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Pan H.M.,National University of Singapore | Beyer S.,Alliance Technology Group | Beyer S.,1 CREATE Way and 04 13 14 Enterprise Wing | Zhu Q.,National University of Singapore | Trau D.,National University of Singapore
Advanced Functional Materials | Year: 2013

The unique inwards interweaving morphology of polyamines and polyacids within agarose hydrogels that leads to the formation of striated shells with different porosities within the spherical scaffold is reported. Microcompartments with sophisticated structures are commonly used in drug delivery, tissue engineering, and other biomedical applications. However, a method capable of producing well-defined, multiporous shells within a single compartment is still lacking. By the alternating deposition of polyallylamine (PA) and polystyrenesulfonic acid (PSS) in 1-butanol, at equal mass ratios, multiple levels of porosity are generated within an agarose microsphere. Each level of porosity is represented by a well-defined, concentric shell of interweaving PA and PSS layers. The number, thickness, and porosity of the striated shells can be easily controlled by varying the number of PA/PSS bilayers and the polymer concentration, respectively. The feasibility of utilizing this morphology for the assembly of a multi-shell porous spherical scaffold is validated by trapping different molecular weight dextrans within different regions of porosity. The unique interaction of polyacids and polyamines in hydrogels represents a facile and inexpensive approach to the development of intricate scaffold architectures. The inwards interweaving of polyamine and polyacid layers within an agarose matrix leads to the creation of well-defined, spherical multi-shells with different porosities. The higher the density of interweaving layers, the lower the porosity. The number and thickness of different levels of porosity are easily tuned by varying the number of polymer depositions and polymer concentration, respectively. © 2013 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim. Source

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