Claire Grant

A multi-site comparison of in vivo safety pharmacology studies conducted to support ICH S7A & B regulatory submissions

INTRODUCTION Parts A and B of the ICH S7 guidelines on safety pharmacology describe the in vivo studies that must be conducted prior to first time in man administration of any new pharmaceutical. ICH S7A requires a consideration of the sensitivity and reproducibility of the test systems used. This could encompass maintaining a dataset of historical pre-dose values, power analyses, as well as a demonstration of acceptable model sensitivity and robust pharmacological validation. During the process of outsourcing safety pharmacology studies to Charles River Laboratories, AstraZeneca set out to ensure that models were performed identically in each facility and saw this as an opportunity to review the inter-laboratory variability of these essential models. METHODS The five in vivo studies outsourced were the conscious dog telemetry model for cardiovascular assessment, the rat whole body plethysmography model for respiratory assessment, the rat modified Irwin screen for central nervous system assessment, the rat charcoal meal study for gastrointestinal assessment and the rat metabolic cage study for assessment of renal function. Each study was validated with known reference compounds and data were compared across facilities. Statistical power was also calculated for each model. RESULTS The results obtained indicated that each of the studies could be performed with comparable statistical power and could achieve a similar outcome, independent of facility. DISCUSSION The consistency of results obtained from these models across multiple facilities was high thus providing confidence that the models can be run in different facilities and maintain compliance with ICH S7A and B.

Automated recording of home cage activity and temperature of individual rats housed in social groups: The Rodent Big Brother project

Measuring the activity and temperature of rats is commonly required in biomedical research. Conventional approaches necessitate single housing, which affects their behavior and wellbeing. We have used a subcutaneous radiofrequency identification (RFID) transponder to measure ambulatory activity and temperature of individual rats when group-housed in conventional, rack-mounted home cages. The transponder location and temperature is detected by a matrix of antennae in a baseplate under the cage. An infrared high-definition camera acquires side-view video of the cage and also enables automated detection of vertical activity. Validation studies showed that baseplate-derived ambulatory activity correlated well with manual tracking and with side-view whole-cage video pixel movement. This technology enables individual behavioral and temperature data to be acquired continuously from group-housed rats in their familiar, home cage environment. We demonstrate its ability to reliably detect naturally occurring behavioral effects, extending beyond the capabilities of routine observational tests and conventional monitoring equipment. It has numerous potential applications including safety pharmacology, toxicology, circadian biology, disease models and drug discovery.

Incorporation of capillary microsampling into whole body plethysmography and modified Irwin safety pharmacology studies in rats

UNLABELLED Limited toxicokinetic data is generated during modified Irwin screen and whole body plethysmography safety pharmacology studies, due to disturbance of primary endpoints by standard blood sampling methods. We evaluated if incorporation of microsampling would impact on data quality, as providing toxicokinetic data from main test animals could reduce the need for satellite animals. METHODS A modified Irwin screen was performed, testing oral clonidine (0, 0.03, 0.1, or 0.3 mg/kg). One cohort of rats per dose level underwent standard blood sampling (post-4 h Irwin assessment), and another cohort underwent microsampling after the 0.5, 1, 2, 4 and 24 h Irwin assessments. The respiratory effects of oral theophylline (0 or 10 mg/kg) and oral baclofen (0 or 5 mg/kg), were tested using whole body plethysmography. Groups of animals underwent standard blood sampling (at end of recording at 4 h post-dose) or microsampling at either 0.5 h or 1 h intervals (4 or 8 microsamples, respectively). RESULTS Microsampling did not impact on the quality of the data generated. The expected effects of clonidine on behavioural parameters, and of theophylline and baclofen on changes in ventilatory parameters were observed at a similar magnitude and duration independent of sampling method. DISCUSSION The incorporation of multiple capillary microsamples into the modified Irwin or respiratory study did not adversely affect the primary endpoints. The capillary microsampling method is a refinement in blood sampling technique which can easily be adapted into safety pharmacology studies to generate pharmacokinetic profiles within the same animal as the primary data, thus enhancing scientific robustness and reducing the satellite animals required.

