University of Houston ranks among top schools for issued patents

best in class

UH has maintained its spot on the top 100 global universities for number of patents issued. Photo courtesy of University of Houston

A new ranking shows the University of Houston is flexing its brains and its brawn as one of the most prolific producers of patents in the academic world.

The new ranking, published by the National Academy of Inventors and the Intellectual Property Owners Association, puts UH at No. 88 among the world's top 100 universities for patent activity in 2018.

"As the UH research portfolio grows and the medical school starts up, we would continue to anticipate a strong IP portfolio going forward for UH," says Tom Campbell, executive director of the Office of Technology Transfer and Innovation at UH.

UH tied with the Texas A&M University on this year's list; each recorded 28 patents in 2018. A year earlier, UH received 39 patents. The University of Texas was the only other Texas school on the new list. With 187 patents issued in 2018, it landed at No. 5.

Houston's Rice University showed up at No. 79 on the 2018 list but dropped out of this year's top 100.

Amr Elnashai, UH's vice president and vice chancellor for research and technology transfer since 2017, says his school's appearance in the ranking reflects an emphasis on converting faculty inventions into meaningful innovations. During the 2018 budget year, UH collected $43 million in patent royalties.

Among the patents UH received last year were those for a mutant herpes simplex virus connected to cancer therapy and a rechargeable alkaline battery.

"UH researchers are driven by making a positive impact on the quality of life," Elnashai says in a release. "From new remedies for persistent medical conditions to sustainable energy technologies, researchers from the University of Houston are addressing many of the world's most pressing challenges. The UH ranking, tied with our larger neighbor Texas A&M, is a testament to our emphasis on and excellence in technology transfer and innovation."

To ramp up UH's impact, the university last year rebranded its research park as the UH Technology Bridge. With 30,000 square feet of incubator space and over 700,000 square feet of space for labs, pilot-scale facilities, and light manufacturing, the Technology Bridge houses 21 startups and two established companies.

"From clean energy solutions and medicines to uses of artificial intelligence, data science tools and other emerging technologies, the University of Houston is focusing on bridging the gap between technological discoveries by our faculty and actual products that change peoples' lives," Elnashai said in 2018.

The list from the National Academy of Inventors and the Intellectual Property Owners Association started in 2013. UH first cracked the top 100 in 2016 (for patents issued in 2015). That year, it ranked 88th. UH dropped to No. 91 on the 2017 list but rose to No. 67 on the 2018 list.

"The patents our universities produce represent important processes and collaborations which have the potential to make a significant impact on society on a local, regional, national, and global scale," says Paul Sanberg, president of the National Academy of Inventors.

The annual ranking relies on data from the U.S. Patent and Trademark Office regarding utility patents, which make up 90 percent of all patents issued.

According to Investopedia, a utility patent covers the creation of a new or improved — and useful — product, process, or machine. This type of patent prohibits other people or companies from making, using, or selling the invention without authorization.

"Patenting an invention is the first step towards making a lasting impact on the innovation ecosystem," says Jessica Landacre, deputy executive director of the Intellectual Property Owners Association.

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UH researchers develop breakthrough material to boost efficiency of sodium-ion batteries

eyes on clean energy

A research lab at the University of Houston has developed a new type of material for sodium-ion batteries that could make them more efficient and boost their energy performance.

Led by Pieremanuele Canepa, Robert Welch assistant professor of electrical and computer engineering at UH, the Canepa Research Laboratory is working on a new material called sodium vanadium phosphate, which improves sodium-ion battery performance by increasing the energy density. Energy density is the amount of energy stored per kilogram, and the new material can do so by more than 15 percent. With a higher energy density of 458 watt-hours per kilogram — compared to the 396 watt-hours per kilogram in older sodium-ion batteries — this material brings sodium technology closer to competing with lithium-ion batteries, according to the researchers.

The Canepa Lab used theoretical expertise and computational methods to discover new materials and molecules to help advance clean energy technologies. The team at UH worked with the research groups headed by French researchers Christian Masquelier and Laurence Croguennec from the Laboratoire de Reáctivité et de Chimie des Solides, which is a CNRS laboratory part of the Université de Picardie Jules Verne, in Amiens France, and the Institut de Chimie de la Matière Condensée de Bordeaux, Université de Bordeaux, Bordeaux, France for the experimental work on the project.

