digitoxin and oleandrin

Cardiac glycosides have been reported to exhibit cytotoxic activity against several different cancer types, but studies against colorectal cancer are lacking. In a screening procedure aimed at identifying natural products with activity against colon cancer, several cardiac glycosides were shown to be of interest, and five of these were further evaluated in different colorectal cancer cell lines and primary cells from patients. Convallatoxin (1), oleandrin (4), and proscillaridin A (5) were identified as the most potent compounds (submicromolar IC50 values), and digitoxin (2) and digoxin (3), which are used in cardiac disease, exhibited somewhat lower activity (IC50 values 0.27-4.1 microM). Selected cardiac glycosides were tested in combination with four clinically relevant cytotoxic drugs (5-fluorouracil, oxaliplatin, cisplatin, irinotecan). The combination of 2 and oxaliplatin exhibited synergism including the otherwise highly drug-resistant HT29 cell line. A ChemGPS-NP application comparing modes of action of anticancer drugs identified cardiac glycosides as a separate cluster. These findings demonstrate that such substances may exhibit significant activity against colorectal cancer cell lines, by mechanisms disparate from currently used anticancer drugs, but at concentrations generally considered not achievable in patient plasma.

Topics: Antineoplastic Agents; Antineoplastic Combined Chemotherapy Protocols; Camptothecin; Cardenolides; Colonic Neoplasms; Digitoxin; Digoxin; Drug Screening Assays, Antitumor; HT29 Cells; Humans; Irinotecan; NF-kappa B; Proscillaridin; Strophanthins

The microparticle enzyme immunoassay (MEIA for digoxin (Abbott Laboratories, Abbott Park, Ill) requires no sample pretreatment and is widely used in clinical toxicology laboratories for monitoring serum digoxin concentrations. One advantage of the new MEIA is the lower cross-reactivities with such cross-reactants as digitoxin, oleandrin, and bufalin compared with the fluorescence polarization immunoassay (FPIA)for digoxin. Digitoxin, oleandrin, and bufalin showed positive cross-reactivity with MEIA and FPIAs for digoxin in the absence of the primary analyte, digoxin. A surprising finding was that digoxin concentrations were falsely decreased by these cross-reactants when serum pools containing digoxin were supplemented with various concentrations of these cross-reactants and when digoxin concentrations were measured by the MEIA. In contrast, digoxin concentrations were falsely elevated when measured by the FPIA. For example, when a serum pool containing 2.15 nmol/L of digoxin was supplemented with 129.5 nmol/L of bufalin, the apparent digoxin concentrations were 1.45 nmol/L with the MEIA and 3.00 nmol/L with the FPIA. Taking the advantage of only 25% protein binding of digoxin and more than 95% protein binding of digitoxin and bufalin, we demonstrated that monitoring free digoxin instead of total digoxin eliminated negative interference of digoxin by these cross-reactants in the MEIA and positive interference in the FPIA. Although oleandrin is also strongly bound to serum protein, high concentrations of oleandrin still modestly affect the free digoxin assay for both MEIA and FPIAs.

Topics: Bufanolides; Cardenolides; Cardiac Glycosides; Cardiotonic Agents; Cross Reactions; Digitoxin; Digoxin; False Positive Reactions; Fluorescence Polarization Immunoassay; Humans; Immunoenzyme Techniques; Microspheres

Oleandrin plant poisoning is common in children and the plant extract is used in Chinese medicines. The toxicity is due to oleandrin and the deglycosylated metabolite oleandrigenin. Bufalin and cinobufotalin (toad cardiac toxins) are also widely used in Chinese medicines like Chan SU, and Lu-Shen -WU. Severe toxicity from bufalin after consumption of toad soup has been reported. Taking advantage of structural similarities of these toxins with digitoxin, we demonstrated that these compounds can be rapidly detected in blood by the fluorescence polarization immunoassay for digitoxin. The cross reactivities of these compounds with digoxin assay were much lower. For example, when a drug free serum was supplemented with 10 microg/ml of oleandrin, we observed 127.7 ng/ml of digitoxin equivalent but only 2.4 ng/ml of digoxin equivalent concentration. Digibind neutralized all cardiac toxins studied as evidenced by significant fall of free concentrations. When aliquots of serum pool containing 50.0 microg/ml of oleandrin were supplemented with 0, 10.0, 25.0, 50.0, 100, and 200 microg/ml of digibind, the mean free concentrations were 30.6, 23.3, 16.0, 10.7, 7.8 and 5.5 microg/ml respectively. Similarly, with 50.0 microg/ml of oleandrigenin (total concentration: 36.2 ng/ml), the free concentration was 14.5 ng/ml digitoxin equivalent in the absence of digibind and 5.4 ng/ml in the presence of 200 microg/ml of digibind. In another specimen containing 500 ng/ml bufalin (total concentration: 156.9 ng/ml), the free concentration was 8.6 ng/ml in the absence of digibind and none detected in the presence of 100.0 microg/ml digibind. Because such neutralization may also occur in vivo, digibind may be useful in treating patients exposed to these toxins.

