Mitochondria-targeting multifunctional nanoplatform for cascade phototherapy and hypoxia-activated chemotherapy.

Despite considerable progress has been achieved in hypoxia-associated anti-tumor therapy, the efficacy of utilizing hypoxia-activated prodrugs alone is not satisfied owing to the inadequate hypoxia within the tumor regions. In this work, a mitochondrial targeted nanoplatform integrating photodynamic therapy, photothermal therapy and hypoxia-activated chemotherapy has been developed to synergistically treat cancer and maximize the therapeutic window. Polydopamine coated hollow copper sulfide nanoparticles were used as the photothermal nanoagents and thermosensitive drug carriers for loading the hypoxia-activated prodrug, TH302, in our study. Chlorin e6 (Ce6) and triphenyl phosphonium (TPP) were conjugated onto the surface of the nanoplatform. Under the action of TPP, the obtained nanoplatform preferentially accumulated in mitochondria to restore the drug activity and avoid drug resistance. Using 660 nm laser to excite Ce6 can generate ROS and simultaneously exacerbate the cellular hypoxia. While under the irradiation of 808 nm laser, the nanoplatform produced local heat which can increase the release of TH302 in tumor cells, ablate cancer cells as well as intensify the tumor hypoxia levels. The aggravated tumor hypoxia then significantly boosted the anti-tumor efficiency of TH302. Both in vitro and in vivo studies demonstrated the greatly improved anti-cancer activity compared to conventional hypoxia-associated chemotherapy. This work highlights the potential of using a combination of hypoxia-activated prodrugs plus phototherapy for synergistic cancer treatment.

Phosphate prodrugs of isophosphoramide mustard.

Dibenzylphosphorobenzyl and phosphorobenzyl analogues of isophosphoramide mustard, an active metabolite of ifosfamide were synthesized. Phosphorobenzyl analogue posseses stronger cytotoxic activity than isophosphoroamide mustard against the cells of several cancer cell lines suggesting the possibility of the use of this compound in Gene-Directed Enzyme-Prodrug Therapy (GDEPT).

The partitioning of phosphoramide mustard and its aziridinium ions among alkylation and P-N bond hydrolysis reactions.

NMR (1H and 31P) and HPLC techniques were used to study the partitioning of phosphoramide mustard (PM) and its aziridinium ions among alkylation and P-N bond hydrolysis reactions as a function of the concentration and strength of added nucleophiles at 37 degrees C and pH 7.4. With water as the nucleophile, bisalkylation accounted for only 10-13% of the product distribution given by PM. The remainder of the products resulted from P-N bond hydrolysis reactions. With 50 mM thiosulfate or 55-110 mM glutathione (GSH), bisalkylation by a strong nucleophile increased to 55-76%. The rest of the PM was lost to either HOH alkylation or P-N bond hydrolysis reactions. Strong experimental and theoretical evidence was obtained to support the hypothesis that the P-N bond scission observed at neutral pH does not occur in the parent PM to produce nornitrogen mustard; rather it is an aziridinium ion derived from PM which undergoes P-N bond hydrolysis to give chloroethylaziridine. In every buffer studied (bis-Tris, lutidine, triethanolamine, and Tris), the decomposition of PM (with and without GSH) gave rise to 31P NMR signals which could not be attributed to products of HOH or GSH alkylation or P-N bond hydrolysis. The intensities of these unidentified signals were dependent on the concentration of buffer.

[Strategies for studies on mechanism of action of antineoplastic agents]. / Rozwój badan nad czynnikami o dzialaniu przeciwnowotworowym.

A concise review of the progress in strategies of anticancer drug screening methods provides a background for showing the selected examples of the results from our studies in the field of experimental antitumor therapy. The antineoplastic activity of ifosfamide bromoanalogues is presented in comparison with clinically used cytostatic drugs from the same chemical group. The results obtained by combined chemo-immunotherapy with exploitation of mIL-2 gene transfected plasmacytoma cells (X-63-mIL-2) applied in tumor-bearing mice exemplifies one of the novel approaches in anticancer treatment.