Ceramic scaffolds produced by computer‐assisted 3D printing and sintering: Characterization and biocompatibility investigations

Warnke, Patrick H.; Seitz, Hermann; Warnke, Frauke; Becker, Stephan; Sivananthan, Sureshan; Sherry, Eugene; Liu, Qin; Wiltfang, Jens; Douglas, Timothy

doi:10.1002/jbm.b.31577

Cited by 144 publications

(114 citation statements)

References 9 publications

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“…The final part consists of 24 ) that can not only wet the surrounding powder, but also locally harden the wetted area. 25,26 Binder drop volume and wettability are important parameters to consider before printing. Binder wettability influences the green strength (the initial strength after printing but before postprocessing steps) of the printed object, and is directly related to the powder particle surface energy, chemistry, and binder viscosity.…”

Section: Jariwala Et Almentioning

confidence: 99%

3D Printing of Personalized Artificial Bone Scaffolds

Jariwala

Lewis

Bushman

et al. 2015

3D Printing and Additive Manufacturing

128

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Section: Jariwala Et Almentioning

confidence: 99%

3D Printing of Personalized Artificial Bone Scaffolds

Jariwala

Lewis

Bushman

et al. 2015

3D Printing and Additive Manufacturing

128

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“…High-throughput pharmacological study [36,78] 3D bioprinting Primary feline H1 cardiomyocytes First rhythmic beating of 3D printed structure [93][94][95] Lung Microfabrication Epithelial cells Use of porous membrane to mimic lung functions [31,37] 3D bioprinting A549 cells and EA hy926 cells World's first 3D bioprinted lung tissue [101] Bone 3D bioprinting BMSCs High viability in microextrusion-based bioprinting [108,109,158,159] Cancer Self-assembled Intestinal stem cells Discovery of LGR5+ intestinal stem cells [52,62] Microfabrication Breast cancer cells Perfusable human microvascularized bone-mimicking (BMi) microenvironment [81,168] 3D bioprinting OVCAR-5 and MRC-5 cells Insight into complex cell-cell communication in 3D [113][114][115][116][117] Multi Self-assembled Liver, gut, vessel cells High throughput hanging drop [30,[49][50][51][52] Microfabrication Liver, heart, and vessel cells Automated control of perfusion [11,19,27,32] 3D bioprinting NPC and HCT-116 cells Multiorgan bioprinted model [30,122] a)…”

Section: Engineering Technologiesmentioning

confidence: 99%

“…Nevertheless, 3D bioprinted bone systems have been developed. [108,158,159] Campbells and co-workers fabricated bone tissue by stimulating growth factor dose-dependent differentiation of MDSC's toward osteogenic phenotype using jet-based bioprinting of BMP-2 patterns. [109] Primary muscle-derived stem cells were cultured on BMP-2 patterns bioprinted on fibrin substrates.…”

Section: Bioprinted Bonementioning

confidence: 99%

3D Miniaturization of Human Organs for Drug Discovery

Park

Wetzel

Dréau

et al. 2017

Adv Healthcare Materials

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“Engineered human organs” hold promises for predicting the effectiveness and accuracy of drug responses while reducing cost, time, and failure rates in clinical trials. Multiorgan human models utilize many aspects of currently available technologies including self‐organized spherical 3D human organoids, microfabricated 3D human organ chips, and 3D bioprinted human organ constructs to mimic key structural and functional properties of human organs. They enable precise control of multicellular activities, extracellular matrix (ECM) compositions, spatial distributions of cells, architectural organizations of ECM, and environmental cues. Thus, engineered human organs can provide the microstructures and biological functions of target organs and advantageously substitute multiscaled drug‐testing platforms including the current in vitro molecular assays, cell platforms, and in vivo models. This review provides an overview of advanced innovative designs based on the three main technologies used for organ construction leading to single and multiorgan systems useable for drug development. Current technological challenges and future perspectives are also discussed.

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“…One of the important benefits of this method is the powder bed support by itself for each successive layer. The fragility of the obtained parts is considered a drawback [81][82][83][84][85][86][87][88].…”

Section: D Printing (3dp)mentioning

confidence: 99%

Bioceramic Scaffolds

Amin¹,

Ewais²

2017

Scaffolds in Tissue Engineering - Materials, Technologies and Clinical Applications

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Millions of peoples in the world suffer from their bone damage tissues by disease or trauma. Every day, thousands of surgical procedures are performed to replace or repair these tissues. The availability of these tissues is a big problem, and their costs are expensive. The repair of these defects has become a major clinical and socioeconomic need with the increase of aging population and social development. The emerge of tissue engineering (TE) is considered as a glimmer of hope to contribute in solving this problem. It aims at the regeneration of damaged tissues with restoring and maintaining the function of human bone tissues using the combination of cell biology, materials science, and engineering principles. In this chapter, the current state of the tissue engineering in particular bioceramic scaffolds was discussed. Concept of tissue engineering was explored. Bioceramic scaffold materials, their processing techniques, challenges taken into consideration the design of the scaffolds, and their in-vitro and in-vivo studies were highlighted. The scaffolds with extra-functionalities such as drug release ability and clinical applications were mentioned.

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Ceramic scaffolds produced by computer‐assisted 3D printing and sintering: Characterization and biocompatibility investigations

Cited by 144 publications

References 9 publications

3D Printing of Personalized Artificial Bone Scaffolds

3D Printing of Personalized Artificial Bone Scaffolds

3D Miniaturization of Human Organs for Drug Discovery

Bioceramic Scaffolds

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