Nature’s remedies: Using viruses against drug-resistant bacteria

“The story of how phages saved Tom’s life and have helped others, the tremendous depth of scientific knowledge and medical practice, combined with intuition, innovation and just sheer guts, is what UC San Diego is all about,” said Khosla. “IPATH captures many of our most cherished ambitions: a robust, interdisciplinary research that advances science, but also delivers tangible benefits to patients and society. Phage therapy has the potential to save millions of lives.”

Steffanie Strathdee, associate dean of global health sciences and Harold Simon Professor in the Department of Medicine, and Robert Schooley, MD, professor of medicine and an infectious disease expert at UC San Diego School of Medicine, will be co-directors of IPATH. It was Strathdee, who is married to Patterson, who collaborated with Schooley and others to seek an emergency compassionate-use exemption to experimentally treat her husband with phages after all standard antibiotic treatments failed.

“IPATH builds upon what we’ve learned and will apply rigorous principles that span from bench to bedside to better understand the potential role for phage therapeutics in the treatment of patients with infections that cannot successfully be treated with currently available antibiotics,” said Strathdee.

“It taps into and enhances a wide range of existing clinical and translational research programs — there are few places in the world with similar resources to treat multidrug-resistant bacterial infections — and fosters emerging collaborations with the U.S. Navy Medical Research Center, industry partners and the strengths of the UC San Diego Health system.”

Strathdee and Schooley said IPATH will use existing resources at UC San Diego Antiviral Research Center to build the infrastructure needed to validate phage therapy for treating multidrug-resistant bacterial infections in clinical settings.

It will also partner with other like-minded institutions, including the Center for Phage Technology (CPT) at Texas A&M University, San Diego State University and two biotechnology companies specializing in the development of therapeutic bacteriophages: Ampliphi Biosciences, based in San Diego, and Adaptive Phage Therapeutics, Inc. or APT, based in Maryland.

“The CPT has been developing phages as agents for combating bacterial infections in plants, animals and humans since 2010, and promoting best practices for the ethical and sustainable use of this technology,” said Ryland F. Young III, CPT director and Regents Professor at Texas A&M. “The CPT fully supports the establishment of IPATH at UC San Diego, and based on our past collaboration that resulted in successful application of phage therapeutics, we look forward to fruitful interactions in the future.”

Schooley said a primary goal of IPATH is to conduct rigorous clinical trials of phage therapies, thus advancing their potential to practical application: “The clinical research will be integrated with leading-edge translational and basic research that will provide critical insights into the mechanisms by which phage selectively kill their bacterial targets, and that will accelerate the development of more advanced clinical research that we hope will lead the FDA to make phage therapeutics more widely available.

“That requires a lot of things: clinical trial infrastructure and design expertise, microbiome expertise, a patient population needing novel interventions like phage therapy who wish to join us in this journey. Although all of these elements are here, we plan to work with a wide range of partners around the world to advance phage therapeutics from anecdote to a globally available tool to combat the rising tide of multidrug resistant infections.”

Initial research will focus on patients with multidrug-resistant chronic infections associated with cystic fibrosis, organ transplantation and implantable hardware, such as pacemakers or joint replacements.

“The launch of IPATH is a momentous and gratifying step,” said Hubert Mazure, the great-grandson of Félix d’Herelle, the French-Canadian microbiologist who discovered bacteriophages in 1917 at the Pasteur Institute and was the first to experiment with them in treating human diseases caused by pathogenic bacteria. “This is the kind of effort needed to truly and fully explore the healing potential of bacteriophages in the modern era.”