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tag neuronal plasticity culture cell molecular biology

The mitochondria inside of a neuron are shown in red. The neuron’s protrusions called dendritic spines are shown in cyan.
How Mitochondria Stay Still in Neurons
Mariella Bodemeier Loayza Careaga, PhD | Mar 13, 2024 | 5 min read
An endoplasmic reticulum associated protein holds mitochondria in place in dendrites. This spatial stabilization possibly provides a local energy source for synaptic plasticity. 
Microfluidics: Biology’s Liquid Revolution
Laura Tran, PhD | Feb 26, 2024 | 8 min read
Microfluidic systems redefined biology by providing platforms that handle small fluid volumes, catalyzing advancements in cellular and molecular studies.
Microscopic image of a live amoeba.
Illuminating Specimens Through Live Cell Imaging
Charlene Lancaster, PhD | Mar 14, 2024 | 8 min read
Live cell imaging is a powerful microscopy technique employed by scientists to monitor molecular processes and cellular behavior in real time.
Infographic showing the selective strengthening of synapses that received stimulation.
Infographic: Synaptic Plasticity in the Sea Slug
Danielle Gerhard, PhD | Sep 8, 2023 | 1 min read
The sea slug has helped scientists in their quest to understand how neurons encode memories.
Infusion of Artificial Intelligence in Biology
Meenakshi Prabhune, PhD | Feb 23, 2024 | 10 min read
With deep learning methods revolutionizing life sciences, researchers bet on de novo proteins and cell mapping models to deliver customized precision medicines.
Green and red fluorescent proteins in a zebrafish outline the animal’s vasculature in red and lymphatic system in green in a fluorescent image. Where the two overlap along the bottom of the animal is yellow.
Serendipity, Happenstance, and Luck: The Making of a Molecular Tool
Shelby Bradford, PhD | Dec 4, 2023 | 10+ min read
The common fluorescent marker GFP traveled a long road to take its popular place in molecular biology today.
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.
The image shows many neurons in culture expressing the glutamate reporter iGluSnFR3 in green.
Biosensors Illuminate Talk Between Neurons
Mariella Bodemeier Loayza Careaga, PhD | Sep 8, 2023 | 5 min read
First developed in 2013, a fluorescent indicator has evolved to enable precise glutamate tracking.
Molecular Biology
The Scientist Staff | Mar 20, 1994 | 2 min read
Peter H. Seeburg (Center for Molecular Biology, University of Heidelberg): "In our brain, nerve cells communicate by chemical transmission at specialized structures termed synapses. Most excitatory synapses use the neurotransmitter L-glutamate, which activates specific receptor channels in the postsynaptic membrane. Molecularly and functionally different glutamate-activated channels are expressed by the brain, presumably tailored t
Molecular Biology
The Scientist Staff | Mar 20, 1994 | 2 min read
Peter H. Seeburg (Center for Molecular Biology, University of Heidelberg): "In our brain, nerve cells communicate by chemical transmission at specialized structures termed synapses. Most excitatory synapses use the neurotransmitter L-glutamate, which activates specific receptor channels in the postsynaptic membrane. Molecularly and functionally different glutamate-activated channels are expressed by the brain, presumably tailored t

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