Menu

Blog

Page 6201

May 21, 2021

A toxic chemical in tires is causing salmon populations to die

Posted by in category: chemistry

May 21, 2021

Breastfeeding protects mothers from diabetes, new research shows

Posted by in category: biotech/medical

May 21, 2021

Scientists develop a gene-editing tool that’s more powerful than CRISPR

Posted by in categories: biotech/medical, genetics

May 21, 2021

People who live beyond 105 years old have a rare self-repairing DNA

Posted by in category: biotech/medical

May 21, 2021

Electric cars will be cheaper to produce than fossil fuel vehicles by 2027

Posted by in categories: sustainability, transportation

May 21, 2021

New technology eliminates tumors, and could revolutionize cancer therapy

Posted by in category: biotech/medical

May 21, 2021

Polycarpa mytiligera can regrow all of its organs if dissected into three pieces

Posted by in categories: biotech/medical, life extension

It might not look like much, but this little worm could hold the key to biological regeneration!


Researchers have made an extraordinary discovery using a creature in common to the Gulf of Eilat. The creature is called Polycarpa mytiligera and is a species of ascidian, which is a marine animal commonly found in the waters of the Gulf that is capable of regenerating its organs. Surprisingly, the researchers discovered the animal can regenerate all of its organs even when dissected into three fragments.

Scientists say that is an astounding discovery because it’s an animal belonging to the Phylum Chordata, which are animals with a dorsal cord, which also includes humans. The ability to regenerate organs itself is not uncommon in the animal kingdom. One example is the gecko able to regrow its tail. However, it’s not common for creatures to be able to regrow entire body systems.

Continue reading “Polycarpa mytiligera can regrow all of its organs if dissected into three pieces” »

May 21, 2021

AgomAb Therapeutics announce major funding for nanobody research

Posted by in category: biotech/medical

Antibodies are small protein molecules which are used by the body in order to ‘tag’ foreign pathogens in order for the immune system to identify and destroy them. What is unique about these antibodies is that due to their structure they will only attach themselves to a particular pathogen (on a site known as an antigen). In many cases, the binding of an antibody to a pathogen such as a virus is enough to completely inactive the virus, making it effectively harmless.

Due to the existence of millions upon millions of different types of pathogens, there are quite literally trillions of possibilities for the structures of antibodies, which gives them a near infinite ability to bind with extreme prejudice to just about anything within the body, including our own proteins, such as enzymes and cell receptors.

This ability to bind to biological surfaces allows antibodies to effectively mimic the function of proteins within the body, with the added benefit of often being notably more stable that the protein that they are mimicking. However, there is the slight issue with human antibodies in that they are fairly large, which makes them physically incapable of mimicking many types of proteins. Fortunately, antibodies are not universally the same size within the animal kingdom, and animals such as Llamas have very small antibodies, which are commonly known as nanobodies (very small antibodies).

May 21, 2021

Scientists use genetic engineering to increase worm’s lifespan

Posted by in categories: bioengineering, biotech/medical, evolution, genetics, life extension

To answer this question, an internal team of scientists, consisting of researchers affiliated with the Buck Institute for Research on Ageing, and researchers from Nanjing University decided to modify both the Insulin and the rapamycin pathways of a group of C.elegans worms, expecting to see a cumulative result of a 130% increase in lifespan. However, instead of seeing a cumulative effect in lifespan, the worms lived five times longer than they normally would.

“The synergistic extension is really wild. The effect isn’t one plus one equals two, it’s one plus one equals five. Our findings demonstrate that nothing in nature exists in a vacuum; in order to develop the most effective anti-aging treatments we have to look at longevity networks rather than individual pathways.” – Jarad Rollins of Nanjing University.

What could this mean for human regenerative medicine? Humans are not worms, however on a cellular level they do possess very similar biology. Both the insulin pathway and the rapamycin pathway are what is known as ‘conserved’ between humans and C.elegans, meaning that these pathways have been maintained in both organisms. In the distant past, both humans and C.elegans had a common ancestor, in exactly the same way as humans and Chimpanzees have a common ancestor. Evolution has changed our bodies significantly over the millions of years that humans and C.elegans have diverged from one another, but a lot of our fundamental biological functions remain largely unchanged.

May 21, 2021

Strange “Black Swan” Defect Discovered in Soft Matter for First Time

Posted by in categories: biological, materials

Using an advanced microscopy technique, Texas A&M researchers have uncovered a twin boundary defect in a soft polymer that has never been observed before.

Texas A&M University scientists have for the first time revealed a single microscopic defect called a “twin” in a soft-block copolymer using an advanced electron microscopy technique. This defect may be exploited in the future to create materials with novel acoustic and photonic properties.

“This defect is like a black swan — something special going on that isn’t typical,” said Edwin Thomas, professor in the Department of Materials Science and Engineering. “Although we chose a certain polymer for our study, I think the twin defect will be fairly universal across a bunch of similar soft matter systems, like oils, surfactants, biological materials, and natural polymers. Therefore, our findings will be valuable to diverse research across the soft matter field.”