3D-printing enabled micro-assembly of a microfluidic electroporation system for 3D tissue engineering

Qingfu Zhu; Megan Hamilton; Bryan Vasquez; Mei He

doi:10.1039/c9lc00046a

Control of cell proliferation in E-jet 3D-printed scaffolds for tissue engineering applications: the influence of the cell alignment angle

Journal of Materials Chemistry B ◽

10.1039/c7tb00377c ◽

2017 ◽

Vol 5 (20) ◽

pp. 3728-3738 ◽

Cited By ~ 16

Author(s):

Tong Liu ◽

Ruiying Huang ◽

Juchang Zhong ◽

Yikun Yang ◽

Zhikai Tan ◽

...

Keyword(s):

Tissue Engineering ◽

Cell Proliferation ◽

Cell Growth ◽

3D Printing ◽

Cell Alignment ◽

Engineering Applications ◽

3D Printed ◽

Alignment Angle

This study used E-jet 3D printing to fabricate various scaffolds for tissue engineering which could guide and improve cell growth.

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Biomimetic Design of 3D Printed Tissue-engineered bone Constructs

Current Nanoscience ◽

10.2174/1573413716999201022191909 ◽

2020 ◽

Vol 16 ◽

Author(s):

Wei Liu ◽

Shifeng Liu ◽

Yunzhe Li ◽

Peng Zhou ◽

Qian ma

Keyword(s):

Tissue Engineering ◽

3D Printing ◽

Advanced Materials ◽

Bionic Design ◽

Material Interfaces ◽

Precise Control ◽

Cell Printing ◽

Biomimetic Scaffolds ◽

3D Printed

Abstract:: Surgery to repair damaged tissue, which is caused by disease or trauma, is being carried out all the time, and a desirable treatment is compelling need to regenerate damaged tissues to further improve the quality of human health. Therefore, more and more research focus on exploring the most suitable bionic design to enrich available treatment methods. 3D-printing, as an advanced materials processing approach, holds promising potential to create prototypes with complex constructs that could reproduce primitive tissues and organs as much as possible or provide appropriate cell-material interfaces. In a sense, 3D printing promises to bridge between tissue engineering and bionic design, which can provide an unprecedented personalized recapitulation with biomimetic function under the precise control of the composition and spatial distribution of cells and biomaterials. This article describes recent progress in 3D bionic design and the potential application prospect of 3D printing regenerative medicine including 3D printing biomimetic scaffolds and 3D cell printing in tissue engineering.

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3D Printing & Pharmaceutical Manufacturing: Opportunities and Challenges

International Journal of Bioassays ◽

10.21746/ijbio.2016.01.006 ◽

2016 ◽

Vol 5 (01) ◽

pp. 4723 ◽

Cited By ~ 5

Author(s):

Bhusnure O. G.* ◽

Gholve V. S. ◽

Sugave B. K. ◽

Dongre R. C. ◽

Gore S. A. ◽

...

Keyword(s):

Drug Delivery ◽

Tissue Engineering ◽

3D Printing ◽

Computer Aided Design ◽

Patient Specific ◽

Computer Design ◽

3D Scaffolds ◽

Engineering Research ◽

Advantages And Disadvantages ◽

Computer Aided

Many researchers have attempted to use computer-aided design (C.A.D) and computer-aided manufacturing (CAM) to realize a scaffold that provides a three-dimensional (3D) environment for regeneration of tissues and organs. As a result, several 3D printing technologies, including stereolithography, deposition modeling, inkjet-based printing and selective laser sintering have been developed. Because these 3D printing technologies use computers for design and fabrication, and they can fabricate 3D scaffolds as designed; as a consequence, they can be standardized. Growth of target tissues and organs requires the presence of appropriate growth factors, so fabrication of 3Dscaffold systems that release these biomolecules has been explored. A drug delivery system (D.D.S) that administrates a pharmaceutical compound to achieve a therapeutic effect in cells, animals and humans is a key technology that delivers biomolecules without side effects caused by excessive doses. 3D printing technologies and D. D. Ss have been assembled successfully, so new possibilities for improved tissue regeneration have been suggested. If the interaction between cells and scaffold system with biomolecules can be understood and controlled, and if an optimal 3D tissue regenerating environment is realized, 3D printing technologies will become an important aspect of tissue engineering research in the near future. 3D Printing promises to produce complex biomedical devices according to computer design using patient-specific anatomical data. Since its initial use as pre-surgical visualization models and tooling molds, 3D Printing has slowly evolved to create one-of-a-kind devices, implants, scaffolds for tissue engineering, diagnostic platforms, and drug delivery systems. Fuelled by the recent explosion in public interest and access to affordable printers, there is renewed interest to combine stem cells with custom 3D scaffolds for personalized regenerative medicine. Before 3D Printing can be used routinely for the regeneration of complex tissues (e.g. bone, cartilage, muscles, vessels, nerves in the craniomaxillofacial complex), and complex organs with intricate 3D microarchitecture (e.g. liver, lymphoid organs), several technological limitations must be addressed. Until recently, tablet designs had been restricted to the relatively small number of shapes that are easily achievable using traditional manufacturing methods. As 3D printing capabilities develop further, safety and regulatory concerns are addressed and the cost of the technology falls, contract manufacturers and pharmaceutical companies that experiment with these 3D printing innovations are likely to gain a competitive edge. This review compose the basics, types & techniques used, advantages and disadvantages of 3D printing

