Building a biotech workforce: How this Houston program is shaping the next generation

future focused

The goal of the Texas Medical Center's BioPath program is to attract young people considering going into the trades to learn the skills to become biomanufacturing professionals. Photo via TMC

Houston is currently in need of biomanufacturing professionals to keep up with the ever-growing industry. That's what Saniya Mansuri, health care consultant for BioPath @ TMC, says.

“Houston has lost out on a big biopharmaceutical company. And when there was a feasibility study that was done, it was identified that one of the reasons that Houston wasn't chosen was the lack of a workforce and a lack of workforce development programs,” she explains.

Mansuri and the TMC Innovation team are doing just that with the introduction of the new program. She moved from Toronto in 2023. When she applied for a role at TMC Innovation, she was handpicked to help shepherd the BioPath program, thanks to her background that included starting a nonprofit for underserved youth in Canada.

The goal of the BioPath program is to attract young people considering going into the trades to learn the skills to become biomanufacturing professionals. According to BioPath’s website, 42 percent of TMC institutions anticipate a great need for biotechnicians in the near future, but there’s a lack of places for workers to train that aren’t part of a four-year degree. BioPath not only helps to recruit youths to careers that only require two years of training, but educates them for success in their newly chosen jobs.

“For the role of biomanufacturing technician, you can do a certificate program, get certified and enter into an entry level career that pays upwards of $50,000 — a stable career where there is a lot of development and job mobility involved,” says Mansuri.

This school year saw the debut of a pilot program that began with marketing and awareness to begin to get kids excited. Working with the organization Bridge Year, BioPath has created a booth for career fairs at which there’s a simulation of the skills involved in column chromatography that potential technicians would be learning. The booth is currently touring HISD high schools.

BioPath is also partnering with the national nonprofit, Learning Undefeated, to create a mobile STEM lab that will park at schools starting in January.

“Instead of students going to a biology class, you would swap it out for a class on this mobile STEM lab, and we have a biomanufacturing activity and curriculum that the students would learn,” explains Mansuri.

But that’s only the beginning. BioPath is looking at securing internships for the students, as well as sponsoring interested students in attending a biomanufacturing summer camp run by Texas A&M. Once educated, Mansuri and her team will help their charges with certification, mentorship and finding jobs post-certification.

Mansuri says she’s already received emails from interested students who have taken part in the “Career Test Drive” booth, but expects more after a soft launch in February in which 200 high school students will come to the TMC to learn more. The future for biomanufacturing in Houston is looking more promising already.

Ad Placement 300x100
Ad Placement 300x600

CultureMap Emails are Awesome

Property Showcase

MD Anderson makes AI partnership to advance precision oncology

AI Oncology

Few experts will disagree that data-driven medicine is one of the most certain ways forward for our health. However, actually adopting it comes at a steep curve. But what if using the technology were democratized?

This is the question that SOPHiA GENETICS has been seeking to answer since 2011 with its universal AI platform, SOPHiA DDM. The cloud-native system analyzes and interprets complex health care data across technologies and institutions, allowing hospitals and clinicians to gain clinically actionable insights faster and at scale.

The University of Texas MD Anderson Cancer Center has just announced its official collaboration with SOPHiA GENETICS to accelerate breakthroughs in precision oncology. Together, they are developing a novel sequencing oncology test, as well as creating several programs targeted at the research and development of additional technology.

That technology will allow the hospital to develop new ways to chart the growth and changes of tumors in real time, pick the best clinical trials and medications for patients and make genomic testing more reliable. Shashikant Kulkarni, deputy division head for Molecular Pathology, and Dr. J. Bryan, assistant professor, will lead the collaboration on MD Anderson’s end.

“Cancer research has evolved rapidly, and we have more health data available than ever before. Our collaboration with SOPHiA GENETICS reflects how our lab is evolving and integrating advanced analytics and AI to better interpret complex molecular information,” Dr. Donna Hansel, division head of Pathology and Laboratory Medicine at MD Anderson, said in a press release. “This collaboration will expand our ability to translate high-dimensional data into insights that can meaningfully advance research and precision oncology.”

