Home Products “Lifesaving” Low-Dose Ketamine Unlocks Rapid Relief for Depression

“Lifesaving” Low-Dose Ketamine Unlocks Rapid Relief for Depression

by Universalwellnesssystems

summary: Researchers have identified how low doses of ketamine reduce depression by selectively targeting specific NMDA receptors in the brain. Unlike the anesthetic effects of high doses, low doses of ketamine bind to the lateral groove of NMDA receptors, promoting excitatory transmission and long-term synaptic changes. This process improves symptoms of depression almost immediately and maintains symptom relief even after ketamine is metabolized.

This study provides a template for developing ketamine-like drugs that are potentially safer and can be administered orally. Pinpointing these binding sites could help scientists better understand depression and improve treatments for brain disorders.

Important facts:

  • Low doses of ketamine target specific NMDA receptor sites and enhance excitatory transmission.
  • This effect explains ketamine’s rapid and long-lasting antidepressant action.
  • The discovery of ketamine’s binding site could lead to safer oral alternatives.

sauce: university at buffalo

Neuroscientists at the University at Buffalo have identified the binding sites of low-dose ketamine and how the drug, often described as a miracle drug, reduces symptoms of major depression in just a few hours and remains effective for several days. provided important insight into what will continue.

These images show that the different binding sites on the NMDA receptor discovered by the UB team are responsible for ketamine’s unique clinical effects: as an anesthetic at high doses and as an antidepressant at very low doses. It shows. The image on the left shows ketamine bound to the central pore of the receptor, which causes its anesthetic effect. The one on the right shows ketamine bound to the side site, resulting in antidepressant effects. Credit: Jamie Abbott

Published in September molecular psychiatryThe UB discovery will also help scientists identify how depression develops in the brain and will facilitate research into the use of ketamine and ketamine-like drugs for other brain disorders.

life saving medicine

Ketamine has been used as an anesthetic since the 1960s, but the first trials using much lower doses of ketamine in 2000 showed that ketamine was rapidly effective in treating major depression and suicidal thoughts. Proven.

“Due to its rapid onset and long-lasting effect, low-dose ketamine has literally proven to be a life-saving drug,” said Gabriela K., senior author of the study and professor of biochemistry in the Jacobs School of Medicine and Biomedical Sciences. says Dr. Popescu. At U.B.

Traditional antidepressants take several months to take effect, increasing the risk that some patients may become suicidal during the early stages of treatment. Ketamine reduces depressive symptoms almost immediately, with effects lasting from a few days to up to a week after administration.

Since this observation was published in the early 2000s, clinics administering intravenous ketamine to treat depression have been established in cities across the country.

However, how ketamine achieves such dramatic antidepressant effects so quickly is poorly understood at the molecular level. This information is important not only for understanding how best to use ketamine, but also for developing similar drugs.

Selective effect on NMDA receptors

Ketamine binds to a class of neurotransmitter receptors called N-methyl-D-aspartate (NMDA) receptors. Popescu is an expert on how these receptors generate electrical signals essential for cognition, learning and memory, and how dysregulation of these signals can lead to psychiatric symptoms. .

“In this article, we demonstrate how very low concentrations of ketamine affect the activity of only a selected population of NMDA receptors,” Popescu says.

NMDA receptors are found throughout the brain and are essential for maintaining consciousness. Because of this, she explains, drugs that act indiscriminately on all NMDA receptors have unacceptable psychiatric side effects.

“We believe the selectivity revealed in our study explains how low-dose ketamine can treat major depression and prevent suicide in depressed patients,” Popescu said. says.

The study was sparked by observations in the lab of co-author Sheila Gupta, then an undergraduate at UB.

“Sheila noticed that applying ketamine to chronically active NMDA receptors had a stronger inhibitory effect than expected based on the literature,” Popescu explains. “We were interested in this contradiction.”

When ketamine’s antidepressant effects were first known, researchers tried to see how ketamine worked by applying it to synaptic currents generated by NMDA receptors, but the drug had little effect. did not show.

“This observation has led many experts to focus on receptors outside the synapse, which may mediate ketamine’s antidepressant effects,” Popescu says.

“Sheila’s observation that ketamine is a potent inhibitor of longer-active receptors prompted us to look for mechanisms other than DC blockade, which was thought to be the only effect of ketamine on NMDA receptors. He gave it to me.”

