By KIM BELLARD
I feel much about synthetic biology as I do AI: I don’t really understand it from a technical point of view, but I sure am excited about its potential. Sometimes they even overlap, as I’ll discuss later. But I’ll start with some recent developments with bioplastics, a topic I have somehow never really covered.
Let’s start with some work at Washington University (St. Louis) involving, of all things, purple bacteria. In case you didn’t know it – I certainly didn’t – purple bacteria “are a special group of aquatic microbes renowned for their adaptability and ability to create useful compounds from simple ingredients,” according to the press release. The researchers are turning the bacteria into bioplastic factories.
One study, led by graduate student Eric Connors, showed that two “obscure” species of purple bacteria can produce polyhydroxyalkanoates (PHAs), a natural polymer that can be purified to make plastics. Another study, led by research lab supervisor Tahina Ranaivoarisoa, took another “well studied but notoriously stubborn” species of purple bacteria to dramatically ramp up its production of PHAs, by inserting a gene that helped turn them into “relative PHA powerhouses.” The researchers are optimistic they could use other bacteria to produce even higher levels of bioplastics.
The work was done in the lab of associate professor Aripta Bose, who said: “There’s a huge global demand for bioplastics. They can be produced without adding CO2 to the atmosphere and are completely biodegradable. These two studies show the importance of taking multiple approaches to finding new ways to produce this valuable material.”
“It’s worth taking a look at bacteria that we haven’t looked at before,” Mr. Conners said. “We haven’t come close to realizing their potential.” Professor Bose agrees: “We hope these bioplastics will produce real solutions down the road.”
Meanwhile, researchers at Korea Advanced Institute of Science and Technology, led by Sang Yup Lee, have manipulated bacteria to produce polymers that contain “ring-like structures,” which apparently make the plastics more rigid and thermally stable. Normally those structures would be toxic to the bacteria, but the researchers managed to enable E. coli bacteria to both tolerate and produce them. The researchers believe that the polymer would be especially useful in biomedical applications, such as drug delivery.
As with the Washington University work, this research is not producing output at scale, but the researchers have good confidence that it can. “If we put more effort into increasing the yield, then this method might be able to be commercialized at a larger scale,” says Professor Lee. “We’re working to improve the efficiency of our production process as well as the recovery process, so that we can economically purify the polymers we produce.”
Because the polymer is produced using biological instead of chemical processes, and is biodegradable, the researchers believe it can be important for the environment. “I think biomanufacturing will be a key to the success of mitigating climate change and the global plastic crisis,” says Professor Lee. “We need to collaborate internationally to promote bio-based manufacturing so that we can ensure a better environment for our future.”
Environmental impact is also very much on the minds of researchers at the University of Virginia. They are working on creating biodegradable bioplastics from food waste. “By creating cost-effective bioplastics that naturally decompose, we can reduce plastic pollution on land and in oceans and address significant issues such as greenhouse gas emissions and economic losses associated with food waste,” said lead researcher Zhiwu “Drew” Wang.
The team is developing microorganisms that convert food waste into fats, which are then processed into bioplastics. Those bioplastics then should easily be composed. “Our first step is to make single-layer film to see if it can be utilized as an actual product,” said Chenxi Cao, a senior in packaging and system design. “If it has good oxygen and water vapor barriers and other properties, we can move to the next step. We aim to replace traditional coated paper products with PHA. Current paper products are often coated with polyethylene or polyactic acid, which are not fully degradable. PHA is fully biodegradable in nature, even in a backyard environment.”
The approach is currently still in the pilot project stage.
If all that isn’t cool enough, our own bodies may become biofactories, such as to deliver drugs or vaccines. Earlier this year researchers at UT Southwestern reported on “in situ production and secretion of proteins,” which in this case targeted psoriasis and two types of cancer.
The researchers say: “Through this engineering approach, the body can be utilized as a bioreactor to produce and systemically secrete virtually any encodable protein that would otherwise be confined to the intracellular space of the transfected cell, thus opening up new therapeutic opportunities.”
“Instead of going to the hospital or outpatient clinic frequently for infusions, this technology may someday allow a patient to receive a treatment at a pharmacy or even at home once a month, which would be a significant boost to their quality of life,” said study leader Daniel Siegwart, Ph.D. Professor Siegwart believes this type of in situ production could eventually improve health and quality of life for patients with inflammatory diseases, cancers, clotting disorders, diabetes, and a range of genetic disorders.
I promised I’d touch on an example of synthetic biology and AI overlapping. Last year I wrote about how “organoid intelligence” was a new approach to biocomputing and AI. Earlier this year Swiss firm FinalSpark launched its Neuroplatform, which uses 16 human brain organoids as the computing platform, claiming it was: “The next evolutionary leap for AI.”
“Our principal goal is artificial intelligence for 100,000 times less energy,” FinalSpark co-founder Fred Jordan says.
Now FinalSpark is renting its biocomputers to AI researchers at several top universities…for only $500 a month. “As far as I know, we are the only ones in the world doing this” on a publicly rentable platform, Dr. Jordan told Scientific American. Reportedly, around 34 universities requested access, but FinalSpark so far has limited use to 9 institutions, including the University of Michigan, the Free University of Berlin, and the Lancaster University in Germany.
Scientific America reports related work at Spain’s National Center for Biotechnology, using cellular computing, and at the University of the West of England, using – I’m serious! – fungal networks. “Fungal computing offers several advantages over brain-organoid-based computing,” Andrew Adamatzky says, “particularly in terms of ethical simplicity, ease of cultivation, environmental resilience, cost-effectiveness and integration with existing technologies.”
Bioplastics, biofactories, biocomputing — pretty cool stuff all around. I’ll admit I don’t know where all of this is leading, but I can’t wait to see where it leads.
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