MicroRNA-27a has been shown to stimulate both the wingless-type integration site family, or Wnt signaling, and the bone morphogenetic protein pathways to actively promote bone regeneration, according to a recent study from Institute of Science Tokyo, Japan. Their important findings shed light on the intrinsic cellular pathways and mechanisms that are critical for the development of new bone-like tissue and could inform the design and development of future tissue regeneration therapies.

Scientists have developed a new microscope that significantly improves the way heat flow in materials can be measured. This advancement could lead to better designs for electronic devices and energy systems.

New Reichman University Study: A Temporary International Market Exit May Lead to Future Global Expansion

A strategic withdrawal from international activity can free up resources, spur business growth and technological development — ​​and enable a stronger reentry onto the global stage

Might a temporary reduction in international presence today open the door to significant global success in the future?

A new study conducted by Prof. Niron Hashai, dean of the Arison School of Business at Reichman University, Prof. Christian Asmussen of Copenhagen Business School, and Netanel Drori of Northeastern University reveals an unexpected dynamic in global business strategy: companies that choose to scale back international operations in the short term may actually be laying the foundation for large-scale global expansion in the future. The researchers call this pattern “international contraction for the sake of international expansion,” and identify the key mechanisms that drive the effect: the freeing up of organizational capital and resources, renewed investment in emerging areas, the fueling of innovation, and the development of technological knowledge — all processes that lead to business growth and a powerful return to global markets.

Researchers at Nanjing University of Science and Technology (NJUST) developed eDL-cSIM, an AI-driven super-resolution imaging technique that captures fine cellular details in a single shot, enabling faster, gentler observation of dynamic cellular processes with broad implications for advancing biomedical research.

Critical raw materials are fundamental to feeding the EU industrial value chains and strategic sectors and the green energy transition. SEMACRET project, led by the University of Oulu Finland, promoted sustainable exploration for green transition critical raw materials in the EU, securing the continued supply for its industries.