A highly sensitive canine telemetry model for detection of QT interval prolongation: studies with moxifloxacin, haloperidol and MK-499.

INTRODUCTION: Preclinical evaluation of delayed ventricular repolarization manifests electrocardiographically as QT interval prolongation and is routinely used as an indicator of potential risk for pro-arrhythmia (potential to cause Torsades de Pointes) of novel human pharmaceuticals. In accordance with ICH S7A and S7B guidelines we evaluated the sensitivity and validity of the beagle dog telemetry (Integrated Telemetry Services (ITS)) model as a preclinical predictor of QT interval prolongation in humans. METHODS: Cardiovascular monitoring was conducted for 2 h pre-dose and 24 h post-dosing with moxifloxacin (MOX), haloperidol (HAL), and MK-499, with a toxicokinetic (TK) evaluation in a separate group of dogs. In both cardiovascular and TK studies, MOX (0, 10, 30 and 100 mg/kg), HAL (0, 0.3, 1, 3 mg/kg) and MK-499 (0, 0.03, 0.3 and 3 mg/kg) were administered orally by gavage in 0.5% methylcellulose. Each dog received all 4 doses using a dose-escalation paradigm. Inherent variability of the model was assessed with administration of vehicle (0.5% methylcellulose) alone for 4 days. RESULTS: Significant increases in QT(c) were evident with 10, 30 and 100 mg/kg of MOX (C(max)< or =40 microM), 0.3, 1 and 3 mg/kg of HAL (C(max)< or =0.36 microM) and 0.3 and 3 mg/kg of MK-499 (C(max)< or =825 nM) with peak increases of 45 (20%), 31 (13%), and 45 (19%) ms, respectively (p< or =0.05). DISCUSSION: In conclusion, we have demonstrated that the ITS-telemetry beagle dog exhibits low inherent intra-animal variability and high sensitivity to detect small but significant increases in QT/QT(c) interval ( approximately 3-6%) with MOX, HAL and MK-499 in the same range of therapeutic plasma concentrations attained in humans. Therefore, this dog telemetry model should be considered an important preclinical predictor of QT prolongation of novel human pharmaceuticals.

Pharmacology of L-754,142, a highly potent, orally active, nonpeptidyl endothelin antagonist.

L-754,142, (-)-N-(4-iso-propylbenzenesulfonyl)-alpha-(4-carboxyl-2-n-propy lphenoxy)-3,4- methylenedioxyphenylacetamide, is a potent nonpeptidyl endothelin antagonist (e.g., Ki: cloned human ETA = 0.062 nM: cloned human ETB = 2.25 nM), with high specificity for endothelin receptors. In vitro, L-754,142 is a potent antagonist of ET-1-induced phosphatidyl inositol hydrolysis in Chinese hamster ovary cells expressing cloned human endothelin receptors (IC50: hETA = 0.35 nM; hETB = 26 nM) and of ET-1 induced contractions in rabbit iliac artery rings (pA2 = 7.74) and rat aortic rings (pA2 = 8.7). In vivo, L-754,142 is a potent and specific antagonist of exogenously administered ET-1 or big ET-1, L-754,142 fully protects against ET-1-induced lethality in mice (AD50 = 0.26 mg/kg i.v.). The pressor response to big ET-1 in the anesthetized ferret is blocked by this compound with an ED50 value of 0.019 mg/kg i.v. L-754,142 also blocks the pressor response to big ET-1 in the conscious rat with ED50 values of 0.30 mg/kg i.v. and 0.56 mg/kg p.o. The duration of action of L-754,142 in this rat model is more than 12 hr after an oral dose of 3 mg/kg. In summary, L-754,142 is a potent, orally active ET antagonist with a long duration of action in several in vivo models.

In vivo pharmacology of an angiotensin AT1 receptor antagonist with balanced affinity for AT2 receptors.

