The ultimate goal of this research project is to develop a novel injectable, bilayered, biodegradable hydrogel composite for the co-delivery of chondrogenic growth factors and mesenchymal stem cells (MSCs) to influence the degree and quality of cartilage tissue regeneration within osteochondral defects. We hypothesize that controlled dual delivery of transforming growth factor-21 (TGF-21) and insulin-like growth factor-1 (IGF-1) using optimal release kinetics and doses will induce chondrogenic differentiation of progenitor cells within the recipient to influence the regeneration of cartilage tissue in an osteochondral defect. Additionally, we hypothesize that the duration of exposure of MSCs to TGF-21 and osteogenic medium supplements during in vitro expansion will modulate the chondrogenic and osteogenic differentiation stages of the cells, respectively, which will in turn influence the degree and quality of osteochondral tissue regeneration when the cells are encapsulated within and transplanted with a hydrogel construct. Finally, we hypothesize that the co-delivery of growth factor(s) from hydrogel composites, coupled with the transplantation of progenitor cells encapsulated within the hydrogels will act cooperatively to promote regeneration of cartilage tissue in an osteochondral defect, with the initial cell seeding density influencing the degree and quality of the cartilage regeneration. To address these hypotheses, three Specific Aims are proposed. First, TGF-21 and IGF-1 will be loaded into OPF hydrogel constructs at different doses and released with different kinetics to determine the effect of these parameters on tissue regeneration in a rabbit osteochondral defect. Second, MSCs will be exposed to TGF-21 as a chondrogenic culture medium supplement or osteogenic medium supplements for various durations to result in cells of different chondrogenic and osteogenic differentiation stages, respectively, then they will be encapsulated within and transplanted with OPF hydrogel scaffolds (without loaded growth factors) into a rabbit osteochondral defect model to assess the effect of the differentiation stages of the transplanted cells upon osteochondral tissue regeneration. Third, cells of the optimal differentiation stages will be encapsulated for transplantation within OPF scaffolds corresponding to the optimal growth factor delivery formulation and will be implanted into rabbit osteochondral defects to determine the optimal seeding density of the progenitor cells for osteochondral tissue regeneration, which will be assessed post-implantation through histomorphometric analysis and mechanical testing. This novel strategy for the concurrent and spatially defined delivery of chondrogenic growth factors and in vitro expanded autologous progenitor cells to osteochondral defects presents tremendous potential for clinical translation and osteochondral tissue regeneration.

Public Health Relevance

Due to the limited natural ability of cartilage tissue to repair itself, damage to articular cartilage and underlying bone often leads to significant clinical problems that afflict millions of people worldwide, including pain, limited mobility and osteoarthritis. No strategies currently exist that are consistently successful in treating cartilage defects of this nature. The project described in this proposal aims to develop novel injectable, bilayered, degradable materials that can be implanted as a vehicle for the concurrent delivery of bioactive molecules and adult derived stem cells to promote regeneration of damaged cartilage tissue.

Agency
National Institute of Health (NIH)
Institute
National Institute of Arthritis and Musculoskeletal and Skin Diseases (NIAMS)
Type
Research Project (R01)
Project #
5R01AR048756-08
Application #
8289677
Study Section
Musculoskeletal Tissue Engineering Study Section (MTE)
Program Officer
Wang, Fei
Project Start
2002-04-01
Project End
2015-06-30
Budget Start
2012-07-01
Budget End
2013-06-30
Support Year
8
Fiscal Year
2012
Total Cost
$320,816
Indirect Cost
$104,816
Name
Rice University
Department
Biomedical Engineering
Type
Schools of Engineering
DUNS #
050299031
City
Houston
State
TX
Country
United States
Zip Code
77005
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Lam, Johnny; Clark, Elisa C; Fong, Eliza L S et al. (2016) Evaluation of cell-laden polyelectrolyte hydrogels incorporating poly(L-Lysine) for applications in cartilage tissue engineering. Biomaterials 83:332-46
Lam, Johnny; Clark, Elisa C; Fong, Eliza L S et al. (2016) Data describing the swelling behavior and cytocompatibility of biodegradable polyelectrolyte hydrogels incorporating poly(L-lysine) for applications in cartilage tissue engineering. Data Brief 7:614-9
Lam, Johnny; Lu, Steven; Kasper, F Kurtis et al. (2015) Strategies for controlled delivery of biologics for cartilage repair. Adv Drug Deliv Rev 84:123-34
Madhurakkat Perikamana, Sajeesh Kumar; Lee, Jinkyu; Lee, Yu Bin et al. (2015) Materials from Mussel-Inspired Chemistry for Cell and Tissue Engineering Applications. Biomacromolecules 16:2541-55
Watson, Brendan M; Vo, Tiffany N; Tatara, Alexander M et al. (2015) Biodegradable, phosphate-containing, dual-gelling macromers for cellular delivery in bone tissue engineering. Biomaterials 67:286-96
Trachtenberg, Jordan E; Vo, Tiffany N; Mikos, Antonios G (2015) Pre-clinical characterization of tissue engineering constructs for bone and cartilage regeneration. Ann Biomed Eng 43:681-96
Tatara, Alexander M; Kretlow, James D; Spicer, Patrick P et al. (2015) Autologously generated tissue-engineered bone flaps for reconstruction of large mandibular defects in an ovine model. Tissue Eng Part A 21:1520-8
Lu, Steven; Lam, Johnny; Trachtenberg, Jordan E et al. (2015) Technical Report: Correlation Between the Repair of Cartilage and Subchondral Bone in an Osteochondral Defect Using Bilayered, Biodegradable Hydrogel Composites. Tissue Eng Part C Methods 21:1216-25
Wang, Limin; Lu, Steven; Lam, Johnny et al. (2015) Fabrication of cell-laden macroporous biodegradable hydrogels with tunable porosities and pore sizes. Tissue Eng Part C Methods 21:263-73

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