David Olson
TBD
Data updated
Research Footprint
David Olson appears in 17 tracked papers (2018–2026), most studied alongside MDMA, Psilocybin and Ibogaine, across Depressive Disorders, Substance Use Disorders (SUD) and PTSD.
Most-cited paper: Psychedelics promote structural and functional neural plasticity (1134 citations).
Frequent co-authors: Lindsay Cameron, Maxemiliano Vargas and Lee Edmunds Dunlap.
Publication Landscape
How the 17 papers Blossom tracks for David Olson line up by year, topic, and journal. These are the psychedelic-relevant papers in Blossom's records as of July 2026, not a complete bibliography.
How has David Olson's publishing grown?
SourcedTracked papers by publication year. Click a year for the running total.
Don't read as total output: only the 17 of 17 tracked papers with a recorded publication date are counted, and these are the psychedelic-relevant papers Blossom tracks, not a complete bibliography. The current year is still filling in.
What does David Olson publish on?
SourcedTracked papers per topic. Orange marks the largest research focus.
Don't read shares as adding to 100%: a paper tagged with several topics counts once per topic. These are the psychedelic-relevant papers Blossom tracks, not a complete bibliography.
Where does David Olson publish?
SourcedTracked papers per journal. Orange marks the most-used journal.
Counts the journal recorded on each tracked paper; preprints and papers with no journal on file are not shown. These are the psychedelic-relevant papers Blossom tracks, not a complete bibliography.
Background & Research
TBD
Key Impact
TBD
Collaboration Network
12 collaborators· click a node to visit their profile
Full network →Collaboration Network
See David Olson's full collaboration network, shared papers, and research connections.
Compounds
Topics
Top Collaborators
Top Collaborators
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Affiliations
Institutions, companies, and organisations David Olson is associated with.
University of California Davis
academicThe Institute for Psychedelics and Neurotherapeutics (IPN) at UC Davis explores the neuroscience of psychedelics. Under the lead of David Olson, the team conducts high-impact interdisciplinary psychedelic science using modern neurobiology and chemistry tools. Contributions by the group include discovering that psychedelics promote neural plasticity, developing a biosensor for measuring hallucinogenic potential, and designing non-hallucinogenic psychedelic analogues with therapeutic potential.
View stakeholder →University of California, San Francisco
academicUniversity of California, San Francisco (UCSF) hosts major psychedelic research activity through the Translational Psychedelic Research Program (TrPR), Neuroscape Psychedelics Division, and psychiatry-led clinical research on psychedelic-assisted therapies.
View stakeholder →Delix Therapeutics
Private BiotechDelix Therapeutics is harnessing the power of neuroplastogens, a novel class of compounds designed to bring about a new paradigm in brain health therapeutics with treatments intended to be safe, fast-acting, and long-lasting. Through its discovery platform, Delix has identified non-hallucinogenic versions of psychedelic compounds with favorable safety and therapeutic profiles. The company was co-founded in 2019 by David E. Olson and Nick Haft, building upon Olson's discovery at the University of California, Davis, of several novel psychoplastogens that have significant therapeutic potential in preclinical models, without hallucinogenic side effects. Delix's treatments are designed to address the root cause of neuropsychiatric conditions by repairing the underlying synaptic damage through targeted neuroplasticity. To date, the company has synthesized over 2000 novel psychoplastogens, many of which are analogs of known psychedelics such as ibogaine and 5-MeO-DMT. Their lead compound, zalsupindole (DLX-001), produces the same rapid and sustained structural and functional plasticity as ketamine, psilocybin, and DMT, without inducing hallucinations or dissociation. Recent Phase I data have demonstrated that DLX-001 is associated with robust signs of CNS engagement and a favorable safety and tolerability profile, with no serious adverse events reported to date. The company's compounds are tailored for swift neuronal repair and can be taken at-home, providing significant advantages to patients, their loved ones, and healthcare providers. Delix focuses on developing non-hallucinogenic psychoplastogens as scalable alternatives to first-generation hallucinogenic psychoplastogens like ketamine and psilocybin.
View stakeholder →