A discovery from Australian researchers could lead to better treatment for children with neuroblastoma, a cancer that currently claims 9 out of 10 young patients who experience recurrence. The team at the Garvan Institute of Medical Research in Sydney, Australia, found a drug combination that can bypass the cellular defenses these tumors develop that lead to relapse.

In findings made in animal models and published today in Science Advances, Associate Professor David Croucher and his team have shown that a drug already approved for other cancers can trigger neuroblastoma cell death through alternative pathways when the usual routes become blocked. This discovery could lead to better treatment strategies for children whose cancers have stopped responding to standard chemotherapy.

Neuroblastoma is the most common solid tumor in children outside the brain, developing from nerve cells in the adrenal glands above the kidneys or along the spine, chest, abdomen or pelvis. It is typically diagnosed in children under 2 years old. While those with low-risk disease have excellent outcomes, around half of patients are diagnosed with high-risk neuroblastoma—an aggressive form where tumors have already spread. Of these high-risk patients, 15% don’t respond to initial treatment, and half of those who do respond will see their cancer return.

Researchers around the world are studying how the human brain achieves its extraordinary complexity. A team at the Central Institute of Mental Health in Mannheim and the German Primate Center—Leibniz Institute for Primate Research in Göttingen has now used organoids to show that the ARHGAP11A gene plays a crucial role in brain development. If this gene is missing, key processes involved in cell division and structure become unbalanced.

The human brain distinguishes us from other living beings like no other organ. It enables language, abstract thinking, complex social behavior, and culture. But how can this extraordinarily powerful organ develop, and how is it ensured that nerve cells and supporting cells form in exactly the right places to create the complexity of the human brain?

A team led by Dr. Julia Ladewig at the Central Institute of Mental Health (CIMH) in Mannheim and Dr. Michael Heide at the German Primate Center (DPZ) in Göttingen has investigated this question at the molecular level.

The accompanying diagram presents a comprehensive anatomical overview of the human brain, integrating both lateral surface morphology and a midsagittal section to illustrate the spatial organization of cortical and subcortical structures. Major gyri, sulci, and lobar divisions are delineated alongside deep nuclei, commissural pathways, and the ventricular system. The transparent rendering of the ventricles highlights their relationship to surrounding neural tissue and emphasizes the topology of cerebrospinal fluid pathways. This visualization serves as a structural reference point for understanding functional domains such as sensorimotor processing, higher-order cognition, limbic integration, and autonomic regulation. Collectively, the diagram provides a detailed framework for interpreting neuroanatomical connectivity and its relevance to neural function.

#study:

Cerebrospinal Fluid Mechanics and Its Coupling to Cerebrovascular Dynamics: https://www.annualreviews.org/content/journals/10.1146/annur…#45;034321

CSF dynamics throughout the ventricular system using 4D flow MRI: associations to arterial pulsatility, ventricular volumes, and age: https://link.springer.com/article/10.1186/s12987-024-00570-4

Fundamental functional differences between gyri and sulci: implications for brain function, cognition, and behavior: https://pubmed.ncbi.nlm.nih.gov/38665307/?utm_source=chatgpt.com.

Brain ventricles as windows into brain development and disease: https://www.sciencedirect.com/science/article/pii/S089662732…hatgpt.com

Early signs of Alzheimer’s disease may be hidden in the way a person speaks, but it’s not yet clear which details of our diction are most critical for diagnosis.

A study from 2023 suggests that as we age, how we say something may matter more than what we say. Researchers at the University of Toronto think the pace of everyday speech may be a better indicator of cognitive decline than difficulty finding a word.

“Our results indicate that changes in general talking speed may reflect changes in the brain,” said cognitive neuroscientist Jed Meltzer when the research was published.