Skip to main content
  1. Home
  2. Emerging Tech
  3. Health & Fitness
  4. News

New gene editing tech promises to be even better than CRISPR

Add as a preferred source on Google

Just when we were getting used to the CRISPR/Cas9 gene editing revolution, a new “fourth-generation” DNA base editor has come along — offering a new way to modify the genetic code that may be safer in terms of reducing potential mistakes.

Base editing is a relatively new approach to genome editing. It describes a technique in which a target point mutation is directly converted back to the normal DNA sequence on a permanent basis, without having to introduce a double-stranded cut in the DNA. Because most human genetic variants associated with disease are point mutations, base editing could offer a means by which to advance the study and future treatment of human genetic diseases. The fourth-generation base editor offers a way to improve base editing efficiencies, while greatly reducing undesired byproducts — thereby making the edits much “cleaner”.

Recommended Videos

“Standard CRISPR-mediated genome editing uses CRISPR-Cas9 nuclease to make a double-stranded cut at a target DNA site, then relies on the cell’s response to that cut to install desired DNA changes,” study co-author David Liu, a Harvard University professor of Chemistry and Chemical Biology and Howard Hughes Medical Institute investigator, told Digital Trends. “Cutting-based strategies have their own strengths, but one challenge facing cutting-based approaches is that making double-stranded breaks in genomic DNA tends to result in a stochastic mixture of products containing insertions, deletions, and translocations at the cut site.”

Liu points out that he doesn’t see CRISPR/Cas9 being entirely replaced by the new technique, however. Instead, he thinks both strategies combined will play complementary roles in the future treatment of genetic diseases. “Our lab, as well as many others, are using base editing to research genetic variants that play a role in disease, and to validate potential therapeutic strategies that might one day be used to reverse the root causes of some of these diseases,” he continued.

Given some of the amazing work that has already been achieved through CRISPR gene editing — from carrying out genetic modifications to make animal organs suitable for human transplant to more “far out” demonstrations like encoding GIFs into the DNA of viruses — we can’t wait to see what comes next.

A paper describing the work of Liu and colleagues was recently published in the journal Science Advances.

Luke Dormehl
I'm a UK-based tech writer covering Cool Tech at Digital Trends. I've also written for Fast Company, Wired, the Guardian…
Home robots can already walk. The hard part is stopping them from crushing your glassware
1X’s NEO uses tactile sensing and force control to handle fragile objects, aiming at the kind of household work humanoids still struggle to do.
Baby, Person, Electronics

A robot can look convincing while walking across a stage and still be useless in a kitchen. Picking up a wet glass demands precision, quick corrections, and enough restraint to avoid squeezing too hard. 1X is tackling that problem with new tendon-driven hands for NEO, its humanoid home robot.

1X says each hand has 25 degrees of freedom, with 22 across the fingers and palm and another three in the wrist. Its joints can yield when pushed instead of staying rigid, giving NEO a better chance of handling household objects without treating every collision like a wrestling match.

Read more
This tiny gadget called Moodi could save your thumb during long reading sessions
This tiny remote thinks your finger deserves a vacation
DuRoBo Moodi

Digital reading has become more comfortable thanks to larger displays and e-paper screens, but one small annoyance remains: constantly reaching over to tap or swipe every page. DuRoBo believes it has a solution. The company has unveiled Moodi, its first Bluetooth page-turning remote, designed to make reading, browsing, and media control more comfortable across e-readers, tablets, and smartphones.

Unlike conventional page-turners that focus solely on e-books, Moodi doubles as a compact Bluetooth remote for scrolling through articles, controlling multimedia playback, and navigating long-form content. The device looks towards ergonomic accessories that aim to reduce repetitive hand movements during extended screen time.

Read more
Camera sensor breakthrough promises sharper images without hulking up your phone’s thickness
Camera sensors just got thinner. Your excuses for blurry photos didn't.
Representative Image

Researchers at Nagoya University have developed a new type of transparent optical sensor that could significantly reduce the size of camera sensors while improving image quality. Published in the journal ACS Nano, the study demonstrates how gallium-doped zinc oxide (GZO) nanosheets can detect red, green, and blue (RGB) light within a single pixel, potentially replacing the decades-old Bayer filter design used in nearly every digital camera today.

If commercialized, the technology could enable thinner smartphone cameras, higher-resolution medical imaging devices, and more compact sensors for automotive and aerospace applications, all while simplifying manufacturing.

Read more