Yasuki Akie

Microminipig, a non-rodent experimental animal optimized for life science research: in vivo proarrhythmia models of drug-induced long QT syndrome: development of chronic atrioventricular block model of microminipig.

A new in vivo proarrhythmia model of drug-induced long QT syndrome was developed using the Microminipig, an incredibly small minipig established by Fuji Micra Inc. (Shizuoka). The atrioventricular (AV) node of the Microminipig of either sex weighing approximately 6 - 7 kg was ablated under halothane anesthesia, and proper care was taken for them. Proarrhythmic effects of drugs were assessed at >2 months after the onset of AV block using a Holter recording system. Oral administration of dl-sotalol (10 mg/kg) to the AV-block Microminipig prolonged the QT interval; moreover, it frequently induced dangerous ventricular premature beats, whereas no arrhythmia was detected after the vehicle administration (n = 4). Such dl-sotalol-induced ventricular arrhythmias were not detected in the intact Microminipig with sinus rhythm, although significant QT prolongation was observed (n = 4). Thus, the sensitivity and specificity of the AV-block Microminipig for detecting the drug-induced long QT syndrome can be considered to be comparable to previously established AV-block animal models of dogs and monkeys.

Halothane-Anaesthetized, Closed-Chest, Guinea-Pig Model for Assessment of Drug-Induced QT-Interval Prolongation

For the halothane-anaesthetized, closed-chest, guinea-pig model, corrected QT interval (QTc) has been empirically used to estimate the extent of drug-induced QT-interval prolongation. In the present study, we employed an atrial pacing method to clarify a net effect of a drug on the QT interval in this model. The atrial pacing catheter was inserted via the jugular vein with a minimal surgical invasion, and the effects of d-sotalol (0.3 and 3 mg/kg, intravenously) and verapamil (0.01 and 0.1 mg/kg, intravenously) on electrocardiogram parameters were assessed under the sinus rhythm and during the atrial pacing of 200 and 240 beats/min. d-Sotalol significantly prolonged the QT interval in a reverse use-dependent manner and decreased the heart rate, while verapamil prolonged the PR interval without affecting the heart rate or QT interval, indicating the sensitivity and specificity of this model in assessing the pharmacodynamics of the drug-induced QT-interval prolongation. Using the QT/RR relationship under the sinus rhythm, we obtained the following two types of QT-interval correcting formulae; namely, QTc = QT - 0.207(RR - 300) by a linear regression method; and QTc = QT/(RR/300)0.332 by a non-linear regression method, the latter of which is equal to 0.67 times of Fridericias formula, providing rationale for the use of mathematical correction in this model. Thus, the halothane-anaesthetized, closed-chest, guinea-pig model may be highly useful for assessing the drug-induced QT-interval prolongation, which may become an alternative to current models for the in vivo QT assay.

Spontaneous Basal Cell Carcinoma of the Submandibular Gland in a Rat

At necropsy, a white nodule (about 5 × 3 mm in size) was observed in the right submandibular gland of a 10-week-old female GALAS rat. Histopathologically, oval to spindle-shaped and pale basophilic tumor cells proliferated closely, and formed variably sized foci. The nodule partially spread into or invaded the surrounding normal tissue, and necrotic foci were recognized in the tumor. Immunohistochemically, the nuclei of the tumor cells showed a diffusely positive reaction for p63, and the cytoplasm showed a diffusely positive reaction for cytokeratin and negative reaction for αSMA, vimentin, desmin and S-100. Many tumor cells were positive for PCNA. Ultrastructurally, the tumor cells contained many tonofilaments in the cytoplasm and a few desmosomes at the intercellular portion. Based on these findings, the tumor was diagnosed as a basal cell carcinoma originating from the duct in the rat submandibular gland.

Pharmacological characterization of microminipig as a model to assess the drug-induced cardiovascular responses for non-clinical toxicity and/or safety pharmacology studies

We tried to establish the halothane-anesthetized microminipigs as an alternative animal model for non-clinical toxicity and/or safety pharmacology studies. In order to characterize the halothane-anesthetized microminipigs, we firstly clarified the effects of halothane anesthesia on their cardiovascular system (n = 5). Then, we examined the cardiovascular effects of dl-sotalol in doses of 0.1, 0.3 and 1 mg/kg, i.v. on the halothane-anesthetized microminipigs (n = 6). Induction of the halothane anesthesia by itself prolonged the QT interval as well as QTcF, suggesting that the halothane anesthesia can reduce the cardiac repolarization reserve in microminipigs like in dogs. dl-Sotalol showed more potent negative chronotropic, dromotropic and hypotensive effects together with repolarization delay in microminipigs than in dogs, although each cardiovascular response to dl-sotalol was directionally similar between them, suggesting greater basal sympathetic tone and/or smaller volume of distribution of the drug in microminipigs than in dogs. Analyses of proarrhythmic surrogate markers indicate that Tpeak-Tend and short-term variability of QT interval may be more sensitive to detect the dl-sotalol-induced direct electrophysiological changes in microminipigs than in dogs, but its reverse will be true for J-Tpeakc. Thus, these results may help better understand the drug-induced cardiovascular responses in microminipigs.

Electropharmacological characterization of microminipigs as a laboratory animal using anti-influenza virus drug oseltamivir

We analyzed electropharmacological characteristics of microminipigs under halothane-anesthesia using anti-influenza virus drug oseltamivir, which has been known to possess multi-channel blocking properties, including Na+, Ca2+ and K+ channels (n = 4). Oseltamivir in doses of 0.3, 3 and 30 mg/kg was intravenously infused over 10 min with an interval of 20 min, which provided peak plasma concentrations 1.4, 7.4 and 125.5 µg/mL, respectively. The low dose did not alter any of the cardiovascular variables. The middle dose decreased the heart rate at 30 min after the start of the infusion. The high dose transiently returned the heart rate toward the baseline for 10-15 min, but decreased it for 20-60 min; decreased the mean blood pressure for 5-60 min; prolonged the PR interval for 10-60 min, and the QRS width for 10-20 min; but shortened the QT interval for 10-30 min, and the QTc for 5-60 min. Thus, oseltamivir can suppress the sinus automaticity, and atrioventricular nodal and intraventricular conduction; and decrease the mean blood pressure, extents of which were greater in microminipigs than in beagle dogs in our previous observation in spite of similar plasma concentrations, reflecting higher sensitivity of microminipigs for Na+ and Ca2+ channel inhibition than that of beagle dogs. In contrast to beagle dogs, oseltamivir shortened the repolarization period in microminipigs, indicating that oseltamivir can more potently inhibit the inward currents than the outward ones in the hearts of microminipigs. This information may help improve utilizatione of microminipigs as a laboratory animal.