Taking a groundbreaking idea from the lab to the orchard

By Holly Riddle

Photo: Kari A. Peter.

Late last year, HappyValley Industry covered the Ben Franklin Technology Partners 2022 BIG IDEA Contest. The 2022 contest focused specifically on the agricultural, food and beverage industries and the second-place winner — and recipient of $10,000 to further his business — was Penn State researcher and associate professor of plant pathology and environmental microbiology, Timothy McNellis. His groundbreaking product is called Blightavast, a unique new solution to combat fire blight, and his new company is called Immunagreen.

We wanted to know more about the impact Blightavast stands to make on its industry, how McNellis ended up winning a BIG IDEA Contest prize and what he’s done with his winnings thus far, so we reached out to see what we could learn.

Finding a solution for a Pennsylvania problem

McNellis was hired at Penn State as an assistant professor in 1999 and says he’s been working on fire blight research ever since.

“When I arrived [at Penn State], my supervisor at the time recommended that I should work on something that was important in the state of Pennsylvania. My supervisor helped me connect to people working on fire blight because I'm a bacteriologist and fire blight is one of the most important bacterial diseases in the state of Pennsylvania. Apples are an important crop here and the disease is a challenge for growers in the state every year,” explained McNellis.

"Apples are an important crop here and the disease is a challenge for growers in the state every year."

If you’re not up to speed on your agricultural terms, fire blight is a contagious bacterial disease that impacts apple and pear trees, killing blossoms, shoots and, in severe cases, the entire tree. When allowed to run rampant, it can cause extensive damage to orchards, which, of course, comes with major economic impacts. One study from the 2000s estimated that the annual cost of fire blight control and losses in the United States totals more than $100 million.

Currently, growers use antibiotics to combat fire blight, but this solution isn’t ideal.

McNellis said, “People want to use fewer antibiotics in agriculture and, in fire blight, there is a problem with antibiotic resistance in the target bacterium. That gets a lot of press — antibiotic resistance in medicine — and the same happens here, in that you keep using the antibiotic and eventually the target becomes resistant. So what do we do? Do we switch to a new antibiotic or is there some other approach? In fire blight, there's a need for other approaches, not other antibiotics … Our product is a non-antibiotic that has potential to at least partially replace antibiotic use.”

Blightavast’s active ingredient is biological, a harmless microbe, which comes with a lessened environmental impact compared to other options. Any residue only lasts a few weeks after application, so there’s no impact on the end consumer. For the grower, cost and labor incurred from using Blightavast will be comparable to current solutions.

Making the big switch from research to commercialization

But while Blightavast seems like a no-brainer solution to a very real problem, McNellis came across the beginnings of the Blightavast product almost out of sheer luck.

He said, “We made a discovery in the lab that looked like it might have an application in the field. On a hunch, we tested it and it worked pretty well right off the bat, which surprised me. I thought, if it works that well, we should really try to commercialize it.”

The switch from research to commercialization, though, was not necessarily an easy one. McNellis admits he didn’t have much prior experience in the business side of things. Suddenly, in order to get a viable product to market, he needed to not just consider whether or not the product worked, but also whether or not it would be marketable to its intended buyer.

“There's the technical challenges of making sure it works, but if you have something that works that's too expensive, then it's useless,” he said. “Especially in agriculture, it has to be cheap. That's the challenge now, to formulate this in a way that is cheap enough for us to make a profit and for growers to also be able to pay for it and maintain their profits.”

McNellis sought help from a range of Penn State and Ben Franklin resources as he got started. He participated in the Ben Franklin TechCelerator Program first, a process that he calls “extremely useful,” noting he “can’t say enough about how awesome the course is.” While he didn’t win any of the prize money available to TechCelerator participants, the experience and what he learned did set him up to succeed in the BIG IDEA Contest.

Now he’s using the $10,000 contest prize to pay for additional field testing to both affirm efficacy and receive Environmental Protection Agency (EPA) approval that is required before bringing the product to market. Testing takes place on experimental farms intended for this use throughout Washington State, Pennsylvania, New York and Michigan.

