Bone Tissue Engineering: Current Strategies and Techniques—Part I: Scaffolds

Szpalski, Caroline; Wetterau, Meredith; Barr, Jason; Warren, Stephen M.

doi:10.1089/ten.teb.2011.0427

Cited by 141 publications

(125 citation statements)

References 141 publications

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“…The natural extracellular matrix (ECM) does not only act as structure for cell anchorage but can also actively provide signalling cues to direct cellular processes, act as reservoir for growth factors and modulate their activity (Rosso et al, 2004;Chan and Leong, 2008). Mimicking the ECM is a common strategy of TE; regarding bone tissue, scaffolds composed of calcium phosphates and collagen type I as well as composites thereof have been proven capable of assisting bone regeneration (Szpalski et al, 2012;Black et al, 2015;Pina et al, 2015;Yunus Basha et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

Heparin modification of a biomimetic bone matrix modulates osteogenic and angiogenic cell response in vitro

Quade¹,

Knaack²,

Weber³

et al. 2017

eCM

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In this study, the effect of heparin-modified collagen type I/hydroxyapatite (HA) nanocomposites on key processes of bone regeneration -osteogenesis and angiogenesiswas characterised in vitro. Two approaches were applied for heparin modification: it was either integrated during material synthesis (in situ) or added to the porous scaffolds after their fabrication (post). Cultivation of human bone marrow-derived stromal cells (hBMSC), in heparinmodified versus heparin-free scaffolds, revealed a positive effect of the heparin modification on their proliferation and osteogenic differentiation. The amount of heparin rather than the method used for modification influenced the cell response favouring proliferation at smaller amount (30 mg/g collagen) and differentiation at larger amount (150 mg/g collagen). A co-culture of human umbilical vein endothelial cells (HUVEC) and osteogenically induced hBMSC was applied for in vitro angiogenesis studies. Pre-vascular networks have formed in the porous structure of scaffolds which were not modified with heparin or modified with a low amount of heparin (30 mg/g collagen).The modification with higher heparin quantities seemed to inhibit tubule formation. Pre-loading of the scaffolds with VEGF influenced formation and stability of the prevascular structures depending on the presence of heparin: In heparin-free scaffolds, induction of tubule formation and sprouting was more pronounced whereas heparinmodified scaffolds seemed to promote stabilisation of the pre-vascular structures. In conclusion, the modification of mineralised collagen with heparin by using both approaches was found to modulate cellular processes essential for bone regeneration; the amount of heparin has been identified to be crucial to direct cell responses.

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Section: Introductionmentioning

confidence: 99%

Heparin modification of a biomimetic bone matrix modulates osteogenic and angiogenic cell response in vitro

Quade¹,

Knaack²,

Weber³

et al. 2017

eCM

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“…HA decomposition at low temperature is possible due to the excess of OH-ions from Zr(OH) 4 and HA. During thermal annealing, the powders dehydrate leading to ZrO 2 crystallization and the decomposition of HA into calcium phosphates from less than 348 K [36]. This process is facilitated by the formation of an acidic environment in the powder during thermal annealing.…”

Section: Discussionmentioning

confidence: 99%

Effect on growth and osteoblast mineralization of hydroxyapatite-zirconia (HA-ZrO ₂ ) obtained by a new low temperature system