Topics: Bufanolides; Cardenolides; Cardiotonic Agents; Chromatography, High Pressure Liquid; Cross Reactions; Digitoxin; Digoxin; Humans; Immunoassay; Immunoglobulin Fab Fragments; Mass Spectrometry; Neutralization Tests

Toxicity from ingestion of the oleander plant is common. Oleandrin, the oleander glycoside, has structural similarity to cardiac glycoside digoxin and is known to cross react with various digoxin immunoassays. The authors studied the cross reactivity of oleandrin and its deglycosylated congener oleandrigenin with a fluorescence polarization immunoassay for digitoxin and compared their results with a new chemiluminescent assay for digitoxin on the Automated Chemiluminescent System (ACS:180 Plus) from Chiron Diagnostics. Even though the chemiluminescent assay has been reported to be comparable with the fluorescence polarization assay among normal patient population, oleandrin and oleandrigenin showed very high cross reactivities with the fluorescence polarization immunoassay and minimal cross reactivity with the new chemiluminescent assay. When the authors supplemented a serum specimen containing no digitoxin with 50 micrograms/ml of oleandrin, the fluorescence polarization assay recorded a value of 535.7 ng/ml of digitoxin equivalent, whereas the new chemiluminescent assay recorded a value of 10.3 ng/ml of digitoxin equivalent. The cross reactivity of oleandrigenin with the fluorescence polarization immunoassay for digitoxin was significantly lower than oleandrin. The presence of oleandrin also falsely elevated total digitoxin level in a specimen supplemented with digitoxin and oleandrin. The authors also measured free digitoxin concentration by the fluorescence polarization immunoassay in the ultrafiltrate of serum supplemented with digitoxin and oleandrin. Because digitoxin and oleandrin are bound strongly to protein, monitoring free digitoxin concentration by the fluorescence polarization immunoassay instead of total digitoxin concentration does not eliminate oleandrin interference. The authors conclude that fluorescence polarization immunoassay for digitoxin has a high cross reactivity with oleandrin and can falsely elevate digitoxin concentration in the presence of oleandrin, whereas the new chemiluminescent assay for digitoxin is almost free from interferences from oleandrin.

Topics: Anti-Arrhythmia Agents; Cardenolides; Cross Reactions; Digitoxin; Fluorescence Polarization Immunoassay; Immunoassay; Luminescent Measurements

Poisoning from the oleander plant is common. Taking advantage of the high cross-reactivity of oleandrin, the major cardiac glycoside found in the oleander plant, we demonstrated that the serum digitoxin assay can be successfully used for the rapid diagnosis of oleander poisoning. Digitoxin is rarely used for treatment of cardiac disorders in the United States and has a therapeutic range of 19.7 to 39.3 nmol/L. In a typical oleander poisoning, serum oleandrin concentrations may reach 174 mmol/L or more. A serum specimen supplemented with 174 mmol/L of oleandrin containing no digitoxin showed an apparent digitoxin concentration of 1,272.1 nmol/L, a very high value compared with the range of the serum digitoxin assay, which is 2.6 to 104.8 nmol/L. Moreover, the response of the serum digitoxin assay with serum specimens containing various concentrations of oleandrin (and no digitoxin) is linear. Therefore, the oleandrin concentration in serum can be calculated from the apparent digitoxin concentration to access the severity of poisoning. Recently, the usefulness of the digoxin-specific Fab antibody fragment in the treatment of oleander poisoning has been described; however, no laboratory test was performed to demonstrate the progress of therapy. We demonstrated that the digoxin-specific Fab antibody can bind oleandrin in vitro, thus reducing the pharmacologically active free oleandrin. Because Fab and oleandrin bound to Fab are absent in the protein-free ultrafiltrates, monitoring the activity of free oleandrin in the ultrafiltrates can be used for monitoring the effectiveness of therapy.

Topics: Cardenolides; Cardiac Glycosides; Cross Reactions; Digitoxin; Digoxin; Fluorescence Polarization; Humans; Immunoassay; Immunoglobulin Fab Fragments; Plants, Toxic

Topics: Cardenolides; Digitoxin; Digoxin; Nerium; Ouabain; Research

Topics: Animals; Anura; Cardenolides; Cardiac Glycosides; Cardiotonic Agents; Digitoxin; Guinea Pigs; Heart; Pharmacology; Rabbits; Research