Brain tissue characterisation by infrared imaging in a rat glioma model.

Pathological changes associated with the development of brain tumor were investigated by Fourier transform infrared microspectroscopy (FT-IRM) with high spatial resolution. Using multivariate statistical analysis and imaging, all normal brain structures were discriminated from tumor and surrounding tumor tissues. These structural changes were mainly related to qualitative and quantitative changes in lipids (tumors contain little fat) and were correlated to the degree of myelination, an important factor in several neurodegenerative disorders. Lipid concentration and composition may thus be used as spectroscopic markers to discriminate between healthy and tumor tissues. Additionally, we have identified one peculiar structure all around the tumor. This structure could be attributed to infiltrative events, such as peritumoral oedema observed during tumor development. Our results highlight the ability of FT-IRM to identify the molecular origin that gave rise to the specific changes between healthy and diseased states. Comparison between pseudo-FT-IRM maps and histological examinations (Luxol fast blue, Luxol fast blue-cresyl violet staining) showed the complementarities of both techniques for early detection of tissue abnormalities.

Influence of C6 and CNS1 brain tumors on methotrexate pharmacokinetics in plasma and brain tissue.

PURPOSE: Comparison of the influence of two different brain tumors (C6 and CNS1 glioma) on methotrexate (MTX) disposition in plasma, brain, and tumor tissue extracellular fluid (ECF). METHODS: Serial collection of plasma samples and brain ECF dialysates after i.v. bolus administration of MTX (50 mg kg(-1)) for 4 h. Quantitation of MTX concentrations by HPLC-UV. RESULTS: Histological studies revealed a 3-fold higher number of blood vessels in CNS1 than in C6 tumor tissue. In vivo recoveries (reverse dialysis) were significantly different in tumor tissue (C6: 8.0 +/- 3.8%; CNS1: 4.9 +/- 2.5%), and in the contralateral hemisphere (C6: 6.0 +/- 4.0%; CNS1: 3.9 +/- 2.5%) between the two tumors. Area under the concentration-time curve (AUC) in plasma was 30% higher in CNS1 than in C6 due to a lower systemic clearance. Maximum MTX levels in brain tumor ECF were significantly higher in CNS1 than in C6, and decreased faster in CNS1 than in C6 tumor-bearing rats. Penetration in tumor ECF (AUC(ECF)/AUC(Plasma) ratio) was similar in CNS1 and C6. MTX concentrations in contralateral hemisphere were significantly lower than in tumor tissue and dependent on tumor model. CONCLUSION: C6 and CNS1 brain tumors have a distinct yet highly variable impact on MTX penetration in brain and brain tumor ECF.