Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0027651 (tumor)
685,946 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Pharmacokinetic studies demonstrated the advantage of intraperitoneal oxaliplatin (1-OHP) for cancers restricted to the peritoneal cavity. The area under the concentration X time curve (AUC) in the peritoneal cavity for both total and ultrafiltered drug was almost 2 times higher for 1-OHP than cisplatin (cDDP). The AUC for ultrafiltered 1-OHP in plasma was also a factor 4 higher than cDDP, indicating that peritoneal tumors received a higher exposure from 1-OHP than cDDP directly in the peritoneal cavity and indirectly via the systemic circulation. Total platinum concentrations in peritoneal tumors of rats were determined after i.p. administration of equimolar doses of 1-OHP and cDDP. In spite of the pharmacological advantages, no significant difference in platinum concentration was demonstrated. In addition, no difference in the distribution of platinum within peritoneal tumors was detected after i.p. treatment with equimolar doses, i.e., platinum concentrations were comparable both in the periphery, 29 +/- 4 ppm for cDDP and 22 +/- 8 for 1-OHP and in the center of the tumor, 18 +/- 3 for both drugs. When CC531 tumor cells were incubated in vitro with equimolar concentrations of 1-DHP and cDDP in vitro, 2 to 4 times less platinum was found in cells treated with 1-OHP, indicating that the uptake of 1-OHP differed from that of cDDP. Oxaliplatin was not cross resistant for cDDP in CC531.RL4 tumor cells, a cDDP resistant cell line, which may indicate its value in ovarian cancer patients who did not respond to earlier cDDP treatment.
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PMID:The use of oxaliplatin versus cisplatin in intraperitoneal chemotherapy in cancers restricted to the peritoneal cavity in the rat. 234 88

The in vitro cytotoxicity, protein binding, partitioning of platinum from whole blood into erythrocytes, its exchange back into plasma, and the in vitro biotransformation in plasma were studied for the new nonnephrotoxic platinum analogue oxaliplatin. The cytotoxicity studies were carried out against a panel of human tumor cell lines derived from carcinomas of the ovary (A2780, A2780/cp), bladder (TCCSUP, RT4), colon (HT-29), melanoma (SKMEL-2, HTB144), and glioma (U373MG and U87MG). The relative potency of the five platinum complexes was oxaliplatin = tetraplatin > cisplatin > iproplatin > carboplatin. Oxaliplatin was active against HT-29 and only minimally cross-resistant with cisplatin against A2780/cp. Both bladder carcinoma cell lines, both melanoma cell lines, and one of the two glioblastoma cell lines were resistant to both oxaliplatin and tetraplatin. The cytotoxicity profiles of the drug pairs oxaliplatin-tetraplatin and cisplatin-carboplatin showed statistically significant correlation by the Spearman rank correlation test. Oxaliplatin was similar to cisplatin and tetraplatin in protein binding; 85-88% of all platinum from oxaliplatin (5, 10, or 20 micrograms/ml) was bound to plasma proteins within the first 5 h with an average half-life of 1.71 +/- 0.06 h. When oxaliplatin was incubated in whole blood (5, 10, and 20 micrograms/ml), the erythrocytes took up 37.1 +/- 2.1% of the total platinum in 2 h (maximum uptake) which was not exchangeable into plasma. Thus the erythrocyte-bound fraction does not serve as a reservoir of drug. In plasma, oxaliplatin was unchanged at 0.5 h, but at 1 h, 30% of the total platinum in plasma was in a peak which had identical retention to that of (trans-1,2-diaminocyclohexane)dichloroplatinum(II), the major biotransformation product of tetraplatin. At 2 h, (trans-1,2-diaminocyclohexane)dichloroplatinum(II) and three other platinum-containing peaks were detected but no unchanged oxaliplatin. All the platinum eluted in a single peak near the solvent front at 4 h. The marked similarity in cytotoxicity between oxaliplatin and tetraplatin may be due to the formation of (trans-1,2-diaminocyclohexane)dichloroplatinum(II) in tissue culture media.
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PMID:In vitro cytotoxicity, protein binding, red blood cell partitioning, and biotransformation of oxaliplatin. 826 11

