Scientists are rethinking how depression should be treated by focusing less on reducing negative feelings and more on rebuilding the brain’s capacity for positive emotion.
Category: neuroscience
How the brain decides which memories belong together could reshape schizophrenia research
Our memories of past events are typically not isolated, but they are linked to other related memories. This ability to establish connections between related memories is highly advantageous, as it helps us to recognize familiar patterns in new situations and make predictions that can inform our decisions.
Researchers at UCLA’s Brain Research Institute recently carried out a study on mice aimed at better understanding how the brain decides what memories are connected and which ones are not. Their paper, published in Nature Neuroscience, pinpoints brain regions that could play a role in the organization of memories into coherent pools of knowledge.
“Our lab has long been interested in understanding how the brain connects related memories,” André F. de Sousa, first author of the paper, told Medical Xpress. “In everyday life, new experiences are rarely processed in isolation. Instead, they are often shaped by what we have learned before. This ability allows us to link related events, build knowledge, and use past experiences to guide future behavior. However, this process needs to be carefully controlled.”
Noninvasive deep brain stimulation technique shows early promise for treating Parkinson’s disease
A novel, noninvasive brain stimulation approach—known as transcranial temporal interference stimulation (TIs)—may offer a new way to treat motor symptoms in Parkinson’s disease without the need for surgery, according to a pilot study appearing in eBioMedicine. The technique, which uses overlapping electrical currents to selectively target deep brain regions, significantly improved movement in patients compared with a sham treatment when targeting the subthalamic nucleus.
Parkinson’s disease is a progressive neurological disorder that affects movement, often causing tremor, stiffness, and slowed motion. One of the most effective treatments for advanced symptoms is deep brain stimulation (DBS), which involves implanting electrodes into the brain. TIs may be able to achieve a similar effect—targeting the same deep brain structures —but entirely from outside the skull, using carefully calibrated electrical fields delivered through the scalp.
In the randomized, double-blind, crossover study, titled “Transcranial temporal interference stimulation targeting the subthalamic region for motor symptoms in Parkinson’s disease: a pilot, randomised, double-blind, sham-controlled crossover study,” 30 people with early-to mid-stage Parkinson’s disease received a single 20-minute session of individualized TIs targeting the subthalamic region—a key node in the brain’s motor control network—as well as a sham or placebo treatment in a separate session.
Rewiring the urge to smoke: How targeted brain stimulation may help people to quit
For many people who smoke, quitting is not just a matter of willpower. It is a tug-of-war in the brain—between the pull of reward and the ability to resist.
A study published in the Journal of Psychiatric Research suggests that shifting that balance may be possible. Using a noninvasive brain stimulation technique called repetitive transcranial magnetic stimulation, or rTMS, researchers at MUSC Hollings Cancer Center found that stimulating a specific brain region that regulates self-control significantly reduced how much people smoked.
Discovery of brain-body connection offers clues for Parkinson’s and alcohol use disorder
When danger lurks, instinct keeps us safe. It compels us to run from a burning building or wrestle a knife-wielding attacker to the ground. It also adjusts our body physiology to support these behaviors.
Survival helps explain why. But the mechanisms that link the brain and the body—the “switch” between rest and action—have long been shrouded in mystery.
A research team at Rutgers University-New Brunswick thinks they may have identified a key mechanism, and the findings may hold important clues to how diverse neurological conditions, such as alcohol use disorder and Parkinson’s, could be diagnosed and treated.
A protein directs neuronal migration in the embryonic brain
During brain development, neurons can regulate their movement until they reach their final destination thanks to a “molecular switch” involving the protein Teneurin 4 (Ten4). This protein can guide neuronal migration through mutually exclusive molecular pathways and determine the direction of nerve cells.
The discovery, published in the journal Nature Communications, improves our understanding of the molecular mechanisms that control neuronal migration and offers new insights into how the brain develops at the molecular level.
The study combines advanced techniques — structural protein studies, gene editing in animal models and super-resolution microscopy — to broaden our understanding of the origins of neurodevelopmental disorders and psychiatric or neurological conditions —schizophrenia, epilepsy, autism, bipolar disorder, etc. — which may be linked to errors in neuronal migration.
Optogenetic mediated contractility enables reversible control of microglial morphology and migration in vivo
Biermeier et al. use live imaging in zebrafish to show that microglia alternate between distinct morphological states that support brain surveillance and phagocytosis. By optogenetically controlling cytoskeletal contractility, they demonstrate programmable, reversible control of microglial behavior in the living brain.