et al. 2018

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Ceramics and bioceramics, such as hydroxyapatite and zirconium, are used in bone tissue engineering. Hydroxyapatite has chemical properties similar to bone while zirconium offers suitable mechanical properties. The aim of this article is to evaluate the ability to support cell growth and osteoblastic mineralization of hydroxyapatite-zirconium obtained by a new system based on different low temperatures, such as 873 K (HZ600), 923 K (HZ650) and 973 K (HZ700). Hydroxyapatite-zirconia obtained by this new system was examined in terms of thermogravimetric features and x-ray diffractograms. Furthermore, the ability for supporting osteoblast growth and mineralization were analyzed. By x-ray diffraction analysis, we clearly demonstrated that no high-temperature processing was required. Moreover, it is possible to form tetragonal-zirconium at 923 K. Proliferation assays showed that osteoblast growth was not influenced by any of the composite evaluated. Regarding the osteogenic marker Col1, a 2-fold increase in expression was observed for HZ650 compared to HZ600 and HZ700. Interestingly, osteoblasts grown on HZ650 showed globular accretions covered with collagen bundles and calcium-rich extracellular matrix whereas HZ600 and HZ700 showed no phosphate or calcium deposits. This study demonstrated that at 923 K it is possible to generate stable tetragonal-zirconium and the resulting HZ650 composite is able to promote a suitable osteoblast mineralization process.

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“…Of these compounds, miR148b has been shown to induce de novo osteogenesis in bone marrow-derived MSC and ASC and has been demonstrated to enhance progenitor osteogenesis and bone repair both in vitro and in vivo [79,[81][82][83] . Several miRNAs such as miR-146a, miR-9, miR-29a and miR-140 play a role in the regulation of chondrogenesis [84][85][86][87][88][89] . In addition, different drug delivery systems can be incorporated into "bioinks" and be deposited in regions that require controlled release of cell-signaling molecules [90] .…”

Section: Towards Mimicking the Heterogeneity And Anisotropymentioning

confidence: 99%

Bioprinting of osteochondral tissues: A perspective on current gaps and future trends

Datta

Dhawan

et al. 2024

IJB

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Abstract:Osteochondral tissue regeneration has remained a critical challenge in orthopaedic surgery, especially due to complications of arthritic degeneration arising out of mechanical dislocations of joints. The common gold standard of autografting has several limitations in presenting tissue engineering strategies to solve the unmet clinical need. However, due to the complexity of joint anatomy, and tissue heterogeneity at the interface, the conventional tissue engineering strategies have certain limitations. The advent of bioprinting has now provided new opportunities for osteochondral tissue engineering. Bioprinting can uniquely mimic the heterogeneous cellular composition and anisotropic extra-cellular matrix (ECM) organization, while allowing for targeted gene delivery to achieve heterotypic differentiation. In this perspective, we discuss the current advances made towards bioprinting of composite osteochondral tissues and present an account of challenges-in terms of tissue integration, long-term survival, and mechanical strength at the time of implantation-required to be addressed for effective clinical translation of bioprinted tissues. Finally, we highlight some of the future trends related to osteochondral bioprinting with the hope of in-clinical translation. Keywords: bioprinting; osteochondral injuries; zonal anisotropy; bioink; tissue engineering

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Bone Tissue Engineering: Current Strategies and Techniques—Part I: Scaffolds

Cited by 141 publications

References 141 publications

Heparin modification of a biomimetic bone matrix modulates osteogenic and angiogenic cell response in vitro

Heparin modification of a biomimetic bone matrix modulates osteogenic and angiogenic cell response in vitro

Effect on growth and osteoblast mineralization of hydroxyapatite-zirconia (HA-ZrO ₂ ) obtained by a new low temperature system

Bioprinting of osteochondral tissues: A perspective on current gaps and future trends

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Bone Tissue Engineering: Current Strategies and Techniques—Part I: Scaffolds

Cited by 141 publications

References 141 publications

Heparin modification of a biomimetic bone matrix modulates osteogenic and angiogenic cell response in vitro

Heparin modification of a biomimetic bone matrix modulates osteogenic and angiogenic cell response in vitro

Effect on growth and osteoblast mineralization of hydroxyapatite-zirconia (HA-ZrO 2 ) obtained by a new low temperature system

Bioprinting of osteochondral tissues: A perspective on current gaps and future trends

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Effect on growth and osteoblast mineralization of hydroxyapatite-zirconia (HA-ZrO ₂ ) obtained by a new low temperature system