Cellular copper import by nanocarrier systems, intracellular availability, and effects on amyloid beta peptide secretion.

Studies in animals have reported that normalized or elevated Cu levels can inhibit or even remove Alzheimer's disease-related pathological plaques and exert a desirable amyloid-modifying effect. We tested engineered nanocarriers composed of diverse core-shell architectures to modulate Cu levels under physiological conditions through bypassing the cellular Cu uptake systems. Two different nanocarrier systems were able to transport Cu across the plasma membrane of yeast or higher eukaryotic cells, CS-NPs (core-shell nanoparticles) and CMS-NPs (core-multishell nanoparticles). Intracellular Cu levels could be increased up to 3-fold above normal with a sublethal dose of carriers. Both types of carriers released their bound guest molecules into the cytosolic compartment where they were accessible for the Cu-dependent enzyme SOD1. In particular, CS-NPs reduced Abeta levels and targeted intracellular organelles more efficiently than CMS-NPs. Fluorescently labeled CMS-NPs unraveled a cellular uptake mechanism, which depended on clathrin-mediated endocytosis in an energy-dependent manner. In contrast, the transport of CS-NPs was most likely driven by a concentration gradient. Overall, nanocarriers depending on the nature of the surrounding shell functioned by mediating import of Cu across cellular membranes, increased levels of bioavailable Cu, and affected Abeta turnover. Our studies illustrate that Cu-charged nanocarriers can achieve a reasonable metal ion specificity and represent an alternative to metal-complexing agents. The results demonstrate that carrier strategies have potential for the treatment of metal ion deficiency disorders.

Development of pH-responsive core-shell nanocarriers for delivery of therapeutic and diagnostic agents.

In this paper new dendritic core-shell architectures with pH-labile linkers based on hyperbranched polyglycerol cores and biocompatible poly(ethylene glycol) shells were synthesized which encapsulate the anticancer agent doxorubicin and a dye for near-infrared imaging, an indotricarbocyanine. Acid-sensitive properties of the new nanocarriers and in vitro cytotoxicity of the doxorubicin-nanocarrier are presented as well as preliminary data regarding their toxicity and tumor targeting potential in nude mice.

Water-soluble pH-responsive dendritic core-shell nanocarriers for polar dyes based on poly(ethylene imine).

A simple general synthetic concept to build dendritic core-shell architectures with pH-labile linkers based on hyperbranched PEI cores and biocompatible PEG shells is presented. Using these dendritic core-shell architectures as nanocarriers, the encapsulation and transport of polar dyes of different sizes is studied. The results show that the acid-labile nanocarriers exhibit much higher transport capacities for dyes than unfunctionalized hyperbranched PEI. The cleavage of imine bonds and controlled release of the polar dyes revealed that weak acidic condition (pH approximately 5.0) could cleave the imine bonds linker and release the dyes up to five times faster than neutral conditions (pH = 7.4).

pH-Responsive dendritic core-shell architectures as amphiphilic nanocarriers for polar drugs.

In this paper a simple general synthetic concept was used to generate dendritic core-shell architectures based on hyperbranched poly(ethylene imine) cores and different shells which contain aliphatic chains and poly(ethylene glycol) chains, respectively. Using these dendritic core-shell architectures as nanocarriers we studied the encapsulation and transport of polar drugs, such as congo red. The results showed that the acid labile nanocarriers exhibited much higher transport capacities for congo red than the bare poly(ethylene imine). This gives an opportunity for the controlled release of encapsulated dyes and drugs by a pH-triggered cleavage of the imine bond. In two cases the pH-sensitivity was studied and a relatively high stability of the imine bond was observed at pH 8, while fast cleavage occurred at pH 5-7. This pH difference correspond to the pH-shift in malignant tissues (tumor, infection) compared to normal tissue, which could trigger the release of the encapsulated drugs.

Synthesis, characterization and photodynamic activity of phenmethylamino-demethoxy-hypocrellin B.

Two phenmethylamino hypocrellin B derivatives are novel photodynamic agents synthesized by a mild reaction between hypocrellin B and phenmethylamine. The red absorption of the photosensitizers is enlarged distinctly and the peri-hydroxylated perylenequinone structure of the parent HB is preserved. 9,10-diphenyl-anthracene (DPA) bleaching and electron paramagnetic resonance (EPR) spin trapping techniques were used to study the photodynamic activities of the phenmethylamino hypocrellin B derivatives in the presence of oxygen. Singlet oxygen (1O2) and superoxide anion radical (O2*-) generated in the process of illumination of the phenmethylamino hypocrellin B in aerobic solution were observed. The photodamage of PMAHBs to MGC803 cancer cells was investigated in vitro. The results in vitro reveal that the phenmethylamino hypocrellin B derivatives show a much less significant decrease in cytotoxicity than that of their parent HB. It exhibits higher selectivity of light-orientation, which can decrease the damage to normal tissues by irradiating the tumor tissues, and so increases the drug safety.

EPR studies of the photodynamic properties of a novel potential photodynamic therapeutic agent: photogeneration of semiquinone radical anion and active oxygen species (O2*-, OH*, H2O2 and 1O2).

Cyclohexylamino-substituted hypocrellin B (CHAHB) has been synthesized with the aim of improving the red absorption and specific affinity for malignant tumors over those of the parent compound. Irradiation of a deoxygenated DMSO solution of CHAHB generates a strong electron paramagnetic resonance (EPR) signal, which is assigned to the semiquinone radical anion of CHAHB with the aid of a series of experimental results. In the presence of oxygen, superoxide radical anions (O2*-) are generated via electron transfer from CHAHB*-, the precursor, to ground-state molecular oxygen. Hydroxyl radicals were detected by spin-trapping EPR when an oxygen-saturated aqueous solution containing CHAHB and DMPO was irradiated. Singlet oxygen (1O2) is produced via energy transfer from triplet CHAHB to ground-state oxygen molecules, with a sharply decreased quantum yield, i.e. 0.11. Furthermore, cell survival studies reveal CHAHB exhibits much higher photodynamic activities than its parent hypocrellins. The strongly enhanced photodynamic activities and sharply decreased quantum yield of 1O2 generation suggest that the type I (free radical) mechanism may play a significant role in CHAHB-PDT, rather than the type II (singlet oxygen) mechanism found in photofrin-PDT.

Investigation of photobleaching of hypocrellin B in non-polar organic solvent and in liposome suspension.

Hypocrellin B (HB) is a natural pigment with a promising application in the photodynamic therapy (PDT) for anticancer treatment. The photobleaching of HB in non-polar organic solvents and in liposomes in aqueous solution were investigated by the measurements of absorption spectra, quenching experiments and determination of photoproducts. Control experiments indicated that the sensitizer, oxygen and light were all essential for the photobleaching of HB, which suggested that it was mainly self-sensitized photooxidation. The illumination of HB with visible light in aerobic non-polar solvent generated singlet oxygen efficiently [Phi(1O(2))=0.76] which then attacked the sensitizer HB with formation of an endoperoxide product. The endoperoxide of HB was unstable at room temperature and underwent predominantly loss of singlet oxygen with regeneration of parent HB. The singlet oxygen released from the endoperoxide of HB was detected with chemical trapping experiments. When HB was embedded in EPC liposomes, no endoperoxide product and no singlet oxygen release from the photobleaching process of HB were detected. The quenching experiments indicated that the singlet oxygen mechanism (type II) played an important role in the non-polar solvent and the free radical mechanism (type I) was predominant in liposomal aqueous solution for the photobleaching of HB.