scholarly journals Biomaterials Based on Marine Resources for 3D Bioprinting Applications

Marine Drugs ◽  
2019 ◽  
Vol 17 (10) ◽  
pp. 555 ◽  
Author(s):  
Yi Zhang ◽  
Dezhi Zhou ◽  
Jianwei Chen ◽  
Xiuxiu Zhang ◽  
Xinda Li ◽  
...  
Keyword(s):  
Hyaluronic Acid ◽  
Regenerative Medicine ◽  
Three Dimensional ◽  
Biologically Active ◽  
Marine Resources ◽  
3D Bioprinting ◽  
Natural Polymers ◽  
Flexible Tool ◽  
Mechanical Integrity ◽  
Further Development

Three-dimensional (3D) bioprinting has become a flexible tool in regenerative medicine with potential for various applications. Further development of the new 3D bioprinting field lies in suitable bioink materials with satisfied printability, mechanical integrity, and biocompatibility. Natural polymers from marine resources have been attracting increasing attention in recent years, as they are biologically active and abundant when comparing to polymers from other resources. This review focuses on research and applications of marine biomaterials for 3D bioprinting. Special attention is paid to the mechanisms, material requirements, and applications of commonly used 3D bioprinting technologies based on marine-derived resources. Commonly used marine materials for 3D bioprinting including alginate, carrageenan, chitosan, hyaluronic acid, collagen, and gelatin are also discussed, especially in regards to their advantages and applications.

scholarly journals Natural Polymers for 3D Bioprinting of Organs

2020 ◽  
pp. 30-40
Author(s):  
Galina Sroslova ◽  
Yuliya Zimina ◽  
Elena Nesmeyanova ◽  
Margarita Postnova
Keyword(s):  
Raw Materials ◽  
Sol Gel ◽  
Three Dimensional ◽  
Biologically Active ◽  
Artificial Organs ◽  
Gel Point ◽  
Layer By Layer ◽  
3D Bioprinting ◽  
Natural Polymers ◽  
Biological Origin

Three-dimensional (3D) bioprintingis a well-known promising technology for the production of artificial biological organs providing unprecedented versatility for manipulating cells and other biomaterials with precise control of their location in space. Over the past decade, a number of 3D bioprinting technologies have been developed. Unlike traditional manufacturing technologies, 3D bioprinting allows to produce individual or personalized fabric designs. This helps to deposit cells of the desired type with selected biomaterials and desired biologically active substances. Natural polymers play a leading role in maintaining cellular and biomolecular processes before, during, as well as after three-dimensional bioprinting. Polymers of biological origin can be extracted from natural raw materials by means of physical or chemical methods. These polymers are widely used as effective hydrogels for loading cells to form tissues, build a vascular, nervous, lymphatic network, and also to implement multiple biological, biochemical, physiological, biomedical and other functions. Any natural polymers that have a sol-gel phase transition (i.e., a gel point) under certain conditions can be printed using the automatic layer-by-layer deposition method. In fact, very few of them can be printed under various conditions (low temperature, without the help of physical, chemical, biochemical crosslinking of the incorporated polymer chains). Thus, not all natural polymers can meet all the basic requirements for 3D bioprinting. As a rule, natural polymers as the main component of various inks, which contain cells suspended in a specific medium, must meet several basic requirements for successful 3D bioprinting of organs, as well as clinical applications. These include biocompatibility, that is, non-toxic or without apparent toxicity; biodegradability (unlikenon-biodegradable polymers can be used as auxiliary structures); biostability with sufficiently high mechanical strength both at the time of processing and during operation; bioprinterness (workability). This review is devoted to modern research in the field of natural polymers used to print biological artificial organs.

Engineered Biomimetic Nanofibers for Regenerative Medicine

2010 ◽  
Vol 76 ◽  
pp. 114-124
Author(s):  
Seeram Ramakrishna ◽  
Jayarama Reddy Venugopal ◽  
Susan Liao
Keyword(s):  
Tissue Engineering ◽  
Stem Cells ◽  
Regenerative Medicine ◽  
Cardiac Tissue ◽  
Three Dimensional ◽  
Electrospun Nanofibers ◽  
Cost Effective ◽  
Bioactive Molecules ◽  
Natural Polymers ◽  
Hematopoietic Stem

