Improved methodology for identifying the teratogenic potential in early drug development of hERG channel blocking drugs.

Drugs blocking the potassium current IKr of the heart (via hERG channel-inhibition) have the potential to cause hypoxia-related teratogenic effects. However, this activity may be missed in conventional teratology studies because repeat dosing may cause resorptions. The aim of the present study was to investigate an alternative protocol to reveal the teratogenic potential of IKr-blocking drugs. The IKr blocker astemizole, given as a single dose (80 mg/kg) on gestation day (GD) 13 to pregnant rats caused digital defects. In whole rat embryo culture (2h) on GD 13, astemizole caused a decrease in embryonic heart rate at 20 nM, and arrhythmias at 200-400 nM. Cetirizine, without IKr-blocking properties, did not affect the rat embryonic heart in vitro. The present study shows that single dose testing on sensitive days of development, together with whole embryo culture, can be a useful methodology to better characterize the teratogenic potential of IKr-blocking drugs.

Stage-specific skeletal and visceral defects of the I(Kr)-blocker almokalant: further evidence for teratogenicity via a hypoxia-related mechanism.

BACKGROUND: As a class effect, potent I(Kr)-blockers have been shown to induce stage-specific external malformations. The aim of this study was to investigate whether I(Kr)-blockers also induce stage-specific visceral and skeletal defects and to further elucidate a proposed arrhythmia-hypoxia hypothesis. METHODS: Single oral doses of the selective I(Kr)-blocker almokalant (ALM) 25-150 micromol/kg, 7-14 dams/group, were given to Sprague-Dawley rats on gestation days (GD) 10-14, and the fetuses were examined for malformations on GD 21. One group was pretreated with the spin-trapping agent, alpha-phenyl-N-t-butylnitrone (PBN), given intraperitoneally 1 hr before ALM on GD 11. RESULTS: Cardiac ventricular septum defects and vascular malformations were observed after dosing on GD 10-11 and, to a lesser degree, on GD 12-13. Urogenital defects, absence/malposition of the postcaval lung lobe, and attenuated diaphragm were observed mainly on GD 10-11. Skeletal examination showed a high incidence of vertebral abnormalities on thoracic level on GD 10, on lower thoracic to caudal level on GD 11, and sternebral defects were observed all days. On GD 13 brachy-, oligo-, and syndactyly of the forepaw were induced, and of the hindpaw on GD 14. PBN reduced the incidence of both visceral and skeletal defects. CONCLUSIONS: The stage specificity of observed visceral and skeletal defects correlates well with what has been reported in the literature after temporary interruption of oxygen supply during the same stages of development. The protective effect by PBN present further evidence that the teratogenicity of potent I(Kr)-blockers is related to induction of hypoxia- reoxygenation injury due to embryonic cardiac arrhythmia.

Class III antiarrhythmics and phenytoin: teratogenicity due to embryonic cardiac dysrhythmia and reoxygenation damage.

Class III antiarrhythmic drugs, like almokalant, dofetilide and ibutilide, cause a spectrum of malformations in experimental teratology studies. The pattern of developmental toxic effects is very similar to those reported for phenytoin, which is an established human and animal teratogen. The toxic effects are characterised by embryonic death, decreased fetal weights, and stage specific malformations, such as distal digital reductions, orofacial clefts and cardiovascular defects. Class III antiarrhythmics decrease the excitability of cardiac cells by selectively blocking the rapid component of the delayed rectified potassium channel (IKr), resulting in prolongation of the repolarisation phase of the action potential. Phenytoin, which decrease the excitability of neurones, has recently also been shown to block IKr, in addition to its known blockade of sodium channels. Animal studies indicate that IKr is expressed in the embryo and that the embryonic heart is extremely susceptible to IKr-blockers during a restricted period in early development. At concentrations not affecting the maternal heart, the embryonic heart reacts with bradycardia, arrhythmia and cardiac arrest when exposed to such drugs. Available studies strongly support the idea that birth defects after in utero exposure to both selective and non-selective IKr-blockers (like phenytoin) are initiated by concentration dependent embryonic bradycardia/arrhythmia resulting in 1) hypoxia; explaining embryonic death and growth retardation, 2) episodes of severe hypoxia, followed by generation of reactive oxygen species within the embryo during reoxygenation, causing orofacial clefts and distal digital reductions, and 3) alterations in embryonic blood flow and blood pressure, inducing cardiovascular defects.

Developmental toxicity in the pregnant rabbit by the class III antiarrhythmic drug sotalol.

