A biotech startup co-founded in Ottawa has landed millions of dollars in new funding for its pioneering solution that helps preserve human cells used in next-generation medical research.
PanTHERA Cryosolutions says it’s secured a $4-million investment from a pair of U.S.-based firms, Washington state-based BioLife Solutions and New York’s Casdin Capital, to help get its system ready for market over the next two years. In exchange, BioLife will receive exclusive worldwide marketing and distribution rights to PanTHERA’s products for use in its cell and gene therapy applications.
Founded four years ago by University of Ottawa chemistry professor Robert Ben and University of Alberta researcher Jason Acker, PanTHERA makes small organic molecules that slow down the buildup of ice – known as recrystallization – that occurs when biological material used in the fields of cell therapy and regenerative medicine is frozen.
Scientists have been freezing cells and tissues for decades to preserve them for research into therapies for a wide range of diseases, explained Ben, who specializes in synthetic organic and medicinal chemistry.
Protective agents such as glycerol are used to prevent the cells from drying out in the freezing and thawing process, he said. But that process “is kind of hit and miss,” Ben noted in a recent post on uOttawa’s website.
Preventing cellular damage
“We might freeze 100,000 cells, but only 25,000 will survive and be viable for research or clinical applications,” he said, likening the process to “freezer burn” that changes the structure – and subsequently the taste – of ice cream that’s been stored for too long.
“That’s because up to 80 per cent of the cellular damage that happens during freezing is due to the uncontrolled growth of ice. Since current cryoprotectant solutions don’t address this problem, our returns, measured in cell recovery and function, are quite dismal.”
PanTHERA’s technology also allows cells to survive at higher temperatures than traditional methods, making it easier to store and ship them to remote locations.
“Small ice crystals are innocuous,” Ben said. “They’re like grains of sand on a Caribbean beach. They’re so small that they mould to your body and you can lay comfortably on the beach for an entire day. Now, let’s say those grains of sand were replaced by gravel or pebbles. That’s a lot less comfortable. Our cryopreservation technology prevents ice crystals from growing too large for comfort.”
For the past 10 months, Ben and his team have been working on a new class of compounds that can protect proteins and viruses. They’re now in the process of proving that the technology can preserve COVID testing materials and RNA-based vaccines.
“Our molecules are unique because, unlike conventional cryoprotectants, they prevent all that cellular damage caused by ice,” Ben said. “In the end, we recover more cells, they’re healthier and more functional. There is nothing else like it out there.”
Toward customizable timber, grown in a lab – EurekAlert
Each year, the world loses about 10 million hectares of forest — an area about the size of Iceland — because of deforestation. At that rate, some scientists predict the world’s forests could disappear in 100 to 200 years.
In an effort to provide an environmentally friendly and low-waste alternative, researchers at MIT have pioneered a tunable technique to generate wood-like plant material in a lab, which could enable someone to “grow” a wooden product like a table without needing to cut down trees, process lumber, etc.
These researchers have now demonstrated that, by adjusting certain chemicals used during the growth process, they can precisely control the physical and mechanical properties of the resulting plant material, such as its stiffness and density.
They also show that, using 3D bioprinting techniques, they can grow plant material in shapes, sizes, and forms that are not found in nature and that can’t be easily produced using traditional agricultural methods.
“The idea is that you can grow these plant materials in exactly the shape that you need, so you don’t need to do any subtractive manufacturing after the fact, which reduces the amount of energy and waste. There is a lot of potential to expand this and grow three-dimensional structures,” says lead author Ashley Beckwith, a recent PhD graduate.
Though still in its early days, this research demonstrates that lab-grown plant materials can be tuned to have specific characteristics, which could someday enable researchers to grow wood products with the exact features needed for a particular application, like high strength to support the walls of a house or certain thermal properties to more efficiently heat a room, explains senior author Luis Fernando Velásquez-García, a principal scientist in MIT’s Microsystems Technology Laboratories.
Joining Beckwith and Velásquez-García on the paper is Jeffrey Borenstein, a biomedical engineer and group leader at the Charles Stark Draper Laboratory. The research is published today in Materials Today.
To begin the process of growing plant material in the lab, the researchers first isolate cells from the leaves of young Zinnia elegans plants. The cells are cultured in liquid medium for two days, then transferred to a gel-based medium, which contains nutrients and two different hormones.
Adjusting the hormone levels at this stage in the process enables researchers to tune the physical and mechanical properties of the plant cells that grow in that nutrient-rich broth.
“In the human body, you have hormones that determine how your cells develop and how certain traits emerge. In the same way, by changing the hormone concentrations in the nutrient broth, the plant cells respond differently. Just by manipulating these tiny chemical quantities, we can elicit pretty dramatic changes in terms of the physical outcomes,” Beckwith says.
In a way, these growing plant cells behave almost like stem cells — researchers can give them cues to tell them what to become, Velásquez-García adds.
They use a 3D printer to extrude the cell culture gel solution into a specific structure in a petri dish, and let it incubate in the dark for three months. Even with this incubation period, the researchers’ process is about two orders of magnitude faster than the time it takes for a tree to grow to maturity, Velásquez-García says.
Following incubation, the resulting cell-based material is dehydrated, and then the researchers evaluate its properties.
They found that lower hormone levels yielded plant materials with more rounded, open cells that have lower density, while higher hormone levels led to the growth of plant materials with smaller, denser cell structures. Higher hormone levels also yielded plant material that was stiffer; the researchers were able to grow plant material with a storage modulus (stiffness) similar to that of some natural woods.
Another goal of this work is to study what is known as lignification in these lab-grown plant materials. Lignin is a polymer that is deposited in the cell walls of plants which makes them rigid and woody. They found that higher hormone levels in the growth medium causes more lignification, which would lead to plant material with more wood-like properties.
