Aminolevulinic acid dendrimers in photodynamic treatment of cancer and atheromatous disease.

The use of endogenous protoporphyrin IX after administration of 5-aminolaevulinic acid (ALA) has led to many applications in photodynamic therapy (PDT). We have previously reported that the conjugation of ALA dendrimers enhances porphyrin synthesis. The first aim of this work was to evaluate the ability of ALA dendrimers carrying 6 and 9 ALA residues (6m-ALA and 9m-ALA) to photosensitise cancer cells. For this aim, we employed LM3 mammary carcinoma cells. In these tumour cells, at low concentrations porphyrin synthesis from dendrimers was higher compared to ALA, whereas at high concentrations, porphyrin synthesis was similar from both compounds. Topical application of ALA dendrimers on the skin overlying a subcutaneous LM3 implanted tumour showed no diffusion of the molecules either to distant skin sites or to the adjacent tumour, suggesting a promising use of the ALA macromolecules in superficial cancer models. As a second objective, we proposed the use of ALA-dendrimers in vascular PDT for the treatment of atherosclerosis. Thus, we focused our studies on ALA-dendrimer's selectivity towards macrophages in comparison with endothelial cells. For this aim we employed Raw 264.7 macrophages and HMEC-1 microvasculature cells. Porphyrin synthesis induced in macrophages by 6m-ALA and 9m-ALA (3 h, 0.025 mM) was 6 and 4.6 times higher respectively compared to the endothelial cell line, demonstrating the high affinity of ALA dendrimers for macrophages. On the other hand, ALA employed at low concentrations was slightly selective (1.7-fold) for macrophages. Inhibition studies suggested that ALA dendrimer uptake in macrophages is mainly mediated by caveloae-mediated endocytosis. Our main conclusion is that in addition to being promising molecules in PDT of superficial cancer, ALA dendrimers may also find applications in vascular PDT, since in vitro they showed selectivity to the macrophage component of the atheromatous plaque, as compared to the vascular endothelium.

Synthesis and biological studies of 5-aminolevulinic acid-containing dendrimers for photodynamic therapy.

Using a convergent growth approach, a series of novel 5-aminolevulinic acid (ALA)-containing dendrimers have been synthesized. In these molecules, ALA residues are attached to the periphery by ester linkages, with amide bonds connecting the dendrons. Three first-generation dendrimers, bearing either 6 or 9 ALA residues, were synthesized by attachment of a tris(Boc-protected ALA)-containing wedge (1) to a di- or tripodent aromatic, or tripodent aliphatic core. Two second generation 18-ALA-containing dendrimers were also synthesized using a 3,3'-iminodipropionic acid spacer unit between wedge 1 and the aromatic core. These compounds differed only in the distance between the core and the linker unit. The Boc-protected dendrimers were deprotected using trifluoroacetic acid and isolated as their TFA salts. The potential of these ALA ester dendrimers as macromolecular prodrugs for photodynamic therapy has been demonstrated in the tumorigenic keratinocyte PAM 212 cell line.

Photosensitization of pancreatic tumour cells by delta-aminolaevulinic acid esters.

A series of straight chain, branched and cyclo-delta-aminolaevulinic acid (ALA) esters have been synthesized and their photosensitizing properties analysed using an in vitro system of rat pancreatoma cells. Structurally favourable ALA esters not only induced the formation of more of the endogenous photosensitizer, protoporphyrin IX (PpIX), but they did so at a faster rate than ALA itself. This action was reflected in a substantial increase in photocytotoxicity of some 270 times, using the more potent ALA esters. An important structural feature was identified in two of the ALA esters which greatly limited PpIX production, i.e. a branch point located next to the site of ester cleavage. Experiments on the transport of ALA and of ALA esters across the cell membrane showed that ALA, but not ALA esters, gain access to the cell via the di- and tripeptide transporter, PEPTI. Finally, these results show that the esterification of ALA can greatly increase its cellular uptake, so generating more intracellular PpIX, improved tumour cell photosensitization and enhanced photocytotoxicity.