Resolution of 3D bioprinting inside bulk gel and granular gel baths

Soft Matter ◽  
2021 ◽  
Author(s):  
Zheng-Tian Xie ◽  
Dong-Hee Kang ◽  
Michiya Matsusaki
Keyword(s):  
Tissue Engineering ◽  
Three Dimensional ◽  
Cutting Edge ◽  
3D Bioprinting ◽  
Organ Regeneration

Three-dimensional (3D) bioprinting has rapidly developed in the last decade, playing an increasingly important role in applications including pharmacokinetics research, tissue engineering, and organ regeneration. As a cutting-edge technology in...

Hydrogel-Based Bioinks for Three-Dimensional Bioprinting: Patent Analysis

2021 ◽  
Vol 7 (1) ◽  
pp. 3
Author(s):  
Ahmed Fatimi
Keyword(s):  
Tissue Engineering ◽  
Detailed Analysis ◽  
State Of The Art ◽  
Three Dimensional ◽  
Patent Analysis ◽  
The State ◽  
Driving Factors ◽  
3D Bioprinting ◽  
Preparation Methods

There are a variety of hydrogel-based bioinks commonly used in three-dimensional bioprinting. In this study, in the form of patent analysis, the state of the art has been reviewed by introducing what has been patented in relation to hydrogel-based bioinks. Furthermore, a detailed analysis of the patentability of the used hydrogels, their preparation methods and their formulations, as well as the 3D bioprinting process using hydrogels, have been provided by determining publication years, jurisdictions, inventors, applicants, owners, and classifications. The classification of patents reveals that most inventions intended for hydrogels used as materials for prostheses or for coating prostheses are characterized by their function or properties Knowledge clusters and expert driving factors show that biomaterials, tissue engineering, and biofabrication research is concentrated in the most patents.

scholarly journals Fabrication of 3D Printing Scaffold with Porcine Skin Decellularized Bio-Ink for Soft Tissue Engineering

Materials ◽  
2020 ◽  
Vol 13 (16) ◽  
pp. 3522
Author(s):  
Su Jeong Lee ◽  
Jun Hee Lee ◽  
Jisun Park ◽  
Wan Doo Kim ◽  
Su A Park
Keyword(s):  
Tissue Engineering ◽  
Extracellular Matrix ◽  
3D Printing ◽  
Three Dimensional ◽  
3D Bioprinting ◽  
Research Groups ◽  
Porcine Skin ◽  
Alginate Hydrogel ◽  
Chemical Treatments ◽  
Soft Tissue Engineering

Recently, many research groups have investigated three-dimensional (3D) bioprinting techniques for tissue engineering and regenerative medicine. The bio-ink used in 3D bioprinting is typically a combination of synthetic and natural materials. In this study, we prepared bio-ink containing porcine skin powder (PSP) to determine rheological properties, biocompatibility, and extracellular matrix (ECM) formation in cells in PSP-ink after 3D printing. PSP was extracted without cells by mechanical, enzymatic, and chemical treatments of porcine dermis tissue. Our developed PSP-containing bio-ink showed enhanced printability and biocompatibility. To identify whether the bio-ink was printable, the viscosity of bio-ink and alginate hydrogel was analyzed with different concentration of PSP. As the PSP concentration increased, viscosity also increased. To assess the biocompatibility of the PSP-containing bio-ink, cells mixed with bio-ink printed structures were measured using a live/dead assay and WST-1 assay. Nearly no dead cells were observed in the structure containing 10 mg/mL PSP-ink, indicating that the amounts of PSP-ink used were nontoxic. In conclusion, the proposed skin dermis decellularized bio-ink is a candidate for 3D bioprinting.

