Bioprinting with pre-cultured cellular constructs towards tissue engineering of hierarchical tissues

Nakamura, Makoto; Mir, Tanveer Ahmad; Arai, Kohei; Ito, Satoru; Yoshida, Toshiko; Iwanaga, Shintaroh; Kitano, Hiromi; Obara, Chizuka; Nikaido, Toshio

doi:10.18063/ijb.2015.01.007

Cited by 17 publications

(9 citation statements)

References 36 publications

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“…These facts are also support by the journal published by M. Calado et.al [18]. C. Ventola et.al [19] stated that 3D bio-printing are very famous especially in medical fields for research and study in many fields of researches such as tissue engineering, regenerative medicine and organ transplant since 2000s. The first 3D bio-printer [ 1181 is introduced by Wake Forest Institute in year 1999 in which a fully functioned artificial urinary bladder was successfully printed.…”

Section: Introductionsupporting

confidence: 59%

Development of a 3D bio-printer using CoreXY mechanism and syringe-based extrusion

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Ramilan

Hanafi

et al. 2020

IJEECS

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3D Bio-printer is said to have potential in the applications of medical studies and tissue engineering. A 3D Bio-printer could be used to print the artificial organs for organs transplant and cell tissue culture for generating new cell tissue. It could help in future medical and biological research. This paper presents the development process, i.e. working principle of Fused Deposition Modelling (FDM), mechanical, electrical and related applied software, of a 3D Bio-printer using syringe-based extruder and Core XY mechanism. Up to date, FDM is a popular technique because it is easily implemented, precise and accurate. The printed product revealed high repeativity, where (sample mean, sample standard deviation) is ( mm. The procedure could help future customized 3D Bio-printer. <br />

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Section: Introductionsupporting

confidence: 59%

Development of a 3D bio-printer using CoreXY mechanism and syringe-based extrusion

Soon

Ramilan

Hanafi

et al. 2020

IJEECS

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“…It has brought many benefits to tissue engineering and other biomedical applications by fabricating customized tissue constructs and prostheses [ 1 , 2 , 3 ]. A typical bioprinting system consists of three components including: (i) living materials which mostly refer to cells; (ii) hydrogel or bioink; and (iii) a bioprinter [ 4 , 5 ]. For bioprinters, there are mainly three types: laser-based bioprinters, ink-jet-based bioprinters, and extrusion-based bioprinters [ 6 , 7 ].…”

Section: Introductionmentioning

confidence: 99%

A Mathematical Model on the Resolution of Extrusion Bioprinting for the Development of New Bioinks

et al. 2016

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Pneumatic extrusion-based bioprinting is a recent and interesting technology that is very useful for biomedical applications. However, many process parameters in the bioprinter need to be fully understood in order to print at an adequate resolution. In this paper, a simple yet accurate mathematical model to predict the printed width of a continuous hydrogel line is proposed, in which the resolution is expressed as a function of nozzle size, pressure, and printing speed. A thermo-responsive hydrogel, pluronic F127, is used to validate the model predictions. This model could provide a platform for future correlation studies on pneumatic extrusion-based bioprinting as well as for developing new bioink formulations.

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“…AM is a disruptive technology that promises to build complex geometries in short time and is able to customize the end product according to the end-user. Bioprinting is a type of AM technique that has attracted tremendous attention recently, as it offers automated and advanced manufacturing platform to construct complex bioengineered prototypes [8,9].…”

mentioning

confidence: 99%

3D Printed Bioelectronic Platform with Embedded Electronics

et al. 2018

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Silver nanoparticle based microelectrodes embedded between layers of hydrogel material were successfully fabricated. 3D bioprinting is employed to print the entire bioelectronics platform comprising of conducting silver ink and Gelatin methacryloyl (GelMA) hydrogel. The additive manufacturing technique of bioprinting gives design freedom for the circuit, saves material and shortens the time to fabricate the bioelectronics platform. The silver platform shows excellent electrical conductivity, structural flexibility and stability in wet environment. It is tested for biocompatibility using C2C12 murine myoblasts cell line. The work demonstrates the potential of the fabricated platform for the realization of practical bioelectronic devices.

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Bioprinting with pre-cultured cellular constructs towards tissue engineering of hierarchical tissues

Cited by 17 publications

References 36 publications

Development of a 3D bio-printer using CoreXY mechanism and syringe-based extrusion

Development of a 3D bio-printer using CoreXY mechanism and syringe-based extrusion

A Mathematical Model on the Resolution of Extrusion Bioprinting for the Development of New Bioinks

3D Printed Bioelectronic Platform with Embedded Electronics

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