An Introduction to 3D Bioprinting: Possibilities, Challenges and Future Aspects

Bioprinting is an emerging field in regenerative medicine. Producing cell-laden, three-dimensional structures to mimic bodily tissues has an important role not only in tissue engineering, but also in drug delivery and cancer studies. Bioprinting can provide patient-specific spatial geometry, controlled microstructures and the positioning of different cell types for the fabrication of tissue engineering scaffolds. In this brief review, the different fabrication techniques: laser-based, extrusion-based and inkjet-based bioprinting, are defined, elaborated and compared. Advantages and challenges of each technique are addressed as well as the current research status of each technique towards various tissue types. Nozzle-based techniques, like inkjet and extrusion printing, and laser-based techniques, like stereolithography and laser-assisted bioprinting, are all capable of producing successful bioprinted scaffolds. These four techniques were found to have diverse effects on cell viability, resolution and print fidelity. Additionally, the choice of materials and their concentrations were also found to impact the printing characteristics. Each technique has demonstrated individual advantages and disadvantages with more recent research conduct involving multiple techniques to combine the advantages of each technique.

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Thermal Processing of Tissue Engineering Scaffolds

Journal of Heat Transfer ◽

10.1115/1.4002464 ◽

2010 ◽

Vol 133 (3) ◽

Cited By ~ 11

Author(s):

Alisa Morss Clyne

Keyword(s):

Tissue Engineering ◽

Thermal Processing ◽

Three Dimensional ◽

Processing Parameters ◽

High Pressure Processing ◽

Porous Scaffolds ◽

Tissue Engineering Scaffolds ◽

Thermally Induced ◽

Advantages And Disadvantages ◽

Particulate Leaching

Tissue engineering requires complex three-dimensional scaffolds that mimic natural extracellular matrix function. A wide variety of techniques have been developed to create both fibrous and porous scaffolds out of polymers, ceramics, metals, and composite materials. Existing techniques include fiber bonding, electrospinning, emulsion freeze drying, solvent casting/particulate leaching, gas foaming/particulate leaching, high pressure processing, and thermally induced phase separation. Critical scaffold properties, including pore size, porosity, pore interconnectivity, and mechanical integrity, are determined by thermal processing parameters in many of these techniques. In this review, each tissue engineering scaffold preparation method is discussed, including recent advancements as well as advantages and disadvantages of the technique, with a particular emphasis placed on thermal parameters. Improvements on these existing techniques, as well as new thermal processing methods for tissue engineering scaffolds, will be needed to provide tissue engineers with finer control over tissue and organ development.

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Modelling molecular mechanisms of breast cancer and invasion: lessons from the normal gland

Biochemical Society Transactions ◽

10.1042/bst0350018 ◽

2007 ◽

Vol 35 (1) ◽

pp. 18-22 ◽

Cited By ~ 34

Author(s):

M.J. Bissell

Keyword(s):

Breast Cancer ◽

Cell Culture ◽

Molecular Mechanisms ◽

Three Dimensional ◽

Cell Types ◽

Genes And Environment ◽

Different Cell Types ◽

Cancerous Cells ◽

Cancer Studies ◽

Dimensional Cell

The interplay between genes and environment is complex, particularly when it comes to cancer. Studies on breast cancer cells have shown that environmental influences dominate over genotype in their effect on phenotype, and can cause cancerous cells to revert to a non-malignant phenotype, while remaining genotypically malignant. Using breast tissue in three-dimensional cell culture has proved a better model than traditional two-dimensional cell culture in that different cell types can be seen to behave differently to the same pro-apoptotic signal, with normal cells surviving.

