Your search keyword '"3D bioprinting"' showing total 86 results

1. Coaxial 3D Bioprinting Process Research and Performance Tests on Vascular Scaffolds.

Author

Sun, Jiarun, Gong, Youping, Xu, Manli, Chen, Huipeng, Shao, Huifeng, and Zhou, Rougang

Subjects

BIOPRINTING, TISSUE scaffolds, UMBILICAL veins, CALCIUM chloride, SODIUM alginate, ENDOTHELIAL cells

Abstract

Three-dimensionally printed vascularized tissue, which is suitable for treating human cardiovascular diseases, should possess excellent biocompatibility, mechanical performance, and the structure of complex vascular networks. In this paper, we propose a method for fabricating vascularized tissue based on coaxial 3D bioprinting technology combined with the mold method. Sodium alginate (SA) solution was chosen as the bioink material, while the cross-linking agent was a calcium chloride (CaCl2) solution. To obtain the optimal parameters for the fabrication of vascular scaffolds, we first formulated theoretical models of a coaxial jet and a vascular network. Subsequently, we conducted a simulation analysis to obtain preliminary process parameters. Based on the aforementioned research, experiments of vascular scaffold fabrication based on the coaxial jet model and experiments of vascular network fabrication were carried out. Finally, we optimized various parameters, such as the flow rate of internal and external solutions, bioink concentration, and cross-linking agent concentration. The performance tests showed that the fabricated vascular scaffolds had levels of satisfactory degradability, water absorption, and mechanical properties that meet the requirements for practical applications. Cellular experiments with stained samples demonstrated satisfactory proliferation of human umbilical vein endothelial cells (HUVECs) within the vascular scaffold over a seven-day period, observed under a fluorescent inverted microscope. The cells showed good biocompatibility with the vascular scaffold. The above results indicate that the fabricated vascular structure initially meet the requirements of vascular scaffolds. [ABSTRACT FROM AUTHOR]

Published

2024

2. Coaxial 3D Bioprinting Process Research and Performance Tests on Vascular Scaffolds

Author

Jiarun Sun, Youping Gong, Manli Xu, Huipeng Chen, Huifeng Shao, and Rougang Zhou

Subjects

3D bioprinting, coaxial jet, vascular network, finite element analysis, biological scaffold, Mechanical engineering and machinery, TJ1-1570

Abstract

Three-dimensionally printed vascularized tissue, which is suitable for treating human cardiovascular diseases, should possess excellent biocompatibility, mechanical performance, and the structure of complex vascular networks. In this paper, we propose a method for fabricating vascularized tissue based on coaxial 3D bioprinting technology combined with the mold method. Sodium alginate (SA) solution was chosen as the bioink material, while the cross-linking agent was a calcium chloride (CaCl2) solution. To obtain the optimal parameters for the fabrication of vascular scaffolds, we first formulated theoretical models of a coaxial jet and a vascular network. Subsequently, we conducted a simulation analysis to obtain preliminary process parameters. Based on the aforementioned research, experiments of vascular scaffold fabrication based on the coaxial jet model and experiments of vascular network fabrication were carried out. Finally, we optimized various parameters, such as the flow rate of internal and external solutions, bioink concentration, and cross-linking agent concentration. The performance tests showed that the fabricated vascular scaffolds had levels of satisfactory degradability, water absorption, and mechanical properties that meet the requirements for practical applications. Cellular experiments with stained samples demonstrated satisfactory proliferation of human umbilical vein endothelial cells (HUVECs) within the vascular scaffold over a seven-day period, observed under a fluorescent inverted microscope. The cells showed good biocompatibility with the vascular scaffold. The above results indicate that the fabricated vascular structure initially meet the requirements of vascular scaffolds.

Published

2024

3. Application of 3D Bioprinting in Liver Diseases.

Author

Li, Wenhui, Liu, Zhaoyue, Tang, Fengwei, Jiang, Hao, Zhou, Zhengyuan, Hao, Xiuqing, and Zhang, Jia Ming

Subjects

BIOPRINTING, LIVER diseases, KUPFFER cells, LIVER cells, DRUG discovery, REGENERATIVE medicine, HEART, BIOMATERIALS, BIOCOMPLEXITY

Abstract

Liver diseases are the primary reason for morbidity and mortality in the world. Owing to a shortage of organ donors and postoperative immune rejection, patients routinely suffer from liver failure. Unlike 2D cell models, animal models, and organoids, 3D bioprinting can be successfully employed to print living tissues and organs that contain blood vessels, bone, and kidney, heart, and liver tissues and so on. 3D bioprinting is mainly classified into four types: inkjet 3D bioprinting, extrusion-based 3D bioprinting, laser-assisted bioprinting (LAB), and vat photopolymerization. Bioinks for 3D bioprinting are composed of hydrogels and cells. For liver 3D bioprinting, hepatic parenchymal cells (hepatocytes) and liver nonparenchymal cells (hepatic stellate cells, hepatic sinusoidal endothelial cells, and Kupffer cells) are commonly used. Compared to conventional scaffold-based approaches, marked by limited functionality and complexity, 3D bioprinting can achieve accurate cell settlement, a high resolution, and more efficient usage of biomaterials, better mimicking the complex microstructures of native tissues. This method will make contributions to disease modeling, drug discovery, and even regenerative medicine. However, the limitations and challenges of this method cannot be ignored. Limitation include the requirement of diverse fabrication technologies, observation of drug dynamic response under perfusion culture, the resolution to reproduce complex hepatic microenvironment, and so on. Despite this, 3D bioprinting is still a promising and innovative biofabrication strategy for the creation of artificial multi-cellular tissues/organs. [ABSTRACT FROM AUTHOR]

Published

2023

4. 3D Bioprinting of an Endothelialized Liver Lobule-like Construct as a Tumor-Scale Drug Screening Platform.

Author

Fan, Zicheng, Wei, Xiaoyun, Chen, Keke, Wang, Ling, and Xu, Mingen

Subjects

BIOPRINTING, MEDICAL screening, CELL culture, LIVER, CELL communication, LIVER cancer

Abstract

3D cell culture models replicating the complexity of cell–cell interactions and biomimetic extracellular matrix (ECM) are novel approaches for studying liver cancer, including in vitro drug screening or disease mechanism investigation. Although there have been advancements in the production of 3D liver cancer models to serve as drug screening platforms, recreating the structural architecture and tumor-scale microenvironment of native liver tumors remains a challenge. Here, using the dot extrusion printing (DEP) technology reported in our previous work, we fabricated an endothelialized liver lobule-like construct by printing hepatocyte-laden methacryloyl gelatin (GelMA) hydrogel microbeads and HUVEC-laden gelatin microbeads. DEP technology enables hydrogel microbeads to be produced with precise positioning and adjustable scale, facilitating the construction of liver lobule-like structures. The vascular network was achieved by sacrificing the gelatin microbeads at 37 °C to allow HUVEC proliferation on the surface of the hepatocyte layer. Finally, we used the endothelialized liver lobule-like constructs for anti-cancer drug (Sorafenib) screening, and stronger drug resistance results were obtained when compared to either mono-cultured constructs or hepatocyte spheroids alone. The 3D liver cancer models presented here successfully recreate liver lobule-like morphology, and may have the potential to serve as a liver tumor-scale drug screening platform. [ABSTRACT FROM AUTHOR]

Published

2023

5. Application of 3D Bioprinting in Liver Diseases

Author

Wenhui Li, Zhaoyue Liu, Fengwei Tang, Hao Jiang, Zhengyuan Zhou, Xiuqing Hao, and Jia Ming Zhang

Subjects

liver diseases, 3D bioprinting, biofabrication strategy, artificial multi-cellular tissues/organs, Mechanical engineering and machinery, TJ1-1570

Abstract

Liver diseases are the primary reason for morbidity and mortality in the world. Owing to a shortage of organ donors and postoperative immune rejection, patients routinely suffer from liver failure. Unlike 2D cell models, animal models, and organoids, 3D bioprinting can be successfully employed to print living tissues and organs that contain blood vessels, bone, and kidney, heart, and liver tissues and so on. 3D bioprinting is mainly classified into four types: inkjet 3D bioprinting, extrusion-based 3D bioprinting, laser-assisted bioprinting (LAB), and vat photopolymerization. Bioinks for 3D bioprinting are composed of hydrogels and cells. For liver 3D bioprinting, hepatic parenchymal cells (hepatocytes) and liver nonparenchymal cells (hepatic stellate cells, hepatic sinusoidal endothelial cells, and Kupffer cells) are commonly used. Compared to conventional scaffold-based approaches, marked by limited functionality and complexity, 3D bioprinting can achieve accurate cell settlement, a high resolution, and more efficient usage of biomaterials, better mimicking the complex microstructures of native tissues. This method will make contributions to disease modeling, drug discovery, and even regenerative medicine. However, the limitations and challenges of this method cannot be ignored. Limitation include the requirement of diverse fabrication technologies, observation of drug dynamic response under perfusion culture, the resolution to reproduce complex hepatic microenvironment, and so on. Despite this, 3D bioprinting is still a promising and innovative biofabrication strategy for the creation of artificial multi-cellular tissues/organs.

Published

2023

6. Application of 3D Bioprinting in Urology.

Author

Zhao, Yue, Liu, Yuebai, Dai, Yi, Yang, Luo, and Chen, Guo

Subjects

BIOPRINTING, TISSUE engineering, BIOMATERIALS, UROLOGY, HUMAN abnormalities, BIOLOGICAL models

Abstract

Tissue engineering is an emerging field to create functional tissue components and whole organs. The structural and functional defects caused by congenital malformation, trauma, inflammation or tumor are still the major clinical challenges facing modern urology, and the current treatment has not achieved the expected results. Recently, 3D bioprinting has gained attention for its ability to create highly specialized tissue models using biological materials, bridging the gap between artificially engineered and natural tissue structures. This paper reviews the research progress, application prospects and current challenges of 3D bioprinting in urology tissue engineering. [ABSTRACT FROM AUTHOR]

Published

2022

7. Photo-Crosslinkable Hydrogels for 3D Bioprinting in the Repair of Osteochondral Defects: A Review of Present Applications and Future Perspectives.

