Investigation of a novel dendritic derivative of 5-aminolaevulinic acid for photodynamic therapy

Photodynamic therapy is a treatment for malignant and certain non-malignant lesions that involves administration of a photosensitising drug. The use of 5-aminolaevulinic acid-induced porphyrins has become one of the most active fields of photodynamic therapy research. Since the efficacy of the treatment is somewhat limited by the hydrophilic nature of 5-aminolaevulinic acid, chemical modifications such as esterification with aliphatic alcohols have been made to induce higher porphyrin production. In an attempt to improve delivery of 5-aminolaevulinic acid to tissue, we have investigated the use of dendritic derivatives capable of bearing several drug molecules. The aim of this work was to evaluate in vivo and in vitro the efficacy of the first generation dendron, aminomethane tris-methyl 5-aminolaevulinic acid (containing three 5-aminolaevulinic acid residues) in terms of porphyrin synthesis. In LM3 cells, the dendron induced similar porphyrin levels compared to equimolar concentrations of 5-aminolaevulinic acid. Although the dendron is taken up with comparable efficiency to 5-aminolaevulinic acid, we found that there is only partial intracellular liberation of 5-aminolaevulinic acid residues. Both systemic and topical administration of the dendron to tumour-bearing mice induced higher porphyrin levels than the widely investigated hexyl ester derivative in most tissues studied, although it was not possible to surpass the levels induced by 5-aminolaevulinic acid. In conclusion, aminomethane tris-methyl 5-aminolaevulinic acid is capable of being taken up by cells efficiently, and liberating the active residues, although in vivo it was not possible to improve upon the efficacy of 5-aminolevulinic acid. Studies of accessibility and regulation of the esterases are needed to improve the design of these dendritic derivatives.     

Design of dendritic macromolecules containing folate or methotrexate residues

Polyether dendritic compounds bearing folate residues on their surface were prepared as model drug carriers with potential tumor cell specificity. Starting from ester-terminated polyether dendrimers, hydrazide groups were easily introduced to the surface of the dendrimers by reaction with hydrazine. Folate residues were then conjugated to the hydrazide chain ends of the dendrimers by direct condensation with folic acid in the presence of a condensing agent or by reaction with an active ester derivative of folic acid. Essentially complete functionalization of the terminal hydrazide groups was achieved for both the first and the second generation dendrimers with four and eight hydrazide groups. For the G-2 dendrimer with 16 hydrazide groups, an average number of only 12.6 folate residues were attached to each dendrimer. The conjugates are soluble in aqueous medium above pH 7.4. In addition, a similar conjugation of the antitumor drug methotrexate to the dendrimer was also investigated. Once optimized, these molecules may form the basis for a novel family of multivalent drug carriers.     

Dendritic oligoguanidines as intracellular translocators

A series of polyguanidylated dendritic structures that can be used as molecular translocators have been designed and synthesized based on nonpeptide units. The dendritic oligoguanidines conjugated with fluorescein or with a green fluorescent protein (GFP) mutant as cargos were isolated and characterized. Quantification and time-course analyses of the cellular uptake of the conjugates using HeLa S3 and human cervical carcinoma cells reveal that the polyguanidylated dendrimers have comparable translocation efficiency to the Tat(49-57) peptide. Furthermore, the deconvolution microscopy image analysis shows that they are located inside the cells. These results clearly show that nonlinear, branched dendritic oligoguanidines are capable of translocation through the cell membrane. This work also demonstrates the potential of these nonpeptidic dendritic oligoguanidines as carriers for intracellular delivery of small molecule drugs, bioactive peptides, and proteins.     