Oxaliplatin is a new platinum analog of the DACH family. Recent preclinical data have confirmed its non overlapping spectrum of activity with cisplatin, including acquired and intrinsic platinum resistant cell lines (as KB-CP, A 2780, HT29, CaCo2 colon cancer). When combined with other cytotoxic agents (5FU, SN38, CDDP, carboplatin), oxaliplatin has additive and/or synergistic antitumoral effects on various in vitro and in vivo models (colon, breast, ovarian and epidermoid tumors). Phase II trials have confirmed a sensorial peripherical neuropathy as its limiting toxicity while neither ototoxicity nor renal toxicities and only limited myelotoxicity were noted. Available phase II studies have established its antitumoral activity as single agent in 5FU refractory colon carcinoma while preliminary results suggest efficacy in cisplatin resistant ovarian cancer, in non small cell lung cancer, non Hodgkin lymphoma. Antitumoral activity has been observed during phases 1 in melanoma, glioma, breast and oesophageal cancers. A high response rate (28-65%) with the triple association (FU/folinic acid/oxaliplatin) has been reported in advanced colon cancer treated in first and second line settings. The results of two randomized phase III studies (FU/folinic acid +/- oxaliplatin) are expected. The oxaliplatin/cisplatin combination as salvage regimen had produced significant antitumoral activity (response rate: 45%) in resistant/refractory ovarian cancer. Finally, recent experimental and clinical data have outlined the potential interest in the development of this new original platinum compound. New single agent phases II are expected in other tumor types as well as new oxaliplatin combinations are ongoing (phase I trials of oxaliplatin/CPT-11 and of oxaliplatin/carboplatin, phase II study of oxaliplatin-vinorelbine in lung cancer.
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PMID:[Oxaliplatin: the first DACH platinum in clinical practice]. 929 71

Oxaliplatin, classical [5-fluorouracil (5-FU)] and non-classical (AG337) thymidylate synthase inhibitors have shown promising activity in the treatment of cancer. This study investigates the cytotoxic effects of oxaliplatin in combination with 5-FU and AG337 in cultured human colon (HT29, CaCo2), breast (MCF-7, MDA-MB-231) and ovarian (2008) cancer cell lines, and their derived counterparts selected for their resistance to 5-FU (HT29-5-FU), doxorubicin (MCF-7mdr) or cisplatin (2008C13). Therapeutic experiments were conducted in mice bearing colon-HT29 xenografts and in the GR hormone-independent mammary carcinoma model. In vitro, oxaliplatin shows potent cytotoxic activity in colon (IC50 from 2.1 +/- 1.1 to 5.9 +/- 1.7 microM), ovarian (IC50 = 10 +/- 1.6 microM) and breast cancer cells (IC50 from 7.4 +/- 2.7 to 17.9 +/- 7.1 microM). Oxaliplatin was a potent inhibitor of DNA synthesis and bound to cellular DNA. Surprisingly, the overall amount of oxaliplatin DNA binding was significantly inferior to that induced by isocytotoxic concentrations of cisplatin in HT29 (p=0.026). In vitro, synergistic antiproliferative effects were observed when oxaliplatin was added to 5-FU and AG337. Those synergistic effects of combinations were maintained in colon HT29-5-FU cancer cells. In vivo, 5-FU increased significantly the antitumor activity of oxaliplatin in HT29 xenografts (p=0.0036), and similarly 5-FU and AG337 increased the activity of oxaliplatin in the GR tumor model (p=0.0012). These data may encourage further clinical investigation of oxaliplatin in combination with classical and non-classical thymidylate synthase inhibitors in the treatment of human cancers.
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PMID:Antitumor activity of oxaliplatin in combination with 5-fluorouracil and the thymidylate synthase inhibitor AG337 in human colon, breast and ovarian cancers. 940 15

