Optimized glucuronidation of dual pharmacology β-2 agonists/M3 antagonists for the treatment of COPD

Abstract: Inhalation by design' concepts were developed to create novel dual pharmacology b-2 agonists-M3 antagonists, for the treatment of chronic obstructive pulmonary disorder. A key feature of this work is the combination of balanced potency and pharmacological duration with optimised glucuronidation through the incorporation of metabolically vulnerable phenols.

“…In terms of binding affinity toward the M 3 subtype and selectivity for the M 3 over the M 2 receptor, the biphenyl carbamates OFH244 ( 13m ), OFH243 ( 13n ), OFH3912 ( 14m ), and OFH3911 ( 14n ) range among the best ligands ever developed for this particular muscarinic receptor subtype. In this context, it is interesting to note that 3′-chloro substitution on the B ring already appeared in earlier studies but this effect was so far mainly exploited for the development of highly potent M 1 receptor agonists and nonselective muscarinic antagonists. ,− As briefly mentioned above, the comparably high affinities of OFH3912 ( 14m ) and OFH3911 ( 14n ) to the M 1 subtype, which is predominantly located in the CNS, postganglionic nerves, and exocrine glands, − are less problematic for the quaternary ammonium salts 14m and 14n , as these compounds are unable to pass the blood–brain barrier. For the amines OFH243 ( 13n ) and OFH244 ( 13m ), in contrast, brain penetration can basically not be excluded.…”

“…Having shown that the Phe181/Leu225 distinction between the M 2 and M 3 receptor subtypes represents an eligible starting point for the optimization of M 3 subtype-selective ligands, we continued our research on the lipophilic aromatic moieties pointing at the critical amino acids in ECL2 thereby particularly focusing on nonheterocyclic biphenyl carbamates. The biphenyl motif already was the focus of previous studies − and patents; − however, none of those focused on a more detailed exploration of substituent effects on the ring systems A and B of the biphenyl moiety (Figure ). Biphenyl carbamates such as 4a and 4b were, for example, studied by Naito, and the pharmacophoric moiety was also incorporated into bivalent ligands , addressing muscarinic and adrenergic receptors.…”

“…The biphenyl motif already was the focus of previous studies − and patents; − however, none of those focused on a more detailed exploration of substituent effects on the ring systems A and B of the biphenyl moiety (Figure ). Biphenyl carbamates such as 4a and 4b were, for example, studied by Naito, and the pharmacophoric moiety was also incorporated into bivalent ligands , addressing muscarinic and adrenergic receptors. For the most prominent example of this approach, batefenterol ( 4c ), a dosage for phase III clinical trials, was selected in 2019 …”

Regiospecific Introduction of Halogens on the 2-Aminobiphenyl Subunit Leading to Highly Potent and Selective M3 Muscarinic Acetylcholine Receptor Antagonists and Weak Inverse Agonists

“…In terms of binding affinity toward the M 3 subtype and selectivity for the M 3 over the M 2 receptor, the biphenyl carbamates OFH244 ( 13m ), OFH243 ( 13n ), OFH3912 ( 14m ), and OFH3911 ( 14n ) range among the best ligands ever developed for this particular muscarinic receptor subtype. In this context, it is interesting to note that 3′-chloro substitution on the B ring already appeared in earlier studies but this effect was so far mainly exploited for the development of highly potent M 1 receptor agonists and nonselective muscarinic antagonists. ,− As briefly mentioned above, the comparably high affinities of OFH3912 ( 14m ) and OFH3911 ( 14n ) to the M 1 subtype, which is predominantly located in the CNS, postganglionic nerves, and exocrine glands, − are less problematic for the quaternary ammonium salts 14m and 14n , as these compounds are unable to pass the blood–brain barrier. For the amines OFH243 ( 13n ) and OFH244 ( 13m ), in contrast, brain penetration can basically not be excluded.…”

“…Having shown that the Phe181/Leu225 distinction between the M 2 and M 3 receptor subtypes represents an eligible starting point for the optimization of M 3 subtype-selective ligands, we continued our research on the lipophilic aromatic moieties pointing at the critical amino acids in ECL2 thereby particularly focusing on nonheterocyclic biphenyl carbamates. The biphenyl motif already was the focus of previous studies − and patents; − however, none of those focused on a more detailed exploration of substituent effects on the ring systems A and B of the biphenyl moiety (Figure ). Biphenyl carbamates such as 4a and 4b were, for example, studied by Naito, and the pharmacophoric moiety was also incorporated into bivalent ligands , addressing muscarinic and adrenergic receptors.…”

“…The biphenyl motif already was the focus of previous studies − and patents; − however, none of those focused on a more detailed exploration of substituent effects on the ring systems A and B of the biphenyl moiety (Figure ). Biphenyl carbamates such as 4a and 4b were, for example, studied by Naito, and the pharmacophoric moiety was also incorporated into bivalent ligands , addressing muscarinic and adrenergic receptors. For the most prominent example of this approach, batefenterol ( 4c ), a dosage for phase III clinical trials, was selected in 2019 …”

Regiospecific Introduction of Halogens on the 2-Aminobiphenyl Subunit Leading to Highly Potent and Selective M3 Muscarinic Acetylcholine Receptor Antagonists and Weak Inverse Agonists

Multivalent Dual Pharmacology Muscarinic Antagonist and β2 Agonist (MABA) Molecules for the Treatment of COPD

Molecular hybridization yields triazole bronchodilators for the treatment of COPD