Assistant Professor

first_imgSummaryThe Baylor St. Luke’s Medical Group is a collaboration betweenBaylor College of Medicine and CHI St. Luke’s. This group seeks acommitted physician for cardiothoracic/cardiovascular roles.Clinical excellence, scholarly enthusiasm, track record ofexcellent clinical performance. The provider will have directpatient care responsibilities. The position will report to a BCMdepartment head and a director of BSLMG. Performance goals will bedetermined based on patient volume and production. The positiondoes not require research, teaching or supervisingresponsibilities.Location: Lufkin, TXMinimum QualificationsEducation Required: M.D. or D.O. RequiredMinimum Certification/Licensure: Licensed by the Texas MedicalBoardBaylor College of Medicine is an Equal Opportunity/AffirmativeAction/Equal Access Employer.3794CA; CHlast_img read more

Microscope captures intricate images of glowing brains at record speed

first_img Thanks to sophisticated computational tools that stitch thousands of 3D sections together, the researchers showed they could capture large areas of brain and then zoom in at high resolution. The approach should make it easier to study how circuits of interacting neurons across the brain drive certain behaviors, and how that circuitry varies across lots of individuals, between sexes, or over the course of development. Gao et al./Science 2019 Gao et al./Science 2019 Suppose you’d like to take a close look at a fly brain—an extremely close look. With a new technique called expansion microscopy, scientists have been doing just that: labeling neurons of interest and tracing their thinnest tendrils to chart their connections. But the process, which infuses a piece of brain tissue with a gel that swells up to enlarge the details, dramatically increases the time it takes to image that tissue. And as a microscope beam images parts of this thick sample from top to bottom, it can “burn out” the fluorescent tags attached to proteins that help identify the neurons, making deeper parts of the sample completely dark.In a new study, researchers present a solution: combining that expansion process with an instrument called a lattice light-sheet microscope, which sweeps an ultrathin sheet of light through the sample. Because this microscope can linger longer on any area with less intense light than other microscopes, the fluorescence is less likely to burn out and obscure parts of the image—which means that sharp, intricate details, such as the spines on mouse neurons (shown in green, above) can emerge. And by capturing a whole plane at once instead of a set of points, this microscope worked through an entire fly brain (below) in 62.5 hours, roughly seven times faster than the fastest microscope used in such high-resolution imaging to date, the team reports today in Science.center_img By Kelly ServickJan. 17, 2019 , 2:00 PM Microscope captures intricate images of glowing brains at record speedlast_img read more