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Imaging assessment of immunotherapy in pediatric brain tumors

Immunotherapy is a rapidly evolving field in pediatric neuro-oncology, using diverse strategies to enhance or initiate an antitumor immune response. Its use has expanded from hematologic malignancies to solid central nervous system (CNS) tumors, creating new diagnostic challenges in neuroimaging, particularly in children.

The aim of this review is to summarize current immunotherapeutic strategies for pediatric solid CNS tumors and to discuss their characteristic imaging findings and response patterns, with emphasis on pitfalls in differentiating true progression from treatment‑related inflammatory changes.

Across different immunotherapeutic approaches, a major challenge is distinguishing tumor progression from pseudoprogression, immune‑related flare phenomena, and neurotoxicity. Multiparametric imaging combining advanced MRI techniques and metabolic imaging may improve diagnostic specificity; however, validation in children is limited, and existing response frameworks such as iRANO and RAPNO do not specifically address immunotherapy‑related imaging patterns in the pediatric population.

Blood-based test can predict risk of developing symptoms of Alzheimer’s up to a decade early

A blood test for the biomarker phosphorylated tau 217 (p-tau217) recently received federal clearance, but questions have emerged about the extent to which such tests can accurately predict whether a cognitively healthy individual will develop cognitive impairment—a key symptom of Alzheimer’s disease.

A new international study involving researchers across three continents and led by experts from the Mass General Brigham Neuroscience Institute sheds new light on the prognostic value of such tests.

The study found that cognitively unimpaired individuals with very high levels of the biomarker had a 38% absolute risk of developing cognitive impairment over the next five years and a 78% risk over the next 10 years.

Cytoskeletal remodeling with rhythmic changes lead to axon development

The researchers have uncovered a mechanism that determines why a neuron usually forms a single, long extension called “axon” – a phenomenon that is fundamental to how our brain functions. Contrary to the common view that external cues drive axon formation, the team of scientists comes to the conclusion that its growth originates primarily inside the cell. Their work, based on cell cultures and was published in the journal “Nature” reveals how a neuron’s structure is remodeled to generate the axon.

Neurons in the brain and spinal cord form a vast network in which each cell receives many inputs but sends output through only a single, long extension: the “axon”. “If our neurons had multiple axons, this would cause chaos in the brain,” says the senior author. “Nature has therefore found a clever way to make sure that neurons generate only one axon. This applies not only to humans, but across the entire animal kingdom. So, we’re dealing with very fundamental processes that shape the wiring of the brain and nervous system.”

Scientists discover how macrophages age differently throughout the body

Why does the immune system become less effective as we age? A new USC study published in BMC Biology offers fresh insights by examining a key immune cell type across tissues: macrophages.

Macrophages act as the body’s cleanup and maintenance crew. Found in nearly every tissue, they help fight infections, remove damaged cells, repair tissues and keep inflammation under control, acting as a first line of defense for the immune system. But like many cells in the body, macrophages change as we get older.

In this new study, researchers analyzed data from macrophages collected from different mouse tissues, including the brain, lungs, liver and other organs. By comparing younger and older animals, they uncovered common patterns of aging shared across many macrophage populations, as well as important differences depending on where the cells come from.

The Universe Isn’t Made of Matter… It’s Made of Information

*Description*
What if everything you know about reality is incomplete?

For centuries, scientists believed matter was the foundation of the universe. But modern physics is raising a far more profound question: *What if information is more fundamental than matter itself?*

In this video, we explore the revolutionary ideas behind quantum physics, the Black Hole Information Paradox, consciousness, and the groundbreaking theories of **Sir Roger Penrose**. From empty atoms to the mysterious nature of reality, discover why some physicists believe the universe may be built from information rather than physical objects.

⚠️ *Important:* This video explores scientific theories and ongoing debates. Some ideas discussed—such as Orch-OR and consciousness—remain controversial and are not established scientific consensus.

If you’re fascinated by quantum physics, cosmology, consciousness, and the mysteries of the universe, this journey is for you.

*Don’t forget to Like 👍, Subscribe 🔔, and Share* if you enjoy thought-provoking science content.

Amyloid-clearing treatment may curb tau buildup for years in Alzheimer’s brain

An analysis of the brain of a deceased Alzheimer’s disease (AD) clinical trial participant found that regions where an anti-amyloid therapy successfully cleared amyloid plaques showed little to no evidence of tau tangles, a hallmark of AD closely linked to neurodegeneration and cognitive decline. In contrast, neighboring areas where amyloid remained showed substantially more tau pathology and signs of ongoing brain damage.

The findings provide rare human evidence that clearing amyloid plaques may have long-term effects on the biological processes that drive AD. The study also suggests that removing amyloid early and extensively may slow the progression of the disease by limiting the accumulation of tau and subsequent neurodegeneration, according to findings presented July 13 at the 2026 Alzheimer’s Association International Conference by researchers from the Perelman School of Medicine at the University of Pennsylvania. The report was also concurrently published in JAMA.

“Seeing both disease patterns side-by-side in the same brain gave us a rare opportunity to understand how amyloid removal affects other proteins that contribute to Alzheimer’s disease,” said co-senior author David Wolk, MD, co-director of the Penn Memory Center and director of the Penn Alzheimer’s Disease Research Center. “The findings provide some of the clearest human evidence to date that anti-amyloid therapies may limit the accumulation of tau and slow the brain changes that lead to memory loss and cognitive decline.”

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