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Conductive nanofibrous scaffolds for tissue engineering

Izvestiya of Saratov University New series Series Physics ◽

10.18500/1817-3020-2021-21-1-48-57 ◽

2021 ◽

Vol 21 (1) ◽

pp. 48-57

Author(s):

Ekaterina V. Lengert ◽

◽

Anton M. Pavlov ◽

Keyword(s):

Tissue Engineering ◽

Three Dimensional ◽

Chemical Properties ◽

Cell Types ◽

Target Tissue ◽

Tissue Engineering Scaffolds ◽

Nonwoven Materials ◽

Nanofibrous Scaffolds ◽

Dimensional Network ◽

Physical And Chemical

One of very demanded and actively developed areas of modern biomedicine is tissue engineering, investigating synthesis and reparation of various kinds of tissues, including trauma treatment. Normally cells in tissue grow in the microenvironment provided by exttacellular matrix – a three-dimensional network of macromolecules, mostly peptides and proteins, that provide structural and biochemical support. To substitute this matrix in medical applications and promote new cells growth and repair damaged tissue, various types of artificial scaffolds are proposed. Morphology, as well as physical and chemical properties of scaffolds influence the fate of cells, including attachment, proliferation and differentiation, and strongly correlate with the type of target tissue. This review is aimed to provide a short insight in materials and technologies for synthesis of tissue engineering scaffolds, with focus on polymeric electrospun nonwoven materials and ones with conductive structures that can be potentially used to direct electrical signals to cells for the aims of electrostimulation, which was demonstrated to induce functional repairmen of certain cell types such as myocytes and neurons.

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HYDROXYAPATITE, ALGINATE, AND CHITOSAN FOR BONE SCAFFOLDS: SPECTROSCOPY STUDY

Dentika Dental Journal ◽

10.32734/dentika.v19i2.457 ◽

2016 ◽

Vol 19 (2) ◽

pp. 93-100

Author(s):

Lalita El Milla

Keyword(s):

Tissue Engineering ◽

Bone Tissue Engineering ◽

Bone Tissue ◽

Functional Groups ◽

Bone Growth ◽

Three Dimensional ◽

Dimensional Structure ◽

Tissue Engineering Scaffolds ◽

Hydroxyapatite Powder ◽

Materials Used

Scaffolds is three dimensional structure that serves as a framework for bone growth. Natural materials are often used in synthesis of bone tissue engineering scaffolds with respect to compliance with the content of the human body. Among the materials used to make scafffold was hydroxyapatite, alginate and chitosan. Hydroxyapatite powder obtained by mixing phosphoric acid and calcium hydroxide, alginate powders extracted from brown algae and chitosan powder acetylated from crab. The purpose of this study was to examine the functional groups of hydroxyapatite, alginate and chitosan. The method used in this study was laboratory experimental using Fourier Transform Infrared (FTIR) spectroscopy for hydroxyapatite, alginate and chitosan powders. The results indicated the presence of functional groups PO43-, O-H and CO32- in hydroxyapatite. In alginate there were O-H, C=O, COOH and C-O-C functional groups, whereas in chitosan there were O-H, N-H, C=O, C-N, and C-O-C. It was concluded that the third material containing functional groups as found in humans that correspond to the scaffolds material in bone tissue engineering.

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Uncovering the Diversification of Tissue Engineering on the Emergent Areas of Stem Cells, Nanotechnology and Biomaterials

Current Stem Cell Research & Therapy ◽

10.2174/1574888x15666200103124821 ◽

2020 ◽

Vol 15 (3) ◽

pp. 187-201 ◽

Cited By ~ 1

Author(s):

Sunil K. Dubey ◽

Amit Alexander ◽

Munnangi Sivaram ◽

Mukta Agrawal ◽

Gautam Singhvi ◽

...

