3D Bioprinting Human Induced Pluripotent Stem Cell-Derived Neural Tissues Using a Novel Lab-on-a-Printer Technology

Vega, Laura De la; Gómez, Diego A. Rosas; Abelseth, Emily; Abelseth, Laila; Silva, Victor Allisson da; Willerth, Stephanie M.

doi:10.3390/app8122414

Cited by 58 publications

(76 citation statements)

References 29 publications

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“…Such bioprinted microenvironments can promote the differentiation of hiPSC-derived NPCs into mature, electrophysiologically active neurons. Our group has engineered 3D bioprinted hiPSC-derived neural tissue that mimics spinal cord tissue by treating these tissues with a variety of small molecules (De La Vega et al, 2018a). While these 3D bioprinted constructs show promise as an in vitro neural tissue models, there is still significant room for improvement.…”

Section: Discussionmentioning

confidence: 99%

“…Our own group developed a novel fibrin-based bioink for printing hiPSC-derived neural aggregates that both maintained their viability and differentiated into mature neural tissues after 46 days of culture (Abelseth et al, 2018). This same formulation was also used to print dissociated hiPSC-derived neural progenitor cells (NPCs) that could be matured into spinal cord-resembling tissues upon treatment with specific small molecules (De La Vega et al, 2018a). This bioink formulation supported the generation of ring shaped constructs containing the human glioblastoma cell line where the tissues exhibited high levels of viability and expressed cancer associated protein markers (Lee et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

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3D Bioprinting Pluripotent Stem Cell Derived Neural Tissues Using a Novel Fibrin Bioink Containing Drug Releasing Microspheres

Sharma

Smits

Vega

et al. 2020

Front. Bioeng. Biotechnol.

Self Cite

103

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3D bioprinting combines cells with a supportive bioink to fabricate multiscale, multicellular structures that imitate native tissues. Here, we demonstrate how our novel fibrinbased bioink formulation combined with drug releasing microspheres can serve as a tool for bioprinting tissues using human induced pluripotent stem cell (hiPSC)-derived neural progenitor cells (NPCs). Microspheres, small spherical particles that generate controlled drug release, promote hiPSC differentiation into dopaminergic neurons when used to deliver small molecules like guggulsterone. We used the microfluidics based RX1 bioprinter to generate domes with a 1 cm diameter consisting of our novel fibrin-based bioink containing guggulsterone microspheres and hiPSC-derived NPCs. The resulting tissues exhibited over 90% cellular viability 1 day post printing that then increased to 95% 7 days post printing. The bioprinted tissues expressed the early neuronal marker, TUJ1 and the early midbrain marker, Forkhead Box A2 (FOXA2) after 15 days of culture. These bioprinted neural tissues expressed TUJ1 (15 ± 1.3%), the dopamine marker, tyrosine hydroxylase (TH) (8 ± 1%) and other glial markers such as glial fibrillary acidic protein (GFAP) (15 ± 4%) and oligodendrocyte progenitor marker (O4) (4 ± 1%) after 30 days. Also, quantitative polymerase chain reaction (qPCR) analysis showed these bioprinted tissues expressed TUJ1, NURR1 (gene expressed in midbrain dopaminergic neurons), LMX1B, TH, and PAX6 after 30 days. In conclusion, we have demonstrated that using a microsphere-laden bioink to bioprint hiPSC-derived NPCs can promote the differentiation of neural tissue.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

3D Bioprinting Pluripotent Stem Cell Derived Neural Tissues Using a Novel Fibrin Bioink Containing Drug Releasing Microspheres

Sharma

Smits

Vega

et al. 2020

Front. Bioeng. Biotechnol.