The purpose of this study was to investigate the potential of sotalol to cause developmental toxicity in the pregnant rabbit. Sotalol is a beta-adrenoceptor blocking drug which also has class III antiarrhythmic properties via Ikr channel blockade. EXPERIMENT 1: Nine pregnant New Zealand White rabbits were given doses of either 300, 225, or 150 mg/kg of sotalol during gestational days, called Days, 13-16 which resulted in total litter loss. EXPERIMENT 2: A single dose of sotalol, 100 or 150 mg/kg was administered during Days 8-17 to 15 rabbits. Dosing on Day 8, 9, or 10 resulted in a slightly higher incidence of embryonic death compared to historical controls. There was marked increased embryonic death of 55-90% (four does with total litter loss), decreased number of live foetuses per litter, and elevated mean foetal weight after dosing during Days 12-16. EXPERIMENT 3: 16 pregnant rabbits were administered single doses of sotalol of either 100, 85, 75, 60 or 50 mg/kg on Day 14. The main finding was increased embryonic death, which ranged from total litter loss to approximately 30% at 50 mg/kg. At 50 mg/kg, the maternal Cmax, AUC(1-24 hr), and t1/2 were approximately 45 microM, 340 micromol x hr/l, and 6 hr, respectively. In conclusion, sotalol treatment resulted in embryonic death in the rabbit in early pregnancy in the same way as has been seen for other drugs with Ikr blocking properties (class III antiarrhythmics) in rodents. The observed developmental toxicity in the rabbit is most likely secondary to embryonic arrhythmia as has been shown in rodent studies. The results may indicate that Ikr blocking agents are developmental toxicants across species including man.

Developmental toxicity of the class III antiarrhythmic agent almokalant in mice. Adverse effects mediated via induction of embryonic heart rhythm abnormalities.

Almokalant (ALM, CAS 123955-10-2), a class III antiarrhythmic drug, has been shown to be embryotoxic in rats. In the absence of human pregnancy outcome data, the human relevance of these findings in rats is unknown, and results from other species would indicate if these findings are of more universal interest. Therefore, this study was initiated to evaluate the potential effects in mice. ALM was given to three groups of pregnant mice (approximately 20 mice/group) during gestation days 6-15 at dose levels of 50, 125 and 300 mumol/kg. A fourth group served as a control. In addition, whole embryo culture was performed on gestation day 10 with doses of ALM ranging from 325-5200 nmol/l (approximately 17 embryos/group) in order to study if ALM had the potential to induce dysrhythmia in the embryonic mouse heart. ALM induced total embryonic death in the high dose group, and in the intermediate group the level of embryonic death was elevated and the mean foetal weights decreased. A slight increase in minor skeletal defects was observed, mainly consisting of reduced calcification of elements in the vertebral column and among the phalanges. ALM caused bradycardia in a concentration dependent manner (13-42% at 650-5200 nmol/l). Irregular heart rhythm and/or episodes of cardiac arrest were observed in one embryo at 2600 and in seven embryos at 5200 nmol/l. In conclusion, ALM caused embryotoxicity in the mouse, most likely secondary to adverse effects on the embryonic heart. The results may suggest that class III antiarrhythmics are embryotoxic also in humans.

Pharmacokinetic data support pharmacologically induced embryonic dysrhythmia as explanation to Fetal Hydantoin Syndrome in rats.

New studies suggest that the teratogenicity of phenytoin (PHT) is linked to its membrane-stabilizing pharmacological action via the rapid component of the delayed rectified potassium channel (lkr), resulting in embryonic cardiac dysrhythmia during a restricted sensitive period. In order to further elucidate this theory, PHT was administered to Sprague-Dawley rats on gestation day (GD) 11 with either a single dose of 150 or 100 mg/kg ip or 150 mg/kg po and developmental toxicity at term (GD 21) was studied. In satellite animals blood samples were withdrawn (0.5-24 h after dose) and total and free maternal plasma concentrations of PHT were measured. Pharmacokinetic data correlated well with pregnancy outcome data. At 150 mg/kg ip high concentrations of long duration (C(max) 240 microM and AUC 5300 microMhl(-1) - total) and marked developmental toxicity (embryonic death, decreased fetal weights, and orofacial clefts) were observed. After 100 mg/kg ip (C(max) 150 microM, AUC 2600 microMhl(-1) - total) only slight developmental toxicity (decreased fetal weights) was recorded and after 150 mg/kg po the plasma concentrations were even lower (C(max) 63 microM and AUC 1100 microMhl(-1) - total) and no adverse effects at all were observed. In separate experiments the effect of different concentrations of PHT on the embryonic heart was studied by adding PHT to GD 11 rat embryos cultured in vitro or by culturing GD 11 embryos from exposed dams. The decrease in heart rates was 3, 16, and 32% after culture with 50, 100, and 200 microM of PHT, respectively. After maternal administration of 150 mg/kg ip or po, the embryonic heart rate in vitro decreased by 25 and 7%, respectively, compared to controls. Altogether the results suggest that the development toxicity of PHT is caused by concentration-dependent induction of embryonic dysrhythmia and hypoxia related damage.

