Benchmarking safety pharmacology regulatory packages and best practice.

INTRODUCTION: The objectives of this survey were to obtain a global information update regarding current industry perspectives that describe Safety Pharmacology programs as they relate to the ICH S7A and S7B regulatory guidelines but also to obtain a broader perspective of other practises practices in the field currently used by companies. Preliminary findings were presented at the 7th Annual Meeting of the Safety Pharmacology Society (SPS) (Edinburgh, Scotland, Sept 19-21, 2007). METHODS: The survey was distributed by the SPS to 125 pharmaceutical companies. Survey topics included (a) an update on ICH S7A and S7B practices, (b) frontloading Safety Pharmacology studies prior to selection of candidate drugs, (c) abuse and dependence-liability studies and (d) an extended evaluation of industry practises practices as assessed by Contract Research Organizations (CROs). RESULTS: Respondents (>94%) include GLP core battery (CV, CNS and respiratory) studies in the drug package submitted to regulatory agencies, and approximately 40% also submit studies on gastrointestinal and renal function. Respondents to the ICH S7B aspects indicate approximately 98% include the hERG assay and QT interval (in vivo) data in submissions, 63% include APD in vitro data and another 23% APD in vivo and other cardiac channel data (26%). SP frontloading is performed by 78% of all responding companies. Respondents indicate that 39% of these non-GLP CV studies are conducted before lead optimization (LO) and 85% during LO and before candidate drug selection. The hERG, CNS selectivity binding screens and rodent behavioral studies are frontloaded by 100%, 90% and 74% of respondents. Responding CROs (26) were surveyed on the services offered including Irwin or Functional Observational Battery (FOB) tests (70%), respiratory studies (85%), in vivo telemeterized dogs (69%) and in vitro CV studies (50%). Only 38% of SP studies are combined with toxicology studies at the CROs. DISCUSSION: The survey results indicate that ICH S7A core battery studies are implemented by most of the responding companies with a clear trend of an enhanced submission of renal and GI studies. The impact of ICH S7B is clear since, all respondents assess cardiac repolarization using cellular hERG (I(Kr)) and whole animal (QT interval) assays as a component of their safety assessment. Responses indicate a diversity of approaches for conducting abuse liability studies, which primarily use the methods of self-administration and drug discrimination. While early SP frontloading of studies seems to vary, the methods used appear to be generic to some extent and include in vitro 'off-target' evaluations and in vivo tests to determine the potential for CNS and cardiovascular issues.

Non-clinical evaluation of ventricular repolarization (ICH S7B): results of an interim survey of international pharmaceutical companies.

INTRODUCTION: The propensity of drugs to cause a potentially fatal arrhythmia, torsades des pointes (TdP), is a significant public health issue. The draft International Conference on Harmonization (ICH) S7B guidelines describe a battery of non-clinical studies to evaluate a drug's potential to prolong ventricular repolarization (VR); an accepted surrogate/risk factor for TdP. A worldwide survey of pharmaceutical industry practices, related to ICH S7B was conducted. The findings were presented at the 4th Annual Meeting of the Safety Pharmacology Society (SPS) meeting (Cincinnati, OH, Sept., 2004). METHODS: The survey was distributed by the SPS to 119 pharmaceutical companies; 29 surveys were returned. Survey topics included: (a) General Strategy and Testing for Risk of QT prolongation, (b) Study Timing and Relationship to Development, and (c) Application of GLPs. RESULTS: Respondents indicate that the basis for assessing prolongation of VR was to: remove compounds with an arrhythmic risk to humans (86%), to satisfy regulatory expectations (79%), or to avoid obstacles in the clinical development of a compound (86%). Development of a compound based on prolongation of VR was halted for 52% of respondents (compared to 45% in a 2003 survey). Models used to evaluate changes in VR included: human ether a go-go related gene (hERG) (93%), action potential duration (APD) (68%; compared to 80% in the 2003 survey), and in vivo QT (100%). The distribution of assays being requested by regulatory agencies includes the hERG (83%), APD (28%), and in vivo QT (79%). In spite of uncertainty regarding the final requirements of ICH S7B, organizations continue to implement (36%) and validate (60%) their electrophysiology laboratories. SUMMARY: The survey results indicate that pharmaceutical companies are testing for VR prolongation of drug candidates and that institutions have established in-house or outsourced capabilities to evaluate this potential risk, even in the absence of final guidelines.

Respiratory function in rats restrained for extended periods: assessment of the effects of bethanecol.

