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Development of Bioisosteric Iboga -alkaloids as Antinociceptive and Anxiolytic Agents with Neuroprotective Effects

Abhishek Gupta, Tuhin Bhattacharya, Subhamoy Pratihar, Sabnur Parvage, Swrajit Nath Sharma, Arnab Sarkar, Akash De, Sanmoy Karmakar, Sanjit Dey, Surajit Sinha

preprint DOI: 10.1101/2025.02.24.639821

Summary

Iboga alkaloids can reverse drug addiction and modulate drug tolerance but cause severe hallucinogenic effects and cardiotoxicity by blocking the hERG potassium channel. Researchers synthesized four new benzofuran-containing iboga analogs (C1, C2, C3, C4) with a bio-isosteric replacement of indole with benzofuran. The Endo-iboga analogs (C2 and C4) showed superior anti-inflammatory and oxidative stress-relieving activity and improved restricted locomotor activity in a formalin-induced acute pain model in mice. They elevated levels of GABA, dopamine, and BDNF. C4 had a superior cardiac safety profile in C2C12 cells (IC50 = 235 µM) and caused no significant QTc prolongation in rat ECG tests, indicating potential for acute pain management without notable cardiotoxicity.

Study at a glance

Characteristics Preclinical study
Population Mice (formalin-induced acute pain model) and rats (ECG tests) and C2C12 cells
Interventions C1 C2 C3
Key finding The Endo-iboga analog C4 demonstrated significant potential for acute pain management without notable cardiotoxicity, representing a breakthrough in pain therapy innovation.

Abstract

Abstract The clinical importance of iboga alkaloids lies in their efficacy in reversing drug addiction and modulating drug tolerance. However, due to safety concerns, their use is restricted to appropriate medical supervision. These alkaloids often cause severe hallucinogenic effects due to differential binding to various brain receptors and cardiotoxicity by blocking the human ether-a-go-go-related gene (hERG) potassium channel. To create safer analogs, our group previously synthesized various benzofuran-containing iboga analogs with good opioid binding selectivity and excellent antinociceptive property. However, the present manuscript disclosed a step-economical and cost-effective synthesis of modified ibogaine/ibogamine analogs ( C1, C2, C3 & C4 ) with bio-isosteric replacement of the indole scaffold with a benzofuran moiety, and comparing their antinociceptive/anxiolytic activity with their natural counterparts. Among the synthesized iboga analogs, the Endo -iboga analogs ( C2 & C4 , epimers of C1 and C3 , respectively) not only exhibited superior anti-inflammatory and oxidative stress-relieving activity, but also effectively improved restricted locomotor activity in a formalin-induced acute pain model in mice. These Endo -iboga analogs significantly elevated the levels of inhibitory neurotransmitters (GABA and dopamine) and brain-derived neurotrophic factor (BDNF) compared to their Exo -counterparts or previously published benzofuran-containing iboga analogs lacking the tetrahydroazepine ring. Amongst, C2 and C4 , the latter exhibited superior cardiac safety profile in C2C12 cells (IC 50 = 235 µM) and showed no adverse effects on rat hearts during in vivo ECG tests, indicated by no significant QTc prolongation. Overall, the development of bioisosteric iboga analogs, particularly C4 , demonstrated significant potential for acute pain management without notable cardiotoxicity, representing a breakthrough in pain therapy innovation.

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