Daniel McNaught Flores scite author profile

Presynaptic histamine H3 receptors (H3R) act as auto- or heteroreceptors controlling, respectively, the release of histamine and of other neurotransmitters in the central nervous system (CNS). The extracellular levels of several neurotransmitters are enhanced by H3R antagonists, and there is a great interest for potent, brain-penetrating H3 receptor antagonists/inverse agonists to compensate for the neurotransmitter deficits present in various neurological disorders. We have shown that 1-[(benzylfuran-2-yl)methyl]piperidinyl-4-oxyl- and benzyl- derivatives of N-propylpentan-1-amines exhibit high in vitro potencies toward the guinea pig H3 receptor (jejunum), with pA2 = 8.47 and 7.79, respectively (the reference compound used was thioperamide with pA2 = 8.67). Furthermore, following the replacement of 4-hydroxypiperidine with a 3-(methylamino)propyloxy chain, the pA2 value for the first group decreased, whereas it increased for the second group. Here, we present data on the impact of elongating the aliphatic chain between the nitrogen of 4-hydroxypiperidine or 3-(methylamino)propan-1-ol and the lipophilic residue. Additionally, the most active compound in this series of non-imidazole H3 receptor antagonists/inverse agonists, i.e., ADS-003, was evaluated for its affinity to the recombinant rat and human histamine H3 receptors transiently expressed in HEK-293T cells. It was shown that ADS-003, given parenterally for 5 days, reduced the food intake of rats, as well as changed histamine and noradrenaline concentrations in the rats’ brain in a manner and degree similar to the reference H3 antagonist Ciproxifan.

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Non-Imidazole Histamine H3 Ligands. Part VII. Synthesis, In Vitro and In Vivo Characterization of 5-Substituted-2-thiazol-4-n-propylpiperazines

Guryn

Staszewski

Stasiak

et al. 2018

Molecules

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H3 receptors present on histaminergic and non-histaminergic neurons, act as autoreceptors or heteroreceptors controlling neurotransmitter release and synthesis. Previous, studies have found that the compound N-methyl-N-3-phenylalkyl-2-[2-(4-n-propylpiperazin-1-yl)-1,3-thiazol-5-yl]ethan-1-amine (ADS-531, 2c) exhibits high in vitro potency toward H3 guinea pig jejunal receptors, with pA2 = 8.27. To optimize the structure of the lead compound ADS-531, a series of 5-substituted-2-thiazol-4-n-propylpiperazines 3 were synthesized and subjected to in vitro pharmacological characterization; the alkyl chain between position 2 of the thiazole ring and the terminal secondary N-methylamino function was elongated from three to four methylene groups and the N-methylamino functionality was substituted by benzyl-, 2-phenylethyl-, and 3-phenyl-propyl- moieties. SAR studies on novel non-imidazole, 5-substituted-2-thiazol-4-n-propyl-piperazines 3 showed that the most active compound 3a (pA2 = 8.38), additionally possessed a weak competitive H1-antagonistic activity. Therefore, compound ADS-531, which did not exhibit any H1-antagonistic activity, was chosen for further evaluation for its affinity to the recombinant rat and human histamine H3 receptors (rH3R and hH3R, respectively). ADS-531 exhibited nanomolar affinity for both rH3R and hH3R receptors. It was also shown that, ADS-531 given subchronically to rats (s.c. 3 mg/kg, 5 days) penetrated the brain, where it affected dopamine, noradrenaline and serotonin concentration; however, it did not affect histamine concentration nor feeding behavior.

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Effects of Hypoxia and Hyperoxia on Lung Prostaglandin E1 Metabolism

Pisarello¹,

Flores²,

Jackson³

1997

The American Journal of the Medical Sciences

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Exposure to hypoxia (10% O2 for 5 to 7 days) results in increased survival and decreased pulmonary toxicity of adult rats subsequently exposed to hyperoxia (> 97% O2). These experiments tested whether hypoxia preexposure minimized the decrease in lung metabolism of prostaglandin E1 (PGE1), a vasoactive and antiinflammatory prostaglandin, caused by hyperoxia. Transpulmonary PGE1 clearance was measured as fractional metabolism of PGE1 (2 microM to 30 microM) infused during a 45-second period in an isolated, buffer-perfused rat lung preparation after exposure of rats to one of the following conditions: (1) hyperoxia (> 97% O2 for 48 hours), (2) hypoxia (10% O2 for 120 hours), or (3) hypoxia followed by hyperoxia. Hyperoxia exposure decreased both lung PGE1 metabolism and lung prostaglandin dehydrogenase activity (PGDH). Hypoxia also decreased lung PGE1 metabolism but, in contrast, increased lung PGDH activity. Hypoxia preexposure did not prevent the depression of PGE1 metabolism or PGDH activity caused by hyperoxia, which indicates that survival in hyperoxia did not depend on lung PGE1 metabolism. Hypoxia itself impaired transpulmonary metabolism of PGE1 despite increasing PGDH activity, which suggests possible interference with substrate delivery.

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