Investigation into the effect of microsampling on mouse fetuses and pregnant mice in the embryofetal development study design

The effects on fetal weights and maternal health of taking 32μL blood microsamples at the end of organogenesis in a mouse embryofetal development (EFD) study design was investigated with the aim of reducing satellite animal usage. The effects of warming, handling and sampling either 3 or 6 times on gestation day 16 was evaluated. Maternal body weight gain was transiently reduced when animals underwent warming and handling with or without microsampling. Fetal weights on gestation day 18 were reduced after 6 occasion warming and handling alone or taking samples, but not when sampling was limited to 3 timepoints. Taking 3 microsamples of 32μL had no permanent adverse effects on maternal health or toxicologically significant effects on fetal development (measured by fetal weights). This regimen could be used to generate composite toxicokinetic profiles using only 6 main test animals in mouse EFD studies provided sampling procedures were matched across groups.

Pharmacological validation of individual animal locomotion, temperature and behavioural analysis in group-housed rats using a novel automated home cage analysis system: A comparison with the modified Irwin test

BACKGROUND The ActualHCA™ system continuously monitors the activity, temperature and behavior of group-housed rats without invasive surgery. The system was validated to detect the contrasting effects of sedative and stimulant test agents (chlorpromazine, clonidine and amphetamine), and compared with the modified Irwin test (mIT) with rectal temperature measurements. METHODS Six male Han Wistar rats per group were used to assess each test agent and vehicle controls in separate ActualHCA™ recordings and mIT. The mIT was undertaken at 15, 30 mins, 1, 2, 4 and 24 h post-dose. ActualHCA™ recorded continuously for 24 h post-dose under 3 experimental conditions: dosed during light phase, dark phase, and light phase with a scheduled cage change at the time of peak effects determined by mIT. RESULTS ActualHCA™ detected an increase stimulated activity from the cage change at 1-2 h post-dose which was obliterated by chlorpromazine and clonidine. Amphetamine increased activity up to 4 h post-dose in all conditions. Temperature from ActualHCA™ was affected by all test agents in all conditions. The mIT showed effects on all 3 test agents up to 4 h post-dose, with maximal effects at 1-2 h post-dose. The maximal effects on temperature from ActualHCA™ differed from mIT. Delayed effects on activity were detected by ActualHCA™, but not on mIT. CONCLUSIONS Continuous monitoring has the advantage of capturing effects over time that may be missed with manual tests using pre-determined time points. This automated behavioural system does not replace the need for conventional methods but could be implemented simultaneously to improve our understanding of behavioural pharmacology.

Provision of food and water in rodent whole body plethysmography safety pharmacology respiratory studies – Impact on animal welfare and data quality

INTRODUCTION We evaluated the feasibility of providing food and water to rodents during whole body plethysmography (WBP) studies as a welfare improvement to standard conditions. METHODS Male Han Wistar rats or CD1 mice (n=8) were placed in WBP chambers and respiratory parameters recorded for approximately 6h on four separate occasions. On each occasion the animals were exposed to a different plethysmography chamber environment using a randomised design: no food/water (the standard conditions), water bottle, hydrating gel and wet food. In a further session, rats (n=8) were administered theophylline, or vehicle and respiratory parameters measured in the plethysmography chamber containing wet food. RESULTS Respiratory parameters of rats were not significantly altered by the provision of water or food. Providing wet food resulted in reduced body weight loss. Administration of theophylline caused the expected increase in respiratory rate. When mice were given access to hydrating gel or wet food the respiratory parameters were significantly affected; respiratory rate and tidal volume were increased. Providing wet food resulted in reduced bodyweight loss. DISCUSSION The provision of food and water did not impact on respiratory parameters in rats placed in WBP chambers. When provided with wet food, rats lost less bodyweight. Therefore, to improve welfare conditions for rats during WBP respiratory studies wet food should be provided when appropriate to the study design. In mice, provision of food and water led to changes in respiratory parameters, therefore these improvements in welfare conditions are not suitable for mice.

Rodent Big Brother: A Comparison to the Modified Irwin Test for Assessing Drug-Induced Changes in Activity and Temperature in Rates

Drug-Induced Changed in Activity and Temperature in Rats Karen Tse1, Amy Keerie1, Rowland Sillito2, Rachel Collier1, Claire Grant3, Catherine Vickers4, Kathryn Chapman4, J Douglas Armstrong2, Will S Redfern1 AstraZeneca, Fleming Building, Babraham Institute, Cambridge, CB22 3AT1, Actual Analytics Ltd, Wilkie Building, Edinburgh, EH8 9AG2, AstraZeneca, Alderley Park, Cheshire, SK10 4TG3, NC3Rs, Gibbs Building, 215 Euston Road, London, NW1 2BE4