The researchers also demonstrated that, using a 3D bioprinting process, the plant material can be grown in a custom shape and size. Rather than using a mold, the process involves the use of a customizable computer-aided design file that is fed to a 3D bioprinter, which deposits the cell gel culture into a specific shape. For instance, they were able to grow plant material in the shape of a tiny evergreen tree.
Research of this kind is relatively new, Borenstein says.
“This work demonstrates the power that a technology at the interface between engineering and biology can bring to bear on an environmental challenge, leveraging advances originally developed for health care applications,” he adds.
The researchers also show that the cell cultures can survive and continue to grow for months after printing, and that using a thicker gel to produce thicker plant material structures does not impact the survival rate of the lab-grown cells.
“Amenable to customization”
“I think the real opportunity here is to be optimal with what you use and how you use it. If you want to create an object that is going to serve some purpose, there are mechanical expectations to consider. This process is really amenable to customization,” Velásquez-García says.
Now that they have demonstrated the effective tunability of this technique, the researchers want to continue experimenting so they can better understand and control cellular development. They also want to explore how other chemical and genetic factors can direct the growth of the cells.
They hope to evaluate how their method could be transferred to a new species. Zinnia plants don’t produce wood, but if this method were used to make a commercially important tree species, like pine, the process would need to be tailored to that species, Velásquez-García says.
Ultimately, he is hopeful this work can help to motivate other groups to dive into this area of research to help reduce deforestation.
“Trees and forests are an amazing tool for helping us manage climate change, so being as strategic as we can with these resources will be a societal necessity going forward,” Beckwith adds.
This research is funded, in part, by the Draper Scholars Program.
Written by Adam Zewe, MIT News Office
Paper: “Physical, mechanical, and microstructural characterization of novel, 3D-printable, tunable, lab-grown plant materials generated from Zinnia elegans cell cultures”
“Physical, mechanical, and microstructural characterization of novel, 3D-printable, tunable, lab-grown plant materials generated from Zinnia elegans cell cultures”
Crumbling comet could create meteor shower May 30 – Northern Daily News
A crumbling comet could create a meteor shower on May 30.
The ‘tau Herculids’ meteor display might be one of the most dramatic observed in over two decades, according to Space.com.
Meteor showers occur when dust or particles from asteroids or comets enter Earth’s atmosphere at a very high speed, the U.K. Sun explained.
This one is expected to be the product of a comet named 73P/Schwassmann-Wachmann, also known as SW3.
SW3 was first discovered in 1930 but did not reappear again until the 1970s, Republic World reported.
In 1995, astronomers noticed that the comet’s nucleus split into four smaller chunks, according to CNET.
It has continued to disintegrate more in the ensuing years.
The display is expected to be very visible in the Northern Hemisphere as it is occurring on a Moon-less night.
A consensus of experts predicts that the shower will be visible starting from 1 a.m. EST on May 31.
It is suggested viewers will want to be outside at least an hour before this so your eyes have a chance to adjust to the dark.
“The southwestern USA and Mexico are favored locations as the radiant, the area of the sky where these meteors come from, will be located highest in a dark sky,” Robert Lunsford wrote for AMS.
“The outburst may be seen from southeastern Canada and the remainder of the (eastern) USA, but at a lower altitude.”
Boeing capsule lands back on Earth after space shakedown – Phys.org
Boeing’s crew taxi returned to Earth from the International Space Station on Wednesday, completing a repeat test flight before NASA astronauts climb aboard.
It was a quick trip back: The Starliner capsule parachuted into the New Mexico desert just four hours after leaving the orbiting lab, with airbags attached to cushion the landing. Only a mannequin was buckled in.
Aside from thruster failures and cooling system snags, Starliner appeared to clinch its high-stakes shakedown cruise, 2 1/2 years after its botched first try. Flight controllers in Houston applauded and cheered the bull’s-eye touchdown.
“It’s great to have this incredible test flight behind us,” said Steve Stich, director of NASA’s commercial crew program. He described the demo as “extremely successful,” with all objectives met.
Added Boeing’s Mark Nappi, a vice president: “On a scale of one to 10, I think I’d give it a 15.”
Based on these early results, NASA astronauts will strap in next for a trip to the space station, perhaps by year’s end. The space agency has long wanted two competing U.S. companies ferrying astronauts, for added insurance as it drastically reduced its reliance on Russia for rides to and from the space station.
Elon Musk’s SpaceX is already the established leader, launching astronauts since 2020 and even tourists. Its crew capsules splash down off the Florida coast, Boeing’s Starliner returns to the Army’s expansive and desolate White Sands Missile Range in New Mexico.
Boeing scrapped its first attempt to reach the space station in 2019, after software errors left the capsule in the wrong orbit and nearly doomed it. The company fixed the flaws and tried again last summer, but corroded valves halted the countdown. Following more repairs, Starliner finally lifted off from Cape Canaveral last Thursday and docked to the space station Friday.
Station astronauts tested Starliner’s communication and computer systems during its five days at the space station. They also unloaded hundreds of pounds (kilograms) of groceries and other supplies that flew up in the Boeing capsule, then filled it with empty air tanks and other discarded gear.
A folded U.S. flag sent up by Boeing stayed behind, to be retrieved by the first Starliner crew.
“We’re a little sad to see her go,” station astronaut Bob Hines radioed as the capsule flew away.
Along for the ride was Starliner’s test dummy—Rosie the Rocketeer, a takeoff on World War II’s Rosie the Riveter.
The repairs and do-over cost Boeing nearly $600 million.
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