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Memories of traumatic experiences can lead to mental health issues such as post-traumatic stress disorder (PTSD), which can destroy a person’s life. There has been a long-debated question of whether fear attenuation involves the suppression of the original memory trace of fear by a new memory trace of safety or the rewriting of the original fear trace towards safety.
The EPFL scientists found that remote fear attenuation in the brain is connected to the activity of the same group of neurons that are also involved in storing memories. Working with mice, the scientists have located these neurons in the brain’s dentate gyrus, an area of the hippocampus that is involved in the encoding, recall, and the reduction of fear.
The mice used in the study are genetically modified to carry a “reporter” gene that produces an identifiable and measurable signal, e.g. a fluorescent protein, following neuronal activity. Using a fear-training exercise that produces long-lasting traumatic memories, the scientists first identified the subpopulation of neurons in the dentate gyrus that are involved in storing long-term traumatic memories.
The mice then underwent fear-reducing training, which resembles exposure-based therapy in humans-the most efficient form of trauma therapy in humans. When the researchers looked again into the brain of the mice, some of the neurons active at recalling the traumatic memories were still active when the animals no longer showed fear. Importantly, the less the mice were scared, the more cells became reactivated.
The researchers then reduced the excitability of the recall neurons during the exposure therapy and found that the mice showed poorer fear reduction compared to controls. But when they reduced the excitability of other neurons in the dentate gyrus, there was no such effect, showing that the recall neurons in the dentate gyrus are crucial for fear attenuation.
Finally, when the researchers enhanced the excitability of these recall neurons during the therapeutic intervention, they found that the mice showed improved fear reduction. Thus, they concluded that attenuating remote fear memories depends on the continued activity of the neurons they identified in the dentate gyrus.
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