L-163,017 (6-[benzoylamino]-7-methyl-2-propyl-3-[[2'-(N-(3-methyl-1-butoxy) carbonylaminosulfonyl)[1,1']-biphenyl-4-yl]methyl]-3H-imidazo[4,5- b]pyridine) is a potent, orally active, nonpeptide angiotensin II receptor antagonist. Conscious rats and dogs were dosed p.o. and i.v.; in both species the plasma bioequivalents are similar at the angiotensin AT1 and AT2 receptor sites indicating balanced activity is maintained in vivo. L-163,017 prevents the pressor response to intravenous (i.v.) angiotensin II in the conscious rat, dog, and rhesus monkey. L-163,017 also significantly reduces blood pressure in a renin-dependent model of hypertension, similar to an angiotensin converting enzyme inhibitor (Enalapril) and an angiotensin AT1 receptor-selective antagonist (L-159,282). These studies indicate that neither the angiotensin AT2 receptor nor bradykinin is important in the acute antihypertensive activity of angiotensin converting enzyme inhibitors or angiotensin II receptor antagonists.

Potent and orally active angiotensin II receptor antagonists with equal affinity for human AT1 and AT2 subtypes.

In order to block the effects induced by the interactions between angiotensin II (AII) and both AT1 and AT2 receptors, we have pursued the discovery of orally active non-peptide AII antagonists that exhibit potent and equal affinity for human AT1 and AT2 receptor subtypes. A series of previously prepared nanomolar (IC50) trisubstituted 1,2,4-triazolinone biphenyl-sulfonamide dual-acting AII antagonists has been modified at five different positions in order to increase AT2 binding affinity, maintain AT1 activity, and reduce the human adrenal AT2/AT1 potency ratio (IC50 ratio) from > or = 10. The targeted human adrenal potency ratio of < or = 1 was achieved with a number of compounds possessing an ethyl group at C5 of the triazolinone and a 3-fluoro substituent at the N4-biarylmethyl moiety. The most favored of these was compound 44 which exhibited subnanomolar potency at both the AT1 (rabbit aorta) and AT2 (rat midbrain) receptors, with a slight preference for the latter, and had a human adrenal AT2/AT1 IC50 ratio of 1. This tert-butyl sulfonylcarbamate with an N2-[2-bromo-5-(valerylamino)phenyl] substituent had excellent iv activity at 1 mg/kg (100% peak inhibition, > or = 4 h duration of action) and is orally active at 3 mg/kg with > 6 h duration of action in a conscious rat model. The present study shows that the NH of the amide on the N2-aryl moiety is not required for subnanomolar binding affinity to either receptor subtype, although a keto functionality at this position is essential for acceptable AT2 binding. Receptor-ligand binding interactions derived from the structure-activity relationships are discussed with respect to both receptor subtypes.

In vivo pharmacology of L-159,913, a new highly potent and selective nonpeptide angiotensin II receptor antagonist.

The present study was designed to characterize the in vivo pharmacology of L-159,913 (4-[[2'-(N-benzoylsulfamoyl)biphenyl-4-yl]-5butyl-2,4-dihydr o-2- [2-(trifluoromethyl)phenyl]-3H-1,2,4-triazol-3-one); a potent All receptor antagonist. In normotensive rats, dogs, rhesus monkeys, and chimpanzees, L-159,913 inhibited All-induced elevations in blood pressure. In conscious rats, the relative potencies (ED50) were 0.51 mg/kg i.v. and 0.72 mg/kg p.o. Duration of action with single i.v. or p.o. doses exceeded 6 hr in rats. L-159,913 was 3 times less potent than losartan in rats and equipotent to losartan in monkeys. All induced elevation of plasma aldosterone in rats was also inhibited by L-159,913. L-159,913 was antihypertensive in high renin hypertensive rats (aortic coarctation). The maximum hypotensive response to an acute dose of L-159,913 (10 mg/kg, po) was equal to that of enalaprilat (0.3 mg/kg, iv) in this renin dependent animal model. In conscious normotensive dogs, L-159,913 had a moderate diuretic, natriuretic and kaliuretic response with no effect on glomerular filtration rate, effective renal plasma flow or filtration fraction, suggesting a tubular site of action. L-159,913 is a selective and potent All receptor antagonist with good oral activity, long duration of action and antihypertensive efficacy.

