Video
New Imaging Approach Reveals Lymph System in Brain
Posted on by Dr. Francis Collins
Considering all the recent advances in mapping the complex circuitry of the human brain, you’d think we’d know all there is to know about the brain’s basic anatomy. That’s what makes the finding that I’m about to share with you so remarkable. Contrary to what I learned in medical school, the body’s lymphatic system extends to the brain—a discovery that could revolutionize our understanding of many brain disorders, from Alzheimer’s disease to multiple sclerosis (MS).
Researchers from the National Institute of Neurological Disorders and Stroke (NINDS), the National Cancer Institute (NCI), and the University of Virginia, Charlottesville made this discovery by using a special MRI technique to scan the brains of healthy human volunteers [1]. As you see in this 3D video created from scans of a 47-year-old woman, the brain—just like the neck, chest, limbs, and other parts of the body—possesses a network of lymphatic vessels (green) that serves as a highway to circulate key immune cells and return metabolic waste products to the bloodstream.
Cool Videos: Insulin from Bacteria to You
Posted on by Dr. Francis Collins
If you have a smartphone, you’ve probably used it to record a video or two. But could you use it to produce a video that explains a complex scientific topic in 2 minutes or less? That was the challenge posed by the RCSB Protein Data Bank last spring to high school students across the nation. And the winning result is the video that you see above!
This year’s contest, which asked students to provide a molecular view of diabetes treatment and management, attracted 53 submissions from schools from coast to coast. The winning team—Andrew Ma, George Song, and Anirudh Srikanth—created their video as their final project for their advanced placement (AP) biology class at West Windsor-Plainsboro High School South, Princeton Junction, NJ.
Robotic Exoskeleton Could Be Right Step Forward for Kids with Cerebral Palsy
Posted on by Dr. Francis Collins
More than 17 million people around the world are living with cerebral palsy, a movement disorder that occurs when motor areas of a child’s brain do not develop correctly or are damaged early in life. Many of those affected were born extremely prematurely and suffered brain hemorrhages shortly after birth. One of the condition’s most common symptoms is crouch gait, which is an excessive bending of the knees that can make it difficult or even impossible to walk. Now, a new robotic device developed by an NIH research team has the potential to help kids with cerebral palsy walk better.
What’s really cool about the robotic brace, or exoskeleton, which you see demonstrated above, is that it’s equipped with computerized sensors and motors that can detect exactly where a child is in the walking cycle—delivering bursts of support to the knees at just the right time. In fact, in a small study of seven young people with crouch gait, the device enabled six to stand and walk taller in their very first practice session!
How Can You Take Part in Clinical Research? Looking Beyond “First in Human”
Posted on by Dr. Francis Collins
For a remarkable journey through the front lines of clinical research, I’d like to invite you to join me in viewing First in Human, which premieres tonight at 9 p.m. ET on the Discovery Channel. This three-part docuseries, to be aired August 10, 17, and 24, provides an unprecedented look inside the NIH Clinical Center here in Bethesda, MD, following four of the many brave patients who’ve volunteered to take part in the clinical trials that are so essential to medical breakthroughs.
You’ll learn about what it’s like to take part in an experimental trial of a new treatment, when all standard options have failed. You’ll see that the NIH Clinical Center and its staff are simply amazing. But keep in mind that you don’t have to travel all the way to Bethesda to be part of outstanding, NIH-funded clinical research. In fact, we support clinical trials all across the country, and it’s often possible to find one at a medical institution near your home. To search for a clinical trial that might be right for you or a loved one with a serious medical problem, try going to ClinicalTrials.gov, a web site run by NIH.
You’ll Want to See This! “First in Human” Debuts August 10
Posted on by Dr. Francis Collins
For over 60 years, the NIH Clinical Center—the world’s largest hospital dedicated to clinical research—has been at the forefront of developing treatments for our most deadly and damaging diseases. It’s here at our “House of Hope” in Bethesda, MD, where, among many other medical firsts, chemotherapy was first used to treat cancerous tumors, gene therapy underwent its first human tests, surgeons first successfully replaced the heart’s mitral valve, and the first anti-viral drug for HIV/AIDS met with early success.
Now, in a Discovery Channel documentary called First in Human, millions of people all around the globe will get a chance to see the doctors, nurses, and other staff of NIH’s remarkable research hospital in action. Narrated by Big Bang Theory star Jim Parsons, the three-part series debuts at 9 p.m.-11 p.m., ET, Thursday, August 10. The second and third segments will air at the same time on August 17 and 24. For a sneak peak, check out the video clip above!
How Kids See the World Depends a Lot on Genetics
Posted on by Dr. Francis Collins
Caption: Child watches video while researchers track his eye movements.
Credit: Washington University School of Medicine, St. Louis
From the time we are born, most of us humans closely watch the world around us, paying special attention to people’s faces and expressions. Now, for the first time, an NIH-funded team has shown that the ways in which children look at faces and many other things are strongly influenced by the genes they’ve inherited from their parents.
