Microfluidic systems are essential to a broad range of technological applications, including biotechnology, [1] microelectronics, [2] sensors, [3] chemical reactors, [4] and autonomic materials. [5] Several approaches have emerged for fabricating two-dimensional (2D) [6] and three-dimensional (3D) [7] microfluidic devices, including photolithographic or soft-lithographic techniques, [1b,2a,3c,4b,5b] laser micromachining, [7b] and derivative methods based on soft lithography.[7d±f] These techniques, however, have been confined to relatively thin device architectures (of only a few layers) and limited by materials constraints, [7b] poor resolution, [7c] or the need for extensive manual labor. [7d±f] We recently demonstrated the direct-write assembly of 3D microvascular networks, consisting of 16-layer structures with interconnected microchannels (200 lm in diameter) encapsulated in an epoxy matrix.[7a] Our approach involved the robotic deposition of a fugitive organic ink, which yields the desired microchannel network upon its subsequent removal from the matrix. Difficulties such as deformation of this fugitive-ink scaffold were encountered during assembly that prevented fabrication of larger 3D structures. Here, we report the development of a new fugitive ink that enables the direct-write assembly of 3D scaffolds (with more than a hundred layers) that retain their shape during fabrication and subsequent matrix infiltration under ambient conditions. The fabrication procedure of 3D microvascular networks (see Scheme 1) begins with the robotic deposition [8] of the fugitive ink onto a moving x±y platform, yielding a 2D pattern. After the initial layer is generated, the deposition nozzle, which is mounted on the z-stage, is raised a finite height and another layer is deposited. This process is repeated until the desired 3D scaffold is created. The interstitial pore space between patterned features is then infiltrated with a low-viscosity epoxy. Upon curing, the ink-based scaffold is removed, yielding an interconnected 3D microvascular network. The fugitive inks used in this directed assembly technique must satisfy several criteria. First, the ink must flow through a fine Scheme 1. Schematic representation of the fabrication procedure for 3D microvascular networks by direct-write assembly: a) deposition of fugitive ink (in blue) through cylindrical nozzle; b) multilayer scaffold after ink deposition; c) resin infiltration into scaffold; d) resin solidification to form structural matrix; and e) 3D microvascular network created after removal of fugitive ink.