PEGylated dendrimers with core functionality for biological applications

The synthesis of a variety of core functionalized PEGylated polyester dendrimers and their in vitro and in vivo properties are described in this report. These water-soluble dendrimers have been designed to carry eight functional groups on their dendritic core for a variety of biological applications such as drug delivery and in vivo imaging as well as eight solubilizing groups. Using a common symmetrical aliphatic ester dendritic core and trifunctional amino acid moieties, a library of dendrimers with phenols, alkyl alcohols, alkynes, ketones, and carboxylic acid functionalities has been synthesized without the need for column chromatography. The amines were PEGylated, leaving the other functionality of the amino acid available for further manipulation such as the attachment of drugs and/or labels. Radiolabeling experiments with the PEGylated dendrimers showed that they had a long circulation half-life in mice, confirming the potential of this class of dendrimers for therapeutic and/or diagnostic applications. A carboxylic acid functionalized dendrimer was elaborated to carry doxorubicin bound via a hydrazone bond. The drug-loaded carrier accumulated more in tumors and less in healthy organs than the clinically used PEGylated liposomal formulation Doxil. The efficient synthesis, high versatility, and favorable biological properties make these PEGylated polyester dendrimers promising structures for therapeutic and/or imaging applications.     

Folate and folate-PEG-PAMAM dendrimers: synthesis, characterization, and targeted anticancer drug delivery potential in tumor bearing mice

Ligand-mediated targeting of drugs especially in anticancer drug delivery is an effective approach. Dendrimers, due to unique surface topologies, can be a choice in this context. In the present study, PAMAM (polyamidoamine) dendrimers up to fourth generation were synthesized and characterized through infrared (IR), nuclear magnetic resonance (NMR), electrospray ionization (ESI) mass spectrometric, and transmission electron microscopic (TEM) techniques. Primary amines present on the dendritic surface were conjugated through folic acid and folic acid-PEG (poly(ethylene glycol))-NHS (N-hydroxysuccinimide) conjugates. Tumor in mice was induced through the use of KB cell culture. Prepared dendritic conjugates were evaluated for the anticancer drug delivery potential using 5-FU (5-fluorouracil) in tumor-bearing mice. Approximately 31% of 5-FU was loaded in folate-PEG-dendritic conjugates. Results indicated that folate-PEG-dendrimer conjugate was significantly safe and effective in tumor targeting compared to a non-PEGylated formulation. Tailoring of dendrimers via PEG-folic acid reduced hemolytic toxicity, which led to a sustained drug release pattern as well as highest accumulation in the tumor area.     

Targeting Cancer Cells with DNA-Assembled Dendrimers: A Mix-and-Match Strategy for Cancer

The unique biology of cancer requires the development of amultifunctional drug delivery system which can be efficientlymanufactured to target subtle molecular alterations that distinguishcancer cells from the many types of healthy cells found in the body. Wesought to produce dendrimers conjugated to different bio-functionalmoieties [fluorescein (FITC) and folic acid (FA)], then link themtogether using complementary DNA oligonucleotides to produce clusteredmolecules that target cancer cells that overexpress the high affinityfolate receptor. This study demonstrates a unique molecular platformbased on the DNA-directed assembly of dendritic polymers for thedelivery of different agents to cancer cells. While only nanometers indiameter (the size of proteins), this DNA-linked dendrimer nanoclusterplatform is considered to allows for the delivery of drugs, geneticmaterials, and imaging agents to cancer cells, offering the potentialfor developing combinatorial therapeutics.     

The effects of bromocriptine and prolactin on porphyrin biosynthesis in the Harderian gland of the male hamster,Mesocritecus auratus

Porphyrin biosynthesis was examined in the Harderian gland of the male golden hamster by fluorometric assays of gland porphyrin content and by measuring the activity of a rate-limiting enzyme for haem biosynthesis, 5-aminolaevulinic acid synthase. Both porphyrin content and enzyme activity are low in normal male glands but were greatly raised in males castrated for 6 weeks. However, porphyrin synthesis remained at basal levels in castrates given the dopamine agonist bromocriptine; this suppression could be reversed by simultaneous prolactin administration, and castrated males receiving prolactin alone exhibited very high enzyme activity and porphyrin content. Bromocriptine also prevents the morphological feminisation of the Harderian gland which would normally occur after castration; again, the simultaneous administration of prolactin permits feminisation to occur. The results support the hypothesis that, while androgens have an inhibitory effect on porphyrin synthesis within this model, other factors, including prolactin, are permissive.Abbreviations ALA 5-aminolaevulinic acid - ALA-s 5-aminolaevulinate synthase - GH growth hormone     

Synthesis and characterization of nanoscale dendritic RGD clusters for potential applications in tissue engineering and drug delivery

