In Stroke due to medium or distal vessel occlusion, endovascular treatment plus best medical treatment preserved more brain tissue and was linked to improved imaging outcomes and better clinical recovery compared with medical treatment alone.

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Interventions EVT plus BMT compared with BMT alone.

Main Outcomes and Measures Primary outcome was calculated as the difference in volume of tissue at risk and the final infarct volume divided by the tissue at risk (change in Vrel). We defined a Vrel of 0.8 or greater as a good imaging outcome, meaning that at least 80% of the brain tissue initially at risk was not infarcted at 24 hours. Additionally, the association between brain tissue preserved and clinical outcome at 90 days was investigated.

Results From the 447 patients (252 [56.4%] male; median [IQR] age, 77.0 [68.0–84.0] years) included in this secondary analysis, 226 received EVT plus BMT and 221 received BMT alone. Median (IQR) time of the follow-up imaging was 22.9 (19.2−25.5) hours. Median (IQR) Time to maximum less than 6 seconds (Tmax6) volume was 34.0 (20.0−50.0) mL. Median follow-up infarct volume was 7.0 (1.0−22.9) mL. The median (IQR) change in absolute volume in the EVT plus BMT group was 23.6 (5.7−38.9) mL and 14.8 (0−30.3) mL in the BMT group. Median (IQR) change in Vrel was 0.8 (0.2−1.0) in the EVT plus BMT group and 0.6 (0−0.9) in the BMT group. Odds for reaching a change in Vrel of 0.8 or greater were higher in the EVT plus BMT group compared with BMT (adjusted odds ratio [aOR], 1.6; 95% CI, 1.1−2.3) and with successful reperfusion compared with no successful reperfusion (aOR, 2.5; 95% CI, 1.3−4.8). Patients with a change in Vrel of 0.8 or greater had a better clinical outcome at 90 days.

It is not yet known how the immune system’s discovery of the pathogens leads to a change in behavior. “As this learned food avoidance can be found in all species, we investigated this question in a model organism – the fruit fly Drosophila,” explains the senior author. “Within this model, we can clarify how the brain and body interact with each other to trigger an avoidance reaction that is vital for survival.”

In the current study, the group had their test animals choose between two food sources. One of them was contaminated with the pathogenic bacterium Pseudomonas entomophila. The other contained a harmless Pseudomonas strain. The two food sources were otherwise completely identical.

Flies that have not yet had any bad experiences with the pathogen prefer the harmful food because they find its odor attractive. “As this is life-threatening for the animals, we wondered how animals that have consumed these bacteria with their food behave,” explains the scientist.

The pathogens did not remain undiscovered among the flies for long: The animals’ innate immune system has sensors that raise the alarm in cases such as this. “In our experiment, receptors were activated in them that respond to components of the bacterial cell wall,” explains another author.

These sensors mainly respond to the harmful Pseudomonas strain, but hardly respond at all to the harmless strain. Many of them sit on the surface of special neurons located near the fly’s throat. Via their branches, these neurons are connected not only to the fly’s brain but also to a fat store in the fly’s head. If the receptors raise the alarm in the presence of harmful microorganisms, this leads to the release of the neurotransmitter octopamine in the neurons, which is closely related to adrenaline. This travels through the neuronal branches to the fat store.

“The octopamine then triggers the formation of another neurotransmitter, dopamine, in the fat cells,” says the author. “The dopamine, in turn, is transported into the fly’s brain, where it causes the continuous, increased activation of neuronal networks that are important for learning and trigger an avoidance response.” The animals then tend to be deterred by the odor of pathogenic bacteria. “We were able to show that the flies chose the food source with the harmless germs following their experience with the spoiled food,” explains the scientist.

The adipose tissue is significantly involved in this learned behavioral change. But why is that so? “We still do not have a definitive answer,” says the author. “However, the flies’ decision may be linked to their nutritional status.”

Researchers at the University of Sussex, in collaboration with scientists from different institutes worldwide, have identified a blood test capable of early diagnosis of the most aggressive form of brain tumor. The technology has the potential to save lives. Lead author Professor Georgios Giamas and his team have identified distinctive biomarkers (molecules that act as signs of normal processes, diseases, or responses to treatment) within patient blood samples, which could signal the presence of glioblastoma, one of the most aggressive forms of brain tumor.

The study published in Cell Reports Medicine investigated whether a simple blood test—analyzing the cargo of tiny particles called small extracellular vesicles (sEVs) that are released by cells into the bloodstream—could accurately detect and classify these tumors.

More than 11,000 people are diagnosed with a primary brain tumor in the U.K. each year. Glioblastoma is the most common high grade primary brain tumor in adults, which means it can grow and spread exceptionally quickly. Currently, diagnosing glioma often requires risky brain surgery.