Discovery of L-162,313: a nonpeptide that mimics the biological actions of angiotensin II.

L-162,313 (5,7-dimethyl-2-ethyl-3-[[4-[2(n- butyloxycarbonylsulfonamido)-5-isobutyl-3-thienyl]phenyl]methyl]- imadazo[4,5-b]pyridine) is a nonpeptide that mimics the biological actions of angiotensin II (ANG II). The intravenous administration of L-162,313 increased blood pressure in the rat. The maximum increase in mean arterial pressure (MAP) was not different from the maximum response to ANG II in the same preparation. However, the duration of the pressor response after L-162,313 greatly exceeded that of ANG II. Pretreatment with ANG II receptor antagonists, L-158,809 (AT1 selective) or saralasin, blocked the L-162,313-induced increase in MAP. Enalaprilat, an angiotensin-converting enzyme inhibitor, failed to block the MAP response to L-162,313. In vitro, L-162,313-activated phosphoinositide turnover in rat aortic smooth muscle cell cultures was also blocked by L-158,809 and losartan (DuP-753). Therefore, L-162,313 is the first reported nonpeptide ANG II receptor agonist.

In vivo pharmacology of a novel AT1 selective angiotensin II receptor antagonist, MK-996.

MK-996, N-(4'-(5,7-dimethyl-2-ethyl-3H-imidazo[4,5-b]pyridin-3-yl- methyl)1,1'-biphenyl-2-yl)-sulfonylbenzamide, is a potent, orally active, highly selective, nonpeptide angiotensin II (AII) receptor antagonist. MK-996 prevents the pressor response to intravenous AII in the conscious rat, dog, and rhesus monkey (ED50, mg/kg; oral/intravenous = 0.067/0.014, 0.035/0.017, and 0.1/0.036, respectively). In the anesthetized chimpanzee, MK-996 (1 mg/kg, iv) produces 100% (peak) inhibition of the AII pressor response and is still active (52%) at 24 h. To our knowledge this pharmacologic profile in the rat, dog, rhesus monkey, and chimpanzee presents the least species variability of any AII receptor antagonist yet described. Responses to methoxamine and arginine vasopressin are not affected by MK-996. In aortic coarcted (high renin) rats, MK-996 (3 mg/kg, by mouth) reduces blood pressure to normotensive (< 120 mm Hg) levels without reflex tachycardia. This dose of MK-996 reduces blood pressure to approximately the same level as both losartan (3 mg/kg, by mouth) and enalapril (3 mg/kg, by mouth) in this model. The duration of antihypertensive activity of MK-996 is similar to enalapril and shorter than losartan at the doses tested. Additionally, in the rat MK-996 does not potentiate the vasodepressor response to bradykinin and completely prevents the ability of AII to stimulate an increase in plasma levels of aldosterone. Therefore, MK-996 is a potent, orally active, nonpeptide AII receptor antagonist with a long duration of action, little species variability, and anti-hypertensive activity.

Triazolinone biphenylsulfonamides as angiotensin II receptor antagonists with high affinity for both the AT1 and AT2 subtypes.

