Evidence of oral translocation of anionic G6.5 dendrimers in mice.

Development of carrier systems to improve oral bioavailability and target drugs to specific sites continues to be an unmet need. The goal of this study was to evaluate the potential of anionic generation (G) 6.5 poly(amido amine) (PAMAM) dendrimers in oral drug delivery by assessing their in vivo oral translocation. G6.5-COOH dendrimers were characterized for their physiochemical characteristics and acute oral toxicity was assessed in CD-1 mice. The dendrimers were labeled with (125)I and their stability evaluated. Oral bioavailability was assessed in the same mouse model. Investigation of the radioactivity profile in plasma revealed presence of both large and small molecular weight compounds. Detailed area under the curve analysis suggests an effective 9.4% bioavailability of radiolabeled marker associated with G6.5-COOH. Results reported here suggest the potential of dendrimers in permeating gastrointestinal barriers in vivo.

Transcriptional responses of human aortic endothelial cells to nanoconstructs used in biomedical applications.

Understanding the potential toxicities of manufactured nanoconstructs used for drug delivery and biomedical applications may help improve their safety. We sought to determine if surface-modified silica nanoparticles and poly(amido amine) dendrimers elicit genotoxic responses on vascular endothelial cells. The nanoconstructs utilized in this study had a distinct geometry (spheres vs worms) and surface charge, which were used to evaluate the contributions of these parameters to any potential adverse effects of these materials. Time-dependent cytotoxicity was found for surfaced-functionalized but geometrically distinct silica materials, while amine-terminated dendrimers displayed time-independent cytotoxicity and carboxylated dendrimers were nontoxic in our assays. Transcriptomic evaluation of human aortic endothelial cell (HAEC) responses indicated time-dependent gene induction following silica exposure, consisting of cell cycle gene repression and pro-inflammatory gene induction. However, the dendrimers did not induce genomic toxicity, despite displaying general cytotoxicity.

Cationic PAMAM dendrimers disrupt key platelet functions.

Poly(amidoamine) (PAMAM) dendrimers have been proposed for a variety of biomedical applications and are increasingly studied as model nanomaterials for such use. The dendritic structure features both modular synthetic control of molecular size and shape and presentation of multiple equivalent terminal groups. These properties make PAMAM dendrimers highly functionalizable, versatile single-molecule nanoparticles with a high degree of consistency and low polydispersity. Recent nanotoxicological studies showed that intravenous administration of amine-terminated PAMAM dendrimers to mice was lethal, causing a disseminated intravascular coagulation-like condition. To elucidate the mechanisms underlying this coagulopathy, in vitro assessments of platelet functions in contact with PAMAM dendrimers were undertaken. This study demonstrates that cationic G7 PAMAM dendrimers activate platelets and dramatically alter their morphology. These changes to platelet morphology and activation state substantially altered platelet function, including increased aggregation and adherence to surfaces. Surprisingly, dendrimer exposure also attenuated platelet-dependent thrombin generation, indicating that not all platelet functions remained intact. These findings provide additional insight into PAMAM dendrimer effects on blood components and underscore the necessity for further research on the effects and mechanisms of PAMAM-specific and general nanoparticle toxicity in blood.

PAMAM-camptothecin conjugate inhibits proliferation and induces nuclear fragmentation in colorectal carcinoma cells.

PURPOSE: To synthesize and characterize a poly (amido amine) dendrimer-camptothecin (PAMAM-CPT) conjugate and evaluate its activity on human colorectal carcinoma cells (HCT-116). METHODS: The attachment of CPT to amine-terminated PAMAM was facilitated through a succinic acid-glycine linker. The conjugate was characterized for absence of small molecular weight impurities, size and drug content. Stability of the conjugate in PBS and growth media and its in vitro activity on HCT-116 were studied. Cell cycle arrest and nuclear fragmentation upon PAMAM-CPT treatment were investigated. RESULTS: The conjugate was stable under physiological pH (7.4) in PBS and in growth media (with 10% FBS) with minimal release of 4% and 6% drug, respectively, at 48 h. PAMAM-CPT inhibited proliferation of HCT-116 cells with an IC50 value of 1.6 ± 0.3 µM. The conjugate induced signs of cell cycle arrest with up to 68% of cells blocked in the G(2) phase. Confocal images of cells treated with PAMAM-CPT suggest nuclear fragmentation and formation of apoptotic bodies. CONCLUSIONS: Results show that the PAMAM-CPT conjugate was active against colorectal cancer cells in vitro, inhibiting their growth and inducing nuclear fragmentation. Coupled with the ability to target macromolecular therapeutics to tumors, this conjugate shows promise for cancer chemotherapy.

Nanoparticle toxicity assessment using an in vitro 3-D kidney organoid culture model.

