Core–shell bioprinting as a strategy to apply differentiation factors in a spatially defined manner inside osteochondral tissue substitutes

Kilian, David; Cometta, Silvia; Bernhardt, Anne; Taymour, Rania; Golde, Jonas; Ahlfeld, Tilman; Emmermacher, Julia; Gelinsky, Michael; Lode, Anja

doi:10.1088/1758-5090/ac457b

Cited by 26 publications

(25 citation statements)

References 74 publications

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“…Thus, cells may grow only on the outer surface [ 10 ]. Creative 3D bioprinting can solve these problems of oxygen and nutrient supply and also allows functionalization of the scaffolds [ 27 , 28 ]. The ideal scaffold can temporarily replace natural tissues, interact with the surrounding microenvironment, and actively guide cellular events, ultimately leading to faster bone formation [ 4 ].…”

Section: Discussionmentioning

confidence: 99%

Treatment of Critical Size Femoral Bone Defects with Biomimetic Hybrid Scaffolds of 3D Plotted Calcium Phosphate Cement and Mineralized Collagen Matrix

Culla

Vater

Tian

et al. 2022

IJMS

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To treat critical-size bone defects, composite materials and tissue-engineered bone grafts play important roles in bone repair materials. The purpose of this study was to investigate the bone regenerative potential of hybrid scaffolds consisting of macroporous calcium phosphate cement (CPC) and microporous mineralized collagen matrix (MCM). Hybrid scaffolds were synthetized by 3D plotting CPC and then filling with MCM (MCM-CPC group) and implanted into a 5 mm critical size femoral defect in rats. Defects left empty (control group) as well as defects treated with scaffolds made of CPC only (CPC group) and MCM only (MCM group) served as controls. Eight weeks after surgery, micro-computed tomography scans and histological analysis were performed to analyze the newly formed bone, the degree of defect healing and the activity of osteoclasts. Mechanical stability was tested by 3-point-bending of the explanted femora. Compared with the other groups, more newly formed bone was found within MCM-CPC scaffolds. The new bone tissue had a clamp-like structure which was fully connected to the hybrid scaffolds and thereby enhanced the biomechanical strength. Together, the biomimetic hybrid MCM-CPC scaffolds enhanced bone defect healing by improved osseointegration and their differentiated degradation provides spatial effects in the process of critical-bone defect healing.

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Section: Discussionmentioning

confidence: 99%

Treatment of Critical Size Femoral Bone Defects with Biomimetic Hybrid Scaffolds of 3D Plotted Calcium Phosphate Cement and Mineralized Collagen Matrix

Culla

Vater

Tian

et al. 2022

IJMS

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“…Kilian et al 92 Extrusion-based hBMSCs Methacrylated hyaluronic acid (MeHA)/ PCL; incorporating kartogening and beta-TCP They manufactured a triphasic construct for osteochondral defect regeneration. The subchondral bone layer was made of PCL and beta-TCP; the cartilage section had MeHA with hBMSCs, PCL with kartogenin; a top anti-inflammatory layer was made of MeHA with diclofenac solution.…”

Section: Golebiowska and Nukavarapu 91mentioning

confidence: 99%

Biofabrication of the osteochondral unit and its applications: Current and future directions for 3D bioprinting

et al. 2022

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Multiple prevalent diseases, such as osteoarthritis (OA), for which there is no cure or full understanding, affect the osteochondral unit; a complex interface tissue whose architecture, mechanical nature and physiological characteristics are still yet to be successfully reproduced in vitro. Although there have been multiple tissue engineering-based approaches to recapitulate the three dimensional (3D) structural complexity of the osteochondral unit, there are various aspects that still need to be improved. This review presents the different pre-requisites necessary to develop a human osteochondral unit construct and focuses on 3D bioprinting as a promising manufacturing technique. Examples of 3D bioprinted osteochondral tissues are reviewed, focusing on the most used bioinks, chosen cell types and growth factors. Further information regarding the applications of these 3D bioprinted tissues in the fields of disease modelling, drug testing and implantation is presented. Finally, special attention is given to the limitations that currently hold back these 3D bioprinted tissues from being used as models to investigate diseases such as OA. Information regarding improvements needed in bioink development, bioreactor use, vascularisation and inclusion of additional tissues to further complete an OA disease model, are presented. Overall, this review gives an overview of the evolution in 3D bioprinting of the osteochondral unit and its applications, as well as further illustrating limitations and improvements that could be performed explicitly for disease modelling.

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“…[11] During alginate crosslinking and the subsequent cultivation, the methylcellulose is partially released, forming a crosslinked construct of mainly alginate.. [11,12] This versatile ink has been successfully applied for bioprinting of various mammalian cell types such as pancreatic islets of Langerhans and chondrocytes, but also for bioprinting of microalgae. [13][14][15][16][17][18][19] Based on the promising results in these ground-based studies, Alg-MC was the first bioink to be selected by the company OHB for use in space. As part of the ISS mission Cosmic Kiss of the German ESA astronaut Matthias Maurer, it was used as one of two for the mission selected bioinks to generate constructs with the aid of a hand-held printer, which in combination with dermal fibroblasts should later provide rapid assistance in the wound closure of large-area skin injuries.…”

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Bioinks for Space Missions: The Influence of Long‐Term Storage of Alginate‐Methylcellulose‐Based Bioinks on Printability as well as Cell Viability and Function

Windisch

Reinhardt

Duin

et al. 2023

Adv Healthcare Materials

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Bioprinting is considered a key technology for future space missions and is currently being established on the International Space Station (ISS). With the aim to perform bioink production as a critical and resource‐consuming preparatory step already on Earth and transport a bioink cartridge “ready to use” to the ISS, the storability of bioinks is investigated. Hydrogel blends based on alginate and methylcellulose are laden with either green microalgae of the species Chlorella vulgaris or with different human cell lines including immortilized human mesenchymal stem cells, SaOS‐2 and HepG2, as well as with primary human dental pulp stem cells. The bioinks are filled into printing cartridges and stored at 4°C for up to four weeks. Printability of the bioinks is maintained after storage. Viability and function of the cells embedded in constructs bioprinted from the stored bioinks are investigated during subsequent cultivation: The microalgae survive the storage period very well and show no loss of growth and functionality, however a significant decrease is visible for human cells, varying between the different cell types. The study demonstrates that storage of bioinks is in principle possible and is a promising starting point for future research, making complex printing processes more effective and reproducible.

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Core–shell bioprinting as a strategy to apply differentiation factors in a spatially defined manner inside osteochondral tissue substitutes

Cited by 26 publications

References 74 publications

Treatment of Critical Size Femoral Bone Defects with Biomimetic Hybrid Scaffolds of 3D Plotted Calcium Phosphate Cement and Mineralized Collagen Matrix

Treatment of Critical Size Femoral Bone Defects with Biomimetic Hybrid Scaffolds of 3D Plotted Calcium Phosphate Cement and Mineralized Collagen Matrix

Biofabrication of the osteochondral unit and its applications: Current and future directions for 3D bioprinting

Bioinks for Space Missions: The Influence of Long‐Term Storage of Alginate‐Methylcellulose‐Based Bioinks on Printability as well as Cell Viability and Function

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