Angiotensin II (AII), the endogenous peptide ligand of the AII receptor, has equivalent high affinity for both the AT1 and AT2 receptor subtypes while most of the reported nonpeptide AII antagonists are AT1-selective. In an effort to identify dual AT1/AT2 nonpeptide AII antagonists, we have pursued modifications of previously prepared trisubstituted 1,2,4-triazolinone biphenylsulfonamides which exhibited subnanomolar in vitro AT1 (rabbit aorta) AII antagonism and AT2 (rat midbrain) IC50 values of < 40 nM. Present results show that a suitable amide (or reversed amide) side chain appropriately positioned on the N2-aryl group of these compounds gave > 15-fold enhancement in AT2 binding affinity without sacrificing nanomolar AT1 potency (IC50). This added amide, combined with an appropriate choice of the N-substituent on the sulfonamide and the ortho substituent on the N2-aryl group, led to an analogue (46, L-163,-007) which exhibited subnanomolar AT1 binding affinity and an AT2/AT1 IC50 ratio of 3. This compound showed excellent iv activity at 1 mg/kg and oral efficacy at 3 mg/kg with > 6 h duration in a conscious rat model. Available data suggest that the newly introduced amide side chain, mandatory for low nanomolar binding affinity at the AT2 receptor, is well-tolerated by the AT1 receptor and has minimal effect on the in vivo properties of these molecules.

Non-peptide angiotensin II receptor antagonists. 1. Design, synthesis, and biological activity of N-substituted indoles and dihydroindoles.

A series of N-acylated indoles (12-18), N-alkylated indoles (19-24), N-acylated dihydroindoles (26-30), and N-alkylated dihydroindoles (31-34) were synthesized and evaluated in the in vitro AT1 (rabbit aorta) and AT2 (rat midbrain) binding assay. The carboxylic acid 3-[[N-(2-carboxy-3,6-dichlorobenzoyl)-5-indolyl]methyl]-5,7-dimeth yl- 2-ethyl-3H-imidazo[4,5-b]pyridine (14b) was found to be the most potent AT1 (IC50 = 0.8 nM) antagonist in the N-acylated indole series and displayed a 25-fold higher potency than the parent unsubstituted derivative 14a (AT1 IC50 = 20 nM) and a 22-fold greater potency than the corresponding dihydroindole analog 27 (AT1 IC50 = 18 nM). Replacement of the terminal carboxyl (COOH) of 14a with the bioisostere tetrazole in 16 (AT1 IC50 = 5 nM, AT2 IC50 = 130 nM) not only improved the AT1 potency by 4-fold but also resulted in a 50-fold increase in AT2 activity. In the N-alkylated indole series, the tetrazole 3-[[N-(2-tetrazol-5-yl-6-chlorobenzyl)-5- indolyl]methyl]-5,7-dimethyl-2-ethyl-3H-imidazo[4,5-b]pyridine (24) exhibited the highest AT1 (IC50 = 1 nM) activity, revealing a 230-fold increase in AT1 activity as a result of the incorporation of the isosteric tetrazole for the carboxyl (COOH) of 20 and a nearly 9-fold increase over the corresponding deschloro analog 22 (AT1 IC50 = 8.7 nM). Tetrazole 34 was identified as the most potent (AT1 IC50 = 18 nM) AT1 receptor antagonist in a structurally distinct series of compounds derived from N-alkylation of dihydroindole 25. A new class of highly potent (14b, AT1 IC50 = 0.8 nM; 24, AT1 IC50 = 1 nM) AT1-selective non-peptide AII receptor antagonists derived from N-substituted indoles and dihydroindoles is disclosed. Tetrazole 24 of the N-alkylated indole series displayed good in vivo activity by blocking the AII-induced pressor response for 5.5 h after intravenous administration in conscious normotensive rats at a 1.0 mg/kg dose level.

Non-peptide angiotensin II receptor antagonists. 2. Design, synthesis, and biological activity of N-substituted (phenylamino)phenylacetic acids and acyl sulfonamides.

