Computer scientists, bioengineers and AI specialists from the Arc Institute and Stanford University have developed an ...

by linking the four nucleotide bases comprising DNA—A, T, C, and G—into a particular genetic sequence. Making these sequences is time-consuming and expensive, though, and the longer your ...

Well-established techniques rely on making DNA sequences from scratch to create the DNA storage medium. The process known as "de novo" is time-consuming, expensive, and prone to errors. Researchers ...

The Massachusetts biotech boasts the ability to measure the in vivo function of new sequences to the tune of billions in a month. AAVs are widely accepted vehicles to deliver gene therapies ...

This letter proposes an efficient low-coherence sequence design algorithm (LOCEDA) that can generate any number of sequences of any length that satisfy user-defined PAPR constraints while supporting ...

The results allowed researchers to better understand how the arrangement of sequences within CREs affects gene activation, paving the way for the design of synthetic CREs with highly specific ...

Different parts of a cell’s genome can be active or inactive depending on the cell’s function in the body, and whether it is in a disease state. The instructions for activating or repressing a ...

Researchers at The Jackson Laboratory (JAX), the Broad Institute of MIT and Harvard, and Yale University, have used artificial intelligence to design ... regulatory DNA sequences—often located ...

Researchers have used artificial intelligence to design thousands of new DNA switches ... but are separate, regulatory DNA sequences -- often located near the genes they control.

In this webinar brought to you by Merck, Jacob Lamberth will present a deep dive into the critical variables and strategies for optimizing gene editing experimental design.