Spatial control over the distribution and the aggregation of arginine-glycine-aspartate (RGD) peptides at the nanoscale significantly affects cell responses. For example, nanoscale clustering of RGD peptides can induce integrins to cluster, thus triggering complete cell signaling. Dendrimers have a unique, highly branched, nearly spherical and symmetrical structure with low polydispersity, nanoscale size, and high functionality. Therefore, dendrimers are a class of ideal scaffold for construction of nanoscale dendritic RGD clusters in which RGD loading degree and cluster size can be finely adjusted. This new type of nanoscale dendritic RGD cluster will aid us to better understand the impact of spatial arrangement of RGD on cellular responses and to engineer RGD to trigger more favorable cellular responses. In this study, nanoscale dendritic RGD clusters were synthesized based on Starburst anionic G3.5 and cationic G4.0 polyamidoamine (PAMAM) dendrimers. The multiple terminal functional groups on the outermost layer of the dendrimer were coupled with RGD tripeptides. Biofunctionalized dendrimer structures were found to be highly dependent on the generation and the extent of peptide modification (ie, number of peptides per PAMAM dendrimer). Fluorescein isothiocyanate (FITC)-conjugated PAMAM dendrimers were utilized to monitor cellular internalization of dendrimers by adherent fibroblasts. Anionic G3.5-based dendritic RGD clusters have been shown to have no negative effect on fibroblast viability and a concentration-dependent effect on lowering cell adhesion on tissue culture polystyrene (TCPS) as that of free RGD. A similar concentration-dependent effect in cell viability and adhesion was also observed for cationic G4.0-based dendritic RGD clusters at lower but not at high concentrations. The results imply that the synthesized nanoscale dendritic RGD clusters have great potential for tissue engineering and drug delivery applications.     

Design of biocompatible chitosan microgels for targeted pH-mediated intracellular release of cancer therapeutics

We report the rational design of a chitosan-based drug delivery system. The chitosan derivative N-[(2-hydroxy-3-trimethylammonium)propyl]chitosan chloride (HTCC) was ionically cross-linked by sodium tripolyphosphate (TPP) to form sub-200-nm microgels that are responsive to pH changes. When these microgels were loaded with methotrexate disodium (MTX), a cytotoxic drug for cancer treatment, and conjugated to the targeting biomolecule apo-transferrin, a protein known to enter cells via receptor-mediated endocytosis, enhanced killing of immortalized HeLa cells was observed. In this intracellular delivery method, the microgel was exposed to low-pH environments that caused the chitosan to swell and release the drug. This rational drug delivery design may be useful in enhancing cancer therapy and reducing side effects.     

Cholesterol conjugated oligonucleotide and LNA: A comparison of cellular and nuclear uptake by Hep2 cells enhanced by Streptolysin-O

Antisense and antigene oligonucleotides (ONs) are attractive drugs for gene therapy, but major limiting factors for their routine use are inefficient cellular uptake and low accessibility to the target sites. Adding various lipophilic conjugates to the ON improves intracellular delivery as has been previously reported.We studied the cellular delivery of various ON modifications, as well as their cytosolic and nuclear distribution in mammalian Hep2-EGFP-NLS cell line. We compared uptake efficacy of ON and LNA, both conjugated with cholesterol at the 5′ end. All ONs were 3′ labeled with fluorescent Cy5 dye. We made a comparison of the ONs uptake efficacy and the kinetics, both adding ONs to the culture medium, and using streptolysin-O (SL-O) permeabilization.The cellular uptake of each ON used in this study was visualized by fluorescent microscopy. We confirmed the results by FACS analysis. We determined the ratio between initial ON-chol concentration (0.4 μM) and the final amount in nucleus.SL-O can highly improve kinetics of ON delivery; not only into the cytoplasm but also to the nucleus, the presumed site of antigene ON action. The most effective nuclear uptake was observed when ON conjugated with cholesterol (ON-chol) and SL-O was used. Nuclear distribution of ON was reached within few minutes. In contrast, ON simply added to the medium reached cytoplasm only and the process of delivery took several hours. (Mol Cell Biochem 276: 61–69, 2005)     

Synthesis and selective tumor targeting properties of water soluble porphyrin-Pt(II) conjugates