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Porous scaffolds with the structure of an interpenetrating polymer network made by gelatin methacrylated nanoparticle-stabilized high internal phase emulsion polymerization targeted for tissue engineering

RSC Advances ◽

10.1039/d1ra03333f ◽

2021 ◽

Vol 11 (37) ◽

pp. 22544-22555

Author(s):

Atefeh Safaei-Yaraziz ◽

Shiva Akbari-Birgani ◽

Nasser Nikfarjam

Keyword(s):

Tissue Engineering ◽

Extracellular Matrix ◽

Cell Growth ◽

Polymer Network ◽

Synthetic Polymers ◽

Tissue Scaffolds ◽

Interpenetrating Polymer Network ◽

Porous Scaffolds ◽

Promising Strategy ◽

Internal Phase

The interlacing of biopolymers and synthetic polymers is a promising strategy to fabricate hydrogel-based tissue scaffolds to biomimic a natural extracellular matrix for cell growth.

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Electrospun Nanofibrous Membranes for Tissue Engineering and Cell Growth

Applied Sciences ◽

10.3390/app11156929 ◽

2021 ◽

Vol 11 (15) ◽

pp. 6929

Author(s):

Ewin Tanzli ◽

Andrea Ehrmann

Keyword(s):

Tissue Engineering ◽

Cell Growth ◽

Polymer Blends ◽

Mammalian Cells ◽

Biological Properties ◽

Specific Substrate ◽

Electrospun Nanofiber ◽

Materials Used ◽

Nanofiber Mats ◽

Surface Morphologies

In biotechnology, the field of cell cultivation is highly relevant. Cultivated cells can be used, for example, for the development of biopharmaceuticals and in tissue engineering. Commonly, mammalian cells are grown in bioreactors, T-flasks, well plates, etc., without a specific substrate. Nanofibrous mats, however, have been reported to promote cell growth, adhesion, and proliferation. Here, we give an overview of the different attempts at cultivating mammalian cells on electrospun nanofiber mats for biotechnological and biomedical purposes. Starting with a brief overview of the different electrospinning methods, resulting in random or defined fiber orientations in the nanofiber mats, we describe the typical materials used in cell growth applications in biotechnology and tissue engineering. The influence of using different surface morphologies and polymers or polymer blends on the possible application of such nanofiber mats for tissue engineering and other biotechnological applications is discussed. Polymer blends, in particular, can often be used to reach the required combination of mechanical and biological properties, making such nanofiber mats highly suitable for tissue engineering and other biotechnological or biomedical cell growth applications.

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3D Printing for Soft Tissue Regeneration and Applications in Medicine

Biomedicines ◽

10.3390/biomedicines9040336 ◽

2021 ◽

Vol 9 (4) ◽

pp. 336

Author(s):

Sven Pantermehl ◽

Steffen Emmert ◽

Aenne Foth ◽

Niels Grabow ◽

Said Alkildani ◽

...

Keyword(s):

Tissue Engineering ◽

Additive Manufacturing ◽

Soft Tissue ◽

3D Printing ◽

Tissue Regeneration ◽

Research Area ◽

Modern Medicine ◽

Soft Tissue Regeneration ◽

General Overview

The use of additive manufacturing (AM) technologies is a relatively young research area in modern medicine. This technology offers a fast and effective way of producing implants, tissues, or entire organs individually adapted to the needs of a patient. Today, a large number of different 3D printing technologies with individual application areas are available. This review is intended to provide a general overview of these various printing technologies and their function for medical use. For this purpose, the design and functionality of the different applications are presented and their individual strengths and weaknesses are explained. Where possible, previous studies using the respective technologies in the field of tissue engineering are briefly summarized.

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Three-Dimensional Printing of Hydroxyapatite Composites for Biomedical Application

Crystals ◽

10.3390/cryst11040353 ◽

2021 ◽

Vol 11 (4) ◽

pp. 353

Author(s):

Yanting Han ◽

Qianqian Wei ◽

Pengbo Chang ◽

Kehui Hu ◽

Oseweuba Valentine Okoro ◽

...

