging from 15.6 to 19.4 nm. Mass spectrometry and light scattering suggest radically different molecular weights with the former approximately 40 kDa mass consistent with expectation, and the latter 400 kDa mass consistent with a decameric structure and the observed hydrodynamic radii. HPLC can be used to assess purity as well as paclitaxel release, which is insignificant in organic solvents or aqueous solutions at neutral and low pH. Paclitaxel release occurs in vitro in human, rat, and mouse plasma and is nonlinear, ranging from 7 to 20% cumulative release over a 48 h incubation period. The construct is 2-3 orders of magnitude less toxic than Taxol by weight in human hepatocarcinoma (Hep G2), porcine renal proximal tubule (LLC-PK1), and human colon carcinoma (LS174T) cells, but shows similar cytotoxicity to Abraxane in LS174T cells. Both Taxol and the construct appear to induce caspase 3-dependent apoptosis. The construct shows a low level of endotoxin, is not hemolytic and does not induce platelet aggregation in vitro, but does appear to reduce collagen-induced platelet aggregation in vitro. Furthermore, the dendrimer formulation slightly activates the complement system in vitro due most likely to the presence of trace amounts (<1%) of free paclitaxel. An animal study provided insight into the maximum tolerated dose (MTD) wherein 10, 25, 50, and 100 mg of paclitaxel/kg of construct or Abraxane were administered once per week for three consecutive weeks to non tumor bearing athymic nude mice. The construct showed in vivo toxicity comparable to that of Abraxane. Both formulations were found to be nontoxic at the administered doses, and the dendrimer had an acute MTD greater than the highest dose administered. In a prostate tumor model (PC-3-h-luc), efficacy was observed over 70 days with an arrest of tumor growth and lack of luciferase activity observed in the twice treated cohort.

Bootstrap method-based estimation of the minimum sample number for obtaining pharmacokinetic parameters in preclinical experiments.

Empirically, 3-6 samples at each sampling time point have been used for most preclinical one-point sampling experiments without any theoretical justification. The purpose of the present study is to propose a practical approach to determine the minimum sample number (N(min)) based on Monte Carlo simulation and a bootstrap resampling. A computer program MOMENT(BS), in which a bootstrap resampling algorithm is used to estimate mean and standard deviations of pharmacokinetic parameters, such as area under the curve and mean residence time, was applied to estimate N(min). A new simulation program, MONTE1, was developed to generate simulated data for bootstrap resampling using the model parameters including inter- and/or intra-individual variations. Then, an index, S(2)CV calculated as the sum of the squared coefficient of variation is proposed to determine the N(min). The proposed approach was applied to the actual data in preclinical experiments, and the usefulness of the approach was suggested. An issue that one-point sampling data cannot separately assess inter- and intra-individual variability is discussed.

Targeted dendrimer-based contrast agents for articular cartilage assessment by MR imaging.

OBJECTIVE: Magnetic resonance (MR) imaging with contrast media has shown promise for articular cartilage assessment. Dendrimer-linked nitroxides, a new family of MR contrast agents targeted to glycosaminoglycan, may improve cartilage evaluation. This study is designed to determine the ability of dendrimer-linked nitroxides to enhance articular cartilage and measure the intra-articular life-time of these agents. DESIGN: Cartilage T(1) was evaluated using immature bovine patella in solutions of five different dendrimer-linked nitroxides, saline or Gd-DTPA at 1.5T. The "relaxivity per dose" (change in cartilage 1/T(1) produced by a given concentration of agent) was calculated. The half-life of joint fluid enhancement was measured at 2T after solutions of three dendrimer-linked nitroxides, Gd-DTPA, and saline were injected into rabbit stifle joints. Twenty-four hours after injection, the joints were examined grossly and by histology for toxicity. RESULTS: All but the largest dendrimer-linked nitroxide were able to intensely enhance articular cartilage on MR. Relaxivity per dose measurements were between 3.5 and 68 times greater than Gd-DTPA. The largest nitroxide appeared to be excluded from articular cartilage. Intra-articular half-lives of the dendrimer-linked nitroxides were sufficiently long (160-208 min) for in vivo MR imaging to be performed. Histological assessments of joints showed minimal synovial inflammatory and necrosis scores 1 day post-injection that were similar for all agents, including Gd-DTPA. CONCLUSION: Dendrimer-linked nitroxides strongly enhance cartilage and are promising as articular cartilage-specific MR contrast agents. The intra-articular life-time is sufficient for imaging studies and, in initial evaluation, the agents exhibit minimal toxicity in rabbit joints.