e15597 Background: Oncolytic virotherapy is developing intensively in modern oncology. Viruses demonstrate the ability to the direct oncolysis and to the stimulation of antitumor immune activity; this experiment was aimed at solving the question of the prevalence of one of them. Glial tumors are the most common brain tumors; oncolytic viruses show certain prospects in their treatment due to the ability to penetrate the blood-brain barrier. The aim of the study was to determine the possible oncolytic effect of new unclassified group K rotaviruses (RVK) on T98G and U87MG glioblastoma cells in vitro. Methods: T98G and U87MG cell cultures were received from Russian banks of cell lines of human and animal tissues. Standard culturing was performed with attenuated apatogenic RVK strains No. 100 and No. 228 at a concentration of 108, 107, 106 and 105 particles/mL. The cytotoxic effect was determined with MTT and Annexin V assays, cell morphology was evaluated by the light-optical method. Results: Both RVK strains demonstrated a dose-dependent cytotoxic activity; the maximal effect was observed in strain No.100 at a dose of 108 particles/mL on U87MG cells (predominantly apoptosis). Studies of cell morphology showed a pronounced effect of RVK on the cell culture: significant degenerative changes in cells, a tendency to a decrease in cluster size, a change in their shape and granularity. Cluster formation in culturing in the serum-free medium is considered in the literature as a property of cancer stem cells responsible in vivo for tumor recurrence and its chemo- and radio-resistance. T98G cells demonstrated morphological changes: nuclear segmentation, diffused cytoplasm, indistinct cell borders with signs of syncytium formation. Conclusions: The established oncolytic effect of RVK strain No. 100 in vitro on glioma cells, presumably with tumor stem cells, indicates a significant potential for the use of these rotaviruses in treatment of glial tumors.
e14515 Background: The choice of cell source for 3D bioprinting of in vivo-like models of glial tumors is crucial and must take into account the ability to proliferation and stable metabolism. Oral administration of 5-aminolevulinic acid (5-ALA) in patients prior to surgery increases the fluorescent contrast between tumor and surrounding tissue, but the effect of contrast agents on cells in vitro is unknown. The aim of the study was obtaining viable glial tumor tissues using 5-ALA, as well as the development of a stable primary cell culture for 3D bioprinting. Methods: Tumor tissue was obtained from patients with glioblastoma during surgery under visual control using the Opmi Pentero Blue E400 microscope and 5-ALA. Material was disaggregated on a BD Machine using Medicons 50 μm (BD). Glioblastoma cells were cultured in DMEM/F12 medium with L-glutamine (Gibco) containing 10% fetal bovine serum (Biolot, Russia), 1% non-essential amino acids (NEAA, Sigma-Aldrich) and 0.5% penicillin-streptomycin (Biolot) at 37C. Glial cell lines were characterized immunohistochemically using antibodies to the glial fibrillary acidic protein (GFAP) and proliferation index (Ki-67). Microsatellite analysis was performed using three dinucleotide repeat markers D2S123, D17S250, D5S346 and five mononucleotide loci BAT25, BAT26, NR21, NR24 and NR27. Results: The positive expression of GFAP on the cell processes of the star-like shape was clearly visualized, indicating a morphological feature of glial tumors. The Ki-67 labeling index was 70%. Changes were observed at the D17S250 locus (148-148/148-152) for the glial tumor primary cells after the sixth passage. Microsatellite instability was not observed in the primary cell culture. Conclusions: The accumulation of porphyrins from 5-ALA in glial tumor cells does not prevent the in vitro creation of a cell culture from tumor tissue. Microsatellite analysis showed that the obtained glioblastoma cell lines remain stable for at least 10 passages. Material obtained during resection using 5-ALA is a reliable source of stable glial tumor cell lines.
2545 Background: The standard treatment of malignant brain gliomas, including surgical and radiation therapies, does not provide recovery and a long-time favorable prognosis. The development of technologies and international guidelines on the introduction of electric (TTF) and electromagnetic (TMS) fields in combination treatment for glioblastomas aims to improve immediate results, as shown in experiments on human glioblastoma cell culture. The TMS protocol requires further refinement in parameters of frequency, intensity, and exposure with an assessment of the immediate results of combined treatment. Methods: The study included 60 patients diagnosed with MBG receiving osteoplastic craniotomy with radical (within visible unchanged tissues) tumor removal. Starting from the second day after the surgery, patients of group 1 (n = 30) received 10 sessions of magnetotherapy in the double exposure mode. For the first morning exposure, we used an ultra-low-frequency magnetic field (ULFMF) (0.03 to 9.0 Hz) on the hypothalamus projection area to induce a general antistress reaction. After 2.5-3 hours, local (on the surgical site) TMS exposure with the Neuro-MSD system (Russia) was applied in the pulse algorithm, up to 1 GHz and 5 Hz, 15 mT, 3 min. The induction was reduced exponentially (C = 0.8). The control group 2 (n = 30) did not receive ULFMF or TMS. Magnetic resonance imaging (MRI) was used to determine the volume of tumors (Vt, cm3) and perifocal edema (Ve, cm3) calculated according to the Shrek’s formula for an ellipsoid (V = a×b×c×π/6). Results: Before surgery, Vt = 54.7±5.7cm3 in group 1, in group 2 - Vt = 60.9±8.5cm3 (no statistical differences). After surgery and the subsequent course of ULFMF and TMS, residual tumor volumes in group 1 were 2.5 times lower than in controls (p < 0.05). The difference between Ve values before and after treatment was on average 80.7 cm3 in group 1 and 41.8 cm3 in group 2 (p < 0.05). Conclusions: The inclusion of sequential ULFMF and TMS exposures into postoperative therapy for gliomas, taking into account various vectors of the influence on the projection of centers of homeostasis regulation and the surgical field, as well as the development of programmed modes of biotropic exposure parameters, improves antitumor and anti-edematous effects.
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