Nanocarriers and nanoparticles remain an intense pharmaceutical and medical imaging technology interest. Their entry into clinical use is hampered by the lack of reliable in vitro models that accurately predict in vivo toxicity. This study evaluates a 3-D kidney organoid proximal tubule culture to assess in vitro toxicity of the hydroxylated generation-5 PAMAM dendrimer (G5-OH) compared to previously published preclinical in vivo rodent nephrotoxicity data. 3-D kidney proximal tubule cultures were created using isolated murine proximal tubule fractions suspended in a biomedical grade hyaluronic acid-based hydrogel. Toxicity in these cultures to neutral G5-OH dendrimer nanoparticles and gold nanoparticles in vitro was assessed using clinical biomarker generation. Neutral PAMAM nanoparticle dendrimers elicit in vivo-relevant kidney biomarkers and cell viability in a 3-D kidney organoid culture that closely reflect toxicity markers reported in vivo in rodent nephrotoxicity models exposed to this same nanoparticle.

Charge affects the oral toxicity of poly(amidoamine) dendrimers.

Poly(amidoamine) (PAMAM) dendrimers have been evaluated for the influence of surface functionality and size on the epithelial barrier of the gut with the goal of identifying safe carriers that can be used for oral drug delivery. Limited studies are conducted to date, however, to assess the toxicity of PAMAM dendrimers in vivo when administered by the oral route. The goal of this research was to conduct an oral acute toxicity study of PAMAM dendrimers as a function of size and charge in immune competent CD-1 mice. Maximum tolerated doses (MTD) of PAMAM dendrimers as a function of size and surface functionality were established and clinical signs of toxicity monitored. Results demonstrate that positively charged dendrimers caused more toxicity, whereas their anionic counterparts were tolerated at ten times higher doses. Severe signs of toxicity observed for large (G7) cationic amine- or hydroxyl-terminated dendrimers include hemobilia and spleenomegaly. The MTD for these dendrimers ranged from 30 mg/kg to 200 mg/kg. Anionic G6.5 or smaller molecular weight carboxyl-, amine-, or hydroxyl-terminated dendrimers (G3.5-COOH, G4-NH2, G4-OH) on the other hand were tolerated at doses of up to 500 mg/kg (300 mg/kg in some cases) with minimal or no signs of toxicity. Establishing the MTD of orally delivered PAMAM dendrimers and the influence of surface functionality and size on toxicity aids in the rational design of PAMAM-drug conjugates for oral drug delivery applications.

In vivo methods of nanotoxicology.

The new field of nanotoxicology is steadily emerging in parallel with rapid advances made in nanotechnology to evaluate biological impact of intended and non-intended nanomaterial exposure over time as their human applications constantly increase. Over the last decade nanotoxicology methods have mostly relied on in vitro cell-based characterizations that do not account for the complexity of in vivo systems with respect to biodistribution, metabolism, hematology, immunology, and neurological ramifications. Comprehensive in vivo studies addressing the toxicity of nanoscale materials are scarce mainly because the field is still nascent. Efforts in standardizing methodology to study the in vivo safety of these materials are currently undertaken by various government agencies and research organizations. Here, we discuss the need for in vivo nanotoxicity studies, outline some of the important methods, and comment on practical considerations in carrying out such studies.

Size and surface charge significantly influence the toxicity of silica and dendritic nanoparticles.

The influence of size, surface charge and surface functionality of poly(amido amine) dendrimers and silica nanoparticles (SNPs) on their toxicity was studied in immunocompetent mice. After systematic characterization of nanoparticles, they were administered to CD-1 (caesarean derived-1) mice to evaluate acute toxicity. A distinct trend in nanotoxicity based on surface charge and functional group was observed with dendrimers regardless of their size. Amine-terminated dendrimers were fatal at doses >10 mg/kg causing haematological complications such as disseminated intravascular coagulation-like manifestations whereas carboxyl- and hydroxyl-terminated dendrimers of similar sizes were tolerated at 50-fold higher doses. In contrast, larger SNPs were less tolerated than smaller SNPs irrespective of their surface functionality. These findings have important implications in the use of these nanoparticles for various biomedical applications.

Cationic PAMAM dendrimers aggressively initiate blood clot formation.

Poly(amidoamine) (PAMAM) dendrimers are increasingly studied as model nanoparticles for a variety of biomedical applications, notably in systemic administrations. However, with respect to blood-contacting applications, amine-terminated dendrimers have recently been shown to activate platelets and cause a fatal, disseminated intravascular coagulation (DIC)-like condition in mice and rats. We here demonstrate that, upon addition to blood, cationic G7 PAMAM dendrimers induce fibrinogen aggregation, which may contribute to the in vivo DIC-like phenomenon. We demonstrate that amine-terminated dendrimers act directly on fibrinogen in a thrombin-independent manner to generate dense, high-molecular-weight fibrinogen aggregates with minimal fibrin fibril formation. In addition, we hypothesize this clot-like behavior is likely mediated by electrostatic interactions between the densely charged cationic dendrimer surface and negatively charged fibrinogen domains. Interestingly, cationic dendrimers also induced aggregation of albumin, suggesting that many negatively charged blood proteins may be affected by cationic dendrimers. To investigate this further, zebrafish embryos were employed to more specifically determine the speed of this phenomenon and the pathway- and dose-dependency of the resulting vascular occlusion phenotype. These novel findings show that G7 PAMAM dendrimers significantly and adversely impact many blood components to produce rapid coagulation and strongly suggest that these effects are independent of classic coagulation mechanisms. These results also strongly suggest the need to fully characterize amine-terminated PAMAM dendrimers in regard to their adverse effects on both coagulation and platelets, which may contribute to blood toxicity.