“It's very encouraging that the EPA is letting us do these tests without any special permit or oversight after their initial safety review of our product,” commented McNellis.

Looking to the future, post-EPA approval, McNellis is already thinking about expanding Blightavast’s use to other crops, which will build the business further.

“Although the disease is serious for apples, the overall market is not really large,” said McNellis. “We estimate about a $20 million market value that we're trying to get our share of, which sounds big, but, really, in the bigger picture, it's not that large, only enough to drive a small operation. So, we’re thinking about how to move this technology to address other plant disease problems, and that's still under development.”

Prolific IBM inventor takes on Penn State Research: Let's make this into Happy Silicon Valley

By Stephanie Kalina-Metzger

Photo: Provided.

All it took for Madhavan Swaminathan was a little encouragement to jumpstart his career in innovation. The new head of the Department of Electrical Engineering in Penn State’s School of Electrical Engineering and Computer Science comes to Penn State by way of Georgia Tech, where he spent 28 years leading the 3D Systems Packaging Research Center and the National Science Foundation Center for Advanced Electronics through Machine Learning.

Swaminathan, who was born in India, said that innovation wasn’t really encouraged when he was young, but that all changed when he came to the United States, earned a Ph.D. in electrical engineering from Syracuse University and joined IBM.

“At that time, IBM was investing in the next supercomputers, when I was asked to develop new packaging technologies and my manager told me to concentrate on developing innovative solutions in that area,” said Swaminathan.

For those who might conjure up the idea of boxes and bubble wrap when it comes to packaging, Swaminathan explains that the packaging he speaks of is an entirely different concept. “If you view any electronic system, it has two parts. The first part are the transistors within a chip and the second part is the packaging. The transistors within the chip act as the brain and then there’s everything around the chip that supports its function, similar to the human body,” he said.

Swaminathan goes on to explain how minute these transistors are. “There can be one billion transistors within a chip and those transistors have to communicate within the external world and with other chips as well. To reduce the size of the system, you have to work on new packaging technologies,” he said, adding that packaging is very important in 5G and 6G communications and computers, where efficiency and battery life are important to send the electrons back and forth between chips.

“Students these days are very different. They are very much interested in startups and commercializing ideas, but college faculty members don’t always have an eye towards business. You need to have both sides and I intend to meet with faculty to encourage them towards providing a holistic education focused not only on research, but also on marketing and business."

Being given the green light to begin innovating at IBM was a boon for Swaminathan and he took to the task with enthusiasm. From 1991 to 1994, while working there, he registered six patents related to advanced packaging.

Later, during a 28-year career at Georgia Tech as the John Pippin Chair in Microsystems Packaging and Electromagnetics at the School of Electrical and Computer Engineering, he developed 25 additional patents, mainly related to advanced packaging and heterogeneous integration of semiconductors.

“At Georgia Tech, we were studying new technologies for packaging and were licensed to create companies,” said Swaminathan, adding that Jacket Micro Devices was just one of those companies that began under his purview and was later acquired by a larger company.

Throughout all of these achievements, what excites Swaminathan most, he said, is living between the worlds of innovation and commercialization. “Being able to commercialize that which emerges from leading-edge research is a very important component, otherwise these great ideas can get lost,” he said.

A Penn State recruit

Swaminathan said that he wasn’t actively seeking a job when Penn State came calling. “I was actually very happy where I was at the time, but I was encouraged to apply via a search firm, so I did.”

“I can’t see any reason why Happy Valley can’t one day be known as Happy Silicon Valley."

Swaminathan explains that he made it through the first round and a final interview before the Dean contacted him and asked him what it would take to convince him to relocate to Happy Valley.

“Continuing my research was very important to me and what struck me about Penn State were the people. I connected with them and their dedication to cutting-edge research was truly outstanding, which is why I thought, why not?” he said.

Swaminathan brings with him to Penn State a large packaging research center, which will include 13 other universities and which he will continue to lead, paving a path for his students.

