3D bioprinting using stem cells

Ong, Chin Siang; Yesantharao, Pooja; Huang, Chen Yu; Mattson, Gunnar; Boktor, Joseph C.; Fukunishi, Takuma; Zhang, Huaitao; Hibino, Narutoshi

doi:10.1038/pr.2017.252

Cited by 193 publications

(207 citation statements)

References 69 publications

(129 reference statements)

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“…A practical biomaterial for 3D bio-printing is usually a biocompatible substance, which should be easily manipulated and it could maintain or even enhance cell viability and functions [70]. Different types of 3D bio-printing technologies have been introduced so far, including ink-jet-based bio-printing [71], laser-assisted bio-printing [72], extrusion-based bio-printing [73], stereo-lithography-based bio-printing [74] and microvalve-based bio-printing [75] and many other novel emerging technologies [76] (Table 2). Among these technologies, probably extrusion-based bio-printing has been the most widely used one to construct living 3D tissues and organs [77].…”

Section: D Bio-printing In Liver Tementioning

confidence: 99%

Tissue Engineering in Liver Regenerative Medicine: Insights into Novel Translational Technologies

Heydari

Najimi

Mirzaei

et al. 2020

Cells

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Organ and tissue shortage are known as a crucially important public health problem as unfortunately a small percentage of patients receive transplants. In the context of emerging regenerative medicine, researchers are trying to regenerate and replace different organs and tissues such as the liver, heart, skin, and kidney. Liver tissue engineering (TE) enables us to reproduce and restore liver functions, fully or partially, which could be used in the treatment of acute or chronic liver disorders and/or generate an appropriate functional organ which can be transplanted or employed as an extracorporeal device. In this regard, a variety of techniques (e.g., fabrication technologies, cell-based technologies, microfluidic systems and, extracorporeal liver devices) could be applied in tissue engineering in liver regenerative medicine. Common TE techniques are based on allocating stem cell-derived hepatocyte-like cells or primary hepatocytes within a three-dimensional structure which leads to the improvement of their survival rate and functional phenotype. Taken together, new findings indicated that developing liver tissue engineering-based techniques could pave the way for better treatment of liver-related disorders. Herein, we summarized novel technologies used in liver regenerative medicine and their future applications in clinical settings.

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Section: D Bio-printing In Liver Tementioning

confidence: 99%

Tissue Engineering in Liver Regenerative Medicine: Insights into Novel Translational Technologies

Heydari

Najimi

Mirzaei

et al. 2020

Cells

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“…Three-dimensional (3D) cell culture represents a promising approach to better elucidate cell behavior, ECM remodeling, tissue remodeling, and tissue fusion, and ultimately to investigate clinical applications for tissue engineering (Ong et al, 2017). 3D constructs are more similar to the tissue microenvironment than classical 2D cell cultures (plastic-based) as they demonstrate more realistic cell morphology and physiology; furthermore, observation of 3D cultures over time is considered to represent 4D systems (Bissell, 2017).…”

Section: New Approaches To Studying Palatogenesis and Cl/p In Vitromentioning

confidence: 99%

Extracellular Matrix Composition and Remodeling: Current Perspectives on Secondary Palate Formation, Cleft Lip/Palate, and Palatal Reconstruction

Paiva

Maas

Santos

et al. 2019

Front. Cell Dev. Biol.

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Craniofacial development comprises a complex process in humans in which failures or disturbances frequently lead to congenital anomalies. Cleft lip with/without palate (CL/P) is a common congenital anomaly that occurs due to variations in craniofacial development genes, and may occur as part of a syndrome, or more commonly in isolated forms (non-syndromic). The etiology of CL/P is multifactorial with genes, environmental factors, and their potential interactions contributing to the condition. Rehabilitation of CL/P patients requires a multidisciplinary team to perform the multiple surgical, dental, and psychological interventions required throughout the patient's life. Despite progress, lip/palatal reconstruction is still a major treatment challenge. Genetic mutations and polymorphisms in several genes, including extracellular matrix (ECM) genes, soluble factors, and enzymes responsible for ECM remodeling (e.g., metalloproteinases), have been suggested to play a role in the etiology of CL/P; hence, these may be considered likely targets for the development of new preventive and/or therapeutic strategies. In this context, investigations are being conducted on new therapeutic approaches based on tissue bioengineering, associating stem cells with biomaterials, signaling molecules, and innovative technologies. In this review, we discuss the role of genes involved in ECM composition and remodeling during secondary palate formation and pathogenesis and genetic etiology of CL/P. We also discuss potential therapeutic approaches using bioactive molecules and principles of tissue bioengineering for state-of-the-art CL/P repair and palatal reconstruction.

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“…7,23 Although the inkjet bioprinter has the advantages of low cost, achievable speed, and high cell viability as well as high resolution, the bioink used in this bioprinter must be liquid and less viscous. 14,24,25 There are also some other obstacles, such as the difficulty of cross-linking and a limited range of viscosities of bioink. 2 The laser-assisted bioprinter is based on laser-induced forward transfer.…”

Section: D Bioprintermentioning

confidence: 99%

Beyond 2D: 3D bioprinting for skin regeneration

Wang

Yao

et al. 2018

International Wound Journal

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Essential cellular functions that are present in tissues are missed by two‐dimensional (2D) cell monolayer culture. It certainly limits their potential to predict the cellular responses of real organisms. Engineering approaches offer solutions to overcome current limitations. For example, establishing a three‐dimensional (3D)‐based matrix is motivated by the need to mimic the functions of living tissues, which will have a strong impact on regenerative medicine. However, as a novel approach, it requires the development of new standard protocols to increase the efficiency of clinical translation. In this review, we summarised the various aspects of requirements related to well‐suited 3D bioprinting techniques for skin regeneration and discussed how to overcome current bottlenecks and propel these therapies into the clinic.

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3D bioprinting using stem cells

Cited by 193 publications

References 69 publications

Tissue Engineering in Liver Regenerative Medicine: Insights into Novel Translational Technologies

Tissue Engineering in Liver Regenerative Medicine: Insights into Novel Translational Technologies

Extracellular Matrix Composition and Remodeling: Current Perspectives on Secondary Palate Formation, Cleft Lip/Palate, and Palatal Reconstruction

Beyond 2D: 3D bioprinting for skin regeneration

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