Digitally Tunable Microfluidic Bioprinting of Multilayered Cannular Tissues

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Abstract

<p class="first" id="P1">Despite advances in the bioprinting technology, biofabrication of circumferentially multilayered tubular tissues or organs with cellular heterogeneity, such as blood vessels, trachea, intestine, colon, ureter, and urethra, remains a challenge. Herein, a promising multichannel coaxial extrusion system (MCCES) for microfluidic bioprinting of circumferentially multilayered tubular tissues in a single step, using customized bioinks constituting gelatin methacryloyl, alginate, and eight-arm poly(ethylene glycol) acrylate with a tripentaerythritol core, is presented. These perfusable cannular constructs can be continuously tuned up from monolayer to triple layers at regular intervals across the length of a bioprinted tube. Using customized bioink and MCCES, bioprinting of several tubular tissue constructs using relevant cell types with adequate biofunctionality including cell viability, proliferation, and differentiation is demonstrated. Specifically, cannular urothelial tissue constructs are bioprinted, using human urothelial cells and human bladder smooth muscle cells, as well as vascular tissue constructs, using human umbilical vein endothelial cells and human smooth muscle cells. These bioprinted cannular tissues can be actively perfused with fluids and nutrients to promote growth and proliferation of the embedded cell types. The fabrication of such tunable and perfusable circumferentially multilayered tissues represents a fundamental step toward creating human cannular tissues. </p>

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Most cited references 30

Record: found
Abstract: found
Article: not found

The cell-cell adhesion molecule E-cadherin.

F Van Roy, G. Berx (2008)

This review is dedicated to E-cadherin, a calcium-dependent cell-cell adhesion molecule with pivotal roles in epithelial cell behavior, tissue formation, and suppression of cancer. As founder member of the cadherin superfamily, it has been extensively investigated. We summarize the structure and regulation of the E-cadherin gene and transcript. Models for E-cadherin-catenin complexes and cell junctions are presented. The structure of the E-cadherin protein is discussed in view of the diverse functions of this remarkable protein. Homophilic and heterophilic adhesion are compared, including the role of E-cadherin as a receptor for pathogens. The complex post-translational processing of E-cadherin is reviewed, as well as the many signaling activities. The role of E-cadherin in embryonic development and morphogenesis is discussed for several animal models. Finally, we review the multiple mechanisms that disrupt E-cadherin function in cancer: inactivating somatic and germline mutations, epigenetic silencing by DNA methylation and epithelial to mesenchymal transition-inducing transcription factors, and dysregulated protein processing.

0 comments Cited 391 times – based on 0 reviews      Review now

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Record: found
Abstract: found
Article: not found

Gelatin-Methacryloyl Hydrogels: Towards Biofabrication-Based Tissue Repair.

Barbara J Klotz, Debby Gawlitta, Antoine Rosenberg … (2016)

Research over the past decade on the cell-biomaterial interface has shifted to the third dimension. Besides mimicking the native extracellular environment by 3D cell culture, hydrogels offer the possibility to generate well-defined 3D biofabricated tissue analogs. In this context, gelatin-methacryloyl (gelMA) hydrogels have recently gained increased attention. This interest is sparked by the combination of the inherent bioactivity of gelatin and the physicochemical tailorability of photo-crosslinkable hydrogels. GelMA is a versatile matrix that can be used to engineer tissue analogs ranging from vasculature to cartilage and bone. Convergence of biological and biofabrication approaches is necessary to progress from merely proving cell functionality or construct shape fidelity towards regenerating tissues. GelMA has a critical pioneering role in this process and could be used to accelerate the development of clinically relevant applications.

0 comments Cited 246 times – based on 0 reviews      Review now

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Record: found
Abstract: found
Article: not found

A decade of progress in tissue engineering.

Ali Khademhosseini, Robert Langer (2016)

Tremendous progress has been achieved in the field of tissue engineering in the past decade. Several major challenges laid down 10 years ago, have been studied, including renewable cell sources, biomaterials with tunable properties, mitigation of host responses, and vascularization. Here we review advancements in these areas and envision directions of further development.

0 comments Cited 206 times – based on 0 reviews      Review now

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Author and article information

Journal

Title: Advanced Materials

Abbreviated Title: Adv. Mater.

Publisher: Wiley

ISSN: 09359648

Publication date (Electronic): August 23 2018

Page: 1706913

Affiliations

[1 ]Division of Engineering in Medicine; Brigham and Women's Hospital; Harvard Medical School; Cambridge MA 02139 USA

[2 ]Harvard-MIT Division of Health Sciences and Technology; Massachusetts Institute of Technology; Cambridge MA 02139 USA

[3 ]Department of Plastic and Reconstructive Surgery; Renji Hospital; Shanghai Jiao Tong University School of Medicine; Shanghai 200127 China

[4 ]Research Institute for Bioscience and Biotechnology; Nakkhu-4 Lalitpur 44600 Nepal

[5 ]Department of Urology; Drum Tower Hospital; Medical School of Nanjing University; Institute of Urology; Nanjing University; Nanjing 210008 China

[6 ]Department of Urology; Anqing Petrochemical Hospital; Nanjing Gulou Hospital Group; Anqing 246002 China

[7 ]Beijing Advanced Innovation Center for Biomedical Engineering; Key Laboratory for Biomechanics and Mechanobiology of Ministry of Education; School of Biological Science and Medical Engineering; Beihang University; Beijing 100083 China

[8 ]School of Engineering and Applied Sciences; Harvard University; Cambridge MA 02138 USA

[9 ]ENCIT - Science Engineering and Technology School Tecnologico de Monterrey; Monterrey 64849 Mexico

[10 ]Biosensor National Special Laboratory; Key Laboratory of Biomedical Engineering of Education Ministry; Department of Biomedical Engineering; Zhejiang University; Hangzhou 310027 China

[11 ]Department of Orthopedic Surgery; Shanghai Jiaotong University Affiliated Sixth People's Hospital; Shanghai Jiaotong University; Shanghai 200233 China

[12 ]The First Clinical Medical College; Nanjing University of Chinese Medicine; Jiangsu Collaborative Innovation; Center of Traditional Chinese Medicine Prevention and Treatment of Tumor; Nanjing University of Chinese Medicine; Nanjing 210023 China

[13 ]State Key Laboratory of Physical Chemistry of Solid Surface; College of Chemistry and Chemical Engineering; Xiamen University; Xiamen 361005 China

[14 ]Research Institute for Soft Matter and Biomimetics; College of Physical Science and Engineering; Xiamen University; Xiamen 361005 China

[15 ]Department of Bioengineering; Department of Chemical and Biomolecular Engineering; Henry Samueli School of Engineering and Applied Sciences; Department of Radiology; David Geffen School of Medicine; Center for Minimally Invasive Therapeutics (C-MIT); California NanoSystems Institute (CNSI); University of California; Los Angeles CA 90095 USA

[16 ]Department of Bioindustrial Technologies; College of Animal Bioscience and Technology; Konkuk University; Seoul 05029 Republic of Korea