Author

Tan, Gang, Xu, Jing, Yu, Qin, Zhang, Jieyu, Hu, Xuefeng, Sun, Chenwei, and Zhang, Hui

Subjects

BIOPRINTING, REPAIRING, HYDROGELS, BIOMATERIALS, THERAPEUTICS, CARTILAGE

Abstract

An osteochondral defect is a common and frequent disease in orthopedics and treatment effects are not good, which can be harmful to patients. Hydrogels have been applied in the repair of cartilage defects. Many studies have reported that hydrogels can effectively repair osteochondral defects through loaded cells or non-loaded cells. As a new type of hydrogel, photo-crosslinked hydrogel has been widely applied in more and more fields. Meanwhile, 3D bioprinting serves as an attractive platform to fabricate customized tissue-engineered substitutes from biomaterials and cells for the repair or replacement of injured tissues and organs. Although photo-crosslinkable hydrogel-based 3D bioprinting has some advantages for repairing bone cartilage defects, it also has some disadvantages. Our aim of this paper is to review the current status and prospect of photo-crosslinkable hydrogel-based 3D bioprinting for repairing osteochondral defects. [ABSTRACT FROM AUTHOR]

Published

2022

8. 3D Bioprinting of an Endothelialized Liver Lobule-like Construct as a Tumor-Scale Drug Screening Platform

Author

Zicheng Fan, Xiaoyun Wei, Keke Chen, Ling Wang, and Mingen Xu

Subjects

3D bioprinting, GelMA hydrogel, liver lobule-like construct, drug screening, Mechanical engineering and machinery, TJ1-1570

Abstract

3D cell culture models replicating the complexity of cell–cell interactions and biomimetic extracellular matrix (ECM) are novel approaches for studying liver cancer, including in vitro drug screening or disease mechanism investigation. Although there have been advancements in the production of 3D liver cancer models to serve as drug screening platforms, recreating the structural architecture and tumor-scale microenvironment of native liver tumors remains a challenge. Here, using the dot extrusion printing (DEP) technology reported in our previous work, we fabricated an endothelialized liver lobule-like construct by printing hepatocyte-laden methacryloyl gelatin (GelMA) hydrogel microbeads and HUVEC-laden gelatin microbeads. DEP technology enables hydrogel microbeads to be produced with precise positioning and adjustable scale, facilitating the construction of liver lobule-like structures. The vascular network was achieved by sacrificing the gelatin microbeads at 37 °C to allow HUVEC proliferation on the surface of the hepatocyte layer. Finally, we used the endothelialized liver lobule-like constructs for anti-cancer drug (Sorafenib) screening, and stronger drug resistance results were obtained when compared to either mono-cultured constructs or hepatocyte spheroids alone. The 3D liver cancer models presented here successfully recreate liver lobule-like morphology, and may have the potential to serve as a liver tumor-scale drug screening platform.

Published

2023

9. Optimized 3D Bioprinting Technology Based on Machine Learning: A Review of Recent Trends and Advances.

Author

Shin, Jaemyung, Lee, Yoonjung, Li, Zhangkang, Hu, Jinguang, Park, Simon S., and Kim, Keekyoung

Subjects

BIOPRINTING, MACHINE learning, BIOMEDICAL materials, THREE-dimensional printing, TRANSPLANTATION of organs, tissues, etc., BRAIN death, FREE flaps, REGENERATIVE medicine

Abstract

The need for organ transplants has risen, but the number of available organ donations for transplants has stagnated worldwide. Regenerative medicine has been developed to make natural organs or tissue-like structures with biocompatible materials and solve the donor shortage problem. Using biomaterials and embedded cells, a bioprinter enables the fabrication of complex and functional three-dimensional (3D) structures of the organs or tissues for regenerative medicine. Moreover, conventional surgical 3D models are made of rigid plastic or rubbers, preventing surgeons from interacting with real organ or tissue-like models. Thus, finding suitable biomaterials and printing methods will accelerate the printing of sophisticated organ structures and the development of realistic models to refine surgical techniques and tools before the surgery. In addition, printing parameters (e.g., printing speed, dispensing pressure, and nozzle diameter) considered in the bioprinting process should be optimized. Therefore, machine learning (ML) technology can be a powerful tool to optimize the numerous bioprinting parameters. Overall, this review paper is focused on various ideas on the ML applications of 3D printing and bioprinting to optimize parameters and procedures. [ABSTRACT FROM AUTHOR]

Published

2022

10. Application of 3D Bioprinting in Urology

Author

Yue Zhao, Yuebai Liu, Yi Dai, Luo Yang, and Guo Chen

Subjects

3D bioprinting, tissue engineering, urology, Mechanical engineering and machinery, TJ1-1570

Abstract

Tissue engineering is an emerging field to create functional tissue components and whole organs. The structural and functional defects caused by congenital malformation, trauma, inflammation or tumor are still the major clinical challenges facing modern urology, and the current treatment has not achieved the expected results. Recently, 3D bioprinting has gained attention for its ability to create highly specialized tissue models using biological materials, bridging the gap between artificially engineered and natural tissue structures. This paper reviews the research progress, application prospects and current challenges of 3D bioprinting in urology tissue engineering.

Published

2022

11. Photo-Crosslinkable Hydrogels for 3D Bioprinting in the Repair of Osteochondral Defects: A Review of Present Applications and Future Perspectives

Author

Gang Tan, Jing Xu, Qin Yu, Jieyu Zhang, Xuefeng Hu, Chenwei Sun, and Hui Zhang

Subjects

photo-crosslinkable hydrogel, 3D bioprinting, osteochondral defects, Mechanical engineering and machinery, TJ1-1570

Abstract

An osteochondral defect is a common and frequent disease in orthopedics and treatment effects are not good, which can be harmful to patients. Hydrogels have been applied in the repair of cartilage defects. Many studies have reported that hydrogels can effectively repair osteochondral defects through loaded cells or non-loaded cells. As a new type of hydrogel, photo-crosslinked hydrogel has been widely applied in more and more fields. Meanwhile, 3D bioprinting serves as an attractive platform to fabricate customized tissue-engineered substitutes from biomaterials and cells for the repair or replacement of injured tissues and organs. Although photo-crosslinkable hydrogel-based 3D bioprinting has some advantages for repairing bone cartilage defects, it also has some disadvantages. Our aim of this paper is to review the current status and prospect of photo-crosslinkable hydrogel-based 3D bioprinting for repairing osteochondral defects.

Published

2022

12. 3D Bioprinting of an In Vitro Model of a Biomimetic Urinary Bladder with a Contract-Release System

Author

Suhun Chae, Jaewook Kim, Hee-Gyeong Yi, and Dong-Woo Cho

Subjects

in vitro bladder model, 3D bioprinting, decellularized bladder extracellular matrix, bladder tissue engineering, Mechanical engineering and machinery, TJ1-1570

Abstract

The development of curative therapy for bladder dysfunction is usually hampered owing to the lack of reliable ex vivo human models that can mimic the complexity of the human bladder. To overcome this issue, 3D in vitro model systems offering unique opportunities to engineer realistic human tissues/organs have been developed. However, existing in vitro models still cannot entirely reflect the key structural and physiological characteristics of the native human bladder. In this study, we propose an in vitro model of the urinary bladder that can create 3D biomimetic tissue structures and dynamic microenvironments to replicate the smooth muscle functions of an actual human urinary bladder. In other words, the proposed biomimetic model system, developed using a 3D bioprinting approach, can recreate the physiological motion of the urinary bladder by incorporating decellularized extracellular matrix from the bladder tissue and introducing cyclic mechanical stimuli. The results showed that the developed bladder tissue models exhibited high cell viability and proliferation rate and promoted myogenic differentiation potential given dynamic mechanical cues. We envision the developed in vitro bladder mimicry model can serve as a research platform for fundamental studies on human disease modeling and pharmaceutical testing.

Published

2022

13. Optimized 3D Bioprinting Technology Based on Machine Learning: A Review of Recent Trends and Advances

Author

Jaemyung Shin, Yoonjung Lee, Zhangkang Li, Jinguang Hu, Simon S. Park, and Keekyoung Kim

Subjects

3D bioprinting, regenerative medicine, optimization, machine learning, Mechanical engineering and machinery, TJ1-1570

Abstract

The need for organ transplants has risen, but the number of available organ donations for transplants has stagnated worldwide. Regenerative medicine has been developed to make natural organs or tissue-like structures with biocompatible materials and solve the donor shortage problem. Using biomaterials and embedded cells, a bioprinter enables the fabrication of complex and functional three-dimensional (3D) structures of the organs or tissues for regenerative medicine. Moreover, conventional surgical 3D models are made of rigid plastic or rubbers, preventing surgeons from interacting with real organ or tissue-like models. Thus, finding suitable biomaterials and printing methods will accelerate the printing of sophisticated organ structures and the development of realistic models to refine surgical techniques and tools before the surgery. In addition, printing parameters (e.g., printing speed, dispensing pressure, and nozzle diameter) considered in the bioprinting process should be optimized. Therefore, machine learning (ML) technology can be a powerful tool to optimize the numerous bioprinting parameters. Overall, this review paper is focused on various ideas on the ML applications of 3D printing and bioprinting to optimize parameters and procedures.

Published

2022

14. Applications of 3D Bioprinting Technology in Induced Pluripotent Stem Cells-Based Tissue Engineering

Author

Arvind Kumar Shukla, Ge Gao, and Byoung Soo Kim

Subjects

induced pluripotent stem cells (iPSCs), 3D bioprinting, Mechanical engineering and machinery, TJ1-1570

Abstract

Induced pluripotent stem cells (iPSCs) are essentially produced by the genetic reprogramming of adult cells. Moreover, iPSC technology prevents the genetic manipulation of embryos. Hence, with the ensured element of safety, they rarely cause ethical concerns when utilized in tissue engineering. Several cumulative outcomes have demonstrated the functional superiority and potency of iPSCs in advanced regenerative medicine. Recently, an emerging trend in 3D bioprinting technology has been a more comprehensive approach to iPSC-based tissue engineering. The principal aim of this review is to provide an understanding of the applications of 3D bioprinting in iPSC-based tissue engineering. This review discusses the generation of iPSCs based on their distinct purpose, divided into two categories: (1) undifferentiated iPSCs applied with 3D bioprinting; (2) differentiated iPSCs applied with 3D bioprinting. Their significant potential is analyzed. Lastly, various applications for engineering tissues and organs have been introduced and discussed in detail.

