Can a non-invasive magnetic helmet treat brain cancer?

Can a non-invasive magnetic helmet treat brain cancer?
Brain Cancer Chromosomes. Chromosomes prepared from a malignant glioblastoma visualized by spectral karyotyping (SKY) reveal an enormous degree of chromosomal instability -- a hallmark of cancer. Created by Thomas Ried, 2014

Glioblastoma is an aggressive and deadly brain cancer, causing more than 10,000 deaths in the US per year. In the last 30 years there has only been limited improvement in the survival rate despite advances in radiation therapy and chemotherapy. Today the typical survival rate is just 14 months and that extra time is spent suffering from the adverse and often brutal effects of radiation and chemotherapy.

Scientists are trying to design more effective treatments for glioblastoma with fewer side effects, and a team at the Department of Neurosurgery at Houston Methodist Hospital has created a magnetic helmet-based treatment called oncomagnetic therapy: a promising non-invasive treatment for shrinking cancerous tumors. In the first patient tried, the device was able to reduce the tumor of a glioblastoma patient by 31%. The researchers caution, however, that much more research is needed to determine its safety and effectiveness.

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Sarah Philip
Sarah Philip is a London-based freelance journalist who writes about science, film and TV. You can follow her on Twitter @sarahph1lip.
Autonomous, indoor farming gives a boost to crops

Artificial Intelligence is already helping to grow some of the food we eat.

Courtesy Babylon Micro-Farms

The glass-encased cabinet looks like a display meant to hold reasonably priced watches, or drugstore beauty creams shipped from France. But instead of this stagnant merchandise, each of its five shelves is overgrown with leaves — moss-soft pea sprouts, spikes of Lolla rosa lettuces, pale bok choy, dark kale, purple basil or red-veined sorrel or green wisps of dill. The glass structure isn’t a cabinet, but rather a “micro farm.”

The gadget is on display at the Richmond, Virginia headquarters of Babylon Micro-Farms, a company that aims to make indoor farming in the U.S. more accessible and sustainable. Babylon’s soilless hydroponic growing system, which feeds plants via nutrient-enriched water, allows chefs on cruise ships, cafeterias and elsewhere to provide home-grown produce to patrons, just seconds after it’s harvested. Currently, there are over 200 functioning systems, either sold or leased to customers, and more of them are on the way.

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Lela Nargi
Lela Nargi is a Brooklyn, NY-based veteran freelance journalist covering food and agriculture system, social justice issues, science & the environment, and the places where those topics intersect for The New York Times, The Guardian, the Food and Environment Reporting Network (FERN), Eater, Modern Farmer, USA Today, and other outlets. Find her at lelanargi.com.
Scientists make progress with growing organs for transplants

Researchers from the University of Cambridge have laid the foundations for growing synthetic embryos that could develop a beating heart, gut and brain.

Adobe Stock

Story by Big Think

For over a century, scientists have dreamed of growing human organs sans humans. This technology could put an end to the scarcity of organs for transplants. But that’s just the tip of the iceberg. The capability to grow fully functional organs would revolutionize research. For example, scientists could observe mysterious biological processes, such as how human cells and organs develop a disease and respond (or fail to respond) to medication without involving human subjects.

Recently, a team of researchers from the University of Cambridge has laid the foundations not just for growing functional organs but functional synthetic embryos capable of developing a beating heart, gut, and brain. Their report was published in Nature.

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Peter Rogers
Dr. Peter Rogers grew up milking cows and building barns. This provided him the transferable skills necessary for a smooth transition into academic research. Three years of genetics research led to six years of immunology research, which led to a Ph.D. from Auburn University. That led to three and half years of instructional design research at Tufts University School of Medicine. His expertise includes biomedical sciences & technology, social determinants of health, bovine birthing, training & development, and cognitive psychology. He’s taught dozens of university courses, ranging from Principles of Biology to Advanced Medical Immunology. He is currently co-writing a book with his father, George Rogers, called "How to Correctly Hold a Flashlight: A Disagreement in Academic and Agricultural Perspectives."