Few laboratories have this NMDA expertise

Popescu’s lab is one of the few in the world with the expertise to quantify the processes by which NMDA receptors are activated. This allowed Popescu et al. to pinpoint and measure what changed during NMDA activation when ketamine was present at very low doses versus at high doses (an anesthetic). I was able to do that.

“Because we track the activity of single receptor molecules over long periods of time, we are able to graph the entire behavioral repertoire of each receptor, and when the receptor binds a drug or “We can identify which parts of the process change when you have a mutation,” Popescu explains.

“The mechanism we have uncovered is that at low doses, ketamine only affects currents carried by receptors that have been active in the background for some time, whereas synaptic receptors that only experience short, intermittent activation are affected. “It suggests that there will be no impact,” she continued.

“This immediately increases excitatory transmission, resulting in alleviation of symptoms of depression. Additionally, increased excitability initiates the formation of new or stronger synapses, allowing ketamine to be removed from the body.” It works to maintain higher arousal levels later on, which is responsible for the long-term symptom relief observed in patients.”

UB’s research helps explain why such low doses of ketamine are effective.

“Our results show that very low nanoscale levels of ketamine are sufficient to fill the two lateral grooves of NMDA receptors, selectively slowing down extrasynaptic receptors and reducing depression. As you increase the dose, ketamine begins to spill out of the sulcus and into the pores, blocking synaptic currents, and the anesthetic effect begins,” Popescu says.

Popescu’s co-authors from the School of Arts and Sciences’ Department of Physics simulated the three-dimensional structure of the NMDA receptor and predicted the exact residues to which ketamine binds at the lateral sites. “These interactions are strong and explain the high receptor affinity for low doses of ketamine,” she says.

“Simulations show that at the high concentrations that ketamine is used as an anesthetic, it actually lodges in the central ion-conducting pore of the receptor, where it blocks ionic current from flowing through the receptor,” Popescu said. he says.

In contrast, at low concentrations, ketamine has a very different function: it binds to two symmetrical sites on the sides of the pore, and instead of stopping the current, it slows the receptor’s opening, reducing the current only slightly.

“Finding the precise binding site on the receptor provides the perfect template for developing ketamine-like drugs that can be administered orally and may not be as addictive as ketamine,” Popescu says.

The logical next step is to screen, first computationally and then experimentally, existing drugs that fit into the NMDA receptor transverse groove.

The lead authors are Dr. Jamie A. Abbott from the Department of Biochemistry and Han Wen from the Department of Physics. Other co-authors are Gupta, Wenjun Zheng Beiying Liu, and Gary J. Iacobucci.

Funding: This study was funded by the National Institutes of Health.

About this psychopharmacology and depression research news

author: Ellen Goldbaum
sauce: university at buffalo
contact: Ellen Goldbaum – University at Buffalo
image: Image credit to Jamie Abbott

Original research: Closed access.
Allosteric inhibition of NMDA receptors by low-dose ketamine” by Jamie Abbott et al. molecular psychiatry


abstract

Allosteric inhibition of NMDA receptors by low-dose ketamine

Ketamine, a general anesthetic, produces rapid and long-lasting antidepressant effects when administered at lower doses. Anesthetic levels of ketamine reduce excitatory transmission by binding deep within the pores of NMDA receptors, blocking the influx of electrical current.

In contrast, the molecular targets responsible for ketamine’s antidepressant levels remain controversial.

We investigated the effects of ketamine on NMDA receptors over a wide range of concentrations using electrophysiology, structure-based mutagenesis, and molecular and kinetic modeling.

We report functional and structural evidence that ketamine, at nanomolar concentrations, interacts with a membrane-accessible hydrophobic site of the NMDA receptor that is distinct from the established pore-blocking site.

These interactions stabilize the receptor in a pre-open state, causing incomplete voltage- and pH-dependent reduction in receptor gating.

Remarkably, this allosteric inhibition mechanism avoids activation of short-term synapse-like receptors and preferentially directs currents from receptors that are tonicly activated by ambient levels of neurotransmitters. reduce

We demonstrate here that the hydrophobic moieties explain the clinical efficacy of ketamine, which is absent from other NMDA receptor open channel blockers such as memantine, and hold promise for developing safe and effective neurostimulatory therapeutics. I suggest that it will be a good target.

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