INTRODUCTION: The ICH guideline S7A recommends that the effects of drugs on the respiratory system are evaluated in laboratory mammals prior to administration in man. Previously, animals have been placed in plethysmography chambers for short durations. This study investigates the possibility of restraining animals in chambers for a longer duration to assess respiratory function over extended periods. METHODS: Respiratory function in conscious rats was assessed using plethysmography chambers where the rat body was enclosed in a sealed chamber while the head was free. Thoracic movements were measured by pressure transducers linked to a Buxco amplifier system and respiratory parameters were captured and analyzed by the Notocord HEM data acquisition system. Each animal was subjected to 5 acclimatization sessions of escalating duration (1, 2, 4, 5, and 6 hours (h)) over 5 days prior to testing, with a baseline recording session conducted the day prior to dosing. Animals (8 males/group) were dosed subcutaneously with saline or bethanecol (3, 10, or 30 mg/kg) and placed in the chambers for 6 h of continuous recording. Additionally, a recording session was conducted at 24 h post-dose. RESULTS: Subcutaneous administration of 30 mg/kg bethanecol decreased respiration rate by up to 33% during the first 1.5 h post-dose and increased tidal volume by up to 46% from 0.25 to 1.25 h post-dose when compared to vehicle group data. A decrease in minute volume of up to 33% was observed 0.25 h following administration of the 10 and 30 mg/kg doses. DISCUSSION: These data show a respiratory depression caused by the cholinergic agonist bethanecol, an effect partially compensated for by an increase in tidal volume. This also demonstrates the ability to continuously restrain and record respiratory parameters in conscious rats for up to 6 h without any negative impact on the quality of the data.

Effects of the antiepileptic drugs lamotrigine, topiramate and gabapentin on hERG potassium currents.

Drugs that inhibit the cardiac rapid delayed rectifier potassium ion current (I(Kr)) can be proarrhythmic and their clinical use has been associated with sudden unexpected death (SUD) due to cardiac arrhythmia. SUD is 20-40 times more common among people with epilepsy than in the general population and case-control studies have identified polytherapy with antiepileptic drugs (AEDs) as a risk factor. In a previous study, it was described that the old AEDs phenytoin and phenobarbital had the potential to inhibit the I(Kr) channel and it was suggested that this could contribute to the increased risk for SUD in patients with epilepsy. In this study, we have investigated the I(Kr) blocking potential of some more recently introduced AEDs, lamotrigine (LTG), topiramate (TPM) and gapapentin (GBP). The whole cell patch-clamp recording technique was used to study the effects on I(Kr) channels expressed by the human ether-a-go-go related gene (hERG) stably expressed in human embryo kidney (HEK) 293 cells. Tail currents, which are purely related to hERG currents, were blocked with IC50 and IC20 (the concentrations when 50% and 20% inhibition was obtained compared to control values) of 229 and 21 microM, respectively, for LTG. A 40% inhibition of tail currents was obtained at GBP concentrations of 100 mM and a 20% inhibition at 54 mM. A 35% inhibition of tail currents was obtained at TPM concentrations of 1000 microM and a 20% inhibition at 87 microM, respectively. Collective data show that drugs with the same margins (ratio hERG IC50/unbound therapeutic concentration) as LTG, may have arrhythmogenic potential. The risk for arrhythmia may be clinically significant in the presence of predisposing factors such as seizure-induced acidosis and in the case of concurrent treatment with other I(Kr) blocking drugs, or in case of pharmacokinetic drug-drug interactions resulting in excessively high concentrations of LTG.

Phenytoin and phenobarbital inhibit human HERG potassium channels.

Drugs that inhibit the cardiac rapid delayed rectifier potassium ion current (IKr) channel can be proarrhythmic and their clinical use has been associated with sudden unexpected death (SUD). Since SUD is about 20 times more common among people with epilepsy than in the general population, and some data indicate that drug treatment may contribute, we tested the hypothesis that the classic antiepileptic drugs phenytoin (PHT), carbamazepine (CBZ), and phenobarbital (PB) have a potential to block IKr. The whole cell patch-clamp recording technique was used to study the effects on IKr channels expressed by the human ether-a-go-go related gene (HERG) stably expressed in Human Embryo Kidney (HEK) 293 cells. Tail currents, which are purely related to HERG, were blocked with an IC50 (the concentration when 50% inhibition was obtained compared to control values) of 240 microM for PHT and 3 mM for PB. A 20% inhibition of tail currents was obtained at CBZ concentrations of 250 and 500 microM. Collective data show that drugs with the same margins (ratio HERG IC50/unbound therapeutic concentration), as PHT and PB, may have arrhythmogenic potential, especially when used in predisposed patients and in the case of drug-drug interactions. SUD in epilepsy is generally a seizure-related phenomenon. However, our data suggest that PHT and PB may play a contributing role, perhaps by making some patients more vulnerable to the cardiovascular depression induced by seizures.