Published

2022

15. Theoretical and Experimental Research on Multi-Layer Vessel-like Structure Printing Based on 3D Bio-Printing Technology

Author

Huanbao Liu, Xianhai Yang, Xiang Cheng, Guangxi Zhao, Guangming Zheng, Xuewei Li, and Ruichun Dong

Subjects

vessel-like, 3D bioprinting, synchronous relationship, multi-material, Mechanical engineering and machinery, TJ1-1570

Abstract

Cardiovascular disease is the leading cause of death worldwide. Traditional autologous transplantation has become a severe issue due to insufficient donors. Artificial blood vessel is an effective method for the treatment of major vascular diseases, such as heart and peripheral blood vessel diseases. However, the traditional single-material printing technology has been unable to meet the users’ demand for product functional complexity, which is not only reflected in the field of industrial manufacturing, but also in the field of functional vessel-like structure regeneration. In order to achieve the printing and forming of multi-layer vessel-like structures, this paper carries out theoretical and experimental research on the printing and forming of a multi-layer vessel-like structure based on multi-material 3D bioprinting technology. Firstly, theoretical analysis has been explored to research the relationship among the different parameters in the process of vessel forming, and further confirm the synchronous relationship among the extrusion rate of material, the tangential speed of the rotating rod, and the movement speed of the platform. Secondly, sodium alginate and gelatin have been used as the experimental materials to manufacture the vessel-like structure, and the corrected parameter of the theoretical analysis is further verified. Finally, the cell-loaded materials have been printed and analyzed, and cell viability is more than 90%, which provides support for the research of multi-layer vessel-like structure printing.

Published

2021

16. Biofabrication in Congenital Cardiac Surgery: A Plea from the Operating Theatre, Promise from Science

Author

Laszlo Kiraly and Sanjairaj Vijayavenkataraman

Subjects

bioactive molecules, biofabrication, biomaterials, 3D bioprinting, congenital heart disease, congenital cardiac surgery, Mechanical engineering and machinery, TJ1-1570

Abstract

Despite significant advances in numerous fields of biofabrication, clinical application of biomaterials combined with bioactive molecules and/or cells largely remains a promise in an individualized patient settings. Three-dimensional (3D) printing and bioprinting evolved as promising techniques used for tissue-engineering, so that several kinds of tissue can now be printed in layers or as defined structures for replacement and/or reconstruction in regenerative medicine and surgery. Besides technological, practical, ethical and legal challenges to solve, there is also a gap between the research labs and the patients’ bedside. Congenital and pediatric cardiac surgery mostly deal with reconstructive patient-scenarios when defects are closed, various segments of the heart are connected, valves are implanted. Currently available biomaterials lack the potential of growth and conduits, valves derange over time surrendering patients to reoperations. Availability of viable, growing biomaterials could cancel reoperations that could entail significant public health benefit and improved quality-of-life. Congenital cardiac surgery is uniquely suited for closing the gap in translational research, rapid application of new techniques, and collaboration between interdisciplinary teams. This article provides a succinct review of the state-of-the art clinical practice and biofabrication strategies used in congenital and pediatric cardiac surgery, and highlights the need and avenues for translational research and collaboration.

Published

2021

17. Engineered Microgels—Their Manufacturing and Biomedical Applications

Author

Hamzah Alzanbaki, Manola Moretti, and Charlotte A. E. Hauser

Subjects

microgels, self-assembling peptides, biofabrication, 3D bioprinting, cell-laden constructs, Mechanical engineering and machinery, TJ1-1570

Abstract

Microgels are hydrogel particles with diameters in the micrometer scale that can be fabricated in different shapes and sizes. Microgels are increasingly used for biomedical applications and for biofabrication due to their interesting features, such as injectability, modularity, porosity and tunability in respect to size, shape and mechanical properties. Fabrication methods of microgels are divided into two categories, following a top-down or bottom-up approach. Each approach has its own advantages and disadvantages and requires certain sets of materials and equipments. In this review, we discuss fabrication methods of both top-down and bottom-up approaches and point to their advantages as well as their limitations, with more focus on the bottom-up approaches. In addition, the use of microgels for a variety of biomedical applications will be discussed, including microgels for the delivery of therapeutic agents and microgels as cell carriers for the fabrication of 3D bioprinted cell-laden constructs. Microgels made from well-defined synthetic materials with a focus on rationally designed ultrashort peptides are also discussed, because they have been demonstrated to serve as an attractive alternative to much less defined naturally derived materials. Here, we will emphasize the potential and properties of ultrashort self-assembling peptides related to microgels.

Published

2021

18. Simulation Analysis of the Influence of Nozzle Structure Parameters on Material Controllability

Author

Huanbao Liu, Guangming Zheng, Xiang Cheng, Xianhai Yang, and Guangxi Zhao

Subjects

3D bioprinting, nozzle, orthogonal experiment, numerical simulation, Mechanical engineering and machinery, TJ1-1570

Abstract

With the evolution of three-dimensional (3D) printing, many restrictive factors of 3D printing have been explored to upgrade the feasibility of 3D printing technology, such as nozzle structure, print resolution, cell viability, etc., which has attracted extensive attention due to its possibility of curing disease in tissue engineering and organ regeneration. In this paper, we have developed a novel nozzle for 3D printing, numerical simulation, and finite element analysis have been used to optimize the nozzle structure and further clarified the influence of nozzle structure parameters on material controllability. Using novel nozzle structure, we firstly adopt ANSYS-FLUENT to analyze material controllability under the different inner cavity diameter, outer cavity diameter and lead length. Secondly, the orthogonal experiments with the novel nozzle are carried out in order to verify the influence law of inner cavity diameter, outer cavity diameter, and lead length under all sorts of conditions. The experiment results show that the material P diameter can be controlled by changing the parameters. The influence degree of parameters on material P diameter is shown that lead length > inner cavity diameter > outer cavity diameter. Finally, the optimized parameters of nozzle structure have been adjusted to estimate the material P diameter in 3D printing.

Published

2020

19. Novel Strategies in Artificial Organ Development: What Is the Future of Medicine?

Author

Marta Klak, Tomasz Bryniarski, Patrycja Kowalska, Magdalena Gomolka, Grzegorz Tymicki, Katarzyna Kosowska, Piotr Cywoniuk, Tomasz Dobrzanski, Pawel Turowski, and Michal Wszola

Subjects

3D bioprinting, organ-on-a-chip, bionic tissue, bioink, cell culture, Mechanical engineering and machinery, TJ1-1570

Abstract

The technology of tissue engineering is a rapidly evolving interdisciplinary field of science that elevates cell-based research from 2D cultures through organoids to whole bionic organs. 3D bioprinting and organ-on-a-chip approaches through generation of three-dimensional cultures at different scales, applied separately or combined, are widely used in basic studies, drug screening and regenerative medicine. They enable analyses of tissue-like conditions that yield much more reliable results than monolayer cell cultures. Annually, millions of animals worldwide are used for preclinical research. Therefore, the rapid assessment of drug efficacy and toxicity in the early stages of preclinical testing can significantly reduce the number of animals, bringing great ethical and financial benefits. In this review, we describe 3D bioprinting techniques and first examples of printed bionic organs. We also present the possibilities of microfluidic systems, based on the latest reports. We demonstrate the pros and cons of both technologies and indicate their use in the future of medicine.

Published

2020

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

Author

Tiffany Cameron, Emad Naseri, Ben MacCallum, and Ali Ahmadi

Subjects

multi-material printing, 3D bioprinting, continuous multi-material printing, single-nozzle printing, Mechanical engineering and machinery, TJ1-1570

Abstract

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.

Published

2020

21. An Engineered Infected Epidermis Model for In Vitro Study of the Skin’s Pro-Inflammatory Response

Author

Maryam Jahanshahi, David Hamdi, Brent Godau, Ehsan Samiei, Carla Liria Sanchez-Lafuente, Katie J. Neale, Zhina Hadisi, Seyed Mohammad Hossein Dabiri, Erik Pagan, Brian R. Christie, and Mohsen Akbari

Subjects

epidermis, 3d bioprinting, wound modeling, infection, pro-inflammatory response, Mechanical engineering and machinery, TJ1-1570

Abstract

Wound infection is a major clinical challenge that can significantly delay the healing process, can create pain, and requires prolonged hospital stays. Pre-clinical research to evaluate new drugs normally involves animals. However, ethical concerns, cost, and the challenges associated with interspecies variation remain major obstacles. Tissue engineering enables the development of in vitro human skin models for drug testing. However, existing engineered skin models are representative of healthy human skin and its normal functions. This paper presents a functional infected epidermis model that consists of a multilayer epidermis structure formed at an air-liquid interface on a hydrogel matrix and a three-dimensionally (3D) printed vascular-like network. The function of the engineered epidermis is evaluated by the expression of the terminal differentiation marker, filaggrin, and the barrier function of the epidermis model using the electrical resistance and permeability across the epidermal layer. The results showed that the multilayer structure enhances the electrical resistance by 40% and decreased the drug permeation by 16.9% in the epidermis model compared to the monolayer cell culture on gelatin. We infect the model with Escherichia coli to study the inflammatory response of keratinocytes by measuring the expression level of pro-inflammatory cytokines (interleukin 1 beta and tumor necrosis factor alpha). After 24 h of exposure to Escherichia coli, the level of IL-1β and TNF-α in control samples were 125 ± 78 and 920 ± 187 pg/mL respectively, while in infected samples, they were 1429 ± 101 and 2155.5 ± 279 pg/mL respectively. However, in ciprofloxacin-treated samples the levels of IL-1β and TNF-α without significant difference with respect to the control reached to 246 ± 87 and 1141.5 ± 97 pg/mL respectively. The robust fabrication procedure and functionality of this model suggest that the model has great potential for modeling wound infections and drug testing.