This study was conducted to identify tumor types warranting Phase II clinical trials of oxaliplatin using the human tumor cloning assay. Oxaliplatin was tested at concentrations ranging from 0.5 to 50.0 microg/ml in 1-h and 14-day continuous exposures along with 1.4 microg/ml carboplatin and 0.2 microg/ml cisplatin for comparison. We defined in vitro response as tumor growth inhibition >50% of control. In the 1-h exposure schedule, in vitro responses were observed in 9 of 116 (8%), 18 of 115 (16%), 38 of 103 (37%), and 7 of 13 (54%) tumor specimens at concentrations of 0.5, 5.0, 10.0, and 50.0 microg/ml oxaliplatin, respectively. In the 14-day exposure schedule, in vitro responses were observed in 10 of 121 (8%), 37 of 121 (31%), 57 of 106 (54%), and 15 of 15 (100%) tumor specimens at concentrations of 0.5, 5.0, 10.0, and 50.0 microg/ml oxaliplatin, respectively. Activity was observed against colon cancer, non-small cell lung cancer, gastric cancer, and melanoma colony-forming units. In both cisplatin-resistant and cisplatin-sensitive tumors, the activity of oxaliplatin was concentration and time dependent. A 1-h exposure to 5.0 and 10.0 microg/ml oxaliplatin led to 7.4 and 23.4% in vitro responses, respectively, in specimens resistant to 1-h exposure of 0.2 microg/ml cisplatin. Moreover, 1-h exposures to 5.0 microg/ml and 10.0 microg/ml oxaliplatin showed in vitro antitumor responses in 10.2 and 24.3%, 17.2 and 34.5%, 10.0 and 20.0%, 6.7 and 16.7%, and 11.4 and 34.3% of specimens resistant to 1.4 microg/ml carboplatin, 6.0 microg/ml 5-fluorouracil, 3.0 microg/ml irinotecan, 10.0 microg/ml paclitaxel, and 0.04 microg/ml doxorubicin, respectively. The effect in those drug-resistant specimens was improved when oxaliplatin was used on the protracted exposure regimen. Our data indicate that oxaliplatin is an active drug in vitro against a large variety of human tumors. Both concentration and duration of exposure are important factors for oxaliplatin cytotoxicity. The broad spectrum of activity and the in vitro activity against some tumors primarily resistant to conventional anticancer drugs encourage further clinical investigations of oxaliplatin in patients with advanced cancer refractory to conventional chemotherapy.
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PMID:Activity of oxaliplatin against human tumor colony-forming units. 956 98

Oxaliplatin, a platinum-based chemotherapeutic agent with a 1,2-diaminocyclohexane (DACH) carrier ligand, has shown in vitro and in vivo efficacy against many tumor cell lines, including some that are resistant to cisplatin and carboplatin. The retention of the bulky DACH ring by activated oxaliplatin is thought to result in the formation of platinum-DNA adducts, which appear to be more effective at blocking DNA replication and are more cytotoxic than adducts formed from cisplatin. Studies by the National Cancer Institute (NCI) have suggested that oxaliplatin has a spectrum of activity different from that of either cisplatin or carboplatin, suggesting that it has different molecular targets and/or mechanisms of resistance. Oxaliplatin has been demonstrated to differ in some mechanisms associated with the development of cisplatin resistance. Compared with cisplatin-conditioned cells, deficiencies in mismatch repair (MMR) and increases in replicative bypass, which appear to contribute to cisplatin resistance, have not been shown to induce a similar resistance to oxaliplatin. A decreased likelihood of resistance development makes oxaliplatin a good candidate for first-line therapy. Studies also demonstrate additive and/or synergistic activity with a number of other compounds, however, suggesting the possible use of oxaliplatin in combination therapies.
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PMID:Oxaliplatin: mechanism of action and antineoplastic activity. 960 3

Oxaliplatin is a clinical anticancer drug with a pharmacological profile distinct from that of cisplatin. Our studies compared site- and region-specificity of lesions induced by oxaliplatin and cisplatin in naked and intracellular DNA, respectively. Oxaliplatin adducts in naked Simian virus 40 (SV40 DNA) were mapped by repetitive primer extension. The sites of oxaliplatin adducts were nearly identical to the sites of cisplatin adducts and were focused in G clusters and GNG motifs probably reflecting intrastrand cross-links. Although alkaline agarose electrophoresis of specific SV40 fragments showed that oxaliplatin formed interstrand cross-links, the levels of this lesion type were low. Drug-induced lesions in discrete loci of cellular DNA were assessed by the polymerase chain reaction stop assay in human tumor A2780 cells. Oxaliplatin at 200 microM induced approximately 1300, approximately 1500, approximately 800, and approximately 300 lesions/10(6) bp in the human beta-globin, c-myc, and HPRT genes and in mitochondrial DNA, respectively. Cisplatin formed two to six times more lesions in the same regions. For both drugs, lesion frequencies seem to parallel the density of drug-binding motifs in the nuclear regions, whereas mitochondrial DNA was disproportionately less affected. Despite less potent induction of DNA lesions, oxaliplatin was more cytotoxic than cisplatin against A2780 cells. Because our findings clearly demonstrate that oxaliplatin forms covalent adducts with a similar sequence- and region-specificity to that of cisplatin, other properties of oxaliplatin adducts, factors other than DNA binding, or both determine the unique features of the mechanism of action of oxaliplatin.
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PMID:Sequence- and region-specificity of oxaliplatin adducts in naked and cellular DNA. 980 12