We have designed and synthesized a series of novel water soluble porphyrins and their platinum(II) conjugates, cis-[(Por)Pt(dmso)X], where Por=5-(4-pyridyl)-10,15,20-tris(4-sulfonatophenyl)porphyrin) (PyTPPS) or 5-[4-(3-aminopropyl)pyridiniumyl]-10,15,20-tris(4-sulphonatophenyl)porphyrin (PyTPPS-NPn), X=2Cl, 1,1-cyclobutanedicarboxylic acid, oxalate, or malonate. Their biodistribution in tumor bearing mouse was examined along with their antitumor activity against murine leukemia L1210 cell line. The representative complex 1 exhibited a significant accumulation in tumor tissue with a tumor/muscle ratio of 7 after 24 h post injection. The antitumor activity of the title compounds was marginal (T/C: 95-117%), but it was found that platinum(II) coordination to the porphyrin periphery did not affect the tumor accumulating properties of the porphyrin permitting further derivatization for efficient delivery of the Pt(II) antitumor agent.     

Dendrimer-based targeted delivery of an apoptotic sensor in cancer cells

Our previous studies have demonstrated the applicability of poly(amidoamine) (PAMAM) dendrimers as a platform for the targeted delivery of chemotherapeutic drugs both in vitro and in vivo. To monitor the rate and extent of cell-killing caused by the delivered chemotherapeutic drug, we wished to analyze the degree of apoptosis in targeted cells on a real-time basis. As the apoptosis-regulating caspases are activated during the apoptotic process, several caspase-hydrolyzable, fluorescence resonance energy transfer (FRET)-based substrates have been marketed for the detection of apoptosis. However, the applicability of these agents is limited because of their nonspecificity and the consequent high background fluorescence in tissues. Here we show the synthesis, characterization, and in vitro targeting of an engineered PAMAM nanodevice in which folic acid (FA) is conjugated as the targeting molecule and a caspase-specific FRET-based agent (PhiPhiLux G1D2) is conjugated as the apoptosis-detecting agent. This conjugate specifically targets FA-receptor-positive, KB cells. In these cells, the apoptosis-inducing agent staurosporine caused a 5-fold increase in the cellular fluorescence. These results show, for the first time, the potential applicability of a targeted apoptosis-measuring nanodevice, which could be used for simultaneously monitoring the apoptotic potential of a delivered drug.     

Surface-modified and internally cationic polyamidoamine dendrimers for efficient siRNA delivery

A novel internally quaternized and surface-acetylated poly(amidoamine) generation four dendrimer (QPAMAM-NHAc) was synthesized and evaluated for intracellular delivery of siRNA. The proposed dendrimer as a nanocarrier possesses the following advantages: (1) modified neutral surface of the dendrimer for low cytotoxicity and enhanced cellular internalization; (2) existence of cationic charges inside the dendrimer (not on the outer surface) resulting in highly organized compact nanoparticles, which can potentially protect nucleic acids from degradation. The properties of this dendrimer were compared with PAMAM-NH 2 dendrimer, possessing surface charges, and with an internally quaternized charged and hydroxyl-terminated QPAMAM-OH dendrimer. Atomic force microscopy studies revealed that internally charged and surface neutral dendrimers, QPAMAM-OH and QPAMAM-NHAc, formed well-condensed, spherical particles (polyplexes) with siRNA, while PAMAM-NH 2 resulted in the formation of nanofibers. The modification of surface amine groups to amide significantly reduced cytotoxicity of dendrimers with QPAMAM-NHAc dendrimer showing the lowest toxicity. Confocal microscopy demonstrated enhanced cellular uptake and homogeneous intracellular distribution of siRNA delivered by the proposed QPAMAM-NHAc nanocarrier. The results clearly demonstrated distinct advantages of developed QPAMAM-NHAc/siRNA polyplexes over the existing nucleic acid dendrimeric carriers.     