Published

2020

22. Chitosans for Tissue Repair and Organ Three-Dimensional (3D) Bioprinting

Author

Shenglong Li, Xiaohong Tian, Jun Fan, Hao Tong, Qiang Ao, and Xiaohong Wang

Subjects

3d bioprinting, chitosan, chitin, tissue repair, rapid prototyping (rp), implantable bioartificial organs, Mechanical engineering and machinery, TJ1-1570

Abstract

Chitosan is a unique natural resourced polysaccharide derived from chitin with special biocompatibility, biodegradability, and antimicrobial activity. During the past three decades, chitosan has gradually become an excellent candidate for various biomedical applications with prominent characteristics. Chitosan molecules can be chemically modified, adapting to all kinds of cells in the body, and endowed with specific biochemical and physiological functions. In this review, the intrinsic/extrinsic properties of chitosan molecules in skin, bone, cartilage, liver tissue repair, and organ three-dimensional (3D) bioprinting have been outlined. Several successful models for large scale-up vascularized and innervated organ 3D bioprinting have been demonstrated. Challenges and perspectives in future complex organ 3D bioprinting areas have been analyzed.

Published

2019

23. Three-Dimensional Bioprinting of Functional Skeletal Muscle Tissue Using Gelatin Methacryloyl-Alginate Bioinks

Author

Rasoul Seyedmahmoud, Betül Çelebi-Saltik, Natan Barros, Rohollah Nasiri, Ethan Banton, Amir Shamloo, Nureddin Ashammakhi, Mehmet Remzi Dokmeci, and Samad Ahadian

Subjects

muscle tissue engineering, gelma-alginate bioink, 3d bioprinting, oxygen-generating bioink, Mechanical engineering and machinery, TJ1-1570

Abstract

Skeletal muscle tissue engineering aims to fabricate tissue constructs to replace or restore diseased or injured skeletal muscle tissues in the body. Several biomaterials and microscale technologies have been used in muscle tissue engineering. However, it is still challenging to mimic the function and structure of the native muscle tissues. Three-dimensional (3D) bioprinting is a powerful tool to mimic the hierarchical structure of native tissues. Here, 3D bioprinting was used to fabricate tissue constructs using gelatin methacryloyl (GelMA)-alginate bioinks. Mechanical and rheological properties of GelMA-alginate hydrogels were characterized. C2C12 myoblasts at the density 8 × 106 cells/mL were used as the cell model. The effects of alginate concentration (0, 6, and 8% (w/v)) and crosslinking mechanism (UV crosslinking or ionic crosslinking with UV crosslinking) on printability, cell viability, proliferation, and differentiation of bioinks were studied. The results showed that 10% (w/v) GelMA-8% (w/v) alginate crosslinked using UV light and 0.1 M CaCl2 provided the optimum niche to induce muscle tissue formation compared to other hydrogel compositions. Furthermore, metabolic activity of cells in GelMA bioinks was improved by addition of oxygen-generating particles to the bioinks. It is hoped that such bioprinted muscle tissues may find wide applications in drug screening and tissue regeneration.

Published

2019

24. In Vivo Tracking of Tissue Engineered Constructs

Author

Carmen J. Gil, Martin L. Tomov, Andrea S. Theus, Alexander Cetnar, Morteza Mahmoudi, and Vahid Serpooshan

Subjects

in vivo imaging, tissue engineering, 3D bioprinting, additive manufacturing, scaffold tracking, magnetic resonant imaging (MRI), computed tomography (CT), ultrasound, fluorescence spectroscopy, bioluminescence, optical coherence tomography, photoacoustic imaging, magnetic-particle imaging, multimodal imaging, Mechanical engineering and machinery, TJ1-1570

Abstract

To date, the fields of biomaterials science and tissue engineering have shown great promise in creating bioartificial tissues and organs for use in a variety of regenerative medicine applications. With the emergence of new technologies such as additive biomanufacturing and 3D bioprinting, increasingly complex tissue constructs are being fabricated to fulfill the desired patient-specific requirements. Fundamental to the further advancement of this field is the design and development of imaging modalities that can enable visualization of the bioengineered constructs following implantation, at adequate spatial and temporal resolution and high penetration depths. These in vivo tracking techniques should introduce minimum toxicity, disruption, and destruction to treated tissues, while generating clinically relevant signal-to-noise ratios. This article reviews the imaging techniques that are currently being adopted in both research and clinical studies to track tissue engineering scaffolds in vivo, with special attention to 3D bioprinted tissue constructs.

Published

2019

25. Novel Compound-Forming Technology Using Bioprinting and Electrospinning for Patterning a 3D Scaffold Construct with Multiscale Channels.

Author

Yuanshao Sun, Yuanyuan Liu, Shuai Li, Change Liu, and Qingxi Hu

Subjects

BIOPRINTING, ELECTROSPINNING, MICROFLUIDIC devices

Abstract

One of the biggest challenges for tissue engineering is to efficiently provide oxygen and nutrients to cells on a three-dimensional (3D) engineered scaffold structure. Thus, achieving sufficient vascularization of the structure is a critical problem in tissue engineering. This facilitates the need to develop novel methods to enhance vascularization. Use of patterned hydrogel structures with multiscale channels can be used to achieve the required vascularization. Patterned structures need to be biocompatible and biodegradable. In this study, gelatin was used as the main part of a hydrogel to prepare a biological structure with 3D multiscale channels using bioprinting combined with selection of suitable materials and electrostatic spinning. Human umbilical vein endothelial cells (HUVECs) were then used to confirm efficacy of the structure, inferred from cell viability on different engineered construct designs. HUVECs were seeded on the surface of channels and cultured in vitro. HUVECs showed high viability and diffusion within the construct. This method can be used as a practical platform for the fabrication of engineered construct for vascularization. [ABSTRACT FROM AUTHOR]

Published

2016

26. Recapitulating the Cancer Microenvironment Using Bioprinting Technology for Precision Medicine

Author

Jisoo Kim, Dong-Woo Cho, and Jinah Jang

Subjects

3D bioprinting, Drug discovery, Computer science, Mechanical Engineering, biofabrication, Cancer Model, Cancer, Cancer Microenvironment, Computational biology, Review, Precision medicine, medicine.disease, cancer model, law.invention, Control and Systems Engineering, law, tissue engineering, Cancer cell, TJ1-1570, medicine, Mechanical engineering and machinery, Electrical and Electronic Engineering, Biofabrication, cancer biology, cancer microenvironment

Abstract

The complex and heterogenous nature of cancer contributes to the development of cancer cell drug resistance. The construction of the cancer microenvironment, including the cell–cell interactions and extracellular matrix (ECM), plays a significant role in the development of drug resistance. Traditional animal models used in drug discovery studies have been associated with feasibility issues that limit the recapitulation of human functions; thus, in vitro models have been developed to reconstruct the human cancer system. However, conventional two-dimensional and three-dimensional (3D) in vitro cancer models are limited in their ability to emulate complex cancer microenvironments. Advances in technologies, including bioprinting and cancer microenvironment reconstruction, have demonstrated the potential to overcome some of the limitations of conventional models. This study reviews some representative bioprinted in vitro models used in cancer research, particularly fabrication strategies for modeling and consideration of essential factors needed for the reconstruction of the cancer microenvironment. In addition, we highlight recent studies that applied such models, including application in precision medicine using advanced bioprinting technologies to fabricate biomimetic cancer models. Furthermore, we discuss current challenges in 3D bioprinting and suggest possible strategies to construct in vitro models that better mimic the pathophysiology of the cancer microenvironment for application in clinical settings.

Published

2021

27. 3D-Bioprinting Strategies Based on In Situ Bone-Healing Mechanism for Vascularized Bone Tissue Engineering

Author

Ye Lin Park, Jae Min Cha, and Kiwon Park

Subjects

Computer science, bone healing mechanism, lcsh:Mechanical engineering and machinery, Review, 02 engineering and technology, Bone healing, Bone tissue engineering, law.invention, 03 medical and health sciences, Tissue engineering, vascularization, law, lcsh:TJ1-1570, Electrical and Electronic Engineering, Bone regeneration, bone tissue engineering, mesenchymal stem cell, 030304 developmental biology, 0303 health sciences, 3D bioprinting, Mechanism (biology), Mechanical Engineering, Mesenchymal stem cell, biomaterial, Biomaterial, 021001 nanoscience & nanotechnology, Control and Systems Engineering, 0210 nano-technology, bioprinting, Biomedical engineering

Abstract

Over the past decades, a number of bone tissue engineering (BTE) approaches have been developed to address substantial challenges in the management of critical size bone defects. Although the majority of BTE strategies developed in the laboratory have been limited due to lack of clinical relevance in translation, primary prerequisites for the construction of vascularized functional bone grafts have gained confidence owing to the accumulated knowledge of the osteogenic, osteoinductive, and osteoconductive properties of mesenchymal stem cells and bone-relevant biomaterials that reflect bone-healing mechanisms. In this review, we summarize the current knowledge of bone-healing mechanisms focusing on the details that should be embodied in the development of vascularized BTE, and discuss promising strategies based on 3D-bioprinting technologies that efficiently coalesce the abovementioned main features in bone-healing systems, which comprehensively interact during the bone regeneration processes.

