Ophelia Venturelli: Manipulating the Microbial Interactions in our Guts

9/16/24 Pratt School of Engineering

New faculty member Ophelia Venturelli explores how the microbial world in our gastrointestinal tract can be engineered to keep us healthy

Ophelia Venturelli: Manipulating the Microbial Interactions in our Guts

Ophelia Venturelli joined the faculty of Duke University’s Department of Biomedical Engineering on August 1, 2024. Using a combination of computational modeling and high-throughput experiments and synthetic biology, Venturelli strives to understand how the bustling communities of microbes within our gastrointestinal system can be engineered to improve human health.

Our guts contain an invisible world filled with trillions of microbes. These microscopic organisms help us digest our food, produce and degrade molecules that impact gut-brain communication, train our immune system and protect us from infections by harmful bacteria. The critical role of these microbial communities in shaping our physiology and behavior is clear, but a quantitative understanding how these organisms interact and how this ecosystem could be predictably manipulated to our benefit is not.

But Venturelli is working to change that.

Ophelia Venturelli Portrait

Every person’s microbiome is unique. We want to understand how the interactions between different types of microbes control the outputs of this community, from inhibiting human gut pathogens to the dynamic production of metabolites that shape our immune response and gut-brain signaling. We integrate computational and experimental techniques to decipher these interactions from molecular to ecological scales and develop approaches using synthetic biology to control them for therapeutic purposes.

Ophelia Venturelli Associate Professor of Biomedical Engineering

In previous work, Venturelli and her team explored how they could use these gut microbe interactions to design a precision therapeutic for inhibiting Clostridioides difficile, or C. diff., a bacterium that can cause serious infections in the colon. Symptoms can range from mild diarrhea and stomach pain to significant colon damage, which can sometimes require surgery.

“Antibiotics are used as a first-line treatment for C. diff., and while it may work for a majority of cases, a significant minority of patients will often experience a recurrent infection,” said Venturelli. Patients with these recurring infections get stuck taking more antibiotics, further disrupting their gut microbiome and making them more likely to get another infection.

But there is an alternative treatment option.

“Recurrent infections can be effectively treated with a fecal microbiota transplantation, where stool from a healthy donor is transplanted into a patient with C. diff.,” Venturelli said. “The transplant introduces healthy bacteria to the patient’s microbiome, which interact to treat the infection.”

Although these fecal microbiota transplants are remarkably effective, they are not a widespread solution.  While they may contain microbes that help resolve a C. diff. infection, other microbes in the sample may trigger different health problems in the recipient. And there is no way to standardize or scale up the therapy.

Instead, one of Venturelli’s goals is to develop a framework for designing precision probiotics combined with potential dietary interventions that can replace both antibiotics and fecal transplants as a therapy by using combinations of gut bacteria and dietary fibers that have been shown to safely eradicate the pathogen.

In her new role at Duke, Venturelli and her team aim to expand on this work by exploring how they can develop similar precision probiotics to treat illnesses caused by drug-resistant bacteria and therapeutics that could help gut bacteria produce helpful molecules to treat disease.

“One of the things we explore is how to design precision interventions that enhance beneficial metabolites such as butyrate or tailor secondary bile acid profiles, which helps maintain cells in the intestinal tract,” she said. “If we could figure out ways to predictably increase butyrate, we could potentially reduce disease propensities or even treat and prevent gastrointestinal illnesses like inflammatory bowel disease.”

Venturelli is already looking forward to collaborating with researchers in disciplines spanning medicine, synthetic biology, gut-brain communication and immune engineering as she pursues this work at Duke.

“Our lab will synergize with Duke’s strengths in medicine, automation and machine learning, protein engineering and synthetic biology,” she said. “I’m excited about the work I’ll be able to accomplish with researchers across the department.”

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