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tag xenopus developmental biology neuroscience

Gia Voeltz: Cellular Cartographer
Karen Zusi | Dec 1, 2015 | 3 min read
Associate Professor, Department of Molecular, Cellular, and Developmental Biology, University of Colorado, Boulder. Age: 43
Guts and Glory
Anna Azvolinsky | Apr 1, 2016 | 9 min read
An open mind and collaborative spirit have taken Hans Clevers on a journey from medicine to developmental biology, gastroenterology, cancer, and stem cells.
Sensory Biology Around the Animal Kingdom
The Scientist | Sep 1, 2016 | 10+ min read
From detecting gravity and the Earth’s magnetic field to feeling heat and the movement of water around them, animals can do more than just see, smell, touch, taste, and hear.
Frogs Have a Bioelectric Mirror
Catherine Offord | Jan 1, 2019 | 2 min read
Amputation of one limb triggers a rapid electric response that reflects the injury in the opposite one, researchers find.
Tadpoles See with Extra Eyes
Sabrina Richards | Feb 27, 2013 | 3 min read
Blind tadpoles regain vision when new eyes are grafted onto their tails. 
Using Temperature-Sensitive Channels to Study Neural Circuitry
Devika G. Bansal | Nov 1, 2018 | 8 min read
Meet the researchers building a thermogenetic toolbox.
Into the Limelight
Kate Yandell | Oct 1, 2015 | 8 min read
Glial cells were once considered neurons’ supporting actors, but new methods and model organisms are revealing their true importance in brain function.
Top 10 Innovations 2021
2021 Top 10 Innovations
The Scientist | Dec 1, 2021 | 10+ min read
The COVID-19 pandemic is still with us. Biomedical innovation has rallied to address that pressing concern while continuing to tackle broader research challenges.
Brains in Action
The Scientist | Feb 1, 2014 | 10+ min read
Neuroscientists are automating neural imaging and recording, allowing them to monitor increasingly large swaths of the brain in living, behaving animals.
 
Cutting Neurons Down To Size
Douglas Steinberg | Nov 2, 2003 | 10+ min read
© Mehau Kulyk/Photo Researchers, Inc. A typical neuron's axons and dendrites, when loaded with dye and magnified, resemble long, untended tresses on an extremely bad hair day. They extend wildly, usually to one side, and then bend at weird angles as their ends split into branches and sub-branches. This neuronal coiffure must appear even more chaotic before the nervous system has undergone the developmental equivalent of a crew cut crossed with a topiary trimming. From the late embryonic

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