Published

2021

28. Bionic Organs: Shear Forces Reduce Pancreatic Islet and Mammalian Cell Viability during the Process of 3D Bioprinting

Author

Patrycja Kowalska, Marta Klak, Tomasz Dobrzanski, Andrzej Berman, Piotr Cywoniuk, Michał Wszoła, Bartosz Górecki, Agnieszka Dobrzyn, Tomasz Bryniarski, Wojciech Sadowski, Grzegorz Tymicki, Magdalena Gomółka, and Katarzyna Kosowska

Subjects

endocrine system, lcsh:Mechanical engineering and machinery, 02 engineering and technology, bioprinting 3D, shear forces, Article, law.invention, 3d printer, Andrology, 03 medical and health sciences, law, Mammalian cell, medicine, lcsh:TJ1-1570, Electrical and Electronic Engineering, 030304 developmental biology, Bioactive scaffold, islets, 0303 health sciences, geography, 3D bioprinting, geography.geographical_feature_category, Chemistry, Cell carrier, Mechanical Engineering, Pancreatic islets, viability, 021001 nanoscience & nanotechnology, Islet, Staining, medicine.anatomical_structure, Control and Systems Engineering, cells, 0210 nano-technology

Abstract

Background: 3D bioprinting is the future of constructing functional organs. Creating a bioactive scaffold with pancreatic islets presents many challenges. The aim of this paper is to assess how the 3D bioprinting process affects islet viability. Methods: The BioX 3D printer (Cellink), 600 μm inner diameter nozzles, and 3% (w/v) alginate cell carrier solution were used with rat, porcine, and human pancreatic islets. Islets were divided into a control group (culture medium) and 6 experimental groups (each subjected to specific pressure between 15 and 100 kPa). FDA/PI staining was performed to assess the viability of islets. Analogous studies were carried out on α-cells, β-cells, fibroblasts, and endothelial cells. Results: Viability of human pancreatic islets was as follows: 92% for alginate-based control and 94%, 90%, 74%, 48%, 61%, and 59% for 15, 25, 30, 50, 75, and 100 kPa, respectively. Statistically significant differences were observed between control and 50, 75, and 100 kPa, respectively. Similar observations were made for porcine and rat islets. Conclusions: Optimal pressure during 3D bioprinting with pancreatic islets by the extrusion method should be lower than 30 kPa while using 3% (w/v) alginate as a carrier.

Published

2021

29. Engineered Microgels—Their Manufacturing and Biomedical Applications

Author

Charlotte A. E. Hauser, Hamzah Alzanbaki, and Manola Moretti

Subjects

Materials science, Fabrication, Micrometer scale, lcsh:Mechanical engineering and machinery, Nanotechnology, 02 engineering and technology, Review, 010402 general chemistry, 01 natural sciences, cell-laden constructs, Synthetic materials, law.invention, microgels, law, Fabrication methods, self-assembling peptides, lcsh:TJ1-1570, Electrical and Electronic Engineering, Modularity (networks), 3D bioprinting, Mechanical Engineering, biofabrication, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Control and Systems Engineering, 0210 nano-technology, Biofabrication

Abstract

Microgels are hydrogel particles with diameters in the micrometer scale that can be fabricated in different shapes and sizes. Microgels are increasingly used for biomedical applications and for biofabrication due to their interesting features, such as injectability, modularity, porosity and tunability in respect to size, shape and mechanical properties. Fabrication methods of microgels are divided into two categories, following a top-down or bottom-up approach. Each approach has its own advantages and disadvantages and requires certain sets of materials and equipments. In this review, we discuss fabrication methods of both top-down and bottom-up approaches and point to their advantages as well as their limitations, with more focus on the bottom-up approaches. In addition, the use of microgels for a variety of biomedical applications will be discussed, including microgels for the delivery of therapeutic agents and microgels as cell carriers for the fabrication of 3D bioprinted cell-laden constructs. Microgels made from well-defined synthetic materials with a focus on rationally designed ultrashort peptides are also discussed, because they have been demonstrated to serve as an attractive alternative to much less defined naturally derived materials. Here, we will emphasize the potential and properties of ultrashort self-assembling peptides related to microgels.

Published

2021

30. Simulation Analysis of the Influence of Nozzle Structure Parameters on Material Controllability

Author

Zheng Guangming, Liu Huanbao, Zhao Guangxi, Yang Xianhai, and Xiang Cheng

Subjects

3D bioprinting, Materials science, nozzle, Computer simulation, business.industry, lcsh:Mechanical engineering and machinery, Mechanical Engineering, 0206 medical engineering, Nozzle, 3D printing, 02 engineering and technology, Mechanics, 021001 nanoscience & nanotechnology, 020601 biomedical engineering, Article, Finite element method, Controllability, Control and Systems Engineering, numerical simulation, lcsh:TJ1-1570, Electrical and Electronic Engineering, orthogonal experiment, 0210 nano-technology, business, Organ regeneration

Abstract

With the evolution of three-dimensional (3D) printing, many restrictive factors of 3D printing have been explored to upgrade the feasibility of 3D printing technology, such as nozzle structure, print resolution, cell viability, etc., which has attracted extensive attention due to its possibility of curing disease in tissue engineering and organ regeneration. In this paper, we have developed a novel nozzle for 3D printing, numerical simulation, and finite element analysis have been used to optimize the nozzle structure and further clarified the influence of nozzle structure parameters on material controllability. Using novel nozzle structure, we firstly adopt ANSYS-FLUENT to analyze material controllability under the different inner cavity diameter, outer cavity diameter and lead length. Secondly, the orthogonal experiments with the novel nozzle are carried out in order to verify the influence law of inner cavity diameter, outer cavity diameter, and lead length under all sorts of conditions. The experiment results show that the material P diameter can be controlled by changing the parameters. The influence degree of parameters on material P diameter is shown that lead length &gt, inner cavity diameter &gt, outer cavity diameter. Finally, the optimized parameters of nozzle structure have been adjusted to estimate the material P diameter in 3D printing.

Published

2020

31. Fabrication of Microspheres from High-Viscosity Bioink Using a Novel Microfluidic-Based 3D Bioprinting Nozzle

Author

Guiling Li, Donghai Li, Jianyong Li, Jia Man, Jianfeng Li, Song Zhang, and Shanguo Zhang

Subjects

Fabrication, Calcium alginate, Materials science, lcsh:Mechanical engineering and machinery, Nozzle, Microfluidics, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Article, law.invention, chemistry.chemical_compound, phase-inversion method, law, lcsh:TJ1-1570, Electrical and Electronic Engineering, microfluidic system, 3D bioprinting, droplet-based bioprinting, Mechanical Engineering, 021001 nanoscience & nanotechnology, 0104 chemical sciences, microcomponent, chemistry, Control and Systems Engineering, Drug delivery, Self-healing hydrogels, Functional polymers, 0210 nano-technology

Abstract

Three-dimensional (3D) bioprinting is a novel technology utilizing biocompatible materials, cells, drugs, etc. as basic microcomponents to form 3D artificial structures and is believed as a promising method for regenerative medicine. Droplet-based bioprinting can precisely generate microspheres and manipulate them into organized structures with high fidelity. Biocompatible hydrogels are usually used as bioinks in 3D bioprinting, however, the viscosity of the bioink could be increased due to the additives such as cells, drugs, nutrient factors and other functional polymers in some particular applications, making it difficult to form monodispersed microspheres from high-viscosity bioink at the orifice of the nozzle. In this work, we reported a novel microfluidic-based printing nozzle to prepare monodispersed microspheres from high-viscosity bioink using the phase-inversion method. Different flowing conditions can be achieved by changing the flow rates of the fluids to form monodispersed solid and hollow microspheres using the same nozzle. The diameter of the microspheres can be tuned by changing the flow rate ratio and the size distribution of the microspheres is narrow. The prepared calcium alginate microspheres could also act as micro-carriers in drug delivery.

Published

2020

32. Novel Strategies in Artificial Organ Development: What Is the Future of Medicine?

Author

Michał Wszoła, Katarzyna Kosowska, Tomasz Dobrzanski, Pawel Turowski, Patrycja Kowalska, Marta Klak, Grzegorz Tymicki, Piotr Cywoniuk, Tomasz Bryniarski, and Magdalena Gomółka

Subjects

Computer science, lcsh:Mechanical engineering and machinery, bionic tissue, 02 engineering and technology, Review, Regenerative medicine, Organ-on-a-chip, law.invention, 03 medical and health sciences, Preclinical research, law, lcsh:TJ1-1570, Electrical and Electronic Engineering, 030304 developmental biology, 0303 health sciences, 3D bioprinting, organ-on-a-chip, cell culture, Mechanical Engineering, bioink, 021001 nanoscience & nanotechnology, Rapid assessment, Artificial organ, Risk analysis (engineering), Control and Systems Engineering, Preclinical testing, 0210 nano-technology

Abstract

The technology of tissue engineering is a rapidly evolving interdisciplinary field of science that elevates cell-based research from 2D cultures through organoids to whole bionic organs. 3D bioprinting and organ-on-a-chip approaches through generation of three-dimensional cultures at different scales, applied separately or combined, are widely used in basic studies, drug screening and regenerative medicine. They enable analyses of tissue-like conditions that yield much more reliable results than monolayer cell cultures. Annually, millions of animals worldwide are used for preclinical research. Therefore, the rapid assessment of drug efficacy and toxicity in the early stages of preclinical testing can significantly reduce the number of animals, bringing great ethical and financial benefits. In this review, we describe 3D bioprinting techniques and first examples of printed bionic organs. We also present the possibilities of microfluidic systems, based on the latest reports. We demonstrate the pros and cons of both technologies and indicate their use in the future of medicine.

Published

2020

33. An Engineered Infected Epidermis Model for In Vitro Study of the Skin’s Pro-Inflammatory Response

Author

Ehsan Samiei, Erik Pagan, Carla Liria Sanchez-Lafuente, Maryam Jahanshahi, David Hamdi, Brent Godau, Seyed Mohammad Hossein Dabiri, Brian R. Christie, Katie J Neale, Mohsen Akbari, and Zhina Hadisi

Subjects

lcsh:Mechanical engineering and machinery, wound modeling, Human skin, 02 engineering and technology, Article, 03 medical and health sciences, Tissue engineering, epidermis, lcsh:TJ1-1570, Electrical and Electronic Engineering, Barrier function, 030304 developmental biology, 0303 health sciences, 3D bioprinting, Epidermis (botany), Chemistry, Mechanical Engineering, 021001 nanoscience & nanotechnology, Molecular biology, In vitro, infection, 3. Good health, Control and Systems Engineering, Cell culture, Tumor necrosis factor alpha, 0210 nano-technology, Filaggrin, pro-inflammatory response

Abstract

Wound infection is a major clinical challenge that can significantly delay the healing process, can create pain, and requires prolonged hospital stays. Pre-clinical research to evaluate new drugs normally involves animals. However, ethical concerns, cost, and the challenges associated with interspecies variation remain major obstacles. Tissue engineering enables the development of in vitro human skin models for drug testing. However, existing engineered skin models are representative of healthy human skin and its normal functions. This paper presents a functional infected epidermis model that consists of a multilayer epidermis structure formed at an air-liquid interface on a hydrogel matrix and a three-dimensionally (3D) printed vascular-like network. The function of the engineered epidermis is evaluated by the expression of the terminal differentiation marker, filaggrin, and the barrier function of the epidermis model using the electrical resistance and permeability across the epidermal layer. The results showed that the multilayer structure enhances the electrical resistance by 40% and decreased the drug permeation by 16.9% in the epidermis model compared to the monolayer cell culture on gelatin. We infect the model with Escherichia coli to study the inflammatory response of keratinocytes by measuring the expression level of pro-inflammatory cytokines (interleukin 1 beta and tumor necrosis factor alpha). After 24 h of exposure to Escherichia coli, the level of IL-1&beta, and TNF-&alpha, in control samples were 125 &plusmn, 78 and 920 &plusmn, 187 pg/mL respectively, while in infected samples, they were 1429 &plusmn, 101 and 2155.5 &plusmn, 279 pg/mL respectively. However, in ciprofloxacin-treated samples the levels of IL-1&beta, without significant difference with respect to the control reached to 246 &plusmn, 87 and 1141.5 &plusmn, 97 pg/mL respectively. The robust fabrication procedure and functionality of this model suggest that the model has great potential for modeling wound infections and drug testing.

