Michael j sailor
Psw 2432 the year nanomaterials saved the world from
Our Cecil and Ida Green Honors Chair for the 2019-20 academic year is Michael Sailor, Distinguished Professor, Department of Chemistry and Biochemistry, University of California, San Diego. Professor Sailor holds appointments in the UCSD Departments of Bioengineering and Nanoengineering, as well as membership in the Moores Cancer Center. He specializes in nanomaterial chemistry, electrochemistry, and optical properties, with a focus on porous silicon-based systems.
Uc san diego & you: michael sailor, ph.d.
Michael J. Sailor is a Distinguished Professor of Chemistry and Biochemistry at the University of California, San Diego (UCSD), as well as a member of the Bioengineering, Nanoengineering, and Materials Science and Engineering programs.
Professor Sailor refers to these nanomaterials as “nanorobots” to describe how they function inside the body. The team uses chemistry to tell the nanoparticles where to go, what to do once they get there, and, maybe most importantly, how long they should stay. He explained, “A targeted nanoparticle is a structure that usually has some sort of antibody or molecule that the cells you’re trying to target want to see.” “When a cancer cell grows rapidly, for example, it tries to take nutrients and other molecules from the bloodstream that will help it develop faster.”
Folate is one of the nutrients that cancer cells seek out, according to Sailor. “If you place a folate molecule on your nanoparticle, as it swims around and comes across a cancer cell, it has a higher chance of sticking to the cancer cell than it does to normal cells.”
Michael j. sailor: porous silicon nanoparticles as self
We make silicon-based nanomaterials and investigate their chemical, electrochemical, photophysical, and nanomedical properties at a fundamental level. We are particularly interested in mesoporous nanostructures, particularly porous silicon. Porous nanoparticles for controlled delivery of protein, nucleic acid, and small molecule drugs, luminescent silicon quantum dots, in-vitro and in-vivo imaging, and chemical/biochemical sensors are among the current research projects. On nanotechnology-enabled approaches to treating cancer, bacterial and viral infections, and eye diseases, we work closely with the medical community.
Prof. Sailor oversees the NSF UC San Diego Materials Research Science and Engineering Center, and Prof. Sailor also co-directs the cross-divisional Institute for Materials Discovery and Design. To discover, design, and characterize advanced materials required to address global societal challenges, we use the research tools of the San Diego Nanotechnology Infrastructure (a member of the NSF National Nanotechnology Coordinated Infrastructure).
Michael j. saylor talks about the mobile wave on bloomberg
He dreamed of becoming a paleontologist and finding a new dinosaur on his own as a child. Michael Sailor, a distinguished professor of chemistry and biochemistry at the University of California, San Diego, is now a recognized pioneer in the field of nanotechnology and porous silicon.
Professor Sailor’s fascination with chemistry started when he was a teenager, when he would conduct experiments in his backyard involving “smoke, fire, and explosions”—what he refers to as “interesting reactions”—and even made his own charcoal furnace out of bricks, a stainless steel mixing cup, and his sister’s hair dryer.
Michael’s smoldering passion for science was stoked during his high school years, when he met his physics and chemistry professors, Ed Duncan and Richard Smith. Smith allowed him to remain alone in the chemistry laboratory after school to conduct experiments, with the single requirement that he put all the chemicals away, switch off the instruments, and lock the door on his way out. Michael points out that if a high school teacher today gave a student that much independence and responsibility, he would almost certainly be fired. Although he doesn’t advocate leaving adolescents alone in chemistry laboratories, he cherished the moment in his life when he discovered the thrill of autonomous, curiosity-driven experimentation and discovered a love for experimenting.