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tag alternative energy neuroscience genetics genomics

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.
Antibody Alternatives
Paul Ko Ferrigno and Jane McLeod | Feb 1, 2016 | 10+ min read
Nucleic acid aptamers and protein scaffolds could change the way researchers study biological processes and treat disease.
Nourishing the Aging Brain
Morten Scheibye-Knudsen | Mar 1, 2015 | 10 min read
Research reveals how the brain changes as we age and hints at ways to slow the decline.
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.
Scanning electron micrograph (SEM) of the unicellular yeast Saccharomyces cerevisiae, known as Baker's or Brewer's yeast.
Yeast Models Provide New Insights into Neurodegenerative Diseases
Mahlon Collins | Oct 1, 2021 | 10+ min read
The single-celled fungus allows researchers to study Alzheimer’s, Parkinson’s, ALS and other brain diseases with unparalleled speed and scale.
Pufferfish Genomes Probe Human Genes
Ricki Lewis | Mar 17, 2002 | 7 min read
It may be humbling to think that humans have much in common with pufferfish, but at the genome level, the two are practically kissing cousins. "In terms of gene complement, we are at least 90% similar—probably higher. There are big differences in gene expression levels and alternate transcripts, but if you're talking about diversity, number and types of proteins, then it's pretty difficult to tell us apart," says Greg Elgar, group leader of the Fugu genome project at the Medical Research C
Will Genomics Spoil Gene Ownership?
Douglas Steinberg | Sep 3, 2000 | 8 min read
Consider a scenario for the year 2002: Using commercially available software, bioprospector "Craig Collins" spends a day scavenging the Human Genome Project (HGP) database for the alternatively spliced genes prized by Wall Street. He enters the sequences of several candidate genes into a software package that prints out the likely functions of their protein products. One protein looks like it could be pharmaceutical paydirt, so he isolates the corresponding cDNA, inserts it into a vector, then
The Genetics of Society
Claire Asher and Seirian Sumner | Jan 1, 2015 | 10 min read
Researchers aim to unravel the molecular mechanisms by which a single genotype gives rise to diverse castes in eusocial organisms.
Beyond Sanger: Toward the $1,000 Genome
Aileen Constans | Jun 29, 2003 | 10 min read
Courtesy of Solexa Total Genotyping Without a doubt, the quarter-century-old Sanger sequencing method performed like a champ during the Human Genome Project. But with the capacity to read only a few hundred bases per reaction, it is far too slow and expensive for routine use in clinical settings. Reaping the rewards of the genomics era will clearly require faster and cheaper alternatives. Some companies estimate that within the next five years, technical advances could drop the cost of seque

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