The Fabrication of Tissue Engineering Scaffolds by Inkjet Printing Technology

2018 ◽  
Vol 934 ◽  
pp. 129-133 ◽  
Author(s):  
Chao Fan Lv ◽  
Li Ya Zhu ◽  
Jian Ping Shi ◽  
Zong An Li ◽  
Wen Lai Tang ◽  
...  
Keyword(s):  
Tissue Engineering ◽  
Sodium Alginate ◽  
Inkjet Printing ◽  
Three Dimensional ◽  
3D Bioprinting ◽  
Tissue Engineering Scaffolds ◽  
Printing Technology ◽  
3D Printed ◽  
Inkjet Printing Technology ◽  
Alginate Scaffold

Three-dimensional (3D) printing has been playing an important role in diverse areas in medicine. In order to promote the development of tissue engineering, this study attempts to fabricate tissue engineering scaffolds using the inkjet printing technology. Sodium alginate, exhibiting similar properties to the native human extracellular matrix (ECM), was used as bioink. The jetted fluid of sodium alginate would be gelatinized when printed into the calcium chloride solution. The characteristics of the 3D-printed sodium alginate scaffold were systematically measured and analyzed. The results show that, the pore size, porosity and degradation property of these scaffolds could be well controlled. This study indicates the capability of 3D bioprinting technology for preparing tissue engineering scaffolds.

scholarly journals Biodegradable Microfluidic Scaffolds for Vascular Tissue Engineering

2004 ◽  
Vol 845 ◽  
Author(s):  
C. J. Bettinger ◽  
J. T. Borenstein ◽  
R. S. Langer
Keyword(s):  
Tissue Engineering ◽  
Vascular Tissue ◽  
Time Lag ◽  
Three Dimensional ◽  
Single Layer ◽  
Vascular Tissue Engineering ◽  
Engineering Applications ◽  
Organ Regeneration ◽  
Superior Mechanical Properties ◽  
Microfabrication Techniques

ABSTRACTThis work describes the integration of novel microfabrication techniques for vascular tissue engineering applications in the context of a novel biodegradable elastomer. The field of tissue engineering and organ regeneration has been borne out of the high demand for organ transplants. However, one of the critical limitations in regeneration of vital organs is the lack of an intrinsic blood supply. This work expands on the development of scaffolds for vascular tissue engineering applications by employing microfabrication techniques. Unlike previous efforts, this work focuses on fabricating single layer and three-dimensional scaffolds from poly(glycerol-sebacate) (PGS), a novel biodegradable elastomer with superior mechanical properties. The transport properties of oxygen and carbon dioxide in PGS were measured through a series of time-lag diffusion experiments. The results of these measurements were used to calculate a characteristic length scale for oxygen diffusion limits in solid PGS scaffolds. Single layer and three-dimensional microfluidic scaffolds were then produced using fabrication techniques specific for PGS. This work has resulted in the fabrication of solid PGS-based scaffolds with biomimetic fluid flow and capillary channels on the order of 10 microns in width. Fabrication of complex, three-dimensional microfluidic PGS scaffolds was also demonstrated by stacking and bonding multiple microfluidic layers.

scholarly journals Of balls, inks and cages: Hybrid biofabrication of 3D tissue analogs

2018 ◽  
Vol 5 (1) ◽  
Author(s):  
Nicanor Moldovan ◽  
Leni Maldovan ◽  
Michael Raghunath
Keyword(s):  
Tissue Engineering ◽  
Extracellular Matrix ◽  
Hybrid Approach ◽  
Three Dimensional ◽  
3D Bioprinting ◽  
Support Structures ◽  
Cell Clusters ◽  
3D Space ◽  
Technical Solutions

The overarching principle of three-dimensional (3D) bioprinting is the placing of cells or cell clusters in the 3D space to generate a cohesive tissue microarchitecture that comes close to in vivo characteristics. To achieve this goal, several technical solutions are available, generating considerable combinatorial bandwidth: (i) Support structures are generated first, and cells are seeded subsequently; (ii) alternatively, cells are delivered in a printing medium, so-called “bioink,” that contains them during the printing process and ensures shape fidelity of the generated structure; and (iii) a “scaffold-free” version of bioprinting, where only cells are used and the extracellular matrix is produced by the cells themselves, also recently entered a phase of accelerated development and successful applications. However, the scaffold-free approaches may still benefit from secondary incorporation of scaffolding materials, thus expanding their versatility. Reversibly, the bioink-based bioprinting could also be improved by adopting some of the principles and practices of scaffold-free biofabrication. Collectively, we anticipate that combinations of these complementary methods in a “hybrid” approach, rather than their development in separate technological niches, will largely increase their efficiency and applicability in tissue engineering.

