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tag drug addiction neuroscience microbiology cell molecular biology

Different colored cartoon viruses entering holes in a cartoon of a human brain.
A Journey Into the Brain
Danielle Gerhard, PhD | Mar 22, 2024 | 10+ min read
With the help of directed evolution, scientists inch closer to developing viral vectors that can cross the human blood-brain barrier to deliver gene therapy.
A rendering of a human brain in blue on a dark background with blue and white lines surrounding the brain to represent the construction of new connections in the brain.
Defying Dogma: Decentralized Translation in Neurons
Danielle Gerhard, PhD | Sep 8, 2023 | 10+ min read
To understand how memories are formed and maintained, neuroscientists travel far beyond the cell body in search of answers.
Drug Institute Tackles Neurology of Addiction
Karen Young Kreeger | Aug 20, 1995 | 8 min read
Tracing its origin back 60 years to the Research Division of the United States Narcotics Farm--a treatment facility for opiate addicts located in Lexington, Ky.--the National Institutes of Health's National Institute on Drug Abuse (NIDA) has grown into the world's largest drug addiction research facility. Sidebar: DISCUSSING THE SCIENCE BEHIND DRUG ADDICTION "This institute intramurally and extramurally provides 85 percent of the world support for research on drug abuse and addiction," remark
Researchers in George Church&rsquo;s lab modified wild type ADK proteins (left) in <em >E.coli</em>, furnishing them with an nonstandard amino acid (nsAA) meant to biocontain the resulting bacterial strain.
A Pioneer of The Multiplex Frontier
Rashmi Shivni, Drug Discovery News | May 20, 2023 | 10 min read
George Church is at it again, this time using multiplex gene editing to create virus-proof cells, improve organ transplant success, and protect elephants.
bacteria inside a biofilm
How Bacterial Communities Divvy up Duties
Holly Barker, PhD | Jun 1, 2023 | 10+ min read
Biofilms are home to millions of microbes, but disrupting their interactions could produce more effective antibiotics.
illustration of neurons in blue with synapses lighting up
Gut Molecule Linked to Decreased Myelination in Mouse Brains
Angie Voyles Askham, Spectrum | Feb 17, 2022 | 4 min read
A study shows that a molecule produced by intestinal microbes can enter the brain and that its presence is also associated with altered brain connectivity.
Artist’s rendering of a light purple Ebola virus looping around itself that’s surrounded by red blood cells
Ebola Lurking in Brain Fluid Kills Monkeys Weeks After Recovery
Dan Robitzski | Feb 9, 2022 | 4 min read
New research reveals where the virus was hiding and hints at how to truly purge it from the body.
Illustration of newly discovered mechanism allowing kinesin to &ldquo;walk&rdquo; down a microtubule. A green kinesin molecule with an attached yellow fluorophore is shown passing through a blue laser as it rotates step by step along a red and purple microtubule, fueled by blue ATP molecules that are hydrolyzed into orange ADP and phosphate groups.
High-Resolution Microscope Watches Proteins Strut Their Stuff
Holly Barker, PhD | Mar 31, 2023 | 3 min read
Modification on a high-resolution fluorescent microscopy technique allow researchers to track the precise movements of motor proteins. 
Top 7 papers in neuroscience
Jef Akst | Aug 30, 2010 | 2 min read
1. How neurons grow There's another layer of complexity in the developing nervous system: Spontaneous neuronal activity can regulate the differentiation of neurons, which can in turn affect swimming behavior in frog larvae. M. Demarque et al., Neuron 2010 Jul 29 67(2):321-34. linkurl:Eval by;http://f1000biology.com/article/9dmj38ygwp234jw/id/4525956 Keith Sillar, University of St Andrews; Judith S Eisen, University of Oregon; Antonia Marin-Burgin and Alejandro Schinde, Leloir Institute ID: 452
A mutated cell with a spiky membrane
Mutations in Autism-Linked Gene Cause Membrane Mischief
Holly Barker, PhD, Spectrum | Jan 26, 2023 | 4 min read
Inactivating TAOK1 prompts tentacle-like protrusions to form all over a neuron’s surface, revealing the gene’s role in molding the membrane.

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