Dr. Bilgen is a current CDA-1 recipient (2008) and has a strong bioengineering background with hands-on research experience over 10 years in cartilage tissue engineering. Dr. Bilgen's research interests include bioengineering applications to clinical problems in orthopaedics, specifically skeletal biology, repair and regeneration. This application aims to develop a transplantable biocomposite to restore cartilage of a traumatized joint. Limb trauma in young veterans often results in loss of cartilage tissue function that leads to severe arthritis and osteoarthritis. Total national cost of arthritis was $81 billion in medical costs and $47 billion in lost wages in 2003. US veterans face increased risks of arthritis compared with non-veterans due to orthopedic injuries at the military. Implantation of engineered cartilage that is produced by the patient's autologous chondrocytes is not fully successful in healing cartilage defects. This project addresses two main problems in cartilage tissue engineering: 1) limited availability of adult autologous chondrocytes and limited differentiation of mesenchymal stem cells (MSC), 2) insufficient mechanical properties of engineered cartilage. Due to limited chondrocyte availability, adult mesenchymal stem cells (MSC) are widely used to produce cartilage tissue, but they do not secrete cartilage matrix at the same rate as chondrocytes. We and others have shown that co-culturing adult stem cells with chondrocytes improve the biochemical composition of engineered cartilage. Application of intermittent mechanical loading such as compression or shear during tissue cultivation has been shown to improve cartilage formation, however the optimum dose differs with cell and tissue properties. The central hypothesis is that the combination of co-culturing chondrocytes and MSC and application of biaxial mechanical loading will synergistically enhance deposition of extracellular matrix (ECM) and improve the functional properties of cartilage tissue after transplantation. Over the five-year CDA-2 program, Dr. Bilgen aims to achieve three research goals: 1- Develop a co-culture system to address the limited availability of chondrocytes: The approach is to optimize ECM deposition using a combination of chondrocytes and synovial MSC and growth factors. The expected outcome is a novel cell sourcing methodology that utilizes co-cultures of chondrocytes and synovial MSC. 2- Create a cartilage biocomposite with improved mechanical properties: We designed a novel biaxial loading device, which was shown to be compatible with the development of tissue-engineered cartilage biocomposites in long term in vitro studies. The approach is to investigate the effects of uniaxial and biaxial mechanical loading in vitro on the differentiation of cells and the mechanical properties of engineered tissue. The expected outcome is the development of a novel biaxial loading system to create a biocomposite that can successfully repair and restore function to cartilage. 3- Develop an in vivo-compatible biocomposite for cartilage repair: The approach will be to cultivate the biocomposite in vitro to improve functional properties followed by implantation in vivo in a chondral defect in a minipig model. The expected outcome is the development of a biocomposite that can successfully repair cartilage in vivo. The innovation in this grant proposal lies in the synergistic application of instructive co- culturing and a novel mechanical loading scheme on a cartilage tissue engineering system using mesenchymal stem cells. The broader impact is that the developed techniques are anticipated to treat degenerative joint diseases and prevent joint replacement surgeries, thus impacting nearly half of the population.

Public Health Relevance

This project aims to develop a transplantable biocomposite to restore cartilage of a traumatized joint. Limb trauma in young veterans often results in loss of cartilage tissue function that leads to severe arthritis and osteoarthritis. Total national cost of arthritis was $81 billion in medical costs and $47 billion in lost wages in 2003. US veterans face increased risks of arthritis compared with non-veterans due to orthopedic injuries at the military. Over the five-year CDA-2 program, Dr. Bilgen aims to develop an implantable biocomposite for cartilage repair using adult stem cells and a bioreactor that can apply mechanical stimuli on the growing tissue, which mimics the mechanical environment in the knee joint. The broader impact is that the developed techniques are anticipated to treat degenerative joint diseases and prevent joint replacement surgeries, thus impacting nearly half of the population.

Agency
National Institute of Health (NIH)
Institute
Veterans Affairs (VA)
Type
Veterans Administration (IK2)
Project #
5IK2RX000760-04
Application #
8840083
Study Section
Blank (RRD8)
Project Start
2012-04-01
Project End
2017-03-31
Budget Start
2015-04-01
Budget End
2016-03-31
Support Year
4
Fiscal Year
2015
Total Cost
Indirect Cost
Name
Providence VA Medical Center
Department
Type
DUNS #
182465745
City
Providence
State
RI
Country
United States
Zip Code
02908
Bilgen, Bahar; Jayasuriya, Chathuraka T; Owens, Brett D (2018) Current Concepts in Meniscus Tissue Engineering and Repair. Adv Healthc Mater 7:e1701407
Bautista, Catherine A; Bilgen, Bahar (2017) Decellularization and Recellularization of Cartilage. Methods Mol Biol :
Du, Guoqing; Zhan, Hongsheng; Ding, Daofang et al. (2016) Abnormal Mechanical Loading Induces Cartilage Degeneration by Accelerating Meniscus Hypertrophy and Mineralization After ACL Injuries In Vivo. Am J Sports Med 44:652-63
Bautista, Catherine A; Park, Hee Jun; Mazur, Courtney M et al. (2016) Effects of Chondroitinase ABC-Mediated Proteoglycan Digestion on Decellularization and Recellularization of Articular Cartilage. PLoS One 11:e0158976
Bilgen, Bahar; Chu, Danielle; Stefani, Robert et al. (2013) Design of a biaxial mechanical loading bioreactor for tissue engineering. J Vis Exp :e50387