SOPHiA GENETICS is based in Switzerland and France, and has its U.S. offices in Boston.

“This collaboration with MD Anderson amplifies our shared ambition to push the boundaries of what is possible in cancer research,” Dr. Philippe Menu, chief product officer and chief medical officer at SOPHiA GENETICS, added in the release. “With SOPHiA DDM as a unifying analytical layer, we are enabling new discoveries, accelerating breakthroughs in precision oncology and, most importantly, enabling patients around the globe to benefit from these innovations by bringing leading technologies to all geographies quickly and at scale.”

Houston company plans lunar mission to test clean energy resource

lunar power

Houston-based natural resource and lunar development company Black Moon Energy Corporation (BMEC) announced that it is planning a robotic mission to the surface of the moon within the next five years.

The company has engaged NASA’s Jet Propulsion Laboratory (JPL) and Caltech to carry out the mission’s robotic systems, scientific instrumentation, data acquisition and mission operations. Black Moon will lead mission management, resource-assessment strategy and large-scale operations planning.

The goal of the year-long expedition will be to gather data and perform operations to determine the feasibility of a lunar Helium-3 supply chain. Helium-3 is abundant on the surface of the moon, but extremely rare on Earth. BMEC believes it could be a solution to the world's accelerating energy challenges.

Helium-3 fusion releases 4 million times more energy than the combustion of fossil fuels and four times more energy than traditional nuclear fission in a “clean” manner with no primary radioactive products or environmental issues, according to BMEC. Additionally, the company estimates that there is enough lunar Helium-3 to power humanity for thousands of years.

"By combining Black Moon's expertise in resource development with JPL and Caltech's renowned scientific and engineering capabilities, we are building the knowledge base required to power a new era of clean, abundant, and affordable energy for the entire planet," David Warden, CEO of BMEC, said in a news release.

The company says that information gathered from the planned lunar mission will support potential applications in fusion power generation, national security systems, quantum computing, radiation detection, medical imaging and cryogenic technologies.

Black Moon Energy was founded in 2022 by David Warden, Leroy Chiao, Peter Jones and Dan Warden. Chiao served as a NASA astronaut for 15 years. The other founders have held positions at Rice University, Schlumberger, BP and other major energy space organizations.

Houston co. makes breakthrough in clean carbon fiber manufacturing

Future of Fiber

Houston-based Mars Materials has made a breakthrough in turning stored carbon dioxide into everyday products.

In partnership with the Textile Innovation Engine of North Carolina and North Carolina State University, Mars Materials turned its CO2-derived product into a high-quality raw material for producing carbon fiber, according to a news release. According to the company, the product works "exactly like" the traditional chemical used to create carbon fiber that is derived from oil and coal.

Testing showed the end product met the high standards required for high-performance carbon fiber. Carbon fiber finds its way into aircraft, missile components, drones, racecars, golf clubs, snowboards, bridges, X-ray equipment, prosthetics, wind turbine blades and more.

The successful test “keeps a promise we made to our investors and the industry,” Aaron Fitzgerald, co-founder and CEO of Mars Materials, said in the release. “We proved we can make carbon fiber from the air without losing any quality.”

“Just as we did with our water-soluble polymers, getting it right on the first try allows us to move faster,” Fitzgerald adds. “We can now focus on scaling up production to accelerate bringing manufacturing of this critical material back to the U.S.”

Mars Materials, founded in 2019, converts captured carbon into resources, such as carbon fiber and wastewater treatment chemicals. Investors include Untapped Capital, Prithvi Ventures, Climate Capital Collective, Overlap Holdings, BlackTech Capital, Jonathan Azoff, Nate Salpeter and Brian Andrés Helmick.

---

This article originally appeared on our sister site, EnergyCapitalHTX.com.

View All Listings