A Study of Variable Stiffness Alginate Printing for Medical Applications
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Date
2009-09-18
Authors
Mookerjee, Adaleena
Cohen, Daniel L.
Peng, David H.
Bonassar, Lawrence J.
Lipson, Hod
Journal Title
Journal ISSN
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Publisher
University of Texas at Austin
Abstract
Technologies for multi-material 3D-printing of anatomical shapes are useful both for fabrication of heterogeneous cell-seeded implants as well as for fabrication of synthetic models for surgical planning and training. For both these applications, it would be desirable to print directly with biological materials to best emulate the target’s properties. Using a novel material platform, we describe a series of experiments attempting to print variable-stiffness hydrogels. We vary compliances by alternating 2% alginate hydrogel and a Dextran-infused calcium chloride post-crosslinker. Stiffness throughout the construct ranged from 4 kPa to 20 kPa as a function of post-crosslinker concentration, which was spatially specified by the user.