Published

2020

34. Modelling Human Physiology on-Chip: Historical Perspectives and Future Directions

Author

Li Cai Haney, Riccardo Barrile, and Sirjana Pun

Subjects

iPSc, precision medicine, technological trajectories, microfluidic, Review, law.invention, Human disease, law, Organ-on-Chip, TJ1-1570, Mechanical engineering and machinery, Electrical and Electronic Engineering, Lung-on-Chip, 3D bioprinting, microphysiological systems, business.industry, Mechanical Engineering, personalized medicine, Human physiology, Precision medicine, Data science, Cell Microenvironment, Brain-on-Chip, Control and Systems Engineering, Personalized medicine, Construct (philosophy), business, bioprinting

Abstract

For centuries, animal experiments have contributed much to our understanding of mechanisms of human disease, but their value in predicting the effectiveness of drug treatments in the clinic has remained controversial. Animal models, including genetically modified ones and experimentally induced pathologies, often do not accurately reflect disease in humans, and therefore do not predict with sufficient certainty what will happen in humans. Organ-on-chip (OOC) technology and bioengineered tissues have emerged as promising alternatives to traditional animal testing for a wide range of applications in biological defence, drug discovery and development, and precision medicine, offering a potential alternative. Recent technological breakthroughs in stem cell and organoid biology, OOC technology, and 3D bioprinting have all contributed to a tremendous progress in our ability to design, assemble and manufacture living organ biomimetic systems that more accurately reflect the structural and functional characteristics of human tissue in vitro, and enable improved predictions of human responses to drugs and environmental stimuli. Here, we provide a historical perspective on the evolution of the field of bioengineering, focusing on the most salient milestones that enabled control of internal and external cell microenvironment. We introduce the concepts of OOCs and Microphysiological systems (MPSs), review various chip designs and microfabrication methods used to construct OOCs, focusing on blood-brain barrier as an example, and discuss existing challenges and limitations. Finally, we provide an overview on emerging strategies for 3D bioprinting of MPSs and comment on the potential role of these devices in precision medicine.

Published

2021

35. Machine Assisted Experimentation of Extrusion-Based Bioprinting Systems

Author

Rory Stevens, Nastassja Lewinski, Bridget T. McInnes, and Shuyu Tian

Subjects

Computer science, 0206 medical engineering, 3D printing, 02 engineering and technology, Article, law.invention, gelatin, law, TJ1-1570, alginate, Mechanical engineering and machinery, Electrical and Electronic Engineering, 3D bioprinting, Training set, business.industry, Mechanical Engineering, Regression analysis, artificial intelligence, 021001 nanoscience & nanotechnology, 020601 biomedical engineering, Regression, Random forest, machine learning, classification, Control and Systems Engineering, extrusion-based bioprinting, regression, Extrusion, 0210 nano-technology, business, Biological system, random forest

Abstract

Optimization of extrusion-based bioprinting (EBB) parameters have been systematically conducted through experimentation. However, the process is time- and resource-intensive and not easily translatable to other laboratories. This study approaches EBB parameter optimization through machine learning (ML) models trained using data collected from the published literature. We investigated regression-based and classification-based ML models and their abilities to predict printing outcomes of cell viability and filament diameter for cell-containing alginate and gelatin composite bioinks. In addition, we interrogated if regression-based models can predict suitable extrusion pressure given the desired cell viability when keeping other experimental parameters constant. We also compared models trained across data from general literature to models trained across data from one literature source that utilized alginate and gelatin bioinks. The results indicate that models trained on large amounts of data can impart physical trends on cell viability, filament diameter, and extrusion pressure seen in past literature. Regression models trained on the larger dataset also predict cell viability closer to experimental values for material concentration combinations not seen in training data of the single-paper-based regression models. While the best performing classification models for cell viability can achieve an average prediction accuracy of 70%, the cell viability predictions remained constant despite altering input parameter combinations. Our trained models on bioprinting literature data show the potential usage of applying ML models to bioprinting experimental design.

Published

2021

36. 3D Bioprinting of an In Vitro Model of a Biomimetic Urinary Bladder with a Contract-Release System.

Author

Chae, Suhun, Kim, Jaewook, Yi, Hee-Gyeong, and Cho, Dong-Woo

Subjects

BIOPRINTING, MYOBLASTS, BLADDER diseases, BIOMIMETIC materials, SMOOTH muscle, EXTRACELLULAR matrix, SMOOTHNESS of functions, BLADDER

Abstract

The development of curative therapy for bladder dysfunction is usually hampered owing to the lack of reliable ex vivo human models that can mimic the complexity of the human bladder. To overcome this issue, 3D in vitro model systems offering unique opportunities to engineer realistic human tissues/organs have been developed. However, existing in vitro models still cannot entirely reflect the key structural and physiological characteristics of the native human bladder. In this study, we propose an in vitro model of the urinary bladder that can create 3D biomimetic tissue structures and dynamic microenvironments to replicate the smooth muscle functions of an actual human urinary bladder. In other words, the proposed biomimetic model system, developed using a 3D bioprinting approach, can recreate the physiological motion of the urinary bladder by incorporating decellularized extracellular matrix from the bladder tissue and introducing cyclic mechanical stimuli. The results showed that the developed bladder tissue models exhibited high cell viability and proliferation rate and promoted myogenic differentiation potential given dynamic mechanical cues. We envision the developed in vitro bladder mimicry model can serve as a research platform for fundamental studies on human disease modeling and pharmaceutical testing. [ABSTRACT FROM AUTHOR]

Published

2022

37. Applications of 3D Bioprinting Technology in Induced Pluripotent Stem Cells-Based Tissue Engineering.

Author

Shukla, Arvind Kumar, Gao, Ge, and Kim, Byoung Soo

Subjects

BIOPRINTING, TISSUE engineering, INDUCED pluripotent stem cells, PLURIPOTENT stem cells, REGENERATIVE medicine

Abstract

Induced pluripotent stem cells (iPSCs) are essentially produced by the genetic reprogramming of adult cells. Moreover, iPSC technology prevents the genetic manipulation of embryos. Hence, with the ensured element of safety, they rarely cause ethical concerns when utilized in tissue engineering. Several cumulative outcomes have demonstrated the functional superiority and potency of iPSCs in advanced regenerative medicine. Recently, an emerging trend in 3D bioprinting technology has been a more comprehensive approach to iPSC-based tissue engineering. The principal aim of this review is to provide an understanding of the applications of 3D bioprinting in iPSC-based tissue engineering. This review discusses the generation of iPSCs based on their distinct purpose, divided into two categories: (1) undifferentiated iPSCs applied with 3D bioprinting; (2) differentiated iPSCs applied with 3D bioprinting. Their significant potential is analyzed. Lastly, various applications for engineering tissues and organs have been introduced and discussed in detail. [ABSTRACT FROM AUTHOR]

Published

2022

38. Theoretical and Experimental Research on Multi-Layer Vessel-like Structure Printing Based on 3D Bio-Printing Technology.

Author

Liu, Huanbao, Yang, Xianhai, Cheng, Xiang, Zhao, Guangxi, Zheng, Guangming, Li, Xuewei, and Dong, Ruichun

Subjects

BIOPRINTING, THREE-dimensional printing, VASCULAR diseases, BLOOD substitutes, AUTOTRANSPLANTATION, MULTILAYERED thin films

Abstract

Cardiovascular disease is the leading cause of death worldwide. Traditional autologous transplantation has become a severe issue due to insufficient donors. Artificial blood vessel is an effective method for the treatment of major vascular diseases, such as heart and peripheral blood vessel diseases. However, the traditional single-material printing technology has been unable to meet the users' demand for product functional complexity, which is not only reflected in the field of industrial manufacturing, but also in the field of functional vessel-like structure regeneration. In order to achieve the printing and forming of multi-layer vessel-like structures, this paper carries out theoretical and experimental research on the printing and forming of a multi-layer vessel-like structure based on multi-material 3D bioprinting technology. Firstly, theoretical analysis has been explored to research the relationship among the different parameters in the process of vessel forming, and further confirm the synchronous relationship among the extrusion rate of material, the tangential speed of the rotating rod, and the movement speed of the platform. Secondly, sodium alginate and gelatin have been used as the experimental materials to manufacture the vessel-like structure, and the corrected parameter of the theoretical analysis is further verified. Finally, the cell-loaded materials have been printed and analyzed, and cell viability is more than 90%, which provides support for the research of multi-layer vessel-like structure printing. [ABSTRACT FROM AUTHOR]

Published

2021

39. Advanced Polymers for Three-Dimensional (3D) Organ Bioprinting

Author

Xiaohong Wang

Subjects

3d printed, Allograft transplantation, Biocompatibility, Computer science, Nanotechnology, 02 engineering and technology, Review, law.invention, 03 medical and health sciences, law, stem cells, Electrical and Electronic Engineering, Bioartificial Organ, polymers, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, Rapid manufacturing, 3D bioprinting, Mechanical Engineering, Polymer, three-dimensional (3D) printing, 021001 nanoscience & nanotechnology, chemistry, Control and Systems Engineering, 0210 nano-technology, organ manufacturing, biomaterials

Abstract

Three-dimensional (3D) organ bioprinting is an attractive scientific area with huge commercial profit, which could solve all the serious bottleneck problems for allograft transplantation, high-throughput drug screening, and pathological analysis. Integrating multiple heterogeneous adult cell types and/or stem cells along with other biomaterials (e.g., polymers, bioactive agents, or biomolecules) to make 3D constructs functional is one of the core issues for 3D bioprinting of bioartificial organs. Both natural and synthetic polymers play essential and ubiquitous roles for hierarchical vascular and neural network formation in 3D printed constructs based on their specific physical, chemical, biological, and physiological properties. In this article, several advanced polymers with excellent biocompatibility, biodegradability, 3D printability, and structural stability are reviewed. The challenges and perspectives of polymers for rapid manufacturing of complex organs, such as the liver, heart, kidney, lung, breast, and brain, are outlined.