Self Cite

103

View full text Add to dashboard Cite

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“…However, constructing multicellular architectures remains a significant challenge. Recently, commercially available extrusion‐based lab‐on‐a‐printer systems have been utilized for tissue engineering studies . These printers consist of a variable system which can control the desired temperature inside the syringe, a printing stage which is tunable in the range of 4–37 °C depending on the specific requirement of the cell‐hydrogel suspension for maintain cell viability, and a built‐in ultraviolet (UV) light system for sterility and cross‐linking.…”

Section: Design Principle For Developing 3d Printed Neural Regeneratimentioning

confidence: 99%

“…Moreover, depending on the specific requirement for the printing process, the printer can be customized. For instance, to reduce shear stress on cells during extrusion, Willerth et al have integrated microfluidic channels into the printhead, which allowed a separate flow of cells in bioinks and the associated cross‐linker . This enabled low viscous flow, resulting in successful neural differentiation from printed human induced pluripotent stem cells (iPSCs).…”

Section: Design Principle For Developing 3d Printed Neural Regeneratimentioning

confidence: 99%

3D Printed Neural Regeneration Devices

Joung

Lavoie

Guo

et al. 2019

Adv Funct Materials

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Neural regeneration devices interface with the nervous system and can provide flexibility in material choice, implantation without the need for additional surgeries, and the ability to serve as guides augmented with physical, biological (e.g., cellular), and biochemical functionalities. Given the complexity and challenges associated with neural regeneration, a 3D printing approach to the design and manufacturing of neural devices can provide next-generation opportunities for advanced neural regeneration via the production of anatomically accurate geometries, spatial distributions of cellular components, and incorporation of therapeutic biomolecules. A 3D printing-based approach offers compatibility with 3D scanning, computer modeling, choice of input material, and increasing control over hierarchical integration. Therefore, a 3D printed implantable platform can ultimately be used to prepare novel biomimetic scaffolds and model complex tissue architectures for clinical implants in order to treat neurological diseases and injuries. Further, the flexibility and specificity offered by 3D printed in vitro platforms have the potential to be a significant foundational breakthrough with broad research implications in cell signaling and drug screening for personalized healthcare. This progress report examines recent advances in 3D printing strategies for neural regeneration as well as insight into how these approaches can be improved in future studies.spinal cord, and the peripheral nervous system (PNS), composed of the cranial and spinal nerves along with their associated ganglia that connect the CNS to the body. These systems are interconnected via an extensive network of nerves and neural cells (i.e., neurons and supporting glial cells) to facilitate communication and relay information (sensorimotor signals) to and from all parts of the body.

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“…Fibrin hydrogel encapsulated bone marrow stromal cells were inkjet printed and showed cytocompatibility of the encapsulation material [307]. Fibrin has been used as the base bioink for the printing of neural tissue as a glioblastoma model for drug screening [308]; human dental pulp stem cells for tooth tissue engineering [309]; Schwann cells for nerve tissue engineering [219,303]; human umbilical vein endothelial cells, and hMSCs for bone tissue engineering and neovascularization [310]; as well as human induced pluripotent stem cells for neurological diseases [311].…”

Section: Biocompatibility Biodegradability and Bioactivitymentioning

confidence: 99%

Engineered 3D Polymer and Hydrogel Microenvironments for Cell Culture Applications

2019

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The realization of biomimetic microenvironments for cell biology applications such as organ-on-chip, in vitro drug screening, and tissue engineering is one of the most fascinating research areas in the field of bioengineering. The continuous evolution of additive manufacturing techniques provides the tools to engineer these architectures at different scales. Moreover, it is now possible to tailor their biomechanical and topological properties while taking inspiration from the characteristics of the extracellular matrix, the three-dimensional scaffold in which cells proliferate, migrate, and differentiate. In such context, there is therefore a continuous quest for synthetic and nature-derived composite materials that must hold biocompatible, biodegradable, bioactive features and also be compatible with the envisioned fabrication strategy. The structure of the current review is intended to provide to both micro-engineers and cell biologists a comparative overview of the characteristics, advantages, and drawbacks of the major 3D printing techniques, the most promising biomaterials candidates, and the trade-offs that must be considered in order to replicate the properties of natural microenvironments.

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3D Bioprinting Human Induced Pluripotent Stem Cell-Derived Neural Tissues Using a Novel Lab-on-a-Printer Technology

Cited by 58 publications

References 29 publications

3D Bioprinting Pluripotent Stem Cell Derived Neural Tissues Using a Novel Fibrin Bioink Containing Drug Releasing Microspheres

3D Bioprinting Pluripotent Stem Cell Derived Neural Tissues Using a Novel Fibrin Bioink Containing Drug Releasing Microspheres

3D Printed Neural Regeneration Devices

Engineered 3D Polymer and Hydrogel Microenvironments for Cell Culture Applications

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