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Flavone acetic acid (FAA) is a new antitumor agent with broad activity against transplantable solid tumors of mice but with only scant or no activity against leukemias and lymphomas. The technique of alkaline elution was used to study DNA lesions in s.c. implanted Glasgow osteogenic sarcoma in
Flavone acetic acid (FAA) is a new anticancer agent in Phase II trials in Europe. In preclinical testing FAA showed broad activity against murine solid tumors and minimal activity against murine leukemias. Our interest in studying the combination of FAA and radiation was based on two of its
The interaction of FAA or TNF with radiation was studied in the murine KHT sarcoma. When used alone both agents showed a dose- and time-dependent toxicity towards the tumour cells and significantly reduced tumour blood flow within 1 h of treatment. When used in combination with radiation, both TNF
A rat tumour (MC7 sarcoma), growing subcutaneously, has been shown to be sensitive to a single application of flavone acetic acid. Thirteen rats were still alive after 50 days and 8 of these were tumour free, as compared with control rats which survived for 15.7 +/- 2.53 days. The 8 tumour free
Flavone acetic acid (FAA), a new drug with broad activity against transplanted solid tumors of mice, induces nonrepairable DNA single strand breaks that correlate with therapeutic efficacy. To test the hypothesis that the inability of the cells to repair single strand breaks is associated with a
OBJECTIVE
To determine whether larger confluent zones of ablation can be achieved in chemical ablation with use of a multiple-tine infusion device compared with standard needle infusion in a solid tumor model.
METHODS
Multiple canine venereal sarcomas (N=42) were implanted in nine mildly
A fresh specimen from an intracranial tumor, which was histopatologically classified as a synovial sarcoma, was investigated cytogenetically. The direct method failed to give any information due to a lack of mitotic cells after treatment with 70% acetic acid, whereas 6-day cultures showed a
TGF-beta like peptide, termed TGF(BC-1), was partially purified from defatted and decaseinated bovine colostrum by a sequence of DEAE-Sephacel chromatography and Sephadex G-50 gel filtration in 1M acetic acid. TGF(BC-1) was distinct from well-known 25K TGF-beta in chemical properties: TGF(BC-1) was
The autocrine growth factor(s) was isolated from serumfree conditioned medium of rat sarcoma (XC) cells. Autocrine activity was enriched by ultrafiltration using Amicon YM 10 membrane, extraction with 1 M acetic acid and partially purified (650-fold) by chromatography on Bio-Gel P-100 and P-60. The
Intracellular myoglobin represents an excellent marker for specific characterization of normal (adult and fetal) and malignant skeletal muscle cells in paraffin sections. With an immunoperoxidase indirect sandwich technique for detection of intracellular myoglobin, positive staining was observed in
Murine sarcoma virus-transformed mouse fibroblasts produce potent immunosuppressive factors (ISF) in vitro. The partially purified ISF inhibited thymocyte proliferation induced by concanavalin A or phytohemagglutinin plus lymphocyte activating factor (Interleukin 1), lipopolysaccharide-induced
CDP reductase was separated from the cytosol of rat Yoshida ascites sarcoma. The precipitate, which resulted from the acidification of the cytosol by acetic acid at pH 5.2, catalyzed specifically the reduction of CDP, whereas the concurrently resulted supernatant catalyzed those of UDP, ADP and GDP.
Effect of human recombinant TNF (rHu-TNF) on tumor blood vessels was investigated in relation to its mode of anti-neoplastic action against Meth A sarcoma in BALB/c mice. The extent of the blood vessel lesion was evaluated by measuring the degrees of blueing and hemorrhage after intravenous
Flavone acetic acid (FAA) is a new antitumor agent that has recently entered Phase I clinical trials. In preclinical studies, we have found that FAA was broadly active against a variety of transplantable solid tumors of mice (colon #51, #07, #10, #26; pancreatic ductal adenocarcinomas #02 and #03;