Published

2019

40. Three-Dimensional Bioprinting of Functional Skeletal Muscle Tissue Using GelatinMethacryloyl-Alginate Bioinks

Author

Amir Shamloo, Mehmet R. Dokmeci, Samad Ahadian, Natan Roberto de Barros, Rohollah Nasiri, Ethan Banton, Rasoul Seyedmahmoud, Nureddin Ashammakhi, and Betül Çelebi-Saltik

Subjects

Muscle tissue, food.ingredient, lcsh:Mechanical engineering and machinery, 0206 medical engineering, macromolecular substances, 02 engineering and technology, Gelatin, Article, law.invention, food, GelMA-alginate bioink, oxygen-generating bioink, law, medicine, Myocyte, lcsh:TJ1-1570, Viability assay, Electrical and Electronic Engineering, 3D bioprinting, Chemistry, Mechanical Engineering, technology, industry, and agriculture, Skeletal muscle, 021001 nanoscience & nanotechnology, 020601 biomedical engineering, muscle tissue engineering, medicine.anatomical_structure, Control and Systems Engineering, Self-healing hydrogels, 0210 nano-technology, C2C12, Biomedical engineering

Abstract

Skeletal muscle tissue engineering aims to fabricate tissue constructs to replace or restore diseased or injured skeletal muscle tissues in the body. Several biomaterials and microscale technologies have been used in muscle tissue engineering. However, it is still challenging to mimic the function and structure of the native muscle tissues. Three-dimensional (3D) bioprinting is a powerful tool to mimic the hierarchical structure of native tissues. Here, 3D bioprinting was used to fabricate tissue constructs using gelatin methacryloyl (GelMA)-alginate bioinks. Mechanical and rheological properties of GelMA-alginate hydrogels were characterized. C2C12 myoblasts at the density 8 &times, 106 cells/mL were used as the cell model. The effects of alginate concentration (0, 6, and 8% (w/v)) and crosslinking mechanism (UV crosslinking or ionic crosslinking with UV crosslinking) on printability, cell viability, proliferation, and differentiation of bioinks were studied. The results showed that 10% (w/v) GelMA-8% (w/v) alginate crosslinked using UV light and 0.1 M CaCl2 provided the optimum niche to induce muscle tissue formation compared to other hydrogel compositions. Furthermore, metabolic activity of cells in GelMA bioinks was improved by addition of oxygen-generating particles to the bioinks. It is hoped that such bioprinted muscle tissues may find wide applications in drug screening and tissue regeneration.

Published

2019

41. 3D Bioprinting of Model Tissues That Mimic the Tumor Microenvironment

Author

Adrian Neagu, Oana Gavriliuc, Florina Bojin, Virgil Paunescu, Ada Cean, Maria Iulia Bejenariu, Roxana Popescu, Valentin Ordodi, Stelian Arjoca, Monica Neagu, Emilian Olteanu, and Andreea Robu

Subjects

extrusion bioprinting, Cell type, 02 engineering and technology, Peripheral blood mononuclear cell, Article, law.invention, 03 medical and health sciences, breast cancer, law, In vivo, TJ1-1570, medicine, tumor-associated fibroblasts, Mechanical engineering and machinery, Electrical and Electronic Engineering, 030304 developmental biology, 0303 health sciences, 3D bioprinting, Tumor microenvironment, Chemistry, Mechanical Engineering, Cancer, peripheral blood mononuclear cells, 021001 nanoscience & nanotechnology, medicine.disease, In vitro, Cell biology, Control and Systems Engineering, sense organs, 0210 nano-technology, Biofabrication

Abstract

The tumor microenvironment (TME) influences cancer progression. Therefore, engineered TME models are being developed for fundamental research and anti-cancer drug screening. This paper reports the biofabrication of 3D-printed avascular structures that recapitulate several features of the TME. The tumor is represented by a hydrogel droplet uniformly loaded with breast cancer cells (106 cells/mL), it is embedded in the same type of hydrogel containing primary cells—tumor-associated fibroblasts isolated from the peritumoral environment and peripheral blood mononuclear cells. Hoechst staining of cryosectioned tissue constructs demonstrated that cells remodeled the hydrogel and remained viable for weeks. Histological sections revealed heterotypic aggregates of malignant and peritumoral cells, moreover, the constituent cells proliferated in vitro. To investigate the interactions responsible for the experimentally observed cellular rearrangements, we built lattice models of the bioprinted constructs and simulated their evolution using Metropolis Monte Carlo methods. Although unable to replicate the complexity of the TME, the approach presented here enables the self-assembly and co-culture of several cell types of the TME. Further studies will evaluate whether the bioprinted constructs can evolve in vivo in animal models. If they become connected to the host vasculature, they may turn into a fully organized TME.

Published

2021

42. Machine Assisted Experimentation of Extrusion-Based Bioprinting Systems.

Author

Tian, Shuyu, Stevens, Rory, McInnes, Bridget T., and Lewinski, Nastassja A.

Subjects

BIOPRINTING, CELL survival, LITERARY sources, ARTIFICIAL intelligence, MACHINE learning, THREE-dimensional printing

Abstract

Optimization of extrusion-based bioprinting (EBB) parameters have been systematically conducted through experimentation. However, the process is time- and resource-intensive and not easily translatable to other laboratories. This study approaches EBB parameter optimization through machine learning (ML) models trained using data collected from the published literature. We investigated regression-based and classification-based ML models and their abilities to predict printing outcomes of cell viability and filament diameter for cell-containing alginate and gelatin composite bioinks. In addition, we interrogated if regression-based models can predict suitable extrusion pressure given the desired cell viability when keeping other experimental parameters constant. We also compared models trained across data from general literature to models trained across data from one literature source that utilized alginate and gelatin bioinks. The results indicate that models trained on large amounts of data can impart physical trends on cell viability, filament diameter, and extrusion pressure seen in past literature. Regression models trained on the larger dataset also predict cell viability closer to experimental values for material concentration combinations not seen in training data of the single-paper-based regression models. While the best performing classification models for cell viability can achieve an average prediction accuracy of 70%, the cell viability predictions remained constant despite altering input parameter combinations. Our trained models on bioprinting literature data show the potential usage of applying ML models to bioprinting experimental design. [ABSTRACT FROM AUTHOR]

Published

2021

43. Tissue-Engineered Models for Glaucoma Research

Author

Renhao Lu, Esak Lee, and Paul A Soden

Subjects

Intraocular pressure, medicine.medical_specialty, genetic structures, lcsh:Mechanical engineering and machinery, 3D scaffold, Nerve fiber layer, soft lithography, Glaucoma, Review, Retinal ganglion, 03 medical and health sciences, 0302 clinical medicine, Schlemm’s canal, Ophthalmology, medicine, lcsh:TJ1-1570, retinal ganglion cell, Electrical and Electronic Engineering, electrospinning, 030304 developmental biology, 3D bioprinting, 0303 health sciences, Retina, business.industry, Mechanical Engineering, trabecular meshwork, optic nerve head, medicine.disease, eye diseases, Review article, glaucoma, medicine.anatomical_structure, Retinal ganglion cell, Control and Systems Engineering, tissue engineering, 030221 ophthalmology & optometry, sense organs, Trabecular meshwork, business, intraocular pressure

Abstract

Glaucoma is a group of optic neuropathies characterized by the progressive degeneration of retinal ganglion cells (RGCs). Patients with glaucoma generally experience elevations in intraocular pressure (IOP), followed by RGC death, peripheral vision loss and eventually blindness. However, despite the substantial economic and health-related impact of glaucoma-related morbidity worldwide, the surgical and pharmacological management of glaucoma is still limited to maintaining IOP within a normal range. This is in large part because the underlying molecular and biophysical mechanisms by which glaucomatous changes occur are still unclear. In the present review article, we describe current tissue-engineered models of the intraocular space that aim to advance the state of glaucoma research. Specifically, we critically evaluate and compare both 2D and 3D-culture models of the trabecular meshwork and nerve fiber layer, both of which are key players in glaucoma pathophysiology. Finally, we point out the need for novel organ-on-a-chip models of glaucoma that functionally integrate currently available 3D models of the retina and the trabecular outflow pathway.

Published

2020

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

Author

Ben MacCallum, Ali Ahmadi, Tiffany Cameron, and Emad Naseri

Subjects

Extension set, Materials science, lcsh:Mechanical engineering and machinery, single-nozzle printing, 0206 medical engineering, Nozzle, Mechanical integrity, Nanotechnology, 02 engineering and technology, engineering.material, Article, law.invention, Coating, law, lcsh:TJ1-1570, Electrical and Electronic Engineering, multi-material printing, continuous multi-material printing, 3D bioprinting, Mechanical Engineering, Multi material, 021001 nanoscience & nanotechnology, 020601 biomedical engineering, Control and Systems Engineering, engineering, 0210 nano-technology

Abstract

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.