Keyword(s):

Tissue Engineering ◽

3D Printing ◽

Biomedical Application ◽

Three Dimensional ◽

Antibacterial Properties ◽

Natural Polymers ◽

Three Dimensional Printing ◽

3D Printed ◽

Dental Applications ◽

Hard Tissue Engineering

Hydroxyapatite (HA) and HA-based nanocomposites have been recognized as ideal biomaterials in hard tissue engineering because of their compositional similarity to bioapatite. However, the traditional HA-based nanocomposites fabrication techniques still limit the utilization of HA in bone, cartilage, dental, applications, and other fields. In recent years, three-dimensional (3D) printing has been shown to provide a fast, precise, controllable, and scalable fabrication approach for the synthesis of HA-based scaffolds. This review therefore explores available 3D printing technologies for the preparation of porous HA-based nanocomposites. In the present review, different 3D printed HA-based scaffolds composited with natural polymers and/or synthetic polymers are discussed. Furthermore, the desired properties of HA-based composites via 3D printing such as porosity, mechanical properties, biodegradability, and antibacterial properties are extensively explored. Lastly, the applications and the next generation of HA-based nanocomposites for tissue engineering are discussed.

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Low-temperature 3D printing of collagen and chitosan composite for tissue engineering

Materials Science and Engineering C ◽

10.1016/j.msec.2021.111963 ◽

2021 ◽

Vol 123 ◽

pp. 111963

Author(s):

Hairui Suo ◽

Jiaying Zhang ◽

Mingen Xu ◽

Ling Wang

Keyword(s):

Tissue Engineering ◽

3D Printing ◽

Low Temperature ◽

Chitosan Composite

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Three-dimensionally printed polycaprolactone/multicomponent bioactive glass scaffolds for potential application in bone tissue engineering

Biomedical glasses ◽

10.1515/bglass-2020-0006 ◽

2020 ◽

Vol 6 (1) ◽

pp. 57-69

Author(s):

Amirhosein Fathi ◽

Farzad Kermani ◽

Aliasghar Behnamghader ◽

Sara Banijamali ◽

Masoud Mozafari ◽

...

Keyword(s):

Tissue Engineering ◽

3D Printing ◽

Bone Tissue Engineering ◽

Bone Tissue ◽

Three Dimensional ◽

Layer By Layer ◽

Composite Scaffolds ◽

3D Printed ◽

Co Doped

AbstractOver the last years, three-dimensional (3D) printing has been successfully applied to produce suitable substitutes for treating bone defects. In this work, 3D printed composite scaffolds of polycaprolactone (PCL) and strontium (Sr)- and cobalt (Co)-doped multi-component melt-derived bioactive glasses (BGs) were prepared for bone tissue engineering strategies. For this purpose, 30% of as-prepared BG particles (size <38 μm) were incorporated into PCL, and then the obtained composite mix was introduced into a 3D printing machine to fabricate layer-by-layer porous structures with the size of 12 × 12 × 2 mm3.The scaffolds were fully characterized through a series of physico-chemical and biological assays. Adding the BGs to PCL led to an improvement in the compressive strength of the fabricated scaffolds and increased their hydrophilicity. Furthermore, the PCL/BG scaffolds showed apatite-forming ability (i.e., bioactivity behavior) after being immersed in simulated body fluid (SBF). The in vitro cellular examinations revealed the cytocompatibility of the scaffolds and confirmed them as suitable substrates for the adhesion and proliferation of MG-63 osteosarcoma cells. In conclusion, 3D printed composite scaffolds made of PCL and Sr- and Co-doped BGs might be potentially-beneficial bone replacements, and the achieved results motivate further research on these materials.

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14-3-3ε protein-loaded 3D hydrogels favor osteogenesis

Journal of Materials Science Materials in Medicine ◽

10.1007/s10856-020-06434-1 ◽

2020 ◽

Vol 31 (11) ◽

Author(s):

Ana A. Aldana ◽

Marina Uhart ◽

Gustavo A. Abraham ◽

Diego M. Bustos ◽

Aldo R. Boccaccini

Keyword(s):

Tissue Engineering ◽

Stem Cells ◽

Mesenchymal Stem Cells ◽

3D Printing ◽

Osteogenic Differentiation ◽

Alginate Hydrogel ◽

Hydrogel Scaffolds ◽

Future Developments ◽

Positive Effect ◽

Cell Adhesion And Proliferation

Abstract3D printing has emerged as vanguard technique of biofabrication to assemble cells, biomaterials and biomolecules in a spatially controlled manner to reproduce native tissues. In this work, gelatin methacrylate (GelMA)/alginate hydrogel scaffolds were obtained by 3D printing and 14-3-3ε protein was encapsulated in the hydrogel to induce osteogenic differentiation of human adipose-derived mesenchymal stem cells (hASC). GelMA/alginate-based grid-like structures were printed and remained stable upon photo-crosslinking. The viscosity of alginate allowed to control the pore size and strand width. A higher viscosity of hydrogel ink enhanced the printing accuracy. Protein-loaded GelMA/alginate-based hydrogel showed a clear induction of the osteogenic differentiation of hASC cells. The results are relevant for future developments of GelMA/alginate for bone tissue engineering given the positive effect of 14-3-3ε protein on both cell adhesion and proliferation.

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