Modulation of tumor hypoxia by topical formulations with vasodilators for enhancing therapy.

Tumor hypoxia is a well known therapeutic problem which contributes to radioresistance and aggressive tumor characteristics. Lack of techniques for repeated measurements of tumor oxygenation (pO(2), partial pressure of oxygen) has restricted the optimization of hypoxia modifying methods and their efficacious application with radiotherapy. We have investigated a non-invasive method to enhance tissue pO(2) of peripheral tumors using topical application of formulations with BN (Benzyl Nicotinate), a vasodilator, and have used EPR (Electron Paramagnetic Resonance) oximetry to follow its effect on tumor oxygenation.We incorporated 2.5% BN in both hydrogel and microemulsions and investigated the effects on pO(2) of subcutaneous RIF-1 (Radiation Induced Fibrosarcoma) tumors in C3H mice. The experiments were repeated for five consecutive days. The topical application of BN in hydrogel led to a significant increase from a pre-treatment pO(2) of 9.3 mmHg to 11 - 16 mmHg at 30 - 50 min on day 1. However, the magnitude and the time of significant increase in pO(2) decreased with repeated topical applications. The BN in a microemulsion resulted in a significant increase from a baseline pO(2) of 8.8 mmHg to 13 - 18 mmHg at 10 - 50 min on day 1. Experiments repeated on subsequent days showed a decline in the magnitude of pO(2) increase on repeated applications. No significant change in tumor pO(2) was observed in experiments with formulations without BN (vehicle only).EPR oximetry was successfully used to follow the temporal changes in tumor pO(2) during repeated applications for five consecutive days. This approach can be potentially used to enhance radiotherapeutic outcome by scheduling radiation doses when an increase in tumor pO(2) is observed after topical applications of BN formulations.

Analysis of surface properties of cellulose ethers and drug release from their matrix tablets.

Detailed knowledge based on new developments, especially in analytical techniques, is needed for characterizing polymer excipients. Inverse gas chromatography (IGC) is a useful method for investigating polymer surfaces in terms of thermodynamic parameters. The aim of our work was to study the correlation between polymer surface properties determined with IGC and the mechanisms of release of water-soluble pentoxifylline and vancomycin hydrochloride from cellulose ether matrices. Tablets were made of hydroxypropyl (HPC), hydroxyethyl (HEC) or hydroxypropylmethyl (HPMC) cellulose and contained 25% of drug. Differences in dispersive component of the surface free energy for these polymers were relatively small and ranged from 26 to 33mN/m. However, polar properties, expressed as specific component of the enthalpy of adsorption and as acid-base properties show larger differences between the polymers and demonstrate their relative polarity in the order HEC>HPMC>HPC, which correlates well with water sorption on bulky polymers and with the swelling degree of polymer matrices. The release of pentoxifylline and vancomycin from HPC is governed mainly by Fickian diffusion, whereas from HEC the relaxation of polymer chains is important too. The analysis of the release profiles in the light of Peppas-Sahlin model lead to the conclusion that the surface properties of the cellulose ethers influence the interactions with water and the release mechanisms of the drug. It was found out, that data obtained by IGC enable rapid inference about the behaviour of polymers in water and the release of water-soluble drugs.

The effect of lipophilicity of spin-labeled compounds on their distribution in solid lipid nanoparticle dispersions studied by electron paramagnetic resonance.

Solid lipid nanoparticles (SLN) constitute an attractive drug carrier system. The aim of this study was to investigate the influence of lipophilicity and structure of different model molecules on their distribution in SLN dispersions. SLN composed of glyceryl tripalmitate as lipid and soybean lecithin and poloxamer 188 as stabilizers were prepared by a melt-emulsification process. PC(10,3), MeFASL(10,3), C(14)-Tempo, and Tempol were incorporated into SLN as spin-labeled compounds. The partition of SP between triglyceride and water was determined experimentally by electron paramagnetic resonance (EPR) and compared with calculated partition coefficients. The distribution of molecules in SLN dispersions was determined from the parameters of EPR spectra, from the reduction kinetics of the spin-labeled compounds with sodium ascorbate, and by computer simulation of EPR spectral line shapes. The experimentally obtained partition coefficients increase in the order Tempol < MeFASL(10,3) < C(14)-Tempo, showing the same trend as the partition coefficients calculated according to Rekker. In SLN dispersions, it was estimated that the ratio of SP between solid lipid core, phospholipid layers (deeper in SLN layer or in liposomes and closer to the surface of SLN), and water is for Tempol 0:0:100, for C(14)-Tempo 46:54(20:34):0, for MeFASL(10,3) 34:65(38:27):1, and for PC(10,3) 10:89(26:3:60):1.