Attempts have been made to fabricate nanofibrous scaffolds to mimic the chemical composition and structural properties of extracellular matrix (ECM) for tissue/organ regeneration. Nanofibers with various patterns have been successfully produced from synthetic and natural polymers through a relatively simple technique of electrospinning. The resulting patterns can mimic some of the diverse tissue-specific orientation and three-dimensional (3D) fibrous structure. Studies on cell-nanofiber interactions have revealed the importance of nanotopography on cell adhesion, proliferation and differentiation. Our recent data showed that hematopoietic stem cells (HSCs) as well as mesenchymal stem cells (MSCs) can rapidly and effectively attached to the functionalized nanofibers. Mineralized 3D nanofibrous scaffold with bone marrow derived MSCs has been applied for bone tissue engineering. The use of injectable nanofibers for cardiac tissue engineering applications is attractive as they allow for the encapsulation of cardiomyocytes/MSCs as well as bioactive molecules for the repair of myocardial infarction. Duplicate 3D heart helix microstructure by the nanofibrous cardiac patch might provide functional support for infarcted myocardium. Furthermore, clinical applications of electrospun nanofibers for regenerative medicine are highly feasible due to the ease and flexibility of fabrication with the cost-effective method of making nanofibers.

scholarly journals Current research in development of polycaprolactone filament for 3D bioprinting: a review

2021 ◽  
Vol 926 (1) ◽  
pp. 012080
Author(s):  
C Amni ◽  
Marwan ◽  
S Aprilia ◽  
E Indarti
Keyword(s):  
3D Printing ◽  
Three Dimensional ◽  
Development Stage ◽  
Biological Properties ◽  
Fabrication Process ◽  
3D Bioprinting ◽  
Three Dimensional Printing ◽  
Further Development ◽  
Dimensional Printing ◽  
The Ideal

Abstract Three-dimensional printing (3DP) provides a fast and easy fabrication process without demanding post-processing. 3D-bioprinting is a special class in 3DP. Bio-printing is the process of accurately 3DP structural design using filament. 3D bio-printing technology is still in the development stage, its application in various engineering continues to increase, such as in tissue engineering. As a forming material in 3D printing, many types of commercial filaments have been developed. Filaments can be produced from either natural or synthetic biomaterials alone, or a combination of the two as a hybrid material. The ideal filament must have precise mechanical, rheological and biological properties. Polycaprolactone (PCL) is specifically developed and optimized for bio-printing of 3D structures. PCL is a strategy in 3D printing to better control interconnectivity and porosity spatially. Structural stability and less sensitive properties environmental conditions, such as temperature, humidity, etc make PCL as an ideal material for the FDM fabrication process. In this review, we provide an in-depth discussion of current research on PCL as a filament currently used for 3D bio-printing and outline some future perspectives in their further development.

scholarly journals Freeform 3D Bioprinting Involving Ink Gelation by Cascade Reaction of Oxidase and Peroxidase: A Feasibility Study Using Hyaluronic Acid-Based Ink

Biomolecules ◽  
2021 ◽  
Vol 11 (12) ◽  
pp. 1908
Author(s):  
Shinji Sakai ◽  
Ryohei Harada ◽  
Takashi Kotani
Keyword(s):  
Hyaluronic Acid ◽  
Three Dimensional ◽  
Cascade Reaction ◽  
Mouse Fibroblast ◽  
Choline Oxidase ◽  
3D Bioprinting ◽  
Physical Support ◽  
Good Shape ◽  
Supporting Material ◽  
Supporting Materials

Freeform bioprinting, realized by extruding ink-containing cells into supporting materials to provide physical support during printing, has fostered significant advances toward the fabrication of cell-laden soft hydrogel constructs with desired spatial control. For further advancement of freeform bioprinting, we aimed to propose a method in which the ink embedded in supporting materials gelate through a cytocompatible and rapid cascade reaction between oxidase and peroxidase. To demonstrate the feasibility of the proposed method, we extruded ink containing choline, horseradish peroxidase (HRP), and a hyaluronic acid derivative, cross-linkable by HRP-catalyzed reaction, into a supporting material containing choline oxidase and successfully obtained three-dimensional hyaluronic acid-based hydrogel constructs with good shape fidelity to blueprints. Cytocompatibility of the bioprinting method was confirmed by the comparable growth of mouse fibroblast cells, released from the printed hydrogels through degradation on cell culture dishes, with those not exposed to the printing process, and considering more than 85% viability of the enclosed cells during 10 days of culture. Owing to the presence of derivatives of the various biocompatible polymers that are cross-linkable through HRP-mediated cross-linking, our results demonstrate that the novel 3D bioprinting method has great potential in tissue engineering applications.

