Harrisburg University Research Roundup: July 2024
Harrisburg University of Science and Technology
Argonne-led research working toward reducing electronic waste with biodegradable luminescent polymers with high light-emitting efficiencies.
A recent study has developed nanovesicles (NVs) from activated neutrophils, showcasing their ability to perform molecular debridement and accelerate healing in infectious wounds. This novel method significantly enhances treatment effectiveness, particularly for stubborn diabetic wounds, by targeting and neutralizing deep tissue pathogens.
Researchers at the Advanced Photon Source and Center for Nanoscale Materials of the U.S. Department of Energy’s Argonne National Laboratory have developed a new technique that pairs artificial intelligence and X-ray science.
Despite gaining a bad rap in mainstream media in recent years, nanoparticles have been successfully used for decades in targeted drug delivery systems. Drug molecules can be encapsulated within biodegradable nanoparticles to be delivered to specific cells or diseased tissues.
Researchers have made significant strides in nanotechnology with the discovery of a method to self-assemble block molecules into sophisticated two-dimensional (2D) nanopatterns. This innovative approach allows for meticulous crafting of materials at the nanoscale, surpassing the limitations of conventional lithography. The article illuminates the path for developing advanced nanostructures with applications in nanotechnology, promising a new era of material design and fabrication.
In a significant stride for nanotechnology, a new model has been crafted to demystify the stochastic response of nonlinear dynamical systems, particularly the complex behavior of arrays of coupled micromechanical oscillators. This development is key to enhancing the precision of nanomechanical systems critical for detecting molecules and chemicals associated with diseases.
Newly developed nano transparent screen can be mass-produced at one-tenth the cost of existing screens…Viewers can watch high-definition video footages from multiple angles
SMU and the University of Rhode Island have patented an inexpensive, easy-to-use method to create solid-state nanopores (SSNs), while also making it possible to self-clean blocked nanopores.
A team of researchers led by the University of California San Diego has developed a soft, stretchy electronic device capable of simulating the feeling of pressure or vibration when worn on the skin. This device represents a step towards creating haptic technologies that can reproduce a more varied and realistic range of touch sensations for applications such as virtual reality, medical prosthetics and wearable technology.
MD Anderson and Rice announced the creation of the Cancer Bioengineering Collaborative to develop innovative technologies and bioengineering approaches to improve cancer research, diagnosis and treatment.
Engineers at the University of California San Diego have developed a pill that releases microscopic robots, or microrobots, into the colon to treat inflammatory bowel disease (IBD). The experimental treatment, given orally, has shown success in mice.
Georgia Tech bioengineer Ankur Singh and his team have developed a method to enhance adoptive T-cell therapy using nanowires to deliver miRNA to T-cells, preserving their naïve state for more effective disease-fighting. This innovative technique allows the T-cells to remain programmable and robust, offering a potential gamechanger for immunotherapies.
Argonne scientists have used isoporous membranes — membranes with pores of equal size and shape — and recirculation to create separations at the nanoscale that overcome previous limitations.
Argonne National Laboratory physicist Burak Guzelturk is one of the 2024 recipients of the ACS Nano Lectureship. The award recognizes early career investigators in the field of nanoscience and nanotechnology.
SMU nanotechnology expert MinJun Kim and his team have developed a faster, more precise way to detect the properties and interactions of individual proteins crucial in rapid, accurate, and real-time monitoring of virus-cell interactions.
UC San Diego engineers have developed microscopic robots, known as microrobots, capable of swimming through the lungs to deliver cancer-fighting medication directly to metastatic tumors.