A targeted approach to treating glioma
With new method, surgeons would remove tumor, then implant microparticles that attack remaining cancer cells.
With new method, surgeons would remove tumor, then implant microparticles that attack remaining cancer cells.
Silicon-based system offers smaller, cheaper alternative to other “broadband” filters; could improve a variety of photonic devices.
Made of electronic circuits coupled to minute particles, the devices could flow through intestines or pipelines to detect problems.
Novel chip keeps time using the constant, measurable rotation of molecules as a timing reference.
Drugs carried in cellular “backpacks” help T cells to destroy tumors.
Folding and cutting thin metal films could enable microchip-based 3-D optical devices.
MIT-developed process could offer nontoxic alternative to environmentally harmful chemicals.
Headed by Carl Thompson, the newly formed Materials Research Laboratory opens up opportunities for industrial partnerships.
Using diamond dust and laser light to control atomic spin, Ashok Ajoy PhD ’16 pursues alternatives to costly conventional imaging technologies.
Technology captures water evaporating from cooling towers; prototype to be installed on MIT’s Central Utility Plant.
Reducing the wavelength of light could allow it to be absorbed or emitted by a semiconductor, study suggests.
Neural network could expedite complex physics simulations.
Nanoparticles carrying two drugs can cross the blood-brain barrier and shrink glioblastoma tumors.
Nanoparticles could offer a new way to help eradicate the disease worldwide.
Startup develops implantable, encased cells that live in the body and secrete insulin and other therapeutics.