The findings come from experiments that tracked the eye movements of toddlers watching videos of other kids or adult caregivers. The experiments showed that identical twins—who share the same genes and the same home environment—spend almost precisely the same proportion of time looking at faces, even when watching different videos. And when identical twins watched the same video, they tended to look at the same thing at almost exactly the same time! In contrast, fraternal twins—who shared the same home environment, but, on average, shared just half of their genes—had patterns of eye movement that were far less similar.
Interestingly, the researchers also found that the visual behaviors most affected in children with autism spectrum disorder (ASD)—attention to another person’s eyes and mouth—were those that also appeared to be the most heavily influenced by genetics. The discovery makes an important connection between two well-known features of ASD: a strong hereditary component and poor eye contact with other people.
DNA-Encoded Movie Points Way to ‘Molecular Recorder’
Posted on by Dr. Francis Collins
Credit: Seth Shipman, Harvard Medical School, Boston
There’s a reason why our cells store all of their genetic information as DNA. This remarkable molecule is unsurpassed for storing lots of data in an exceedingly small space. In fact, some have speculated that, if encoded in DNA, all of the data ever generated by humans could fit in a room about the size of a two-car garage and, if that room happens to be climate controlled, the data would remain intact for hundreds of thousands of years! [1]
Scientists have already explored whether synthetic DNA molecules on a chip might prove useful for archiving vast amounts of digital information. Now, an NIH-funded team of researchers is taking DNA’s information storage capabilities in another intriguing direction. They’ve devised their own code to record information not on a DNA chip, but in the DNA of living cells. Already, the team has used bacterial cells to store the data needed to outline the shape of a human hand, as well the data necessary to reproduce five frames from a famous vintage film of a horse galloping (see above).
But the researchers’ ultimate goal isn’t to make drawings or movies. They envision one day using DNA as a type of “molecular recorder” that will continuously monitor events taking place within a cell, providing potentially unprecedented looks at how cells function in both health and disease.
Cool Videos: A Biological Fireworks Display
Posted on by Dr. Francis Collins
Let’s kick off the Fourth of July weekend with some biological fireworks! While we’ve added a few pyrotechnic sound effects just for fun, what you see in this video is the product of some serious research. Using a specialized microscope equipped with a time-lapse camera to image fluorescence-tagged proteins in real-time, an NIH-funded team has captured a critical step in the process of cell division, or mitosis: how filaments called microtubules (red) form new branches (green) and fan out to form mitotic spindles.
In this particular experimental system, the team led by Sabine Petry at Princeton University, Princeton, NJ, studies the dynamics of microtubules in a cell-free extract of cytoplasm taken from the egg of an African clawed frog (Xenopus laevis). Petry’s ultimate goal is to learn how to build mitotic spindles, molecule by molecule, in the lab. Such an achievement would mark a major step forward in understanding the complicated mechanics of cell division, which, when disrupted, can cause cancer and many other health problems.
Cool Videos: Making Multicolored Waves in Cell Biology
Posted on by Dr. Francis Collins
Bacteria are single-cell organisms that reproduce by dividing in half. Proteins within these cells organize themselves in a number of fascinating ways during this process, including a recently discovered mechanism that makes the mesmerizing pattern of waves, or oscillations, you see in this video. Produced when the protein MinE chases the protein MinD from one end of the cell to the other, such oscillations are thought to center the cell’s division machinery so that its two new “daughter cells” will be the same size.
To study these dynamic patterns in greater detail, Anthony Vecchiarelli purified MinD and MinE proteins from the bacterium Escherichia coli. Vecchiarelli, who at the time was a postdoc in Kiyoshi Mizuuchi’s intramural lab at NIH’s National Institute of Diabetes and Digestive and Kidney Diseases (NIDDK), labeled the proteins with fluorescent markers and placed them on a synthetic membrane, where their movements were then visualized by total internal reflection fluorescence microscopy. The proteins self-organized and generated dynamic spirals of waves: MinD (blue, left); MinE (red, right); and both MinD and MinE (purple, center) [1].
Cool Videos: Flashes of Neuronal Brilliance
Posted on by Dr. Francis Collins
When you have a bright idea or suddenly understand something, you might say that a light bulb just went on in your head. But, as the flashing lights of this very cool video show, the brain’s signaling cells, called neurons, continually switch on and off in response to a wide range of factors, simple or sublime.
The technology used to produce this video—a recent winner in the Federation of American Societies for Experimental Biology’s BioArt contest—takes advantage of the fact that whenever a neuron is activated, levels of calcium increase inside the cell. To capture that activity, graduate student Caitlin Vander Weele in Kay M. Tye’s lab at the Picower Institute for Learning and Memory, Massachusetts Institute of Technology (MIT), Cambridge, MA, engineered neurons in a mouse’s brain to produce a bright fluorescent signal whenever calcium increases. Consequently, each time a neuron was activated, the fluorescent indicator lit up and the changes were detected with a miniature microscope. The brighter the flash, the greater the activity!
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