Challenges in tissue engineering

Ikada, Yoshito

doi:10.1098/rsif.2006.0124

Cited by 771 publications

(566 citation statements)

References 49 publications

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“…The scaffold can have a variety of roles such as to help retain the cells in the desired location, to provide mechanical properties (sufficient for weight bearing as the disc is always loaded) and/or biochemical cues to the tissue as it is developing or to facilitate and guide tissue ingrowth [45].…”

Section: What Is the Right Scaffold?mentioning

confidence: 99%

Tissue engineering and the intervertebral disc: the challenges

2008

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Disc degeneration is a common disorder. Although the back pain that can develop in association with this is rarely life-threatening, the annual cost in terms of morbidity, lost productivity, medical expenses and workers' compensation benefits is significant. Surgical intervention as practised currently is directed towards removing the damaged or altered tissue. Development of new treatment modalities is critical as there is a growing consensus that the strategies used currently for symptomatic degenerative disc disease may not be effective. Accordingly, there is a need to develop an entirely new way to treat this disorder; regenerative medicine and tissue engineering approaches appear particularly promising in this regard. This paper reviews some of the challenges that currently are limiting the clinical application of this approach to the treatment of disc degeneration.

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Section: What Is the Right Scaffold?mentioning

confidence: 99%

Tissue engineering and the intervertebral disc: the challenges

2008

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“…The scaffold functions as the in vivo ECM by providing structural and functional microenvironment (i.e., ''niche'') for cell growth, migration, and differentiation. [9][10][11][12] Although the composition of ECM environment is unique to each tissue, the major components of ECMs are collagens, fibronectin, laminin, and various types of glycoaminoglycans and proteoglycans. 13 ECM, together with growth factors, cytokines, and interactions with other cell types, renders the biological and physical cues that dictate MSC function and overall fate.…”

Section: Introductionmentioning

confidence: 99%

Stromal-Cell-Derived Extracellular Matrix Promotes the Proliferation and Retains the Osteogenic Differentiation Capacity of Mesenchymal Stem Cells on Three-Dimensional Scaffolds

Antebi

Zhang

Wang

et al. 2015

Tissue Engineering Part C: Methods

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To date, expansion of bone-marrow-derived mesenchymal stem cells (MSCs) is typically carried out on twodimensional (2D) tissue culture plastic. Since this 2D substratum is very different from the physiological situation, MSCs gradually lose their unique multipotent properties during expansion. Recently, the role of the extracellular matrix (ECM) microenvironment (''niche'') in facilitating and regulating stem cell behavior in vivo has been elucidated. As a result, investigators have shifted their efforts toward developing threedimensional (3D) scaffolds capable of functioning like the native tissue ECM. In this study, we demonstrated that stromal-cell-derived ECM, formed within a collagen/hydroxyapatite (Col/HA) scaffold to mimic the bone marrow ''niche,'' promoted MSC proliferation and preserved their differentiation capacity. The ECM was synthesized by MSCs to reconstitute the tissue-specific 3D microenvironment in vitro. Following deposition of the ECM inside Col/HA scaffold, the construct was decellularized and reseeded with MSCs to study their behavior. The data showed that MSCs cultured on the ECM-Col/HA scaffolds grew significantly faster than the cells from the same batch cultured on the regular Col/HA scaffolds. In addition, MSCs cultured on the ECMCol/HA scaffolds retained their ''stemness'' and osteogenic differentiation capacity better than MSCs cultured on regular Col/HA scaffolds. When ECM-Col/HA scaffolds were implanted into immunocompromised mice, with or without loading MSCs, it was found that those scaffolds formed less bone as compared with regular Col/ HA scaffolds (i.e., without ECM), in both cases of with or without loading MSCs. The in vivo study further confirmed that the ECM-Col/HA scaffold was a suitable mimic of the bone marrow ''niche.'' This novel 3D stromal-cell-derived ECM system has the potential to be developed into a biomedical platform for regenerative medicine applications.

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“…10 Growth factors are soluble proteins that stimulate cell proliferation and differentiation and can be used to aid cell migration, increase cell numbers, and increase matrix production. 2,8,11 Injected growth factors have very short halflives in vivo as they are rapidly dispersed by diffusion or digested by enzymes; hence, they require a delivery device to protect the growth factor from proteolysis until it is released. 1,8,12 To this end, the scaffold could be used to reversibly bind growth factors, confine their release to the defect location to limit any possible side effects, and ensure that their bioactivity is maintained when released.…”

Section: Introductionmentioning

confidence: 99%

“…1,7,8 Scaffold microstructure, which can be characterized by porosity, mean pore size, interconnectivity, and specific surface area, significantly affects cell adhesion and proliferation. 9 Ideally, the scaffold should also mimic cell-ECM interactions and provide adequate signals to cells via the ECM and growth factors to induce or maintain a desired state of cell differentiation to aid tissue regeneration.…”

Section: Introductionmentioning

confidence: 99%

Binding and Release Characteristics of Insulin-Like Growth Factor-1 from a Collagen–Glycosaminoglycan Scaffold

Mullen

Best

Brooks

et al. 2010

Tissue Engineering Part C: Methods

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Tissue engineering is a promising technique for cartilage repair, but to optimize novel scaffolds before clinical trials, it is necessary to determine their characteristics for binding and release of growth factors. Toward this goal, a novel, porous collagen-glycosaminoglycan scaffold was loaded with a range of concentrations of insulinlike growth factor-1 (IGF-1) to evaluate its potential as a controlled delivery device. The kinetics of IGF-1 adsorption and release from the scaffold was demonstrated using radiolabeled IGF-1. Adsorption was rapid, and was approximately proportional to the loading concentration. Ionic bonding contributed to this interaction. IGF-1 release was studied over 14 days to compare the release profiles from different loading groups. Two distinct phases occurred: first, a burst release of up to 44% was noted within the first 24 h; then, a slow, sustained release (13%-16%) was observed from day 1 to 14. When the burst release was subtracted, the relative percentage of remaining IGF-1 released was similar for all loading groups and broadly followed t ½ kinetics until approximately day 6. Scaffold cross-linking using dehydrothermal treatment did not affect IGF-1 adsorption or release. Bioactivity of released IGF-1 was confirmed by seeding scaffolds (preadsorbed with unlabeled IGF-1) with human osteoarthritic chondrocytes and demonstrating increased proteoglycan production in vitro.

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Challenges in tissue engineering

Cited by 771 publications

References 49 publications

Tissue engineering and the intervertebral disc: the challenges

Tissue engineering and the intervertebral disc: the challenges

Stromal-Cell-Derived Extracellular Matrix Promotes the Proliferation and Retains the Osteogenic Differentiation Capacity of Mesenchymal Stem Cells on Three-Dimensional Scaffolds

Binding and Release Characteristics of Insulin-Like Growth Factor-1 from a Collagen–Glycosaminoglycan Scaffold

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