Good Social Interactions Slow Cancer Via an Anxiety-Reducing Neural Circuit

Just an hour of socializing per day helped mice fight tumors. Now scientists have traced the brain circuitry that turns companionship into a cancer-fighting signal.

In the 1970s and ‘80s, scientists began noticing that people who had few or poor social relationships had a higher risk of developing illnesses and all-cause mortality. A slew of follow-up studies suggested that social support could protect people from pathological conditions like arthritis, alcoholism, depression, and even death. This link holds true for cancer as well. Upon analyzing disease progression and survival rates in thousands of breast cancer patients, researchers observed a negative impact of social isolation and a positive impact of interpersonal connections on prognosis.

One of the popular theories explaining these effects states that being social eases anxiety, a well-established driver of tumor growth, and consequently inhibits cancer progression. But how exactly does the body sense these stimuli and pump the brakes on cancer?

In a recent study published in Neuron, researchers uncovered the neural circuitry that drives the therapeutic effects of social connections on cancer, in mice. It demonstrates a real biological pathway by which this nebulous subject of social interaction can influence cancer.

That means that now it's technically targetable, by drugs or by neuromodulation techniques, when before, we wouldn't even know what to target or if there was something to target.

 These findings establish a new paradigm for how psychosocial factors influence cancer via neural circuits and could potentially lead to therapies that complement existing treatments.

Wen HZ, et al. Social interaction in mice suppresses breast cancer progression via... Neuron. 2025;113(20)3374-3389.e9.

First ever atlas of brain development

First-ever atlas of brain development shows how stem cells turn into neurons

Scientists have created the most detailed maps yet of how our brains differentiate from stem cells during embryonic development and early life. In a collection of five papers, they tracked hundreds of thousands of early brain cells in the cortices of humans and mice, and captured with unprecedented precision the molecular events that give rise to a mixture of neurons and supporting cells. It's really the initial first draft of any ‘cell atlases’ for the developing brain.

https://www.nature.com/articles/d41586-025-03641-0?utm_source=Live+...

We're Still Evolving: Human Arms Keep Growing an Extra Artery

Subtle shifts in our anatomy today demonstrate how unpredictable evolution can be. Take something as mundane as an extra blood vessel in our arms, which, going by current trends, could be commonplace within just a few generations.

An artery that temporarily runs down the center of our forearms while we're still in the womb isn't vanishing as often as it used to, according to a study published in 2020 by researchers.

That means there are more adults than ever with what amounts to an extra channel of vascular tissue flowing under their wrist.

Since the 18th century, anatomists have been studying the prevalence of this artery in adults and our study shows it's clearly increasing.

The prevalence was around 10 percent in people born in the mid-1880s compared to 30 percent in those born in the late 20th century, so that's a significant increase in a fairly short period of time, when it comes to evolution

https://onlinelibrary.wiley.com/doi/10.1111/joa.13224