Houston Methodist's Dr. Ron Moses has created NanoEar, which he calls “the world’s smallest hearing aid.” Photo via Getty Images.

“What is the future of hearing aids?” That’s the question that led to a potential revolution.

“The current hearing aid market and technology is old, and there are little incremental improvements, but really no significant, radical new ideas, and I like to challenge the status quo,” says Dr. Ron Moses, an ENT specialist and surgeon at Houston Methodist.

Moses is the creator of NanoEar, which he calls “the world’s smallest hearing aid.” NanoEar is an implantable device that combines the invisibility of a micro-sized tympanostomy tube with more power—and a superior hearing experience—than the best behind-the-ear hearing aid.

“You put the NanoEar inside of the eardrum in an in-office procedure that takes literally five minutes,” Moses says.

As Moses explains, because of how the human cochlea is formed, its nerves break down over time. It’s simply an inevitability that if we live long enough, we will need hearing aids.

“The question is, ‘Are we going to all be satisfied with what exists?’” he asks.

Moses says that currently, only about 20 percent of patients who need hearing aids have them. That’s because of the combination of the stigma, the expense, and the hassle and discomfort associated with the hearing aids currently available on the market. That leaves 80 percent untapped among a population of 466 million people with hearing impairment, and more to come as our population ages. In a nearly $7 billion global market, that additional 80 percent could mean big money.

Moses initially patented a version of the invention in 2000, but says that it took finding the right team to incorporate as NanoEar. That took place in 2016, when he joined forces with cofounders Michael Moore and Willem Vermaat, now the company’s president and CFO, respectively. Moore is a mechanical engineer, while Vermaat is a “financial guru;” both are repeat entrepreneurs in the biotech space.

Today, NanoEar has nine active patents. The company’s technical advisors include “the genius behind developing the brains in this device,” Chris Salthouse; NASA battery engineer Will West; Dutch physicist and audiologist Joris Dirckx; and Daniel Spitz, a third-generation master watchmaker and the original guitarist for the famed metal band Anthrax.

The NanoEar concept has done proof-of-concept testing on both cadavers at the University of Antwerp and on chinchillas, which are excellent models for human hearing, at Tulane University. As part of the TMC Innovation Institute program in 2017, the NanoEar team met with FDA advisors, who told them that they might be eligible for an expedited pathway to approval.

Thus far, NanoEar has raised about $900,000 to get its nine patents and perform its proof-of-concept experiments. The next step is to build the prototype, but completing it will take $2.75 million of seed funding.

Despite the potential for making global change, Moses has said it’s been challenging to raise funds for his innovation.

“We're hoping to find that group of people or person who may want to hear their children or grandchildren better. They may want to join with others and bring a team of investors to offset that risk, to move this forward, because we already have a world-class team ready to go,” he says.

To that end, NanoEar has partnered with Austin-based Capital Factory to help with their raise. “I have reached out to their entire network and am getting a lot of interest, a lot of interest,” says Moses. “But in the end, of course, we need the money.”

It will likely, quite literally, be a sound investment in the future of how we all hear the next generation.

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Eli Lilly to build $6.5B pharmaceutical factory at Generation Park

coming soon

Pharmaceutical giant Eli Lilly and Co. plans to build a $6.5 billion manufacturing plant at Houston’s Generation Park. More than 300 locations in the U.S. competed for the factory.

The Houston site will be the first major pharmaceutical manufacturing plant in Texas, according to the Greater Houston Partnership.

Lilly said it plans to hire 615 full-time workers for the 236-acre plant, including engineers, scientists and lab technicians. The company will collaborate with local colleges and universities to help build its talent pipeline.

The plant will also generate an estimated 4,000 construction jobs.

Lilly said every dollar it spends in the Houston area will contribute an additional $4 to the local economy.

“This is a transformative moment for the Houston region and our life sciences industry,” Steve Kean, president and CEO of the Greater Houston Partnership, said in a release. “The Lilly project represents one of the largest for-profit life sciences investments in Texas history and is a powerful endorsement of Houston’s growing position as a global hub for innovation, advanced manufacturing, and biomedical excellence.”

