Fabrication of Biopolymer-Based Organs and Tissues Using 3D Bioprinting

Goel, Apoorva; Meher, Mukesh Kumar; Gulati, Khushboo; Poluri, Krishna Mohan

doi:10.1016/b978-0-12-815890-6.00003-7

Cited by 13 publications

(17 citation statements)

References 134 publications

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“…The extrusion rate can be easily altered in pneumatic-based extrusion systems and it is highly preferred for low-viscosity solutions [ 96 ]. High-viscosity bioinks can be easily extruded using piston-based extrusion and the rate of extrusion can be altered by controlling the movement of the motor [ 97 ]. In screw-based extrusion systems, the raw material is put into the cartridge and pushed by a motor-driven auger screw, and the ink emerges via the extrusion nozzle [ 96 ].…”

Section: 3d Printing Processmentioning

confidence: 99%

Hydrogels—A Promising Materials for 3D Printing Technology

Kaliaraj

Shanmugam

Dasan

et al. 2023

Gels

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Hydrogels are a promising material for a variety of applications after appropriate functional and structural design, which alters the physicochemical properties and cell signaling pathways of the hydrogels. Over the past few decades, considerable scientific research has made breakthroughs in a variety of applications such as pharmaceuticals, biotechnology, agriculture, biosensors, bioseparation, defense, and cosmetics. In the present review, different classifications of hydrogels and their limitations have been discussed. In addition, techniques involved in improving the physical, mechanical, and biological properties of hydrogels by admixing various organic and inorganic materials are explored. Future 3D printing technology will substantially advance the ability to pattern molecules, cells, and organs. With significant potential for producing living tissue structures or organs, hydrogels can successfully print mammalian cells and retain their functionalities. Furthermore, recent advances in functional hydrogels such as photo- and pH-responsive hydrogels and drug-delivery hydrogels are discussed in detail for biomedical applications.

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Section: 3d Printing Processmentioning

confidence: 99%

Hydrogels—A Promising Materials for 3D Printing Technology

Kaliaraj

Shanmugam

Dasan

et al. 2023

Gels

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“…Carrageenan is a class of hydrophilic polysaccharides composed of alternating 3-linked and 4-linked D-galactose residues modified by 3,6-anhydro bridges and substitution with ester sulfate, methyl, or pyruvate groups ( Barros et al, 2013 ; Dave and Gor, 2018 ; Goel et al, 2019 ). A variety of additional carbohydrate residues can be found in carrageenan compositions, such as galactose, sulfate, xylose, glucose, and uronic acids ( Van de Velde et al, 2002 ; Knudsen et al, 2012 ).…”

Section: Carrageenan Structure and Physicochemical Propertiesmentioning

confidence: 99%

Carrageenan From Kappaphycus alvarezii (Rhodophyta, Solieriaceae): Metabolism, Structure, Production, and Application

et al. 2022

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Carrageenan is a polysaccharide derived from red algae (seaweed) with enormous economic potential in a wide range of industries, including pharmaceuticals, food, cosmetics, printing, and textiles. Carrageenan is primarily produced through aquaculture-based seaweed farming, with Eucheuma and Kappaphycus species accounting for more than 90% of global output. There are three major types of carrageenan found in red algae: kappa (κ)-, iota (ι)-, and lambda (λ)-carrageenan. Kappaphycus alvarezii is the most common kappa-carrageenan source, and it is primarily farmed in Asian countries such as Indonesia, the Philippines, Vietnam, and Malaysia. Carrageenan extracted from K. alvarezii has recently received a lot of attention due to its economic potential in a wide range of applications. This review will discuss K. alvarezii carrageenan in terms of metabolic and physicochemical structure, extraction methods and factors affecting production yield, as well as current and future applications.

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“…Bio printing is a type of additive manufacturing in which organic materials are used to produce organic tissues in high demand in the medical sector [21][22][23]. The most active methods of the bio printing technologies incorporate laser-assisted printing, extrusion-based and droplet-based.…”

Section: Bio Printing In Tissue Engineeringmentioning

confidence: 99%

“…The most active methods of the bio printing technologies incorporate laser-assisted printing, extrusion-based and droplet-based. These techniques are categorized as direct or indirect, with direct referring to the printing of the final organic structure and indirect referring to the construction of sacrificial models•s -1 caffolds on which the content is spread and matured before being removed through post-processing [23]. Since bio printing is a type of threedimensional printing, it is similar in terms of both fundamental process phases and the existence of technical variation to address material production requirements, including differences in the processing of macro (cell aggregates), micro (single cells) and nano (cells and protein) [24].…”

Section: Bio Printing In Tissue Engineeringmentioning

confidence: 99%

The amber nano fibers development prospects to expand the capabilites of textile 3D printing in the general process of fabrication methods

Viļuma-Gudmona

Ļašenko

Sanchaniya

et al. 2021

Engineering for Rural Development

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The amber nano fibres are bio-active composites which could be applied in three-dimensional printing. The idea of using the amber for creating a new 3D printing material, including technological composition of the innovative amber nano and micro fibres is based on the hypothesis that organic compounds of succinite have an effective impact on living cells, including reparative, stimulating, for sedative effects as well protective properties from electro-magnetic field. To produce amber nano fibres, bioactive components were used that were isolated from the succinite and tested (in vitro) in the scientific laboratories. Three-dimensional printing is an emerging technology, which has been initially used to design and generate three-dimensional structures mainly for transplantation therapies. This process, which can be used for a variety of polymers, is becoming an increasingly essential component of biotechnological advancements. This article discusses the foundations of this technology, namely the processes used in conventional three-dimensional printing; it also discusses tissue engineering, a discipline of which new implementations of this technology are used as bio printing. The shortcomings of tissue engineering are addressed, including the failure of existing technology to manufacture nanofiber-based constructs used in blood vessels, cartilage, artery valves, tendon, cardiac muscle valves, muscle, and cornea. From this need for nanofiber processing, electrospinning is proposed as a possible roadmap for imminent tissue engineering threedimensional printing technologies, and finally, the latest integration of this technology with three-dimensional printing is addressed, highlighting the existing shortcomings in maintaining mandatory nano resolutions.

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Fabrication of Biopolymer-Based Organs and Tissues Using 3D Bioprinting

Cited by 13 publications

References 134 publications

Hydrogels—A Promising Materials for 3D Printing Technology

Hydrogels—A Promising Materials for 3D Printing Technology

Carrageenan From Kappaphycus alvarezii (Rhodophyta, Solieriaceae): Metabolism, Structure, Production, and Application

The amber nano fibers development prospects to expand the capabilites of textile 3D printing in the general process of fabrication methods

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