Articular cartilage tissue engineering using chondrogenic progenitor cell homing and 3D bioprinting

Articular cartilage damage associated with joint trauma seldom heals and often leads to osteoarthritis (OA). Current treatment often fails to regenerated functional cartilage close to native tissue. We previously identified a migratory chondrogenic progenitor cell (CPC) population that responded che...

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Main Author: Yu, Yin
Other Authors: Martin, James A.
Format: Others
Language:English
Published: University of Iowa 2015
Subjects:
Online Access:https://ir.uiowa.edu/etd/6895
https://ir.uiowa.edu/cgi/viewcontent.cgi?article=8429&context=etd
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spelling ndltd-uiowa.edu-oai-ir.uiowa.edu-etd-84292019-11-09T09:30:42Z Articular cartilage tissue engineering using chondrogenic progenitor cell homing and 3D bioprinting Yu, Yin Articular cartilage damage associated with joint trauma seldom heals and often leads to osteoarthritis (OA). Current treatment often fails to regenerated functional cartilage close to native tissue. We previously identified a migratory chondrogenic progenitor cell (CPC) population that responded chemotactically to cell death and rapidly repopulated the injured cartilage matrix, which suggested their potential for cartilage repair. To test that potential we filled experimental full thickness chondral defects with an acellular hydrogel containing SDF-1α. We expect that SDF-1α can increase the recruitment of CPCs, and then promote the formation of a functional cartilage matrix with chondrogenic factors. Full-thickness bovine chondral defects were filled with hydrogel comprised of fibrin and hyaluronic acid and containing SDF-1α. Cell migration was monitored, followed by chondrogenic induction. Regenerated tissue was evaluated by histology, immunohistochemistry, and scanning electron microscopy. Push-out tests were performed to assess the strength of integration between regenerated tissue and host cartilage. Significant numbers of progenitor cells were recruited by SDF-1α within 12 days. By 5 weeks chondrogenesis, repair tissue cell morphology, proteoglycan density and surface ultrastructure were similar to native cartilage. SDF-1α treated defects had significantly greater interfacial strength than untreated controls. However, regenerated neocartilage had relatively inferior mechanical properties compared with native cartilage. In addition to that, we developed a 3D bioprinting platform, which can directly print chondrocytes as well as CPCs to fabricated articular cartilage tissue in vitro. We successfully implanted the printed tissue into an osteochondral defect, and observed tissue repair after implantation. The regerated tissue has biochemical and mechanical properties within the physiological range of native articular cartilage. This study showed that, when CPC chemotaxis and chondrogenesis are stimulated sequentially, in situ full thickness cartilage regeneration and bonding of repair tissue to surrounding cartilage could occur without the need for cell transplantation from exogenous sources. This study also demonstrated the potential of using 3D bioprinting to engineer articular cartilage implants for repairing cartilage defect. 2015-05-01T07:00:00Z dissertation application/pdf https://ir.uiowa.edu/etd/6895 https://ir.uiowa.edu/cgi/viewcontent.cgi?article=8429&context=etd Copyright © 2015 Yin Yu Theses and Dissertations eng University of IowaMartin, James A. Bioprinting Cartilage repair Cell homing Chondrogenic Progenitor Cells Stem Cells Tissue Engineering Biomedical Engineering and Bioengineering
collection NDLTD
language English
format Others
sources NDLTD
topic Bioprinting
Cartilage repair
Cell homing
Chondrogenic Progenitor Cells
Stem Cells
Tissue Engineering
Biomedical Engineering and Bioengineering
spellingShingle Bioprinting
Cartilage repair
Cell homing
Chondrogenic Progenitor Cells
Stem Cells
Tissue Engineering
Biomedical Engineering and Bioengineering
Yu, Yin
Articular cartilage tissue engineering using chondrogenic progenitor cell homing and 3D bioprinting
description Articular cartilage damage associated with joint trauma seldom heals and often leads to osteoarthritis (OA). Current treatment often fails to regenerated functional cartilage close to native tissue. We previously identified a migratory chondrogenic progenitor cell (CPC) population that responded chemotactically to cell death and rapidly repopulated the injured cartilage matrix, which suggested their potential for cartilage repair. To test that potential we filled experimental full thickness chondral defects with an acellular hydrogel containing SDF-1α. We expect that SDF-1α can increase the recruitment of CPCs, and then promote the formation of a functional cartilage matrix with chondrogenic factors. Full-thickness bovine chondral defects were filled with hydrogel comprised of fibrin and hyaluronic acid and containing SDF-1α. Cell migration was monitored, followed by chondrogenic induction. Regenerated tissue was evaluated by histology, immunohistochemistry, and scanning electron microscopy. Push-out tests were performed to assess the strength of integration between regenerated tissue and host cartilage. Significant numbers of progenitor cells were recruited by SDF-1α within 12 days. By 5 weeks chondrogenesis, repair tissue cell morphology, proteoglycan density and surface ultrastructure were similar to native cartilage. SDF-1α treated defects had significantly greater interfacial strength than untreated controls. However, regenerated neocartilage had relatively inferior mechanical properties compared with native cartilage. In addition to that, we developed a 3D bioprinting platform, which can directly print chondrocytes as well as CPCs to fabricated articular cartilage tissue in vitro. We successfully implanted the printed tissue into an osteochondral defect, and observed tissue repair after implantation. The regerated tissue has biochemical and mechanical properties within the physiological range of native articular cartilage. This study showed that, when CPC chemotaxis and chondrogenesis are stimulated sequentially, in situ full thickness cartilage regeneration and bonding of repair tissue to surrounding cartilage could occur without the need for cell transplantation from exogenous sources. This study also demonstrated the potential of using 3D bioprinting to engineer articular cartilage implants for repairing cartilage defect.
author2 Martin, James A.
author_facet Martin, James A.
Yu, Yin
author Yu, Yin
author_sort Yu, Yin
title Articular cartilage tissue engineering using chondrogenic progenitor cell homing and 3D bioprinting
title_short Articular cartilage tissue engineering using chondrogenic progenitor cell homing and 3D bioprinting
title_full Articular cartilage tissue engineering using chondrogenic progenitor cell homing and 3D bioprinting
title_fullStr Articular cartilage tissue engineering using chondrogenic progenitor cell homing and 3D bioprinting
title_full_unstemmed Articular cartilage tissue engineering using chondrogenic progenitor cell homing and 3D bioprinting
title_sort articular cartilage tissue engineering using chondrogenic progenitor cell homing and 3d bioprinting
publisher University of Iowa
publishDate 2015
url https://ir.uiowa.edu/etd/6895
https://ir.uiowa.edu/cgi/viewcontent.cgi?article=8429&context=etd
work_keys_str_mv AT yuyin articularcartilagetissueengineeringusingchondrogenicprogenitorcellhomingand3dbioprinting
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