Anna-Carin Sköld

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.

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.

Exploration of human, rat, and rabbit embryonic cardiomyocytes suggests K-channel block as a common teratogenic mechanism

AIMS Several drugs blocking the rapidly activating potassium (K(r)) channel cause malformations (including cardiac defects) and embryonic death in animal teratology studies. In humans, these drugs have an established risk for acquired long-QT syndrome and arrhythmia. Recently, associations between cardiac defects and spontaneous abortions have been reported for drugs widely used in pregnancy (e.g. antidepressants), with long-QT syndrome risk. To investigate whether a common embryonic adverse-effect mechanism exists in the human, rat, and rabbit embryos, we made a comparative study of embryonic cardiomyocytes from all three species. METHODS AND RESULTS Patch-clamp and quantitative-mRNA measurements of K(r) and slowly activating K (K(s)) channels were performed on human, rat, and rabbit primary cardiomyocytes and cardiac samples from different embryo-foetal stages. The K(r) channel was present when the heart started to beat in all species, but was, in contrast to human and rabbit, lost in rats in late organogenesis. The specific K(r)-channel blocker E-4031 prolonged the action potential in a species- and development-dependent fashion, consistent with the observed K(r)-channel expression pattern and reported sensitive periods of developmental toxicity. E-4031 also increased the QT interval and induced 2:1 atrio-ventricular block in multi-electrode array electrographic recordings of rat embryos. The K(s) channel was expressed in human and rat throughout the embryo-foetal period but not in rabbit. CONCLUSION This first comparison of mRNA expression, potassium currents, and action-potential characteristics, with and without a specific K(r)-channel blocker in human, rat, and rabbit embryos provides evidence of K(r)-channel inhibition as a common mechanism for embryonic malformations and death.

Teratogenicity of the IKr-blocker cisapride: relation to embryonic cardiac arrhythmia

Cisapride and mosapride are structurally and pharmacologically related prokinetic agents. In contrast to mosapride, cisapride causes embryonic lethality in teratology studies, and has been related to fatal cardiac arrhythmia in the adult. The arrhythmogenic potential of cisapride is linked to its potential to inhibit a specific ion channel (I(Kr)) as a side effect. Mosapride lacks I(Kr)-blocking properties. The aims of this study were (1) to compare the effects of cisapride and mosapride on embryonic heart rhythm in vitro and (2) to investigate if cisapride in vivo, has potential to induce hypoxia-related teratogenic effects as has been shown for selective I(Kr)-blockers. Cisapride induced severe embryonic bradycardia (approximately 60% decrease), and arrhythmia in 94% of the cultured rat embryos at 1000 ng/ml. Mosapride did not induce any bradycardia or arrhythmia up to 2000 ng/ml. In vivo, single dose administration of cisapride to rats on gestational day (GD) 13 caused digital reductions (8/108 fetuses, 4/9 litters) at 75 mg/kg and high incidence of embryonic death (55-82%) at 100-200 mg/kg. Identical developmental toxic effects have been described after temporary interruption of oxygen supply, and after single dose administration of selective I(Kr)-blockers, on the same GD. The results support the idea that all potent I(Kr)-blocking agents have the potential to cause embryolethality and teratogenicity, and that the adverse effects are mediated via hypoxic episodes due to embryonic arrhythmia.

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.

Comparative effects of sodium channel blockers in short term rat whole embryo culture.

This study was undertaken to examine the effect on the rat embryonic heart of two experimental drugs (AZA and AZB) which are known to block the sodium channel Nav1.5, the hERG potassium channel and the l-type calcium channel. The sodium channel blockers bupivacaine, lidocaine, and the l-type calcium channel blocker nifedipine were used as reference substances. The experimental model was the gestational day (GD) 13 rat embryo cultured in vitro. In this model the embryonic heart activity can be directly observed, recorded and analyzed using computer assisted image analysis as it responds to the addition of test drugs. The effect on the heart was studied for a range of concentrations and for a duration up to 3h. The results showed that AZA and AZB caused a concentration-dependent bradycardia of the embryonic heart and at high concentrations heart block. These effects were reversible on washout. In terms of potency to cause bradycardia the compounds were ranked AZB>bupivacaine>AZA>lidocaine>nifedipine. Comparison with results from previous studies with more specific ion channel blockers suggests that the primary effect of AZA and AZB was sodium channel blockage. The study shows that the short-term rat whole embryo culture (WEC) is a suitable system to detect substances hazardous to the embryonic heart.

Robust signal generation and analysis of rat embryonic heart rate in vitro using laplacian eigenmaps and empirical mode decomposition

To develop an accurate and suitable method for measuring the embryonic heart rate in vitro, a system combining Laplacian eigenmaps and empirical mode decomposition has been proposed. The proposed method assess the heart activity in two steps; signal generation and heart signal analysis. Signal generation is achieved by Laplacian eigenmaps (LEM) in conjunction with correlation co-efficient, while the signal analysis of the heart motion has been performed by the modified empirical mode decomposition (EMD). LEM helps to find the template for the atrium and the ventricle respectively, whereas EMD helps to find the non-linear trend term without defining any regression model. The proposed method also removes the motion artifacts produced due to the the non-rigid deformation in the shape of the embryo, the noise induced during the data acquisition, and the higher order harmonics. To check the authenticity of the proposed method, 151 videos have been investigated. Experimental results demonstrate the superiority of the proposed method in comparison to three recent methods.