The human brain contains distinct geographic regions that communicate throughout the day to process information, such as remembering a neighbor’s name or deciding which road to take to work. Key to such processing is a vast network of densely bundled nerve fibers called tracts. It’s estimated that there are thousands of these tracts, and, because the human brain is so tightly packed with cells, they often travel winding, contorted paths to form their critical connections. That situation has previously been difficult for researchers to image three-dimensional tracts in the brain of a living person.
That’s now changing with a new approach called tractography, which is shown with the 3D data visualization technique featured in this video. Here, researchers zoom in and visualize some of the neural connections detected with tractography that originate or terminate near the hippocampus, which is a region of the brain essential to learning and memory. If you’re wondering about what the various colors represent, they indicate a tract’s orientation within the brain: side to side is red, front to back is green, and top to bottom is blue.
If you enjoy action movies, you can probably think of a superhero—maybe Wolverine?—who can lose a limb in battle, yet grow it right back and keep on going. But could regenerating a lost limb ever happen in real life? Some scientists are working hard to understand how other organisms do this.
As shown in this video of a regenerating fish fin, biology can sometimes be stranger than fiction. The zebrafish (Danio rerio), which is a species of tropical freshwater fish that’s an increasingly popular model organism for biological research, is among the few vertebrates that can regrow body parts after they’ve been badly damaged or even lost. Using time-lapse photography over a period of about 12 hours, NIH grantee Sandra Rieger, now at MDI Biological Laboratory, Bar Harbor, ME, used a fluorescent marker (green) to track a nerve fiber spreading through the skin of a zebrafish tail fin (gray). The nerve regeneration was occurring in tissue being spontaneously formed to replace a section of a young zebrafish’s tail fin that had been lopped off 3 days earlier.
Along with other tools, Rieger is using such imaging to explore how the processes of nerve regeneration and wound healing are coordinated. The researcher started out by using a laser to sever nerves in a zebrafish’s original tail fin, assuming that the nerves would regenerate—but they did not! So, she went back to the drawing board and discovered that if she also used the laser to damage some skin cells in the tail fin, the nerves regenerated. Rieger suspects the answer to the differing outcomes lies in the fact that the fish’s damaged skin cells release hydrogen peroxide, which may serve as a critical prompt for the regenerative process . Rieger and colleagues went on discover that the opposite is also true: when they used a cancer chemotherapy drug to damage skin cells in a zebrafish tail fin, it contributed to the degeneration of the fin’s nerve fibers .
Based on these findings, Rieger wants to see whether similar processes may be going on in the hands and feet of cancer patients who struggle with painful nerve damage, called peripheral neuropathy, caused by certain chemotherapy drugs, including taxanes and platinum compounds. For some people, the pain and tingling can be so severe that doctors must postpone or even halt cancer treatment. Rieger is currently working with a collaborator to see if two protective molecules found in the zebrafish might be used to reduce or prevent chemotherapy-induced peripheral neuropathy in humans.
In recent years, a great deal of regenerative medicine has focused on learning to use stem cell technologies to make different kinds of replacement tissue. Still, as Rieger’s work demonstrates, there remains much to be gained from studying model organisms, such as the zebrafish and axolotl salamander, that possess the natural ability to regenerate limbs, tissues, and even internal organs. Now, that’s a super power we’d all like to have.