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Christopher Hwu

Department of Chemistry, Columbia University, New York, New York 10027, United States.

5 papers in the library · 106 citations · publishing 2021-2025

Papers

Pharmacological Mechanism of the Non-hallucinogenic 5-HT2A Agonist Ariadne and Analogs

ACS Chemical Neuroscience December 15, 2022 Michael J. Cunningham, Hailey A. Bock, Inis C. Serrano et al. 65 citations

Ariadne, a non-hallucinogenic analog of the hallucinogen DOM, demonstrates significant therapeutic potential in treating various conditions. In clinical trials, Ariadne led to rapid remission of psychotic symptoms in schizophrenia and improved cognition in elderly patients. It acts as a 5-HT<sub>2A</sub> receptor agonist with modest selectivity for 5-HT<sub>1</sub>, exhibiting lower signaling potency than DOM. Notably, in a Parkinson’s disease model, Ariadne alleviated severe motor deficits comparable to l-DOPA, positioning it as a promising candidate for future psychiatric and neurological therapies.

Oxa-Iboga alkaloids lack cardiac risk and disrupt opioid use in animal models.

Nature communications September 20, 2024 Václav Havel, Andrew C Kruegel, Benjamin Bechand et al. 18 citations

A new class of iboga alkaloids, called oxa-iboga, was created by modifying the iboga molecular structure to replace a key component with a benzofuran ring. These compounds lack the heart rhythm risks (proarrhythmic effects) of ibogaine and noribogaine when tested on human heart cells. In male rats, oxa-iboga compounds were more effective than ibogaine at reducing opioid use. They act as potent kappa opioid receptor agonists but produce different behavioral effects than typical kappa agonists. A single dose or short treatment with oxa-noribogaine led to long-lasting reductions in morphine, heroin, and fentanyl intake, reversed persistent opioid-induced pain sensitivity, and suppressed drug-seeking behavior in relapse models. These compounds offer a mechanistically distinct approach to treating opioid use disorder.

Molecular Design of SERTlight: A Fluorescent Serotonin Probe for Neuronal Labeling in the Brain.

Journal of the American Chemical Society April 10, 2024 Wei-Li Lee, Xavier Westergaard, Christopher Hwu et al. 18 citations

A novel small molecule fluorescent agent called SERTlight specifically labels serotonin neurons in the mammalian brain. SERTlight is a substrate for the serotonin transporter (SERT) and accumulates inside serotonin neurons, producing a bright and selective optical signal. Unlike many other agents, SERTlight does not activate serotonin receptors or other common targets and is not released by neuronal activity or drugs like MDMA. It is compatible with other imaging tools and can label distant axonal projections while allowing simultaneous measurement of serotonin release. This new tool enables detailed study of the serotonin system in health and disease.

Novel Class of Psychedelic Iboga Alkaloids Disrupts Opioid Use

bioRxiv (Cold Spring Harbor Laboratory) July 23, 2021 Václav Havel, Andrew C. Kruegel, Benjamin Bechand et al. 3 citations preprint

A new class of iboga alkaloids, called oxa-iboga, was created by modifying the iboga skeleton to include a benzofuran group. These compounds act as potent kappa opioid receptor agonists but show atypical behavioral effects compared to standard kappa psychedelics. Oxa-noribogaine, a key oxa-iboga compound, demonstrated greater therapeutic efficacy in rat models of opioid use than noribogaine, with no cardiac pro-arrhythmic potential. A single dose produced long-lasting suppression of morphine and fentanyl intake, and a short treatment regimen persistently reduced morphine intake and reinforcing efficacy. It also suppressed drug seeking in relapse models and elevated neurotrophin proteins in brain regions linked to addiction, suggesting targeted neuroplasticity. Oxa-iboga compounds are candidates for a novel pharmacotherapy for opioid use disorder.

Deciphering Ibogaine’s Matrix Pharmacology: Multiple Transporter Modulation at Serotonin Synapses

Journal of the American Chemical Society December 26, 2025 Christopher Hwu, Václav Havel, Xavier Westergaard et al. 2 citations

Ibogaine and its main metabolite noribogaine inhibit the vesicular monoamine transporter 2 (VMAT2) with submicromolar potency, as shown in cell-based assays and two-photon microscopy of mouse brain synaptic vesicle clusters. Noribogaine also induces partial serotonin release from synaptic vesicles and binds VMAT2 at a distinct site from the established inhibitor dihydrotetrabenazine. These compounds additionally inhibit plasma membrane monoamine transporters, prominently the serotonin transporter (SERT), and a novel target, organic cation transporter 2 (OCT2). Several iboga analogs display dual inhibition of VMAT2 and SERT with comparable potencies, termed "Synaptic Reuptake Inhibitors" (SynRIs). This profile explains why ibogaine and noribogaine do not induce catalepsy, unlike other VMAT2 inhibitors, and illustrates the complex "matrix pharmacology" of iboga compounds.