Damage to cellular DNA is believed to determine the antiproliferative properties of platinum (Pt) drugs. This study characterized DNA damage by oxaliplatin, a diaminocyclohexane Pt drug with clinical antitumor activity. Compared with cisplatin, oxaliplatin formed significantly fewer Pt-DNA adducts (e.g., 0.86+/-0.04 versus 1.36+/- 0.01 adducts/10(6) base pairs/10 microM drug/1 h, respectively, in CEM cells, P<.01). Oxaliplatin was found to induce potentially lethal bifunctional lesions, such as interstrand DNA cross-links (ISC) and DNA-protein cross-links (DPC) in CEM cells. As with total adducts, however, oxaliplatin produced fewer (P<.05) bifunctional lesions than did cisplatin: 0.7+/-0.2 and 1.8+/-0.3 ISC and 0.8+/-0.1 and 1.5+/-0.3 DPC/10(6) base pairs/10 microM drug, respectively, after a 4-h treatment. Extended postincubation (up to 12 h) did not compensate the lower DPC and ISC levels by oxaliplatin. ISC and DPC determinations in isolated CEM nuclei unequivocally verified that oxaliplatin is inherently less able than cisplatin to form these lesions. Reactivation of drug-treated plasmids, observed in four cell lines, suggests that oxaliplatin adducts are repaired with similar kinetics as cisplatin adducts. Oxaliplatin, however, was more efficient than cisplatin per equal number of DNA adducts in inhibiting DNA chain elongation ( approximately 7-fold in CEM cells). Despite lower DNA reactivity, oxaliplatin exhibited similar or greater cytotoxicity in several other human tumor cell lines (50% growth inhibition in CEM cells at 1.1/1.2 microM, respectively). The results demonstrate that oxaliplatin-induced DNA lesions, including ISC and DPC, are likely to contribute to the drug's biological properties. However, oxaliplatin requires fewer DNA lesions than does cisplatin to achieve cell growth inhibition.
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PMID:Oxaliplatin-induced damage of cellular DNA. 1104 38

The new platinum compound oxaliplatin (Eloxatin) appears to have activity, either alone or in combination, as both first- and second-line therapy for advanced colorectal cancer. Unlike other platinum derivatives, it is not associated with significant nephrotoxicity or ototoxicity. The addition of oxaliplatin at 85 mg/m2 to a fluorouracil/leucovorin-based regimen administered every 2 weeks is well tolerated. The incidence of diarrhea and stomatitis increases with the addition of oxaliplatin, but can be managed by adjusting the dose. There is also a significantly higher incidence of grade 3 or 4 neutropenia with oxaliplatin. Neutropenic febrile complications are rare. The occurrence of other hematologic, hepatic, or renal toxicities does not increase when oxaliplatin is added to fluorouracil-based regimens. Unlike other agents used for the treatment of colorectal cancer, oxaliplatin causes acute and chronic neurosensory symptoms. These acute symptoms are managed by taking precautions (e.g., avoid cold drinks/food for a few days following treatment). Cumulative neurotoxicity is the dose-limiting toxicity associated with oxaliplatin treatment. This toxicity appears reversible with discontinuation of the drug and typically occurs well after the onset of tumor response.
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PMID:Safety of oxaliplatin in the treatment of colorectal cancer. 1120 57

Oxaliplatin (Eloxatin) has demonstrated significant activity in a variety of tumor types in addition to colorectal cancer. Several studies have reported on the effectiveness of oxaliplatin as single-agent treatment or in combination with cisplatin (Platinol) or paclitaxel (Taxol) in pretreated advanced ovarian cancer patients, with promising data reported for the combination of oxaliplatin and cisplatin as first-line therapy. Other small studies have shown the activity of single-agent oxaliplatin in anthracycline-resistant metastatic breast cancer and refractory non-Hodgkin's lymphoma. Data have also demonstrated the activity of oxaliplatin in combination with gemcitabine (Gemzar) in advanced pancreatic cancer. In recurrent germ-cell cancer, a "biplatin" regimen of oxaliplatin plus cisplatin was found to be effective salvage therapy. Data from these studies indicate that oxaliplatin is active in both platinum-resistant disease and in tumor types that have previously been unresponsive to platinum treatment. Moreover, it enhances the effect of cisplatin or carboplatin, which is a striking demonstration of differing mechanisms of action. Ongoing and planned trials will evaluate the efficacy of oxaliplatin in other disease settings and combinations.
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PMID:Oxaliplatin in tumors other than colorectal cancer. 1120 61


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