Theoretical study of the opioid receptor selectivity of some 7-arylidenenaltrexones

Juan S. Gómez-Jeria; Luis Lagos-Arancibia; Eduardo Sobarzo-Sánchez

doi:10.4067/s0717-97072003000100011

Theoretical study of the opioid receptor selectivity of some 7-arylidenenaltrexones

Juan S. Gómez-Jeria
, Luis Lagos-Arancibia
, Eduardo Sobarzo-Sánchez

University of Chile

Producción científica: Contribución a una revista › Artículo › revisión exhaustiva

17 Citas (Scopus)

Resumen

A ZINDO/1 quantum-chemical structure-affinity relationship study is presented for the interaction of a group of 7-arylidenenaltrexones with m , k and d opioid receptors. From this work it is concluded that:

1. The internal occupied molecular orbitals are extremely important to regulate receptor affinity and, in the case of the drug-receptor interaction, they seem to play a fundamental role in receptor affinity and selectivity.

2. Receptor selectivity seems to be regulated by subtle electronic differences, sometimes at the same atomic center.

3. In 7-arylidenenaltrexones, phenyl ring D is important for the interaction with all three receptors. Here, atoms 4 and/or 17 are possible targets for modifying receptor selectivity and/or affinity.

4. Reactivity indices of a given atom are affected by substituents placed on atoms that may be very far from it. It is suggested that this may be one of the main reasons to treat the drug-receptor interaction quantum-mechanically.

Idioma original	Inglés
Páginas (desde-hasta)	61-66
Número de páginas	6
Publicación	Journal of the Chilean Chemical Society
Volumen	48
N.º	1
DOI	https://doi.org/10.4067/s0717-97072003000100011
Estado	Publicada - mar. 2003

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title = "Theoretical study of the opioid receptor selectivity of some 7-arylidenenaltrexones",

abstract = "A ZINDO/1 quantum-chemical structure-affinity relationship study is presented for the interaction of a group of 7-arylidenenaltrexones with μ, κ and δ opioid receptors. From this work it is concluded that: 1. The internal occupied molecular orbitals are extremely important to regulate receptor affinity and, in the case of the drug-receptor interaction, they seem to play a fundamental role in receptor affinity and selectivity. 2. Receptor selectivity seems to be regulated by subtle electronic differences, sometimes at the same atomic center. 3. In 7-arylidenenaltrexones, phenyl ring D is important for the interaction with all three receptors. Here, atoms 4 and/or 17 are possible targets for modifying receptor selectivity and/or affinity. 4. Reactivity indices of a given atom are affected by substituents placed on atoms that may be very far from it. It is suggested that this may be one of the main reasons to treat the drug-receptor interaction quantum-mechanically.",

keywords = "Delta receptor, Kappa receptor, KPG model, Mu receptor, Quantum pharmacology, ZINDO/1",

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AU - Gómez-Jeria, Juan S.

AU - Lagos-Arancibia, Luis

AU - Sobarzo-Sánchez, Eduardo

PY - 2003/3

Y1 - 2003/3

N2 - A ZINDO/1 quantum-chemical structure-affinity relationship study is presented for the interaction of a group of 7-arylidenenaltrexones with μ, κ and δ opioid receptors. From this work it is concluded that: 1. The internal occupied molecular orbitals are extremely important to regulate receptor affinity and, in the case of the drug-receptor interaction, they seem to play a fundamental role in receptor affinity and selectivity. 2. Receptor selectivity seems to be regulated by subtle electronic differences, sometimes at the same atomic center. 3. In 7-arylidenenaltrexones, phenyl ring D is important for the interaction with all three receptors. Here, atoms 4 and/or 17 are possible targets for modifying receptor selectivity and/or affinity. 4. Reactivity indices of a given atom are affected by substituents placed on atoms that may be very far from it. It is suggested that this may be one of the main reasons to treat the drug-receptor interaction quantum-mechanically.

AB - A ZINDO/1 quantum-chemical structure-affinity relationship study is presented for the interaction of a group of 7-arylidenenaltrexones with μ, κ and δ opioid receptors. From this work it is concluded that: 1. The internal occupied molecular orbitals are extremely important to regulate receptor affinity and, in the case of the drug-receptor interaction, they seem to play a fundamental role in receptor affinity and selectivity. 2. Receptor selectivity seems to be regulated by subtle electronic differences, sometimes at the same atomic center. 3. In 7-arylidenenaltrexones, phenyl ring D is important for the interaction with all three receptors. Here, atoms 4 and/or 17 are possible targets for modifying receptor selectivity and/or affinity. 4. Reactivity indices of a given atom are affected by substituents placed on atoms that may be very far from it. It is suggested that this may be one of the main reasons to treat the drug-receptor interaction quantum-mechanically.

KW - Delta receptor

KW - Kappa receptor

KW - KPG model

KW - Mu receptor

KW - Quantum pharmacology

KW - ZINDO/1

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JO - Journal of the Chilean Chemical Society

JF - Journal of the Chilean Chemical Society

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ER -

Theoretical study of the opioid receptor selectivity of some 7-arylidenenaltrexones

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