The researchers then created a battery prototype using the new materia sodium vanadium phosphate, which demonstrated energy storage improvements. The material is part of a group called “Na superionic conductors” or NaSICONs, which is made to let sodium ions move in and out of the battery during charging and discharging.

“The continuous voltage change is a key feature,” Canepa says in a news release. “It means the battery can perform more efficiently without compromising the electrode stability. That’s a game-changer for sodium-ion technology.”

The synthesis method used to create sodium vanadium phosphate may be applied to other materials with similar chemistries, which could create new opportunities for advanced energy storage. A paper of this work was published in the journal Nature Materials.

"Our goal is to find clean, sustainable solutions for energy storage," Canepa adds. "This material shows that sodium-ion batteries can meet the high-energy demands of modern technology while being cost-effective and environmentally friendly."

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This article originally appeared on EnergyCapital.

Houston hospital names leading cancer scientist as new academic head

new hire

Houston Methodist Academic Institute has named cancer clinician and scientist Dr. Jenny Chang as its new executive vice president, president, CEO, and chief academic officer.

Chang was selected following a national search and will succeed Dr. H. Dirk Sostman, who will retire in February after 20 years of leadership. Chang is the director of the Houston Methodist Dr. Mary and Ron Neal Cancer Center and the Emily Herrmann Presidential Distinguished Chair in Cancer Research. She has been with Houston Methodist for 15 years.

Over the last five years, Chang has served as the institute’s chief clinical science officer and is credited with strengthening cancer clinical trials. Her work has focused on therapy-resistant cancer stem cells and their treatment, particularly relating to breast cancer.

Her work has generated more than $35 million in funding for Houston Methodist from organizations like the National Institutes of Health and the National Cancer Institute, according to the health care system. In 2021, Dr. Mary Neal and her husband Ron Neal, whom the cancer center is now named after, donated $25 million to support her and her team’s research on advanced cancer therapy.

In her new role, Chang will work to expand clinical and translational research and education across Houston Methodist in digital health, robotics and bioengineered therapeutics.

“Dr. Chang’s dedication to Houston Methodist is unparalleled,” Dr. Marc L. Boom, Houston Methodist president and CEO, said in a news release. “She is committed to our mission and to helping our patients, and her clinical expertise, research innovation and health care leadership make her the ideal choice for leading our academic mission into an exciting new chapter.”

Chang is a member of the American Association of Cancer Research (AACR) Stand Up to Cancer Scientific Advisory Council. She earned her medical degree from Cambridge University in England and completed fellowship training in medical oncology at the Royal Marsden Hospital/Institute for Cancer Research. She earned her research doctorate from the University of London.

She is also a professor at Weill Cornell Medical School, which is affiliated with the Houston Methodist Academic Institute.

Texas A&M awarded $1.3M federal grant to develop clean energy tech from electronic waste

seeing green

Texas A&M University in College Station has received a nearly $1.3 million federal grant for development of clean energy technology.

The university will use the $1,280,553 grant from the U.S. Department of Energy to develop a cost-effective, sustainable method for extracting rare earth elements from electronic waste.

Rare earth elements (REEs) are a set of 17 metallic elements.

“REEs are essential components of more than 200 products, especially high-tech consumer products, such as cellular telephones, computer hard drives, electric and hybrid vehicles, and flat-screen monitors and televisions,” according to the Eos news website.

REEs also are found in defense equipment and technology such as electronic displays, guidance systems, lasers, and radar and sonar systems, says Eos.

The grant awarded to Texas A&M was among $17 million in DOE grants given to 14 projects that seek to accelerate innovation in the critical materials sector. The federal Energy Act of 2020 defines a critical material — such as aluminum, cobalt, copper, lithium, magnesium, nickel, and platinum — as a substance that faces a high risk of supply chain disruption and “serves an essential function” in the energy sector.

“DOE is helping reduce the nation’s dependence on foreign supply chains through innovative solutions that will tap domestic sources of the critical materials needed for next-generation technologies,” says U.S. Energy Secretary Jennifer Granholm. “These investments — part of our industrial strategy — will keep America’s growing manufacturing industry competitive while delivering economic benefits to communities nationwide.”