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The approach could revolutionise regenerative medicine, enabling the production of complex tissues and cartilage that would potentially support, repair or augment diseased and damaged areas of the body.

Printing high-resolution living tissues is hard to do, as the cells often move within printed structures and can collapse on themselves. But, led by Professor Hagan Bayley, Professor of Chemical Biology in Oxford’s Department of Chemistry, the team devised a way to produce tissues in self-contained cells that support the structures to keep their shape.

Harmful algal blooms known to pose risks to human and environmental health in large freshwater reservoirs and lakes are projected to increase because of climate change, according to a team of researchers led by a Tufts University scientist.

The team developed a modeling framework that predicts that the largest increase in cyanobacterial harmful algal blooms (CyanoHABs) would occur in the Northeast region of the United States, but the biggest economic harm would be felt by recreation areas in the Southeast.

To help plants better fend off insect pests, researchers are considering arming them with stones.

The University of Delaware’s Ivan Hiltpold and researchers from the Hawkesbury Institute for the Environment at Western Sydney University in Australia are examining the addition of silicon to the soil in which plants are grown to help strengthen plants against potential predators.

The research was published recently in the journal Soil Biology and Biochemistry and was funded by Sugar Research Australia. Adam Frew, currently a postdoctoral research fellow at the Charles Sturt University in Australia, is the lead author on the paper.

NASA looked at the rainfall rates within Tropical Storm Gert as it continued to strengthen and found the most intense rainfall on the tropical cyclone's eastern side. Just over 12 hours later, Gert would strengthen into a hurricane. As Gert has strengthened, the storm began generating dangerous surf along the U.S. East coast.

The Global Precipitation Measurement mission or GPM core observatory satellite passed above tropical storm Gert on August 14, 2017 at 9:36 a.m. EDT (1336 UTC) when winds had reached about 57.5 mph (50 knots). Data collected by GPM's Microwave Imager (GMI) and Dual-Frequency Precipitation Radar (DPR) instruments were used to show the coverage and the intensity of rainfall around Tropical Storm Gert. The area covered by GPM's radar swath revealed that the most intense rainfall, measuring greater 3.5 inches (90 mm) per hour, was located in bands of rain on the eastern side of the storm.

Our Sun is active: Not only does it release a constant stream of material, called the solar wind, but it also lets out occasional bursts of faster-moving material, known as coronal mass ejections, or CMEs. NASA researchers wish to improve our understanding of CMEs and how they move through space because they can interact with the magnetic field around Earth, affecting satellites, interfering with GPS signals, triggering auroras, and — in extreme cases — straining power grids.