(Funded by the U.S. Department of Defense, the National Science Foundation and the U.S. Department of Energy)
In the 1970s, scientists began exploring ways to extend electronic frequency mixing into the terahertz range using diodes. While these early efforts showed promise, progress stalled for decades. Recently, however, advances in nanotechnology have reignited this area of research. Now, researchers at the Massachusetts Institute of Technology have developed an electronic frequency mixer for signal detection that operates beyond 0.350 petahertz using tiny nanoantennae. These nanoantennae can mix different frequencies of light, enabling analysis of signals oscillating orders of magnitude faster than the fastest signal accessible to conventional electronics.

(Funded by the National Institutes of Health)
Researchers from the University of Massachusetts Amherst and the University of Massachusetts Chan Medical School have demonstrated in mice a new method to combat pancreatic cancer that relies on a nanoparticle drug-delivery system to activate an immune pathway, which usually recognizes viral infections in the body, in combination with tumor-targeting agents. “If we can trick the immune system into thinking that there is a viral-type infection, then we harness a very robust anti-tumor immune response to bring in for tumor immunotherapy,” said Prabhani Atukorale, one of the scientists involved in this study.

This summer, middle school teachers from the Bay Area and Southern California have participated in NanoSIMST, a professional development program run by nano@stanford, one of the 16 sites of the National Science Foundation-funded National Nanotechnology Coordinated Infrastructure. The program is designed to connect the teachers with activities, skills, and knowledge about science at the scale of molecules and atoms, so they can incorporate it into their curriculum. NanoSIMST also prioritizes teachers from Title I schools, which are low-income schools with low-income student populations that receive federal funding to improve academic achievement. “There’s a gap in professional development for middle school teachers,” said Daniella Duran, the director of education and outreach for nano@stanford. “But these teachers are in a special place – they can teach their students early on about these amazing sciences and help them develop a picture of themselves as a scientist, engineer, or technician.”

(Funded by the National Institutes of Health)
Researchers at the University of Notre Dame have developed an automated device that can diagnose glioblastoma, an incurable brain cancer, in less than an hour. The device features a biochip that uses a sensor that detects biomarkers, called active Epidermal Growth Factor Receptors (EGFRs), that are overexpressed in glioblastoma. EGFRs are found on extracellular vesicles – structures that carry cargo between cells. The device also features silica nanoparticles that report the presence of active EGFRs on the captured extracellular vesicles, while bringing a high negative charge.

(Funded by the National Institutes of Health)
Researchers from Caltech, the University of Washington, the University of Pennsylvania, the University at Albany, the Rockefeller University, the University of Edinburgh, Creative BioSolutions, LLC (Miami, FL), HDT Bio (Seattle, WA), Acuitas Therapeutics (Vancouver, Canada), and Ingenza Ltd. (RoslIn, United Kingdom) have developed and tested a new COVID-19 vaccine candidate called mosaic-8 that has shown potential to protect against different types of sarbecoviruses, including SARS-CoV-2 (the virus that causes COVID-19) and its variants. The mosaic-8 vaccine is made up of nanoparticles that elicit antibodies against conserved features of sarbecoviruses. Each nanoparticle contains pieces of eight different sarbecoviruses. These pieces are regions of the viruses’ spike protein, called receptor-binding domains (RBDs), that are crucial for the virus to infect a cell. Mosaic-8 is now being prepared for initial human clinical trials.

(Funded by the U.S. Department of Defense)
Researchers at the City University of New York have experimentally demonstrated that metasurfaces (two-dimensional materials structured at the nanoscale) can precisely control the optical properties of thermal radiation generated within the metasurface itself. This work paves the way for creating custom light sources with unprecedented capabilities. Metasurfaces offer a solution for greater utility by controlling electromagnetic waves through meticulously engineered shapes of nanopillars that are arrayed across their surfaces.

(Funded by the National Institutes of Health)
Researchers from Rice University, Vanderbilt University, and the U.S. Department of Energy’s Oak Ridge National Laboratory have developed a system for culturing cancer cell clusters that can shed light on hard-to-study tumor properties. The new zinc oxide-based culturing surface mimics the nanoscale roughness of the lotus leaf surface structure, providing a highly tunable platform for the high-throughput generation of three-dimensional nanoscale tumor models. The superhydrophobic array device can be used to create models for studying the progression of cancer, including metastasis – the stage in the disease when cancerous cells travel through the bloodstream from a primary tumor site to other parts of the body.

(Funded by the National Institutes of Health, the National Science Foundation and the U.S. Department of Defense)
Scientists from the Massachusetts Institute of Technology, Harvard Medical School, Carnegie Mellon University, Georgia Institute of Technology, and the University of California, Riverside, have developed polymeric nanocarriers that can cross plant cell walls, delivering functional proteins directly into the cells with unprecedented efficiency. These nanocarriers are engineered with a high aspect ratio, meaning they are long and thin, which is essential for their ability to cross the plant cell wall. One of the critical findings of the study is that the efficiency of protein delivery highly depends on the size and charge of the nanocarriers: Nanocarriers with a width greater than 14 nanometers or with insufficient positive charge were less effective at penetrating the plant cell wall and delivering their protein cargo.

(Funded by the U.S. Department of Defense, the U.S. Department of Energy, and the National Science Foundation)
Researchers from the University of Minnesota, Auburn University, Purdue University, the City University of New York, Vanderbilt University, Indian Institute of Technology Bombay in India, Zhejiang University in China, Kyung Hee University in South Korea, and Universidad de Zaragoza in Spain have provided insight into how light, electrons, and crystal vibrations interact in materials. The researchers studied planar polaritons – hybrid particles created from the interaction between light and matter – in two-dimensional (2D) crystals. The research has implications for developing on-chip architectures for quantum information processing and thermal management.

(Funded by the U.S. Department of Energy)
Researchers from North Carolina State University and Johns Hopkins University have demonstrated a technology that uses DNA to store data. The new technology is made possible by recent techniques that have enabled the creation of soft polymer materials that have unique morphologies. “Specifically, we have created polymer structures that we call dendricolloids – they start at the microscale, but branch off from each other in a hierarchical way to create a network of nanoscale fibers,” says Orlin Velev, one of the researchers involved in this study. “The ability to distinguish DNA information from the nanofibers it’s stored on allows us to perform many of the same functions you can do with electronic devices,” says Kevin Lin, another researcher involved in this study.