Published

2020

45. 3D-Printed Biosensor Arrays for Medical Diagnostics

Author

James F. Rusling, Abby L Jones, and Mohamed Sharafeldin

Subjects

Medical diagnostic, Computer science, lcsh:Mechanical engineering and machinery, Microfluidics, microfluidics, 3D printing, Nanotechnology, Review, 02 engineering and technology, 01 natural sciences, law.invention, Software, law, diagnostics, lcsh:TJ1-1570, Electronics, Electrical and Electronic Engineering, 3D bioprinting, business.industry, Mechanical Engineering, electronics, 010401 analytical chemistry, biomedical_chemical_engineering, Usability, 021001 nanoscience & nanotechnology, optics, 0104 chemical sciences, Control and Systems Engineering, visual_art, Electronic component, visual_art.visual_art_medium, 0210 nano-technology, business, Biosensor, bioprinting

Abstract

While the technology is relatively new, low cost 3D printing has impacted many aspects of human life. 3D printers are being used as manufacturing tools for a wide variety of devices in a spectrum of applications ranging from diagnosis to implants to external prostheses. The ease of use and availability of 3D design software and low cost has made 3D printing an accessible manufacturing and fabrication tool in many research laboratories. 3D printers can print materials with varying density, optical character, strength and chemical properties providing platforms for a huge number of strategies that can be chosen for user’s needs. In this review, we focus on applications in biomedical diagnostics and how this revolutionary technique is facilitating development of low cost, sensitive and often geometrically complex tools. 3D printing in fabrication of microfluidics, supporting equipment, optical and electronic components of diagnostic devices is presented. Emerging diagnostic 3D bioprinting as a tool to incorporate living cells or biomaterials into 3D printing is also discussed.

Published

2018

46. Biofabrication in Congenital Cardiac Surgery: A Plea from the Operating Theatre, Promise from Science.

Author

Kiraly, Laszlo, Vijayavenkataraman, Sanjairaj, and Dokmeci, Mehmet Remzi

Subjects

CARDIAC surgery, PEDIATRIC surgery, BIOPRINTING, REGENERATIVE medicine, REOPERATION

Abstract

Despite significant advances in numerous fields of biofabrication, clinical application of biomaterials combined with bioactive molecules and/or cells largely remains a promise in an individualized patient settings. Three-dimensional (3D) printing and bioprinting evolved as promising techniques used for tissue-engineering, so that several kinds of tissue can now be printed in layers or as defined structures for replacement and/or reconstruction in regenerative medicine and surgery. Besides technological, practical, ethical and legal challenges to solve, there is also a gap between the research labs and the patients' bedside. Congenital and pediatric cardiac surgery mostly deal with reconstructive patient-scenarios when defects are closed, various segments of the heart are connected, valves are implanted. Currently available biomaterials lack the potential of growth and conduits, valves derange over time surrendering patients to reoperations. Availability of viable, growing biomaterials could cancel reoperations that could entail significant public health benefit and improved quality-of-life. Congenital cardiac surgery is uniquely suited for closing the gap in translational research, rapid application of new techniques, and collaboration between interdisciplinary teams. This article provides a succinct review of the state-of-the art clinical practice and biofabrication strategies used in congenital and pediatric cardiac surgery, and highlights the need and avenues for translational research and collaboration. [ABSTRACT FROM AUTHOR]

Published

2021

47. Engineered Microgels—Their Manufacturing and Biomedical Applications.

Author

Alzanbaki, Hamzah, Moretti, Manola, and Hauser, Charlotte A. E.

Subjects

MICROGELS, NANOGELS, BIOPRINTING, PEPTIDES, HYDROGELS

Abstract

Microgels are hydrogel particles with diameters in the micrometer scale that can be fabricated in different shapes and sizes. Microgels are increasingly used for biomedical applications and for biofabrication due to their interesting features, such as injectability, modularity, porosity and tunability in respect to size, shape and mechanical properties. Fabrication methods of microgels are divided into two categories, following a top-down or bottom-up approach. Each approach has its own advantages and disadvantages and requires certain sets of materials and equipments. In this review, we discuss fabrication methods of both top-down and bottom-up approaches and point to their advantages as well as their limitations, with more focus on the bottom-up approaches. In addition, the use of microgels for a variety of biomedical applications will be discussed, including microgels for the delivery of therapeutic agents and microgels as cell carriers for the fabrication of 3D bioprinted cell-laden constructs. Microgels made from well-defined synthetic materials with a focus on rationally designed ultrashort peptides are also discussed, because they have been demonstrated to serve as an attractive alternative to much less defined naturally derived materials. Here, we will emphasize the potential and properties of ultrashort self-assembling peptides related to microgels. [ABSTRACT FROM AUTHOR]

Published

2021

48. Three-Dimensional Calcium Alginate Hydrogel Assembly via TiOPc-Based Light-Induced Controllable Electrodeposition

Author

Yan Ting Liu, Yajing Shen, Hok Sum Sam Lai, Yang Liu, Cong Wu, and Wen J. Li

Subjects

alginate hydrogel, Calcium alginate, Materials science, Fabrication, light-induced electrodeposition, lcsh:Mechanical engineering and machinery, Microfluidics, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Article, law.invention, chemistry.chemical_compound, Tissue engineering, law, Fabrication methods, lcsh:TJ1-1570, Electrical and Electronic Engineering, 3D bioprinting, three-dimensional (3D) hydrogel assembly, Mechanical Engineering, 021001 nanoscience & nanotechnology, TiOPc, 0104 chemical sciences, chemistry, Control and Systems Engineering, Light induced, Alginate hydrogel, 0210 nano-technology, Biomedical engineering

Abstract

Artificial reconstruction of three-dimensional (3D) hydrogel microstructures would greatly contribute to tissue assembly in vitro, and has been widely applied in tissue engineering and drug screening. Recent technological advances in the assembly of functional hydrogel microstructures such as microfluidic, 3D bioprinting, and micromold-based 3D hydrogel fabrication methods have enabled the formation of 3D tissue constructs. However, they still lack flexibility and high efficiency, which restrict their application in 3D tissue constructs. Alternatively, we report a feasible method for the fabrication and reconstruction of customized 3D hydrogel blocks. Arbitrary hydrogel microstructures were fabricated in situ via flexible and rapid light-addressable electrodeposition. To demonstrate the versatility of this method, the higher-order assembly of 3D hydrogel blocks was investigated using a constant direct current (DC) voltage (6 V) applied between two electrodes for 20–120 s. In addition to the plane-based two-dimensional (2D) assembly, hierarchical structures—including multi-layer 3D hydrogel structures and vessel-shaped structures—could be assembled using the proposed method. Overall, we developed a platform that enables researchers to construct complex 3D hydrogel microstructures efficiently and simply, which has the potential to facilitate research on drug screening and 3D tissue constructs.

Published

2017

49. Novel Compound-Forming Technology Using Bioprinting and Electrospinning for Patterning a 3D Scaffold Construct with Multiscale Channels

Author

Sun Yuanshao, Li Shuai, Qingxi Hu, Change Liu, and Yuanyuan Liu

Subjects

Scaffold, Materials science, food.ingredient, lcsh:Mechanical engineering and machinery, 0206 medical engineering, Nanotechnology, 02 engineering and technology, Gelatin, Article, law.invention, food, Tissue engineering, vascularization, law, lcsh:TJ1-1570, Viability assay, human umbilical vein endothelial cells (HUVECs), Electrical and Electronic Engineering, 3D bioprinting, tissue engineering, multiscale channels, Mechanical Engineering, Construct (python library), 021001 nanoscience & nanotechnology, Biocompatible material, 020601 biomedical engineering, Electrospinning, Control and Systems Engineering, 0210 nano-technology, Biomedical engineering

Abstract

One of the biggest challenges for tissue engineering is to efficiently provide oxygen and nutrients to cells on a three-dimensional (3D) engineered scaffold structure. Thus, achieving sufficient vascularization of the structure is a critical problem in tissue engineering. This facilitates the need to develop novel methods to enhance vascularization. Use of patterned hydrogel structures with multiscale channels can be used to achieve the required vascularization. Patterned structures need to be biocompatible and biodegradable. In this study, gelatin was used as the main part of a hydrogel to prepare a biological structure with 3D multiscale channels using bioprinting combined with selection of suitable materials and electrostatic spinning. Human umbilical vein endothelial cells (HUVECs) were then used to confirm efficacy of the structure, inferred from cell viability on different engineered construct designs. HUVECs were seeded on the surface of channels and cultured in vitro. HUVECs showed high viability and diffusion within the construct. This method can be used as a practical platform for the fabrication of engineered construct for vascularization.

Published

2016

50. Chitosans for Tissue Repair and Organ Three-Dimensional (3D) Bioprinting

Author

Xiaohong Tian, Jun Fan, Qiang Ao, Hao Tong, Xiaohong Wang, and Shenglong Li

Subjects

Biocompatibility, lcsh:Mechanical engineering and machinery, Review, macromolecular substances, 02 engineering and technology, chitin, Polysaccharide, law.invention, rapid prototyping (rp), Chitosan, 03 medical and health sciences, chemistry.chemical_compound, Chitin, implantable bioartificial organs, law, Liver tissue, medicine, lcsh:TJ1-1570, tissue repair, Electrical and Electronic Engineering, 030304 developmental biology, 3d bioprinting, chemistry.chemical_classification, 0303 health sciences, 3D bioprinting, Mechanical Engineering, Cartilage, Tissue repair, 021001 nanoscience & nanotechnology, carbohydrates (lipids), medicine.anatomical_structure, chemistry, Control and Systems Engineering, chitosan, 0210 nano-technology, Biomedical engineering

Abstract

Chitosan is a unique natural resourced polysaccharide derived from chitin with special biocompatibility, biodegradability, and antimicrobial activity. During the past three decades, chitosan has gradually become an excellent candidate for various biomedical applications with prominent characteristics. Chitosan molecules can be chemically modified, adapting to all kinds of cells in the body, and endowed with specific biochemical and physiological functions. In this review, the intrinsic/extrinsic properties of chitosan molecules in skin, bone, cartilage, liver tissue repair, and organ three-dimensional (3D) bioprinting have been outlined. Several successful models for large scale-up vascularized and innervated organ 3D bioprinting have been demonstrated. Challenges and perspectives in future complex organ 3D bioprinting areas have been analyzed.

Published

2019