Natural Hydrogels Applied in Photodynamic Therapy

2020 ◽  
Vol 27 (16) ◽  
pp. 2681-2703 ◽  
Author(s):  
Zhipan Feng ◽  
Shiying Lin ◽  
Andrew McDonagh ◽  
Chen Yu
Keyword(s):  
Photodynamic Therapy ◽  
Hyaluronic Acid ◽  
Drug Release ◽  
Three Dimensional ◽  
Controlled Drug Release ◽  
Natural Polymers ◽  
Current Review ◽  
Design Variables ◽  
Cd44 Targeting

Natural hydrogels are three-dimensional (3D) water-retaining materials with a skeleton consisting of natural polymers, their derivatives or mixtures. Natural hydrogels can provide sustained or controlled drug release and possess some unique properties of natural polymers, such as biodegradability, biocompatibility and some additional functions, such as CD44 targeting of hyaluronic acid. Natural hydrogels can be used with photosensitizers (PSs) in photodynamic therapy (PDT) to increase the range of applications. In the current review, the pertinent design variables are discussed along with a description of the categories of natural hydrogels available for PDT.

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 Three-Dimensional Bioprinting and Its Potential in the Field of Articular Cartilage Regeneration

Cartilage ◽  
2016 ◽  
Vol 8 (4) ◽  
pp. 327-340 ◽  
Author(s):  
Vivian H. M. Mouser ◽  
Riccardo Levato ◽  
Lawrence J. Bonassar ◽  
Darryl D. D’Lima ◽  
Daniel A. Grande ◽  
...  
Keyword(s):  
Articular Cartilage ◽  
Three Dimensional ◽  
Cartilage Regeneration ◽  
Biologically Active ◽  
3D Bioprinting ◽  
Clinical Images ◽  
3D Printed ◽  
Current Article ◽  
Hybrid Printing

Three-dimensional (3D) bioprinting techniques can be used for the fabrication of personalized, regenerative constructs for tissue repair. The current article provides insight into the potential and opportunities of 3D bioprinting for the fabrication of cartilage regenerative constructs. Although 3D printing is already used in the orthopedic clinic, the shift toward 3D bioprinting has not yet occurred. We believe that this shift will provide an important step forward in the field of cartilage regeneration. Three-dimensional bioprinting techniques allow incorporation of cells and biological cues during the manufacturing process, to generate biologically active implants. The outer shape of the construct can be personalized based on clinical images of the patient’s defect. Additionally, by printing with multiple bio-inks, osteochondral or zonally organized constructs can be generated. Relevant mechanical properties can be obtained by hybrid printing with thermoplastic polymers and hydrogels, as well as by the incorporation of electrospun meshes in hydrogels. Finally, bioprinting techniques contribute to the automation of the implant production process, reducing the infection risk. To prompt the shift from nonliving implants toward living 3D bioprinted cartilage constructs in the clinic, some challenges need to be addressed. The bio-inks and required cartilage construct architecture need to be further optimized. The bio-ink and printing process need to meet the sterility requirements for implantation. Finally, standards are essential to ensure a reproducible quality of the 3D printed constructs. Once these challenges are addressed, 3D bioprinted living articular cartilage implants may find their way into daily clinical practice.

scholarly journals Natural polymers for the microencapsulation of cells

2014 ◽  
Vol 11 (100) ◽  
pp. 20140817 ◽  
Author(s):  
Luca Gasperini ◽  
João F. Mano ◽  
Rui L. Reis
Keyword(s):  
Tissue Engineering ◽  
Hyaluronic Acid ◽  
Mammalian Cells ◽  
Three Dimensional ◽  
Cell Phenotype ◽  
Biotechnological Applications ◽  
Natural Polymers ◽  
Mild Conditions ◽  
Hydrogel Matrix ◽  
Stem Cell Phenotype

The encapsulation of living mammalian cells within a semi-permeable hydrogel matrix is an attractive procedure for many biomedical and biotechnological applications, such as xenotransplantation, maintenance of stem cell phenotype and bioprinting of three-dimensional scaffolds for tissue engineering and regenerative medicine. In this review, we focus on naturally derived polymers that can form hydrogels under mild conditions and that are thus capable of entrapping cells within controlled volumes. Our emphasis will be on polysaccharides and proteins, including agarose, alginate, carrageenan, chitosan, gellan gum, hyaluronic acid, collagen, elastin, gelatin, fibrin and silk fibroin. We also discuss the technologies commonly employed to encapsulate cells in these hydrogels, with particular attention on microencapsulation.

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