“The brain is one of the most complex biological systems in the world,” says one of the senior authors. How neurons are wired together is what his group are trying to unravel – a field known as connectomics.

The author explains: “Take the liver: we know of about 40 cell types. We know how they are arranged. We know their functions. This is not true for the brain. And so, one could ask, what is the difference between the brain and the liver? If we look at a cell body in the brain and the liver, it’s not easy to distinguish the two. They both have a nucleus, an endoplasmic reticulum – they both have the same intercellular machinery, the same molecules, the same types of proteins. This is not the difference. What is really different is how the brain cells are organised and connected.”

Let’s talk numbers: in one cubic millimetre of brain tissue there are about 100 000 neurons, connected through about 700 million synapses and 4 kilometres of ‘cabling’

A new drug targets Alzheimer’s at its earliest, most silent stage — before memory loss ever begins.

Ever wondered how the different cells in our body communicate with each other to fulfill their different roles-be it cells repairing a tissue injury or immune cells moving towards an invading pathogen (microorganisms that causes disease) to engulf it? To move forward or migrate, cells must exert forces or interact with their surrounding environment. Interestingly, however, a fault in these interactions can also be the reason for spread of deadly cancer cells, such as in glioblastoma or brain tumor. While the importance of these interactions is well-understood, the machinery involved in these interactions at the molecular level remains a mystery.

Now, a team of researchers led by Professor Naoyuki Inagaki from Nara Institute of Science and Technology, Japan, along with Dr. Yonehiro Kanemura from NHO Osaka National Hospital, Japan; Dr. Tatsuo Kinashi from Kansai Medical University, Japan; and Dr. Daisuke Kawauchi from Nagoya City University, Japan, has identified the underlying mechanism involving a protein called shootin1b that promotes cell migration or movement in glioblastoma. The study was published online in Advanced Science on August 13, 2025.

“We discovered that an abnormal activity of shootin1b promotes the movement of cancer cells and spread of glioblastoma, the most common and difficult to treat brain tumor in adults,” explains Professor Inagaki.

Stra8 links neuronal activity to inhibitory circuit protection in the adult mouse brain.

Huang et al. show that Stra8, a gene previously thought to be germline specific, is expressed in the adult mouse hippocampus in an activity-dependent manner. Stra8 protects neuronal integrity and cognition by regulating neuromodulator genes and preserving inhibitory circuit function.

A Nature analysis of a major Norwegian study challenges existing estimates of Alzheimer’s prevalence, finding that 25% of people aged 85–89 have dementia with Alzheimer’s pathology — far higher than previous 7–13% estimates — while preclinical Alzheimer’s in younger seniors (70−74) occurs at only 8% versus earlier 22% estimates. Using blood biomarker pTau217 in 11,486 participants, researchers identified that 10% of over-70s had dementia, 10% had mild cognitive impairment, and 10% had preclinical Alzheimer’s, but warn that blood tests alone are insufficient for widespread screening due to potential harm from false positives. The discrepancies highlight how previous studies may have been skewed by selection bias, while demonstrating that blood-based biomarkers require careful interpretation and comprehensive clinical assessment.

A survey of Alzheimer’s disease prevalence in Norway confirms earlier estimates and might show how education level relates to risk.

A new stem cell–based therapy challenges traditional pain treatment by using pain-sensing neurons to reduce inflammation and protect joints. Newly released preclinical data describes an unconventional strategy for managing chronic pain while helping preserve joint tissue. The findings focus on SN