When the time comes to get relief from a dental problem, we are all glad that dentistry has come so far—much of the progress based on research supported by NIH’s National Institute of Dental and Craniofacial Research. Still, almost no one looks forward to getting a root canal. Not only can the dental procedure be uncomfortable and costly, there’s also a risk of failure due to infection or other complications. But some NIH-supported researchers have now come up with what may prove to be a dazzling strategy for reducing that risk: nanodiamonds!
That’s right, these researchers decided to add tiny diamonds—so small that millions could fit on the head of the pin—to the standard filler that dentists use to seal off a tooth’s root. Not only are these nanodiamonds extremely strong, they have unique properties that make them very attractive vehicles for delivering drugs, including antimicrobials that help fight infections of the sealed root canal.
Tags: cancer, chemotherapy, cleft lip and palate, clinical trial, dental care, dental health, dentist, dentistry, diamonds, endodontics, gutta percha, liver cancer, nanodiamonds, Nanomedicine, nanoparticles, nanotechnology, NDGP, periodontal disease, root canal, teeth, tooth, tooth infection, tooth root
If you went out and asked folks what they’re seeing in this picture, most would probably guess an elegantly woven basket, or a soft, downy feather. But what this scanning electron micrograph actually shows isn’t at all soft: it is the hardest substance in the mammalian body—tooth enamel!
This exquisitely detailed image—a winner of the Federation of American Societies for Experimental Biology’s 2015 BioArt competition—was generated by Olivier Duverger and Maria Morasso of NIH’s National Institute of Arthritis and Musculoskeletal and Skin Diseases. Before placing a sample of mouse dental enamel under the microscope, they treated it briefly with acid in order to reveal how the tissue’s mineralized rods are interwoven in a manner that gives teeth both strength and flexibility.
Tags: dental enamel, dental research, dentistry, enamel, FASEB Bioart 2015, hair, keratin, mineralized tissue, mouse, oral health, scanning electron micrograph, teeth, tissue regeneration, tooth, tooth bud, tooth decay, tooth enamel
It’s intriguing to find the roots of physical traits: skin color, height, and those weird tufts of hair on Uncle Mike’s ears. We’re all curious to know why we look the way we do. But new technologies are allowing us to discover the precise genetic roots of human traits that vary across the world. Variations in our DNA have helped us resist diseases and adapt to different climates and foods, enabling us to colonize just about every environment on the planet.
Recent studies have pinpointed variations responsible for lighter skin in Northern climates (such as SLC24A5 ) and the ability to tolerate milk sugar (lactose) in adulthood . But a new NIH-funded study of a gene variant that arose in China adds a fascinating wrinkle—the use of a mouse model to help understand a potential human advantage . (Regular readers will note that last week in this space I wrote about how mouse models could sometimes be misleading—this week the mouse is a champion!)