Hetero-cellular prototyping by synchronized multi-material bioprinting for rotary cell culture system

Snyder, Jessica; Son, Ae Rin; Hamid, Qudus; Wu, Honglu; Sun, Wei

doi:10.1088/1758-5090/8/1/015002

Cited by 24 publications

(20 citation statements)

References 57 publications

(58 reference statements)

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“…Na-alginate solutions can be precisely extruded into several jets with distinct patterns and boundaries by taking advantage of laminar flow. [20][21][22][23][24] Afterward, the extruded droplets are rotated by a small airflow which is accurately set up. Due to the spinning process, the arrangement of different jets inside the droplet becomes tunable which was supposed to be the parallel originally.…”

Section: Doi: 101002/smll201802630mentioning

confidence: 99%

“…In this research, we present a brand new bioprinting method that provides multicellular asymmetrical microspheroids with a controlled spatial spiral‐based microarchitecture inside the spheroids. By applying a microfluidic nozzle, cell‐laden Na‐alginate solutions can be precisely extruded into several jets with distinct patterns and boundaries by taking advantage of laminar flow . Afterward, the extruded droplets are rotated by a small airflow which is accurately set up.…”

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confidence: 99%

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Airflow‐Assisted 3D Bioprinting of Human Heterogeneous Microspheroidal Organoids with Microfluidic Nozzle

Zhao

Chen

Shao

et al. 2018

Small

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Hydrogel microspheroids are widely used in tissue engineering, such as injection therapy and 3D cell culture, and among which, heterogeneous microspheroids are drawing much attention as a promising tool to carry multiple cell types in separated phases. However, it is still a big challenge to fabricate heterogeneous microspheroids that can reconstruct built-up tissues' microarchitecture with excellent resolution and spatial organization in limited sizes. Here, a novel airflow-assisted 3D bioprinting method is reported, which can print versatile spiral microarchitectures inside the microspheroids, permitting one-step bioprinting of fascinating hydrogel structures, such as the spherical helix, rose, and saddle. A microfluidic nozzle is developed to improve the capability of intricate cell encapsulation with heterotypic contact. Complex structures, such as a rose, Tai chi pattern, and single cell line can be easily printed in spheroids. The theoretical model during printing is established and process parameters are systematically investigated. As a demonstration, a human multicellular organoid of spirally vascularized ossification is reconstructed with this method, which shows that it is a powerful tool to build mini tissues on microspheroids.

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Section: Doi: 101002/smll201802630mentioning

confidence: 99%

mentioning

confidence: 99%

Airflow‐Assisted 3D Bioprinting of Human Heterogeneous Microspheroidal Organoids with Microfluidic Nozzle

Zhao

Chen

Shao

et al. 2018

Small

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“…42 Another solution is the use of a single print head and a microfluidic system that mixes the various bioinks, coming from different reservoirs, before extruding a single multimaterial filament, characterized by a stable concentration gradient of the mixed bioinks across the filament section. 43,44 Microfluidic techniques assemble multiple material inlets in a single outlet channel without mixing, due to low inertial forces in microscale cross-sectional channels. Even if the microfluidic approach is limited by the mixing of the same fluid solution with different solutes (or different concentrations of the same solute), sub-needle (filament) resolution can be achieved.…”

Section: Multinozzle and Microfluidic Approaches For Extrusion-based mentioning

confidence: 99%

Multimaterial, heterogeneous, and multicellular three-dimensional bioprinting

2017

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Bioprinting promises to create three-dimensional in vitro models to study pathological states and possible new therapies, and in the future, to produce complex tissue and organ replacements. This article will describe the recent advances in bioprinting technologies to engineer artificial tissues and organs by controlling spatial heterogeneity of chemical and physical properties of scaffolds and, at the same time, the cellular composition and spatial arrangement. Despite significant technological improvements in recent years, the positioning at the micrometric level and the switching of different cell types and biomaterials remain a challenge, which limits the development of resilient vascular, neural, and lymphatic networks for metabolites, signaling, and waste transport, and thus limits the development of thick and clinically relevant engineered vascularized tissues

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“…A promising solution is tissue/organ printing that employs living cells and biologically-relevant hydrogels as the printing inks to fabricate living 3D constructs in a controlled and layer-by-layer manner. Recent advances in organ printing with multiple bioprinting heads enabled researchers to capture heterocellular organizations of native organs [88,89]. …”

Section: Am-based Multicellular Constructsmentioning

confidence: 99%

Additive Manufacturing of Biomedical Constructs with Biomimetic Structural Organizations

Zhang

et al. 2016

Materials

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Additive manufacturing (AM), sometimes called three-dimensional (3D) printing, has attracted a lot of research interest and is presenting unprecedented opportunities in biomedical fields, because this technology enables the fabrication of biomedical constructs with great freedom and in high precision. An important strategy in AM of biomedical constructs is to mimic the structural organizations of natural biological organisms. This can be done by directly depositing cells and biomaterials, depositing biomaterial structures before seeding cells, or fabricating molds before casting biomaterials and cells. This review organizes the research advances of AM-based biomimetic biomedical constructs into three major directions: 3D constructs that mimic tubular and branched networks of vasculatures; 3D constructs that contains gradient interfaces between different tissues; and 3D constructs that have different cells positioned to create multicellular systems. Other recent advances are also highlighted, regarding the applications of AM for organs-on-chips, AM-based micro/nanostructures, and functional nanomaterials. Under this theme, multiple aspects of AM including imaging/characterization, material selection, design, and printing techniques are discussed. The outlook at the end of this review points out several possible research directions for the future.

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Hetero-cellular prototyping by synchronized multi-material bioprinting for rotary cell culture system

Cited by 24 publications

References 57 publications

Airflow‐Assisted 3D Bioprinting of Human Heterogeneous Microspheroidal Organoids with Microfluidic Nozzle

Airflow‐Assisted 3D Bioprinting of Human Heterogeneous Microspheroidal Organoids with Microfluidic Nozzle

Multimaterial, heterogeneous, and multicellular three-dimensional bioprinting

Additive Manufacturing of Biomedical Constructs with Biomimetic Structural Organizations

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