Even in an era in which there is increased emphasis on living “green,” humans are constantly exposed to a wide range of toxins in everything from our air, food and water to the goods we buy.
And while we know the harmful effects of such substances as phthalates, VOCs, asbestos, lead and others, there are tens of thousands of toxins present in our environment for which that information is yet unknown.
“To date, we do not have a good understanding of how environmental chemicals might influence human tissues,” says William Murphy, WID Discovery Fellow and the Harvey D. Spangler professor of biomedical engineering and orthopedics and rehabilitation at the University of Wisconsin-Madison.
Murphy is leading a diverse team of UW–Madison researchers who received $6 million from the U.S. Environmental Protection Agency to develop models and screening tools that will rapidly advance knowledge of the health effects of today’s ever-growing assortment of environmental toxins. Awarded through the EPA Science to Achieve Results, or STAR, program, the grant will create the Human Models for Analysis of Pathways (H-MAPs) Center at UW-Madison.
With connections to the College of Engineering, the School of Medicine and Public Health, the School of Veterinary Medicine, the Morgridge Institute for Research at UW-Madison, the research team includes leading experts in human pluripotent stem cell biology, tissue development and microscale tissue engineering.
“This EPA center is a prime example of the interdisciplinary research excellence at the University of Wisconsin-Madison, as it builds upon our recognized leadership in stem cell biology and bioengineering,” says UW-Madison Chancellor Rebecca Blank. “The center promises to fundamentally transform our understanding of how chemicals in the environment can affect human tissues.”
Traditionally, researchers have relied heavily on observing adverse health responses in laboratory animals treated with high doses of toxic compounds.
“There’s a big vacuum of information in this field about how chemicals in our environment affect human tissues, and we were motivated by the underserved need.”
— Bill Murphy
However, recognizing the need for a paradigm shift that transforms chemical toxicity testing, the researchers will draw on their combined expertise to develop “organotypic” culture models — those that mimic human organs — as well as robust, practical technological tools that allow researchers to rapidly and reliably screen many toxins simultaneously.
“There’s a big vacuum of information in this field about how chemicals in our environment affect human tissues, and we were motivated by the underserved need,” says Murphy. “The long-term goal is to replace animal models, and use human micro-scale tissues in a dish to re-create the complex physiology of human tissue.”
Researchers in the H-MAPs Center will focus specifically on surmounting critical obstacles in organotypic toxin screening in the liver, neural and vascular systems, as well as the role of chemicals in breast cancer. And their suite of innovative technologies will support each of these efforts; the researchers will assemble the organotypic models in highly reproducible synthetic matrices, use automated microscale systems to translate the models to high-throughput screening platforms, and use bioinformatics-based pathway analysis to study toxins’ effect on human tissue. “Taken together, these innovative technologies are poised to transform organotypic human models from curious scientific concepts into robust, pragmatic tools for next-generation toxicity testing,” says Murphy.
Thrust leaders within the center include James Thomson, WID researcher Randolph Ashton, David Beebe and Nader Sheibani. Thomson — director of regenerative biology in the Morgridge Institute for Research, the James Kress professor of embryonic stem cell biology, and the John D. MacArthur professor in the School of Medicine and Public Health at UW-Madison — is leading the effort to generate organotypic models that represent mature liver tissue.
Ashton, an assistant professor of biomedical engineering and a member of the BIONATES thrust in WID, is leading the effort to develop a phenotypically diverse, human pluripotent stem cell-derived screening platform for neural cells. Beebe, the John D. MacArthur professor and Claude Bernard professor of biomedical engineering, is leading the effort to apply a novel organotypic in vitro approach to studying estrogen-receptor-mediated breast cancer and identify chemical contributors. Sheibani, a professor of opthalmology and visual sciences, is leading the effort to develop human pluripotent stem cell-derived organotypic vascular networks for high-throughput toxin screening.
In addition, WID researcher Sushmita Roy, an assistant professor of biostatistics and medical informatics, is leading a pathway analysis core that will help researchers understand human tissue assembly and the tissues’ responses to chemicals.
Other collaborators on the grant include Brian McIntosh, an assistant automation scientist in the Morgridge Institute for Research (MIR); Ron Stewart, associate director of bioinformatics in MIR; Krishanu Saha, an assistant professor of biomedical engineering and a member of the BIONATES in WID; Kyung Sung, an assistant scientist in biomedical engineering; Linda Schuler, a professor in the School of Veterinary Medicine; and Mohammad Ali Saghiri, a research associate in opthalmology and visual sciences.
– Renee Meiller, College of Engineering
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