Glycodendrimeric phenylporphyrins as new candidates for retinoblastoma PDT: blood carriers and photodynamic activity in cells.

Photodynamic therapy (PDT) has recently been proposed as a possible indication in the conservative treatment of hereditary retinoblastoma. In order to create photosensitizers with enhanced targeting ability toward retinoblastoma cells, meso-tetraphenylporphyrins bearing one glycodendrimeric moiety have been synthesized. The binding properties to plasma proteins and photodynamic activity of two monodendrimeric porphyrins bearing three mannose units via monoethylene glycol (1) or diethylene glycol (2) linkers have been compared to that of the non-dendrimeric tri-substituted derivative [TPP(p-Deg-O-α-ManOH)(3)]. The dendrimeric structure was found to highly increase the binding affinity to plasma proteins and to modify to some extent plasma distribution. HDL and to a lesser extent LDL have been shown to be the main carriers of dendrimeric and non-dendrimeric compounds. The phototoxicity observed for the two glycodendrimers (1) and (2) (LD(50)=0.5 µM) in Y79 cells is of the same order of magnitude that for TPP(p-Deg-O-α-ManOH)(3) (LD(50)=0.7 µM), with a similar cellular uptake level for (1) and a lower for (2). A serum content increase from 2% to 20% (v/v) in the incubation medium was found to inhibit both cellular uptake and photoactivity of dendrimeric derivatives, whereas those of TPP(p-Deg-O-α-ManOH)(3) remained little affected. Specificities of glycodendrimeric porphyrins, combining a lower cellular uptake together with a higher affinity toward plasma proteins, make these derivatives possible candidates for a vascular targeting PDT.

In vivo efficacy of photodynamic therapy in three new xenograft models of human retinoblastoma.

PURPOSE: Retinoblastoma is the most common primary intraocular tumor in children. In industrialized countries, 95% of patients are cured by chemotherapy and conservative treatments. However, these treatments can increase the risk of secondary tumors in patients with a constitutional alteration of the RB1 gene. Photodynamic therapy represents a nonmutagenic therapeutic approach, and may reduce the incidence of secondary tumors. To study the in vivo efficacy of photodynamic therapy, human retinoblastoma xenografts were established in nude mice. METHODS: Three xenografted cell lines, RB102-FER, RB109-LAK and RB111-MIL, were characterized and used for therapeutic evaluation. Mice were randomly divided into control and treatment groups with 5-8 mice in each group. Treatment groups received irradiation alone, photosensitizer alone or both in 2 of the 3 models and in the third model, photosensitizer plus irradiation was compared to untreated controls. mTHPC was injected intraperitoneally at a dose of 0.6mg/kg and verteporfin intravenously at a dose of 1mg/kg. Illuminations were performed 24h after mTHPC and 1h after verteporfin injections. RESULTS: A transient but significant response to mTHPC was observed for RB102-FER (p=0.03) and a significant response to mTHPC for RB111-MIL (p<10(-4)) with partial regression maintained for more than 60 days. No significant difference between the different groups was observed for RB109-LAK, except in the verteporfin plus laser group (p=0.01). CONCLUSIONS: The studies confirmed the suitability of the three xenograft models for the evaluation of photodynamic therapy in retinoblastoma. Our findings suggest that PDT may represent an alternative conservative treatment for these tumors.

Photodynamic efficiency of diethylene glycol-linked glycoconjugated porphyrins in human retinoblastoma cells.

Photodynamic therapy (PDT) is emerging as a new strategy for the conservative treatment of hereditary retinoblastoma. The glycoconjugated porphyrins TPP(p-Deg-O-alpha-GalOH)(3), TPP(p-Deg-O-beta-GalOH)(3), TPP(p-Deg-O-alpha-ManOH)(3), and their S-analogues were synthesized to obtain efficient photosensitizers with some retinoblastoma cell affinity. In these systems, a sugar motif and porphyrin core were linked by a diethylene glycol spacer (Deg). Cellular uptake, localization, and photoactivity have been examined in human retinoblastoma cells (Y79). After preincubation with corresponding glycosylated albumin, the uptake of TPP(p-Deg-O-beta-GalOH)(3) and TPP(p-Deg-O-alpha-ManOH)(3) was 40-45% inhibited, indicating a possible cell-sugar-receptor saturation. High photoactivity was observed for the two alpha-galacto/manno porphyrins 8 and 10 (LD(50) = 0.05 and 0.35 muM, respectively) at 514 nm and low fluence (1 J/cm(2)). Analysis by MALDI-TOF mass spectrometry only indicated a small metabolic cleavage of the O-glycoconjugates and a good stability of the S-glycoside porphyrins. On the basis of these in vitro data, TPP(p-Deg-O-alpha-GalOH)(3) and TPP(p-Deg-O-alpha-ManOH)(3) were selected for in vivo studies.

Photophysical properties of glucoconjugated chlorins and porphyrins and their associations with cyclodextrins.

Glucoconjugated analogues of the meta-hydroxyphenyl porphyrin (m-THPP) and meta-hydroxyphenyl chlorin (m-THPC) has been recently synthesized. The characteristics of their triplet states have been determined with regard to their involvement in the photodynamic (PDT) efficiency. In the case of porphyrin derivatives, triplet quantum yields (Phi(T)) were ranging from 0.42 to 0.55 and triplet life times (tau(T)) from 1 to 5 micros. High reaction rate constants (k(q)) with molecular oxygen (k(q): 1.2-1.6 x 10(9)s(-1)) have been found. The triplet lifetimes of chlorin derivatives were about four times higher than those of porphyrins whereas the Phi(T) and k(q) values remained quite similar. Singlet oxygen yields of glucosylated and non-glucosylated porphyrins and chlorins were not significantly different within experimental errors (Phi(Delta)((1)O(2)): 0.41-0.58). Furthermore, it has been shown that glucoconjugated photosensitizers could undergo associations with the methyl-beta-cyclodextrin (Me-beta-CD) which exhibit high triplet lifetimes and singlet oxygen yields ranging from 0.27 to 0.48.

5-aminolevulinic acid ester-induced protoporphyrin IX in a murine melanoma cell line.

The use of 5-aminolevulinic acid (5-ALA) ester derivatives as precursors of endogenous protoporphyrin IX (PpIX) has been proposed as a good strategy for improved drug diffusion across biological membranes. In the present work, the 5-ALA ester derivatives hexyl-ALA (h-ALA), octyl-ALA (o-ALA), and decyl-ALA (d-ALA) were synthesized, and their efficacy to induce endogenous PpIX was explored in a murine melanoma cell line (B-16) as compared with that of 5-ALA. The maximum level of PpIX induced in cells treated with 5-ALA, h-ALA, o-ALA, and d-ALA was reached at optimal concentrations of 0.3, 0.075, 0.1, and 0.075 mM, respectively. The derivatives h-ALA and o-ALA appear as the most efficient PpIX precursors in this cell line, since a higher or similar PpIX production could be achieved with a fourfold and threefold lower dose of these precursors compared with 5-ALA. The phototoxicity effect of h-ALA and o-ALA ester derivatives showed the same phototoxicity behavior detected for 5-ALA but at much lower drug doses. Our study suggests that h-ALA and o-ALA esters improve intracellular PpIX formation in B-16 cells at reduced concentrations. This should enable clinical applications at lower precursor doses with reduced effective costs.