Nanomaterials for bioprinting: functionalization of tissue-specific bioinks

2021 ◽  
Author(s):  
Andrea S. Theus ◽  
Liqun Ning ◽  
Linqi Jin ◽  
Ryan K. Roeder ◽  
Jianyi Zhang ◽  
...  
Keyword(s):  
Drug Delivery ◽  
Tissue Engineering ◽  
Regenerative Medicine ◽  
Biomedical Applications ◽  
Disease Modeling ◽  
Three Dimensional ◽  
3D Bioprinting ◽  
Significant Step ◽  
Printing Processes

Abstract Three-dimensional (3D) bioprinting is rapidly evolving, offering great potential for manufacturing functional tissue analogs for use in diverse biomedical applications, including regenerative medicine, drug delivery, and disease modeling. Biomaterials used as bioinks in printing processes must meet strict physiochemical and biomechanical requirements to ensure adequate printing fidelity, while closely mimicking the characteristics of the native tissue. To achieve this goal, nanomaterials are increasingly being investigated as a robust tool to functionalize bioink materials. In this review, we discuss the growing role of different nano-biomaterials in engineering functional bioinks for a variety of tissue engineering applications. The development and commercialization of these nanomaterial solutions for 3D bioprinting would be a significant step towards clinical translation of biofabrication.

scholarly journals Development of a Disposable Single-Nozzle Printhead for 3D Bioprinting of Continuous Multi-Material Constructs

Micromachines ◽  
2020 ◽  
Vol 11 (5) ◽  
pp. 459 ◽  
Author(s):  
Tiffany Cameron ◽  
Emad Naseri ◽  
Ben MacCallum ◽  
Ali Ahmadi
Keyword(s):  
Tissue Engineering ◽  
Three Dimensional ◽  
Complex Geometries ◽  
3D Bioprinting ◽  
Mechanical Integrity ◽  
Silicon Coating

Fabricating multi-cell constructs in complex geometries is essential in the field of tissue engineering, and three-dimensional (3D) bioprinting is widely used for this purpose. To enhance the biological and mechanical integrity of the printed constructs, continuous single-nozzle printing is required. In this paper, a novel single-nozzle printhead for 3D bioprinting of multi-material constructs was developed and characterized. The single-nozzle multi-material bioprinting was achieved via a disposable, inexpensive, multi-fuse IV extension set; the printhead can print up to four different biomaterials. The transition distance of the developed printhead was characterized over a range of pressures and needle inner diameters. Finally, the transition distance was decreased by applying a silicon coating to the inner channels of the printhead.

scholarly journals Multinozzle Multichannel Temperature Deposition System for Construction of a Blood Vessel

2017 ◽  
Vol 23 (1) ◽  
pp. 64-69 ◽  
Author(s):  
Huanbao Liu ◽  
Huixing Zhou ◽  
Haiming Lan ◽  
Fu Liu ◽  
Xuhan Wang
Keyword(s):  
Tissue Engineering ◽  
Blood Vessel ◽  
3D Model ◽  
Model Structure ◽  
3D Bioprinting ◽  
Porous Structures ◽  
Bioactive Materials ◽  
Organ Regeneration ◽  
Hierarchical Porous ◽  
Temperature Deposition

3D bioprinting is an emerging technology that drives us to construct the complicated tissues and organs consisting of various materials and cells, which has been in widespread use in tissue engineering and organ regeneration. However, the protection and accurate distribution of cells are the most urgent problems to achieve tissue and organ reconstruction. In this article, a multinozzle multichannel temperature deposition and manufacturing (MTDM) system is proposed to fabricate a blood vessel with heterogeneous materials and gradient hierarchical porous structures, which enables not only the reconstruction of a blood vessel with an accurate 3D model structure but also the capacity to distribute bioactive materials such as growth factors, nutrient substance, and so on. In addition, a coaxial focusing nozzle is proposed and designed to extrude the biomaterial and encapsulation material, which can protect the cell from damage. In the MTDM system, the tubular structure of a blood vessel was successfully fabricated with the different biomaterials, which proved that the MTDM system has a potential application prospect in tissue engineering and organ regeneration.

