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Expert: Houston has potential to be a major hub for life sciences — if it addresses these concerns

A Houston life science expert shares what she thinks Houston needs to work on to continue growing as an health care innovation ecosystem. Photo via Getty Images

Once upon a time in Houston, a promising startup, let’s call it BioMatrix, set out to revolutionize the world of biomaterials. Their groundbreaking product held immense potential, but the company faced the harsh reality of a lack of funding, resources, and talent in their local life sciences sector.

As they watched well-funded competitors in established hubs like Boston and Silicon Valley flourish, the passionate team at BioMatrix persevered, determined to overcome these challenges, and make their mark in the rapidly evolving world of MedTech and life sciences. But would they ultimately move to a richer life science hub?

Over the years, Houston has emerged as a life sciences hub, fueled by the world's largest medical center, Texas Medical Center, and an expanding network of research institutions, startups, and investors. However, despite all its potential, the city still lags other innovation hubs and isn’t included in many of the lists for top life science ecosystems. The challenges are many-fold, but some primary challenges are associated with lack of capital, trouble with talent acquisition, and weak collaboration.

Despite an uptick in venture capital funding, Houston's life sciences sector still trails the likes of Silicon Valley and Boston. Programs like CPRIT help keep companies within Texas, while Houston's unique advantages, such as lower living costs and the TMC's presence, can attract investments, but ultimately, to secure necessary capital, stakeholders must cultivate relationships with investors, government agencies, and other funding sources to infuse more money into the Houston ecosystem. And, when individuals try to do this, the rest of the ecosystem must be supportive.

Talent retention and attraction pose another challenge, as Houston competes with well-funded life science hubs offering abundant research institutions and funding opportunities. While Houston boasts numerous educational institutions producing skilled life sciences graduates, many curricula primarily prepare students for academic rather than industry careers, creating a skills and knowledge gap.

Having a lot of experience in academia doesn’t often translate well into the industry, as is demonstrated by many startup founders who struggle to understand the various stakeholder requirements in bringing a life science product to market.

To bridge this, educational institutions should incorporate more industry-oriented courses and training programs, like Rice University’s GMI Program, that emphasize practical skills and real-world applications. Collaborating with local companies for internships, co-op placements, and hands-on experiences can expose students to industry practices and foster valuable connections.

For any life science company, navigating the intricate regulatory landscape is also a challenge, as missteps can be disastrous. However, it’s even more of a challenge when you lack the fundamentals knowledge of what is required and the skills to effectively engage with industry experts in the space.

To address this, Houston must provide more opportunities for companies to learn about regulatory complexities from experts. Workshops, accelerators, or dedicated graduate and undergraduate courses focusing on regulatory compliance and best practices can facilitate knowledge and experience exchange between regulatory experts and innovators.

The initial inception of M1 MedTech was the result of a personal experience with a company who didn’t understand the fundamentals for regulatory interactions and didn’t know how to appropriately engage with consultants, resulting in time and money wasted.

Enhancing collaboration among Houston's life science stakeholders — including academia, research institutions, healthcare providers, subject matter experts, innovators, and investors — is fundamental for growth. A robust and lively professional network can stimulate innovation and help emerging companies access essential resources.

To this end, Houston should organize more industry-specific events, workshops, and conferences, connecting key life science players and showcasing the city's commitment to innovation. These events can also offer networking opportunities with industry leaders, attracting and retaining top talent. We’ve seen some of this with the Texas Life Science Forum and now with the Ion's events, but we could afford to host a lot more.

Houston's life sciences sector holds immense growth potential, but addressing funding, talent recruitment, regulatory navigation, and collaboration challenges is needed for continued success. By tackling these issues and leveraging its unique strengths, Houston can establish itself as a significant player in the global life sciences arenas. If we wait too long, we won’t be able to truly establish the Third Coast because another player will come into the mix, and we’ll lose companies like BioMatrix to their golden shores.

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Isabella Schmitt is the director of regulatory affairs at Proxima Clinical Research and principal at M1 MedTech.

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A research team housed out of the newly launched Rice Biotech Launch Pad received funding to scale tech that could slash cancer deaths in half. Photo via Rice University

A research funding agency has deployed capital into a team at Rice University that's working to develop a technology that could cut cancer-related deaths in half.

Rice researchers received $45 million from the National Institutes of Health's Advanced Research Projects Agency for Health, or ARPA-H, to scale up development of a sense-and-respond implant technology. Rice bioengineer Omid Veiseh leads the team developing the technology as principal investigator.

“Instead of tethering patients to hospital beds, IV bags and external monitors, we’ll use a minimally invasive procedure to implant a small device that continuously monitors their cancer and adjusts their immunotherapy dose in real time,” he says in a news release. “This kind of ‘closed-loop therapy’ has been used for managing diabetes, where you have a glucose monitor that continuously talks to an insulin pump. But for cancer immunotherapy, it’s revolutionary.”

Joining Veiseh on the 19-person research project named THOR, which stands for “targeted hybrid oncotherapeutic regulation,” is Amir Jazaeri, co-PI and professor of gynecologic oncology at the University of Texas MD Anderson Cancer Center. The device they are developing is called HAMMR, or hybrid advanced molecular manufacturing regulator.

“Cancer cells are continually evolving and adapting to therapy. However, currently available diagnostic tools, including radiologic tests, blood assays and biopsies, provide very infrequent and limited snapshots of this dynamic process," Jazaeri adds. "As a result, today’s therapies treat cancer as if it were a static disease. We believe THOR could transform the status quo by providing real-time data from the tumor environment that can in turn guide more effective and tumor-informed novel therapies.”

With a national team of engineers, physicians, and experts across synthetic biology, materials science, immunology, oncology, and more, the team will receive its funding through the Rice Biotech Launch Pad, a newly launched initiative led by Veiseh that exists to help life-saving medical innovation scale quickly.

"Rice is proud to be the recipient of the second major funding award from the ARPA-H, a new funding agency established last year to support research that catalyzes health breakthroughs," Rice President Reginald DesRoches says. "The research Rice bioengineer Omid Veiseh is doing in leading this team is truly groundbreaking and could potentially save hundreds of thousands of lives each year. This is the type of research that makes a significant impact on the world.”

The initial focus of the technology will be on ovarian cancer, and this funding agreement includes a first-phase clinical trial of HAMMR for the treatment of recurrent ovarian cancer that's expected to take place in the fourth year of THOR’s multi-year project.

“The technology is broadly applicable for peritoneal cancers that affect the pancreas, liver, lungs and other organs,” Veiseh says. “The first clinical trial will focus on refractory recurrent ovarian cancer, and the benefit of that is that we have an ongoing trial for ovarian cancer with our encapsulated cytokine ‘drug factory’ technology. We'll be able to build on that experience. We have already demonstrated a unique model to go from concept to clinical trial within five years, and HAMMR is the next iteration of that approach.”

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