The design, synthesis, and biological activity of a new class of highly potent non-peptide AII receptor antagonists derived from N-substituted (phenylamino)phenylacetic acids and acyl sulfonamides which exhibit a high selectivity for the AT1 receptor are described. A series of N-substituted (phenylamino)phenylacetic acids (9) and acyl sulfonamides (16) and a tetrazole derivative (19) were synthesized and evaluated in the in vitro AT1 (rabbit aorta) and AT2 (rat midbrain) binding assay. The (phenylamino)phenylacetic acids 9c (AT1 IC50 = 4 nM, AT2 IC50 = 0.74 microM), 9d (AT1 IC50 = 5.3 nM, AT2 IC50 = 0.49 microM), and 9e (AT1 IC50 = 5.3 nM, AT2 IC50 = 0.56 microM) were found to be the most potent AT1-selective AII antagonists in the acid series. Incorporation of various substituents in the central and bottom phenyl rings led to a decrease in the AT1 and AT2 binding affinity of the resulting compounds. Replacement of the carboxylic acid (CO2H) in 9c, 9d, and 9e with the bioisostere acyl sulfonamide (CONHSO2Ph) resulted in a (5-7)-fold increase in the AT1 potency of 16a (AT1 IC50 = 0.9 nM, AT2 IC50 = 0.2 microM), 16b (AT1 IC50 = 1 nM, AT2 IC50 = 2.9 microM), and 16c (AT1 IC50 = 0.8 nM, AT2 IC50 = 0.42 microM) and yielded acyl sulfonamides with subnanomolar AT1 activity. Incorporation of the acyl sulfonamide (CONHSO2Ph) for the CO2H of 9c not only enhanced the AT1 potency but also effected a marked increase in the AT2 potency of 16a (AT2 IC50 = 0.74 microM of 9c vs 0.2 microM of 16a) and made it the most potent AT2 antagonist in this study. Replacement of the CO2H of 9b with the bioisostere tetrazole resulted in 19 (AT1 IC50 = 15 nM) with a 2-fold loss in the AT1 and a complete loss in the AT2 binding affinity. (Phenylamino)phenylacetic acid 9c demonstrated good oral activity in AII-infused conscious normotensive rats at an oral dose of 1.0 mg/kg by inhibiting the pressor response for > 6 h. Acyl sulfonamides 16a-c displayed excellent in vivo activity by blocking the AII-induced pressor response for > 6 h after oral administration in conscious rats at a 3.0 mg/kg dose level. Both acyl sulfonamides 16a and 16c exhibited superior in vivo activity in rats compared to that of (phenylamino)phenylacetic acid 9c.

Nonpeptide angiotensin II antagonists derived from 1H-pyrazole-5-carboxylates and 4-aryl-1H-imidazole-5-carboxylates.

Two series of potential angiotensin II antagonists derived from carboxyl-functionalized "diazole" heterocycles have been prepared and evaluated. Initially, a limited investigation of 4-arylimidazole-5-carboxylates led to 2-n-butyl-4-(2-chlorophenyl)-1-[[2'-(1H-tetrazol-5-yl)biphenyl-4-y l] methyl]-1H-imidazole-5-carboxylic acid (12b), which was found to be a highly potent antagonist of the rabbit aorta AT1 receptor (IC50 0.55 nM). In conscious, normotensive rats, 12b at 0.1 mg/kg iv inhibited the pressor response to AII by 88%, with a duration of > 6 h. More extensively studied was an isosteric series of 3-alkyl-4-[[2'-(1H-tetrazol-5-yl)biphenyl-4-yl]methyl]-1H-pyrazole -5- carboxylates bearing aryl, alkyl, or aralkyl substituents at N1. These compounds were available in highly regioselective fashion via condensation of a substituted hydrazine hydrochloride with a 2-(methoxyimino)-4-oxoalkanoate intermediate. In vitro, the most potent pyrazolecarboxylic acids had n-butyl at C3 and were substituted at N1 by such groups as 2,6-dichlorophenyl (19h), 2-(trifluoromethyl)phenyl (19k), benzyl (19t), and phenethyl (19u), all with IC50 values of 0.18-0.24 nM. Although less potent in the receptor assay, 3-n-propylpyrazolecarboxylic acids were at least as effective as their butyl counterparts in vivo. Several of the pyrazolecarboxylic acid derivatives demonstrated potent, long-lasting oral activity in rats. At 1 mg/kg po, the 1-benzyl-3-butyl (19t), 1-(2,6-dichlorophenyl)-3-propyl (19v), 3-propyl-1-(2,2,2-trifluoroethyl) (19y), and 1-benzyl-3-propyl (19z) analogues all gave > or = 75% inhibition of the AII pressor response in the rat model, with duration of action > 23 h.

