The proof-of-concept study is published online in advance of print in Tissue Engineering Part A.
“For the first time, we have established that a single source of hESC can provide the multiple cell types needed to interact within a three-dimensional tissue model to generate complex, multilayer tissues. We are a step closer to a practical therapy to help with diseases of the skin and mouth,” said Jonathan Garlick, DDS, PhD, professor of oral and maxillofacial pathology at Tufts University School of Dental Medicine and a member of the cell, molecular & developmental biology program faculty at the Sackler School of Biomedical Sciences at Tufts.
“Researchers have been seeking methods to grow skin-like tissues outside of the body using new sources of stem cells such as hESC, with the goal of advancing regenerative medicine as a new therapy to replace or repair damaged or diseased tissue. Little is known about how hESC can be developed into the multilayer tissues similar to those that line the gums, cheeks, lips, and other areas in the mouth. We used in vitro tissue engineering techniques to produce skin-like tissues that mimic the lining tissues found in the oral cavity,” said Garlick.
Using a combination of chemical nutrients and specialized surfaces for cell attachment, an hES cell line (H9) was directed to form two distinct specialized cell populations. The first population forms the surface layer (ectodermal, the precursor to epithelial tissue), while the second is found beneath the surface layer (mesenchymal).
Following the isolation and characterization of these cell populations, the researchers incorporated them into an engineered, three-dimensional tissue system where they were grown at an air-liquid interface to mimic their growth environment in the oral cavity. Within two weeks, tissues developed that were similar in structure to those constructed using mature cells derived from newborn skin, which are the current gold standard for tissue fabrication.
“These engineered tissues are remarkably similar to their human counterparts and can be used to address major concerns facing the field of stem cell biology that are related to their clinical use. We can now use these engineered tissues as ‘tissue surrogates’ to begin to predict how stable and safe hESC-derived cells will be after therapeutic transplantation. Our goal is to produce functional tissues to treat oral and skin conditions, like the early stages of cancer and inflammatory disease, as well as to accelerate the healing of recalcitrant wounds,” said Garlick.
First author Kyle Hewitt is a graduate student in cell, molecular & developmental biology program at the Sackler School of Graduate Biomedical Science at Tufts and is a member of Garlick’s lab.
This study was supported by the National Institute of Dental and Craniofacial Research at the National Institutes of Health.
Garlick is also director of the Center for Integrated Tissue Engineering (CITE) at Tufts University School of Dental Medicine, which is dedicated to furthering the understanding of regenerative medicine through the investigation of three-dimensional tissue models. He has written more than over 60 articles and book chapters on this and related subjects. CITE is now using hESC as a pre-clinical paradigm that now serves as as a translational modality to provide more meaningful correlations between in vitro screening assays for toxicity and efficacy and in vivo tissue outcomes in human clinical trials.
Hewitt K, Shamis Y, Carlson M, Aberdam E, Aberdam D, and Garlick J. Tissue Engineering Part A. “Three-dimensional epithelial tissues generated from human embryonic stem cells.” Published online July 6, 2009 in advance of print, doi: 10.1089/ten.tea.2009.0060
About Tufts University School of Dental Medicine Founded in 1868, Tufts University School of Dental Medicine (TUSDM) is committed to leadership in education, patient care, research and community service. Students obtain an interdisciplinary education, integrated with medicine, with access to training in dental specialties. Clinics managed at TUSDM provide quality comprehensive care to more than 18,000 diverse individuals annually, including those requiring special needs. Nationally and internationally, the School promotes health and educational programs and researches new procedures, materials and technologies to improve oral health.
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