Phospholipidosis in rats treated with amiodarone: serum biochemistry and whole genome micro-array analysis supporting the lipid traffic jam hypothesis and the subsequent rise of the biomarker BMP.

To provide mechanistic insight in the induction of phospholipidosis and the appearance of the proposed biomarker di-docosahexaenoyl (C22:6)-bis(monoacylglycerol) phosphate (BMP), rats were treated with 150 mg/kg amiodarone for 12 consecutive days and analyzed at three different time points (day 4, 9, and 12). Biochemical analysis of the serum revealed a significant increase in cholesterol and phospholipids at the three time points. Bio-analysis on the serum and urine detected a time-dependent increase in BMP, as high as 10-fold compared to vehicle-treated animals on day 12. Paralleling these increases, micro-array analysis on the liver of treated rats identified cholesterol biosynthesis and glycerophospholipid metabolism as highly modulated pathways. This modulation indicates that during phospholipidosis-induction interactions take place between the cationic amphiphilic drug and phospholipids at the level of BMP-rich internal membranes of endosomes, impeding cholesterol sorting and leading to an accumulation of internal membranes, converting into multilamellar bodies. This process shows analogy to Niemann-Pick disease type C (NPC). Whereas the NPC-induced lipid traffic jam is situated at the cholesterol sorting proteins NPC1 and NPC2, the amiodarone-induced traffic jam is thought to be located at the BMP level, demonstrating its role in the mechanism of phospholipidosis-induction and its significance for use as a biomarker.

Unexpected nasal changes in rats related to reflux after gavage dosing.

In a three-week oral gavage toxicity study in rats, a high incidence of respiratory symptoms and high mortality was noted in compound-dosed rats only. Because of audible respiration, an effect in the upper respiratory tract was suspected and the nasal cavity was included for examination. Histology revealed extensive necrosis and purulent inflammation within the nasal passages, indicative of direct irritation. Since posterior nasal regions were most affected, with food material present within the inflammatory exudates, reflux and retrograde aspiration of irritant material (possibly stomach contents with test formulation) into the nasal cavity were suspected. Lowering the dose volume and fasting the rats prior to gavage dosing substantially reduced the respiratory effects and mortality. The current article focuses on the histological changes in the nasal cavity indicative of gavage-related reflux and provides guidance on differentiation between technical gavage error and gavage-related reflux.

Gavage-related reflux in rats: identification, pathogenesis, and toxicological implications (review).

After oral gavage dosing of rats, reflux may occur, resulting in serious respiratory effects and mortality. Published information on gavage-related reflux is limited, as it has not yet been a focus of research. Nevertheless, it represents a recurrent challenge in daily toxicology practice of oral gavage dosing. The absence of clear guidance and criteria for the identification and management of reflux-induced effects can limit the ability to properly interpret toxicity study results. The review presented herein includes an overview of experimental data from gavage studies in rats, in which reflux was observed, and provides a comprehensive analysis of the literature on reflux in general and the different potential pathways contributing to gavage-related reflux in rats. The article aims to increase the awareness and understanding of the pathogenesis of gavage-related reflux and provides guidance on identification of potential risk factors, as well as interpretation of histological changes and their toxicological relevance. Furthermore, differentiation of reflux-induced effects from direct compound-related toxicity and from gavage errors is addressed in particular, and the importance of nasal histology is discussed.

Substituted azoloquinolines and -quinazolines as new potent farnesyl protein transferase inhibitors.

A series of (4-chlorophenyl)-alpha-(1-methyl-1H-imidazol-5-yl)azoloquinolines and -quinazolines was prepared. These compounds displayed potent Farnesyl Protein Transferase inhibitory activity and tetrazolo[1,5-a]quinazolines are promising agents for oral in vivo inhibition.