Brain : a journal of neurology
June 30, 2025
Sara Costi, Chloe Wigg, Erdem Pulcu et al.
3 citations
Ketamine, long used as an anesthetic, was first identified in 2000 as a fast-acting antidepressant. A single dose alleviates depressive symptoms, including anhedonia, within hours, and effects last for days. Research in animals indicates ketamine rapidly influences brain regions involved in punishment and reward processing, reverses negative affective biases in memories, and promotes stress resilience. Translating these findings to humans is ongoing, with emerging evidence suggesting similar mechanisms in healthy volunteers and patients. Clinical use is limited by acute side effects and unknown long-term safety. Understanding ketamine's mechanisms may guide development of safer rapid-acting antidepressants.
Journal of psychopharmacology (Oxford, England)
June 25, 2026
Joost C Van Mechelen, Tobias A Wieles, Laura G J M Borghans et al.
Oral S-ketamine (S-KETPO) has poor bioavailability (9-12%) and produces much lower peak concentrations of S-ketamine but higher levels of its active metabolites norketamine and hydroxynorketamine compared to intravenous S-ketamine (S-KETIV). In 16 healthy participants, S-KETIV caused sedative, psychomotor, and psychotomimetic effects along with reductions in brain electrical activity, while the higher oral dose (0.45 mg/kg) showed limited psychotomimetic effects and smaller brain activity reductions, and the lower oral dose (0.20 mg/kg) had no effects. Safety was similar across treatments. These pharmacokinetic and pharmacodynamic differences may affect dose selection and therapeutic outcomes in treatment-resistant depression.
British journal of clinical pharmacology
June 24, 2026
Catherine M K E De Cuba, Annika A De Goede, Joost C Van Mechelen et al.
A single intravenous dose of S-ketamine produced acute and delayed effects on brain activity and motor cortex excitability that lasted up to seven days in 16 healthy adults. Intravenous S-ketamine reduced motor-evoked potential amplitude acutely and caused a sustained weakening of long-interval intracortical inhibition, which followed a linear relationship with drug concentration. Transcranial magnetic stimulation combined with electroencephalography showed acute changes in brain electrical activity across all treatments, but delayed changes only after intravenous and high-dose oral S-ketamine. Electroencephalography revealed acute decreases in alpha, beta, and delta power with eyes closed, and sustained increases in delta power with eyes open, the latter also showing a linear concentration-effect relationship. These delayed pharmacodynamic effects are distinct from acute effects and may help explain S-ketamine's antidepressant action.
bioRxiv (Cold Spring Harbor Laboratory)
February 10, 2026
Erdem Pulcu, Sara Costi, Pilar Artiach-Hortelano et al.
A single sub-anesthetic dose of ketamine reduces activity in the lateral habenula, a small midbrain structure involved in aversive learning, when healthy volunteers expect or experience unpleasant stimuli a day later. In a randomized trial with 70 adults, those who received ketamine showed attenuated habenula responses during an aversive Pavlovian conditioning task measured with 7-Tesla functional neuroimaging. Preliminary evidence suggests that reduced habenula activity during aversive learning may weaken the emotional impact of negative memories. These results support preclinical models of how ketamine may rapidly relieve depression by acting on the human habenula.