Teratogenicity of the class III antiarrhythmic drug almokalant. Role of hypoxia and reactive oxygen species.

The class III antiarrhythmic drug almokalant (ALM) was given to pregnant rats on Gestation Day 11 (125 micromol/kg) or 13 (25 micromol/kg). Other groups were pretreated with alpha-phenyl-N-t-butylnitrone, (PBN; 850 micromol/kg intraperitoneally) 1 h before administration of ALM or given (-)-2-oxo-4-thiazolidine carboxylic acid (OTC; 250 micromol/kg subcutaneously) 4 h before administration of ALM. PBN is a spin-trapping agent that can capture reactive oxygen species (ROS), and OTC is an antioxidant. Controls received tap water only. All groups (eight in total) consisted of 7 to 10 pregnant rats. ALM induced cardiovascular defects, orofacial clefts, and tail defects after administration on Day 11, and reduced the size of digits on Day 13. Pretreatment with PBN prevented induction of all the above-mentioned malformations by ALM. The results also indicated that OTC may have some protective effect against ALM-induced teratogenicity but not to the same extent as PBN. The results support the hypothesis that almokalant induces malformations via induction of episodes of embryonic arrhythmia/cardiac arrest, which result in hypoxia followed by reoxygenation and generation of ROS.

Postmortem changes in blood concentrations of phenytoin and carbamazepine: an experimental study.

Observations of low postmortem blood concentrations of antiepileptic drugs in cases of sudden unexpected death in epilepsy (SUDEP) have led to the assumption that noncompliance may play a role in SUDEP. However, the reliability of postmortem drug levels has been questioned. The purpose of this study was to analyze possible postmortem changes in blood concentrations of carbamazepine (CBZ) and phenytoin (PHT). New Zealand white rabbits were fed with PHT or CBZ until assumed steady state. A blood sample was then drawn for determination of serum and whole blood concentrations of CBZ and PHT, after which the rabbits were killed and stored at 6 degrees C. A further blood sample for drug analysis was obtained 72 hours after death. Antemortem serum concentrations of CBZ were not significantly different from whole blood concentration 72 hours after death. In contrast, antemortem whole blood concentrations of PHT were only 65% of the corresponding serum concentrations, and postmortem PHT blood levels were even lower, being 35% of antemortem serum concentrations. In conclusion, blood concentrations of CBZ seem to be stable during 72 hours after death under these experimental conditions. However, postmortem PHT concentrations should be interpreted with caution and low postmortem concentrations do not necessarily imply a poor compliance.

Initiation of phenytoin teratogenesis: pharmacologically induced embryonic bradycardia and arrhythmia resulting in hypoxia and possible free radical damage at reoxygenation.

The aim of this study was to investigate if phenytoin has the capacity to induce embryonic hypoxia mediated via adverse effects on the embryonic heart. Mouse embryos of different strains (CD-1, C57B1/6J and A/J) as well as Sprague Dawley (SD) rat embryos were cultured in vitro (in 75-80% rat serum) by the whole embryo technique. Effects on the heart were examined on gestational day 10 for mouse embryos and days 11 and 13 for rat embryos. Phenytoin was dissolved in water to give concentrations of 50-800 microM. In the mouse embryo studies, phenytoin caused a concentration-dependent decrease in embryonic heart rate in all three strains, with a slight decrease at 100 microM (2-7%) and a more pronounced effect at 200 microM (approximately 20%). Temporary or permanent cardiac arrest occurred in 86% of the CD-1 embryos at 500 microM, in 67% of the C57B1/6JM at 400 microM, and in all A/J embryos at 300 microM. Arrhythmias was observed in 8% in CD-1 embryos at 200 microM, in 18% at 150 microM in C57B1/6J embryos, and in 67% of the A/J embryos at 100 microM (lowest tested concentrations where arrhythmias occurred). In rat embryos, a concentration-dependent decrease in heart rate was observed on both days 11 and 13 at similar concentrations as in the mouse embryo studies. In a separate experiment, the effects on the heart rate of free phenytoin (not serum protein bound) were examined in rat embryos cultured in serum-free medium. Already at 12 microM a significant decrease in heart rate was observed. Altogether, the results support the hypothesis that phenytoin teratogenicity is initiated by pharmacologically induced embryonic hypoxia. A genetic susceptibility to the adverse effects of phenytoin on the embryonic heart may be of importance to explain strain and species differences in phenytoin teratogenicity.