Layer-by-layer fabrication of 3D hydrogel structures using open microfluidics

Author(s): Ulri N. Lee ¹ ^, ² ^, ³ ^, ⁴ , John H. Day ¹ ^, ² ^, ³ ^, ⁴ , Amanda J. Haack ¹ ^, ² ^, ³ ^, ⁴ ^, ⁵ , Ross C. Bretherton ⁶ ^, ² ^, ³ ^, ⁴ , Wenbo Lu ¹ ^, ² ^, ³ ^, ⁴ , Cole A. DeForest ⁶ ^, ² ^, ³ ^, ⁴ ^, ⁷ , Ashleigh B. Theberge ¹ ^, ² ^, ³ ^, ⁴ ^, ⁸ , Erwin Berthier ¹ ^, ² ^, ³ ^, ⁴

Publication date (Electronic): 2020

Journal: Lab on a Chip

Publisher: Royal Society of Chemistry (RSC)

Read this article at

ScienceOpenPublisher PMC

Bookmark

There is no author summary for this article yet. Authors can add summaries to their articles on ScienceOpen to make them more accessible to a non-specialist audience.

Abstract

Our simple, robust, open microfluidic 3D hydrogel patterning method fabricates complex structures while minimizing material waste.

Abstract

Patterned deposition and 3D fabrication techniques have enabled the use of hydrogels for a number of applications including microfluidics, sensors, separations, and tissue engineering in which form fits function. Devices such as reconfigurable microvalves or implantable tissues have been created using lithography or casting techniques. Here, we present a novel open-microfluidic patterning method that utilizes surface tension forces to form hydrogel layers on top of each other, into a patterned 3D structure. We use a patterning device to form a temporary open microfluidic channel on an existing gel layer, allowing the controlled flow of unpolymerized gel in device-regions. After layer gelation and device removal, the process can be repeated iteratively to create multi-layered 3D structures. The use of open-microfluidic and surface tension-based methods to define the shape of each individual layer enables patterning to be performed with a simple pipette and with minimal dead-volume. Our method is compatible with unmodified (native) biological hydrogels, and other non-biological materials with precursor fluid properties compatible with capillary flow. With our open-microfluidic layer-by-layer fabrication method, we demonstrate the capability to build agarose, type I collagen, and polymer–peptide 3D structures featuring asymmetric designs, multiple components, overhanging features, and cell-laden regions.

Related collections

Most cited references 50

Record: found
Abstract: found
Article: not found

Controlling Shear Stress in 3D Bioprinting is a Key Factor to Balance Printing Resolution and Stem Cell Integrity.

Andreas Blaeser, Daniela Duarte Campos, Uta Puster … (2016)

A microvalve-based bioprinting system for the manufacturing of high-resolution, multimaterial 3D-structures is reported. Applying a straightforward fluid-dynamics model, the shear stress at the nozzle site can precisely be controlled. Using this system, a broad study on how cell viability and proliferation potential are affected by different levels of shear stress is conducted. Complex, multimaterial 3D structures are printed with high resolution. This work pioneers the investigation of shear stress-induced cell damage in 3D bioprinting and might help to comprehend and improve the outcome of cell-printing studies in the future.

0 comments Cited 247 times – based on 0 reviews      Review now

Bookmark

Record: found
Abstract: found
Article: not found

In vitro microvessels for the study of angiogenesis and thrombosis.

Ying Zheng, Junmei Chen, Michael P Craven … (2012)

Microvascular networks support metabolic activity and define microenvironmental conditions within tissues in health and pathology. Recapitulation of functional microvascular structures in vitro could provide a platform for the study of complex vascular phenomena, including angiogenesis and thrombosis. We have engineered living microvascular networks in three-dimensional tissue scaffolds and demonstrated their biofunctionality in vitro. We describe the lithographic technique used to form endothelialized microfluidic vessels within a native collagen matrix; we characterize the morphology, mass transfer processes, and long-term stability of the endothelium; we elucidate the angiogenic activities of the endothelia and differential interactions with perivascular cells seeded in the collagen bulk; and we demonstrate the nonthrombotic nature of the vascular endothelium and its transition to a prothrombotic state during an inflammatory response. The success of these microvascular networks in recapitulating these phenomena points to the broad potential of this platform for the study of cardiovascular biology and pathophysiology.

0 comments Cited 245 times – based on 0 reviews      Review now

Bookmark

Record: found
Abstract: found
Article: not found

Agarose-based biomaterials for tissue engineering

Payam Zarrintaj, Saeed Manouchehri, Zahed Ahmadi … (2018)

Agarose is a natural polysaccharide polymer having unique characteristics that give reason to consider it for tissue engineering applications. Special characteristics of agarose such as its excellent biocompatibility, thermo-reversible gelation behavior and physiochemical features support its use as a biomaterial for cell growth and/or controlled/localized drug delivery. The resemblance of this natural carbohydrate polymer to the extracellular matrix results in attractive features that bring about a strong interest in its usage in the field. The scope of this review is to summarize the extensive researches addressing agarose-based biomaterials in order to provide an in-depth understanding of its tissue engineering-related applications.