BRL 34915 (cromakalim) activates ATP-sensitive K+ current in cardiac muscle.

The mechanism by which the antihypertensive agent BRL 34915 (cromakalim) affects action potential duration (APD) and effective refractory period (ERP) in isolated cardiac muscle was investigated. BRL 34915 (greater than or equal to 3 microM) shortened ERP of ferret (Mustela putorius furo) and guinea pig (Cavia porcellus) papillary muscles in a concentration-dependent fashion. The reduction in ERP resulted from a decrease in APD. ERP and APD of papillary muscles were also reduced during hypoxia produced by bubbling the physiological bathing solution with N2 instead of O2. Reduction of APD during hypoxia has previously been attributed to activation of ATP-sensitive K+ channels in heart. Glyburide, an inhibitor of ATP-sensitive K+ channels, prevented or reversed the shortening of ERP and APD produced by hypoxia and BRL 34915, respectively. These results suggest that BRL 34915 acts by opening ATP-sensitive K+ channels in heart. The actions of BRL 34915 were temperature-dependent, decreasing ERP 64% at 37 degrees C, but having no effect at 22 degrees C. The effect of BRL 34915 on K+ currents was tested directly in voltage-clamped guinea pig ventricular myocytes. As observed with the papillary muscles, BRL 34915 was without effect at 22 degrees C. At 36 degrees C, BRL 34915 (after a delay) increased outward currents positive to, and less so at potentials negative to, the K+ current reversal potential. The normal inwardly rectifying current-voltage relationship for peak K+ currents during 200-msec pulses was changed to one that was nearly ohmic. The current activated by BRL 34915 was blocked by glyburide. The data support the hypothesis that BRL 34915, like hypoxia, activates ATP-sensitive K+ channels in the heart. Based upon the profound temperature sensitivity of BRL 34915 action, this activation may be indirect, perhaps by means of modulation of an enzymatic activity that regulates gating of these channels. BRL 34915 and glyburide will be valuable tools for studying the role of ATP-sensitive K+ channels in normal and abnormal cardiac function.

The development of orientation and direction selectivity in the rabbit visual cortex.

The postnatal development of orientation and direction selectivity of single cells was examined in the primary visual cortex of rabbits. The percentage of cells which were orientation-selective reached adult levels by day 30, whereas the proportion of cells which were direction-selective did not reach adult levels until day 60. Differences in the time course of development of orientation and direction selectivity, together with data previously reported on differences in the effects of deprivation on orientation and direction selectivity, suggest that (1) different mechanisms underly the organization of orientation and direction selectivity and (2) the critical periods for the effects of deprivation on orientation and direction selectivity reflect the different time course of the normal development of these two response properties.

Rat atriopeptin III alters hypothalamic neuronal activity.

The effect of pressure application of rat atriopeptin III on extracellularly recorded action potentials of 39 hypothalamic neurons was studied in chloral hydrate-anesthetized male rats. Thirteen of these neurons were histologically located within the boundaries of the paraventricular nucleus. Atriopeptin III was a potent inhibitor of the spontaneous activity of 5 (38%) of these neurons and increased the spontaneous activity of one (8%) other neuron (7 paraventricular neurons were unresponsive to atriopeptin III). Neurons not located within the paraventricular nucleus responded similarly to pressure application of atriopeptin III. Twenty-seven percent (n = 7) were inhibited and 12% (n = 3) were excited while the remaining 16 (61%) neurons were unresponsive to atriopeptin III. Similar applications of an inactive fragment of atriopeptin III (amino acid sequence 18-28) did not alter the spontaneous activity of any neuron (n = 6). These results illustrate that atriopeptin III, an atrial peptide which is also present in the brain, can alter the spontaneous activity of hypothalamic neurons. This provides additional evidence for central activity of this peptide.