Keyword(s):

Tissue Engineering ◽

Stem Cells ◽

Immune System ◽

Clinical Application ◽

Cell Types ◽

Patient Specific ◽

Potential Strategy ◽

Induced Pluripotent ◽

Treat All ◽

The Impact

Damaged or disabled tissue is life-threatening due to the lack of proper treatment. Many conventional transplantation methods like autograft, iso-graft and allograft are in existence for ages, but they are not sufficient to treat all types of tissue or organ damages. Stem cells, with their unique capabilities like self-renewal and differentiate into various cell types, can be a potential strategy for tissue regeneration. However, the challenges like reproducibility, uncontrolled propagation and differentiation, isolation of specific kinds of cell and tumorigenic nature made these stem cells away from clinical application. Today, various types of stem cells like embryonic, fetal or gestational tissue, mesenchymal and induced-pluripotent stem cells are under investigation for their clinical application. Tissue engineering helps in configuring the stem cells to develop into a desired viable tissue, to use them clinically as a substitute for the conventional method. The use of stem cell-derived Extracellular Vesicles (EVs) is being studied to replace the stem cells, which decreases the immunological complications associated with the direct administration of stem cells. Tissue engineering also investigates various biomaterials to use clinically, either to replace the bones or as a scaffold to support the growth of stemcells/ tissue. Depending upon the need, there are various biomaterials like bio-ceramics, natural and synthetic biodegradable polymers to support replacement or regeneration of tissue. Like the other fields of science, tissue engineering is also incorporating the nanotechnology to develop nano-scaffolds to provide and support the growth of stem cells with an environment mimicking the Extracellular matrix (ECM) of the desired tissue. Tissue engineering is also used in the modulation of the immune system by using patient-specific Mesenchymal Stem Cells (MSCs) and by modifying the physical features of scaffolds that may provoke the immune system. This review describes the use of various stem cells, biomaterials and the impact of nanotechnology in regenerative medicine.

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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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Spheroid confrontation assay: A simple method to monitor the three-dimensional migration of different cell types in vitro

Annals of Anatomy - Anatomischer Anzeiger ◽

10.1016/j.aanat.2010.12.005 ◽

2011 ◽

Vol 193 (3) ◽

pp. 181-184 ◽

Cited By ~ 22

Author(s):

Kirsten Hattermann ◽

Janka Held-Feindt ◽

Rolf Mentlein

Keyword(s):

Three Dimensional ◽

Cell Types ◽

Simple Method ◽

Different Cell Types ◽

Confrontation Assay

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High-precision 3D inkjet technology for live cell bioprinting

International Journal of Bioprinting ◽

10.18063/ijb.v5i2.208 ◽

2019 ◽

Vol 5 (2) ◽

pp. 27 ◽

Cited By ~ 3

Author(s):

Daisuke Takagi ◽

Waka Lin ◽

Takahiko Matsumoto ◽

Hidekazu Yaginuma ◽

Natsuko Hemmi ◽

...

Keyword(s):

Three Dimensional ◽

Cell Types ◽

Cell Number ◽

Live Cell ◽

Drop On Demand ◽

Long Time ◽

Spatial Positioning ◽

Different Cell Types ◽

Membrane Vibrations

In recent years, bioprinting has emerged as a promising technology for the construction of three-dimensional (3D) tissues to be used in regenerative medicine or in vitro screening applications. In the present study, we present the development of an inkjet-based bioprinting system to arrange multiple cells and materials precisely into structurally organized constructs. A novel inkjet printhead has been specially designed for live cell ejection. Droplet formation is powered by piezoelectric membrane vibrations coupled with mixing movements to prevent cell sedimentation at the nozzle. Stable drop-on-demand dispensing and cell viability were validated over an adequately long time to allow the fabrication of 3D tissues. Reliable control of cell number and spatial positioning was demonstrated using two separate suspensions with different cell types printed sequentially. Finally, a process for constructing stratified Mille-Feuille-like 3D structures is proposed by alternately superimposing cell suspensions and hydrogel layers with a controlled vertical resolution. The results show that inkjet technology is effective for both two-dimensional patterning and 3D multilayering and has the potential to facilitate the achievement of live cell bioprinting with an unprecedented level of precision.

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