scholarly journals 3D Bioprinting of Human Tissues: Biofabrication, Bioinks and Bioreactors

2021 ◽  
Vol 22 (8) ◽  
pp. 3971
Author(s):  
Jianhua Zhang ◽  
Esther Wehrle ◽  
Marina Rubert ◽  
Ralph Müller
Keyword(s):  
Tissue Engineering ◽  
Human Tissue ◽  
Fluid Shear Stress ◽  
Pharmaceutical Research ◽  
Three Dimensional ◽  
Biological Tissues ◽  
Layer By Layer ◽  
Human Tissues ◽  
3D Bioprinting

The field of tissue engineering has progressed tremendously over the past few decades in its ability to fabricate functional tissue substitutes for regenerative medicine and pharmaceutical research. Conventional scaffold-based approaches are limited in their capacity to produce constructs with the functionality and complexity of native tissue. Three-dimensional (3D) bioprinting offers exciting prospects for scaffolds fabrication, as it allows precise placement of cells, biochemical factors, and biomaterials in a layer-by-layer process. Compared with traditional scaffold fabrication approaches, 3D bioprinting is better to mimic the complex microstructures of biological tissues and accurately control the distribution of cells. Here, we describe recent technological advances in bio-fabrication focusing on 3D bioprinting processes for tissue engineering from data processing to bioprinting, mainly inkjet, laser, and extrusion-based technique. We then review the associated bioink formulation for 3D bioprinting of human tissues, including biomaterials, cells, and growth factors selection. The key bioink properties for successful bioprinting of human tissue were summarized. After bioprinting, the cells are generally devoid of any exposure to fluid mechanical cues, such as fluid shear stress, tension, and compression, which are crucial for tissue development and function in health and disease. The bioreactor can serve as a simulator to aid in the development of engineering human tissues from in vitro maturation of 3D cell-laden scaffolds. We then describe some of the most common bioreactors found in the engineering of several functional tissues, such as bone, cartilage, and cardiovascular applications. In the end, we conclude with a brief insight into present limitations and future developments on the application of 3D bioprinting and bioreactor systems for engineering human tissue.

scholarly journals Naturally Derived Photoinitiators for Dental and Biomaterials Applications

2020 ◽  
Vol 1 (02) ◽  
pp. 72-78
Author(s):  
Mohamed Mahmoud Abdul-Monem
Keyword(s):  
Tissue Engineering ◽  
3D Printing ◽  
Experimental Studies ◽  
Three Dimensional ◽  
Water Soluble ◽  
Polymerization Reaction ◽  
3D Bioprinting ◽  
Engineering Applications ◽  
Bonding Agents ◽  
Materials Used

AbstractBiocompatibility of materials used in dental and biomaterials applications is very important and depends on the components of these materials. Photopolymerized materials for dental and biomaterials applications have been progressively used since the 1970s. One of the crucial components in these materials is the photoinitiator (PI) that initiates the polymerization reaction. Synthetic PIs are the most commonly used types, but owing to their drawbacks such as cytotoxicity, insolubility in water, and high cost, research on naturally derived (bio-sourced) PIs is growing, to find an alternative to these synthetic types, especially in the growing field of three-dimensional (3D) printing and bioprinting of biomaterials for tissue engineering applications. Naturally derived PIs are biocompatible, highly water-soluble, and abundant. Naturally derived PIs have been used to prepare experimental dentine bonding agents, dentine primers, photo-crosslinked hydrogels for tissue engineering applications, antibacterial coatings, guided tissue regeneration membranes, and 3D printed biomaterials. An electronic search was done using MEDLINE/PubMed and Scopus databases using the keywords naturally derived, bio-sourced, PIs, dental, biomaterials, 3D printing, and 3D bioprinting, to review potential naturally derived PIs for dental and biomaterials applications. There are a variety of naturally derived PIs with various colors and absorption spectra to choose from, according to the intended application. Most of naturally derived PIs can be used with modern conventional dental light curing units, making them applicable for experimental studies for potential dental and biomaterials applications. Due to their biocompatibility and availability it is expected that in the upcoming years, research on naturally derived PIs and their dental and biomaterials applications will increase especially in the growing field of 3D bioprinting in which cell viability is essential; thus this review was done.

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