Surface modified dendrimers: synthesis and characterization for cancer targeted drug delivery

Dendrimers represents a highly branched three-dimensional structure that provides a high degree of surface functionality and versatility. PAMAM dendrimers are used as well-defined nanocontainers to conjugate, complex or encapsulate therapeutic drugs or imaging moieties. Star-burst [PAMAM] dendrimers represent a superior carrier platform for drug delivery. The present study was aimed at synthesis of a surface modified dendrimer for cancer targeted drug delivery system. For this 4.0 G PAMAM dendrimer was conjugated with Gallic acid [GA] and characterized through UV, IR, 1H NMR and mass spectroscopy. Cytotoxicity study of dendrimer conjugate was carried out against MCF-7 cell line using MTT assay. The study revealed that the conjugate is active against MCF-7 cell line and might act synergistically with anti-cancer drug and gallic acid-dendrimer conjugate might be a promising nano-platform for cancer targeting and cancer diagnosis.     

Enhanced cellular uptake efficiency of DCM probes or SN38 conjugating with phenylboronic acids

High-level of sialic acid (SA) expression on the surface of cancer cells is observed extremely common. Phenylboronic acids (PBAs) have a high affinity with SA. The cellular uptake efficiency could be enhanced by the strategy of introducing PBA fragments to the compounds. In this work, we synthesized five new probes with the Dicyanomethylene-4H-pyran (DCM) fluorophore, three of them conjugated with different phenylboronic acid fragments. By cellular uptake experiments, DLCB and DLAB showed enhanced cellular uptake abilities compared with DLN and DLO. These two effective phenylboronic acid fragments were then conjugated with SN-38 and the conjugates showed enhanced cellular uptake abilities by 3-fold or 7-fold compared with irinotecan. In summary, the strategy of introducing 4-carboxyphenylboronic acid and 3-amino-benzoxaborole groups shows great potential in drug delivery system. Moreover, the released linkers between boric acid and drugs deserve further studies.     

Synthesis and protein binding properties of T-antigen containing GlycoPAMAM dendrimers.

Allyl O-(beta-D-galactopyranosyl)-(1-3)-2-acetamido-2-deoxy-alpha-D-galactopyranoside (8) was prepared in excellent yield from the corresponding galactosyl bromide (6, 7) and allyl 2-acetamido-4,6-benzylidene-2-deoxy-alpha-D-galactopyranoside (5) using Hg(CN)2 as a promoter. Compound 5 was obtained from N-acetylglucosamine 1 following sequential protecting group strategy and C-4 epimerization as a key step. Carboxylic acid functionalized T-antigen derivative 15, obtained by radical addition of 3-mercaptopropionic acid to allyl disaccharide 10, was conjugated to PAMAM dendritic cores 13-16 by an efficient amide coupling strategy using TBTU. GlycoPAMAM dendrimers having T-antigen residues with 4, 8, 16 and 32 valencies (17-20) were obtained in 73 to 99% yields. Their protein binding properties were demonstrated using peanut lectin from Arachis hypogaea and a mouse monoclonal IgG antibody. The higher valency conjugates generated stronger binding interactions indicating a cluster effect. The inhibitory potential of these glycoPAMAM conjugates toward antibody-coating antigen interactions was enhanced up to 3800 times over that of the monomeric T-antigen residue (10).     

Cellular uptake mechanism of an inorganic nanovehicle and its drug conjugates: Enhanced efficacy due to clathrin-mediated endocytosis

We present the mechanism for the cellular uptake of layered double hydroxide (LDH) nanoparticles that are internalized into MNNG/HOS cells principally via clathrin-mediated endocytosis. The intracellular LDHs are highly colocalized with not only typical endocytic proteins, such as clathrin heavy chain, dynamin, and eps15, but also transferrin, a marker of the clathrin-mediated process, suggesting their specific internalization pathway. LDHs loaded with an anticancer drug (MTX-LDH) were also prepared to confirm the efficacy of LDHs as drug delivery systems. The cellular uptake of MTX was higher in MTX-LDH-treated cells than in MTX-treated cells, giving a lower IC50 value for MTX-LDH than for MTX only. The inhibition of the cell cycle was greater for MTX-LDH than for MTX only. This result clearly shows that the internalization of LDH nanoparticles via clathrin-mediated endocytosis may allow the efficient delivery of MTX-LDH in cells and thus enhance drug efficacy.     