“Students these days are very different. They are very much interested in startups and commercializing ideas, but college faculty members don’t always have an eye towards business. You need to have both sides and I intend to meet with faculty to encourage them towards providing a holistic education focused not only on research, but also on marketing and business,” he said.

“Being able to commercialize that which emerges from leading-edge research is a very important component, otherwise these great ideas can get lost."

The reason Swaminathan cites commercialization as high on his list of priorities is because of the challenges faced within the United States.

“Whatever is done in the lab needs to translate into manufacturing. Right now, there are two challenges. [The first is] reshoring. Currently most manufacturing in semi-conductors happens outside of the United States. That needs to come back. Also, there’s the supply chain problem. The U.S. produces only 12% of chips here, while consuming more than 50%,” he said.

Swaminathan said that he’s looking forward to living and innovating in Happy Valley and is optimistic about the future.

“I can’t see any reason why Happy Valley can’t one day be known as Happy Silicon Valley,” he said with a smile.

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Finding inspiration in the tiny-but-mighty hummingbird

By Holly Riddle

You don’t need to be a mechanical engineering professor like Penn State’s Dr. Bo Cheng to recognize that hummingbirds contrast significantly with their avian relatives. The smallest of bird species, hummingbirds flit and dart their way from food source to food source in a way no other bird can. Flying backward, forward and upside down at speeds of up to 45 miles per hour, hummingbirds are the only vertebrae capable of hovering for a period of time during flight — and that’s exactly why hummingbirds have inspired modern aerial vehicles like drones.

Unfortunately, these modern aerial vehicles still have a long way to go to catch up with the biological superiority of the tiny-but-mighty hummingbird. However, Dr. Cheng’s recently published research provides new insights into how hummingbirds’ unique wing movements could be robotically replicated, making for more agile, stable and efficient aerial vehicles.

Dr. Cheng and his team reverse-engineered the hummingbird musculoskeletal system to create a model that simulates hummingbird flight motion, and found that hummingbirds’ primary muscles pull the birds’ wings in three directions, while the birds use multiple smaller muscles to tighten their shoulder joints.

In a Penn State release, Dr. Cheng detailed the findings: “It’s like when we do fitness training and a trainer says to tighten your core to be more agile. We found that hummingbirds are using [a] similar kind of mechanism. They tighten their wings in the pitch and up-down directions but keep the wing loose along the back-and-forth direction, so their wings appear to be flapping back and forth only while their power muscles, or their flight engines, are actually pulling the wings in all three directions. In this way, the wings have very good agility in the up and down motion as well as the twist motion.”

"State College is by far the best college town that I've ever lived in. It's a great place to focus on research, raise young children and explore the wilderness."

HappyValley Industry recently caught up with Dr. Cheng to learn more about his work, what it means for industry and why he chooses to live and work in Happy Valley.

What is your research topic and why is it important on a global scale?

This research reveals how hummingbirds use their flight muscles to generate wing motions and the underlying fundamental principles, which can inform robotics on how to properly mimic hummingbird flight.

Both researchers and [the] general public are very impressed by the unique flight abilities of hummingbirds, in terms of both hovering capability and their agile maneuvers. Understanding and mimicking how hummingbird[s] fly and control their flight can potentially transform the design of aerial vehicles.

How do you envision your research impacting/changing your industry?

This research can be potentially used to improve the drone technologies in the future, in terms of improving flight agility, stability and efficiency.

What inspired you to follow this line of research?

This is a no-brainer. Hummingbirds are arguably the most agile fliers in nature, and state-of-the-art drone technology is far behind researching hummingbird-level flight performance.

Why did you choose to conduct this research at Penn State specifically?

Penn State is a world-renowned research institution that attracts many talented faculty members and students. Here, I can recruit talented students [from] all around world and find world-class collaborators.

Would you encourage other researchers to make their home in Happy Valley? If so, why?

State College is by far the best college town that I've ever lived in. It's a great place to focus on research, raise young children and explore the wilderness. It is also not too far from the major cities on the East Coast.

Do you know a researcher who would be a great fit for our HappyValley Industry 5 Questions with a Happy Valley Researcher series? Let us know!