The factory, expected to go online by 2030, will make small-molecule medicines for fields such as oncology, immunology and neuroscience. Perhaps most notably, the site will manufacture orforglipron, Lilly's first oral small-molecule GLP-1 medicine for treatment of obesity and type 2 diabetes. The drug is currently undergoing clinical trials.

“Our new Houston site will enhance Lilly’s ability to manufacture orforglipron at scale and, if approved, help fulfill the medicine’s potential as a metabolic health treatment for tens of millions of people worldwide who prefer the ease of a pill that can be taken without food and water restrictions,” David Ricks, chairman and CEO of Lilly, said in a release.

The company said it chose Generation Park, a 4,300-acre, master-planned commercial district near Lake Houston, because of factors such as financial incentives, access to utilities and transportation, and the region’s business-friendly environment. Generation Park is home to campuses for San Jacinto College and Lone Star College.

The plant will be outfitted with machine learning, AI, advanced data analytics, digital automation, and similar tools to streamline operations, Lilly said.

Houston engineering firm lands $400M NASA contract

space deal

NASA has granted Houston-based Bastion Technologies Inc. the Safety and Mission Assurance II (SMAS II) award with a maximum potential value of $400 million.

The award stipulates that the engineering and technical services company provide safety and mission services for the agency’s Marshall Space Flight Center in Huntsville, Alabama, according to a release from NASA.

In the deal, Bastion’s services include system safety, reliability, maintainability, software assurance, quality engineering, independent assessment, institutional safety and pressure systems. Bastion’s work will support research and development projects, hardware fabrication and testing, spaceflight and science missions, and other activities at NASA Marshall, Michoud Assembly Facility in New Orleans, Stennis Space Center in Bay St. Louis, Mississippi, NASA’s Kennedy Space Center in Florida and various other sites.

The first base period for the SMASS II award has already begun, with the option for a base ordering period of four years to extend services through March 2034.

Bastion has been a key player in NASA’s Artemis program, and was also awarded a contract to support occupational safety, health and mission assurance at NASA’s Ames Research Center in Silicon Valley in 2024. Also in 2024, Bastion was awarded the NASA Glenn Research Center (GRC) Environmental, Safety, Health, and Mission Assurance (ESHMA) contract.

Since 1998, Bastion has held over 350 contracts at almost every NASA center and most major aerospace industry partners.

Houston research team lands $1.2M grant for ovarian cancer research

cancer funding

A team from the University of Houston and MD Anderson Cancer Center is working to find early markers for ovarian cancer.

Backed by a $1.2 million Department of Defense grant, a team led by Tianfu Wu, associate professor of biomedical engineering at UH, is studying autoantibodies that target a tumor suppressor gene that's often mutated in cancers and serves as an early marker of ovarian cancer development.

According to UH, the majority of women with ovarian cancer (70 percent and 75 percent) are diagnosed once the cancer has already spread, with the chances of survival below 32 percent. Computational models estimate that detecting ovarian cancer earlier could reduce mortality by 10 percent to 30 percent.

Doctors generally screen for ovarian cancer by measuring the rising amount of a protein known as Cancer Antigen 125 (CA125). However, additional biomarkers are needed to improve sensitivity and to detect cancer cases that are missed by CA125 testing.

“Advancing early detection methodologies is essential to improving patient prognosis and survival outcomes,” Wu said in a news release. “The technological challenges in the early detection of ovarian cancer are multifaceted, primarily due to limited sensitivity of currently available biomarkers and the absence of highly accurate biomarkers that can detect the disease well before clinical diagnosis.”

Wu’s team developed a test that detects thousands of immune reactions simultaneously by searching for immune complexes in an effort to identify new autoantibodies. They found more than 100 significantly upregulated immune complexes in ovarian cancer patients compared to healthy patients.

The team will test 10 to 20 of the biomarker candidates to assess their performance in the early detection of ovarian cancer. They will use machine learning modeling to develop computer algorithms for data analysis and disease predictions as well.

Dr. Robert C. Bast at MD Anderson Cancer Center has pioneered the practice of early detection of ovarian cancer, and is Wu’s partner on a team. Ying Lin, associate professor of industrial and systems engineering at UH, and Dr. Zhen Lu from at UT MD Anderson Cancer Center are also working on the project.