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The book of life can now literally be written on paper

An insight from the labs of Harvard chemist George Whitesides and cell biologist Don Ingber is likely to make a fundamental shift in how biologists grow and study cells – and it’s as cheap and simple as reaching for a paper towel.

The steps needed to make multi-layer cultures out of uncoated paper.

Ratmir Derda, a postdoctoral student co-mentored by Whitesides and Ingber at Harvard’s new Wyss Institute for Biologically Inspired Engineering, has realized that by growing cells on several sheets of uncoated paper, he can solve a problem that has bedeviled biologists for years: how to easily grow and study cells that mimic the three-dimensionality of real tissue.

This work will simplify creation of realistic, three-dimensional models of normal or cancerous tissue — potentially making it faster and easier to find drugs that fight cancer and other diseases.

“This research has the potential to become a standard laboratory tool, alongside the Petri dish, in laboratories that work with cells,” said George M. Whitesides, the Woodford L. and Ann A. Flowers University Professor at Harvard University and a founding faculty member of the Wyss Institute. “Filter paper and other kinds of paper are readily available, and the technique is both very flexible in what it can do, and very convenient to use.”

The study, “Paper-Supported Three-Dimensional Cell Culture for Tissue-Based Bioassays,” appears in the October 19, 2009, issue of the Proceedings of the National Academy of Sciences.

Now, researchers grow cells in a Petri dish, creating a thin, two-dimensional layer of cells. If they want to do a better job of mimicking real tissue, they culture the cells in a gel. But because cells in different locations get vastly different amounts of oxygen and food, these cultures fail to mimic real tissues. And studying the cells from different parts of these gels without destroying the 3D culture is tricky.

By growing the cells in a thin layer of gel supported by paper, and then stacking those pieces of paper, the scientists showed they could recreate the benefits of two-dimensional research – where cells receive a uniform amount of oxygen and food — while also closely mimicking real tissue. In this case, they engineered a 3D tumor on paper that exhibited behaviors similar to a cancer in the body.

Endothelial cells grown in small stacks of paper, forming vessel-like structures that crawl among the cellulose fibers (cellulose fibers are purple, nucleus is yellow and the cytoskeleton is red).

Stacking multiple cell-containing sheets also allows researchers to examine the interior of a large cell cluster, either cultured on a dish or grown in vivo, simply by peeling the layers apart, without disturbing the properties of the cells. Isolating cells grown with other 3D culture techniques requires either performing complex laser-assisted surgery on the tumor sections or destroying the architecture of the tissue and then sorting the cells.

 

Derda said he had the initial insight that led to this study when he heard a colleague complain that he couldn’t use paper to filter blood, because the erythrocytes, which give blood their red color, are sometimes trapped in the paper and sometimes go through it. Derda, who developed and used peptide arrays for stem cell research in his Ph.D. work, thought he might be able to use this trapping property for high-throughput screening. When he discussed that insight with Whitesides, the older chemist suggested Derda try stacking the pages instead.

Fellow postdoctoral student Anna Laromaine helped Derda figure out how to clip multiple layers of paper together while submerged in the gel, allowing the first multi-layer cell culture to grow. When he gingerly pulled the sheets of paper apart and analyzed the distribution of cells in different layers, he realized the versatility of paper as a growing medium and its potential to mimic any three-dimensional tissue.

“The best thing about this approach is that it can be used by everyone,” Derda said. “Paper is nearly free, it’s all over the place and you don’t have to know anything other than how to dip.”

The work was supported by funds from the Wyss Institute, National Institutes of Health, Vertex Inc., DoD Breast Cancer Innovator Award, the Fulbright-Generalitat de Catalunya, and the American Heart Association.

In addition to Derda, Whitesides and Ingber, the founding director of the Wyss Institute, a faculty member at Harvard’s Medical School and its School of Engineering and Applied Sciences, and a researcher at Children’s Hospital Boston, the paper’s other authors are: Akiko Mammoto and Tadanori Mammoto of Ingber’s lab, and Laromaine and Sindy K. Y. Tang of Whitesides’ lab.

The Wyss Institute for Biologically Inspired Engineering at Harvard was created at the start of 2009 with a $125 million gift from entrepreneur Hansjorg Wyss. Developed as an alliance between Harvard and other premier academic and clinical partners, the Institute’s faculty and staff collaborate in high-risk, fundamental science-driven technology development that strives to exploit the way Nature builds.

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