Polyamidoamine dendrimers with different surface charge as carriers in anticancer drug delivery

Second-generation (G2) polyamidoamine (PAMAM) dendrimers are branched polymers containing 16 surface primary amine groups. Due to their structural properties, these polymers can be used as universal carriers in various drug delivery systems. Amine-terminated PAMAM dendrimers are characterized by a high positive surface charge, leading to effective but nonspecific interactions with negatively charged cell plasmatic membranes. To reduce the nonspecific internalization of PAMAM dendrimers, their primary amine groups are often modified by acetic or succinic anhydrides, polyethylene glycol derivatives and other compounds. In this work, the role of primary amine groups, which are localized on the surface of doxorubicin-conjugated (Dox) dendrimers, was studied with regard to their intracellular distribution and internalization rates using SKOV3 human ovarian adenocarcinoma cells. It was demonstrated that all Dox-labeled G2-derivatives containing different numbers of acetamide groups synthesized in this work show high rates of cellular uptake at 37°С. As expected, the conjugate carrying the maximum number of primary amine groups demonstrated the highest rates of binding and endocytosis. At the same time, the G2-Dox conjugate containing the maximum number of acetamide groups showed colocalization with LAMP2, a marker of lysosomes and late endosomes, as well as the highest level of cytotoxic activity against SKOV3 cells. We conclude that second-generation PAMAM dendrimers are characterized by varied pathways of internalization and intracellular distribution due to the number of primary amine groups on their surface and, as a consequence, a different surface charge.     

Gene delivery into mesenchymal stem cells: a biomimetic approach using RGD nanoclusters based on poly(amidoamine) dendrimers

Poly(amidoamine) dendrimers (generations 5 and 6) with amine termini were conjugated with peptides containing the arginine-glycine-aspartic acid (RGD) sequence having in view their application as gene delivery vectors. The idea behind the work was to take advantage of the cationic nature of dendrimers and of the integrin targeting capabilities of the RGD motif to improve gene delivery. Dendrimers were used as scaffolds for RGD clustering and, by controlling the number of peptides (4, 8, and 16) linked to each dendrimer, it was possible to evaluate the effect of RGD density on the gene delivery process. The new vectors were characterized in respect to their ability to neutralize and compact plasmid DNA (pDNA). The complexes formed by the vectors and pDNA were studied concerning their size, zeta potential, capacity of being internalized by cells and ability of transferring genes. Transfection efficiency was analyzed, first, by using a pDNA encoding for Enhanced Green Fluorescent Protein and Firefly Luciferase and, second, by using a pDNA encoding for Bone Morphogenetic Protein-2. Gene expression in mesenchymal stem cells was enhanced using the new vectors in comparison to native dendrimers and was shown to be dependent on the electrostatic interaction established between the dendrimer moiety and the cell surface, as well as on the RGD density of nanoclusters. The use of dendrimer scaffolds for RGD cluster formation is a new approach that can be extended beyond gene delivery applications, whenever RGD clustering is important for modulating cellular responses.     

Temporal control over cellular targeting through hybridization of folate-targeted dendrimers and PEG-PLA nanoparticles

Polymeric nanoparticles (NPs) and dendrimers are two major classes of nanomaterials that have demonstrated great potential for targeted drug delivery. However, their targeting efficacy has not yet met clinical needs, largely because of a lack of control over their targeting kinetics, which often results in rapid clearance and off-target drug delivery. To address this issue, we have designed a novel hybrid NP (nanohybrid) platform that allows targeting kinetics to be effectively controlled through hybridization of targeted dendrimers with polymeric NPs. Folate (FA)-targeted generation 4 poly(amidoamine) dendrimers were encapsulated into poly(ethylene glycol)-b-poly(D,L-lactide) (PEG-PLA) NPs using a double emulsion method, forming nanohybrids with a uniform size (~100 nm in diameter) at high encapsulation efficiencies (69-85%). Targeted dendrimers encapsulated within the NPs selectively interacted with FA receptor (FR)-overexpressing KB cells upon release in a temporally controlled manner. The targeting kinetics of the nanohybrids were modulated using three different molecular weights (MW) of the PLA block (23, 30, and 45 kDa). The release rates of the dendrimers from the nanohybrids were inversely proportional to the MW of the PLA block, which dictated their binding and internalization kinetics with KB cells. Our results provide evidence that selective cellular interactions can be kinetically controlled by the nanohybrid design, which can potentially enhance targeting efficacy of nanocarriers.