Advanced Materials Technologies | 2021
Electrostatic Distortion of Melt‐Electrowritten Patterns by 3D Objects: Quantification, Modeling, and Toolpath Correction
Abstract
Melt electrowriting (MEW) is an electrohydrodynamic process capable of producing organized patterns of micrometer-scale polymer fibers. Integrating MEW with other additive manufacturing technologies, such as extrusion-printing or bioprinting, offers tantalizing possibilities for multi-scale biofabrication of anatomically shaped scaffolds. However, introducing 3D\xa0structures onto the conventionally flat collector plate significantly complicates the MEW process because these objects perturb the electrostatic field. Here, the systematic investigation of how simple 3D objects (hemispheres) distort MEW patterns printed in their vicinity is reported. The authors assess the influence of a series of parameters on fiber deflection including: distance from the hemisphere, hemisphere size and material composition, height of the nozzle, translation speed, applied voltage, and applied pressure. In light of these data, a model which captures the basic physics behind the deflection phenomenon is derived. An optimization algorithm to calculate tool-paths which pre-emptively account for these deviations is also introduced. Finally, the authors validate how G-code produced by this algorithm effectively corrects the distortion effect, restoring the ability to create well-defined MEW patterns in the vicinity of 3D objects. This study suggests a foundation for understanding the complexities of MEW on non-planar collectors, and towards multitechnology biofabrication.