Ho-Yi Sun scite author profile

In addition to the widely adopted method of controlling cell attachment for cell patterning, pattern formation via cell proliferation and differentiation is demonstrated using precisely defined interface chemistry and spatial topology. The interface platform is created using a maleimide-functionalized parylene coating (maleimide-PPX) that provides two routes for controlled conjugation accessibility, including the maleimide-thiol coupling reaction and the thiol-ene click reaction, with a high reaction specificity under mild conditions. The coating technology is a prime tool for the immobilization of sensitive molecules, such as growth factor proteins. Conjugation of fibroblast growth factor 2 (FGF-2) and bone morphogenetic protein (BMP-2) was performed on the coating surface by elegantly manipulating the reaction routes, and confining the conjugation reaction to selected areas was accomplished using microcontact printing (μCP) and/or UV irradiation photopatterning. The modified interface provides chemically and topologically defined signals that are recognized by cultured murine preosteoblast cells for proliferation (by FGF-2) and osteogenesis (by BMP-2) activities in specific locations. The reported technique additionally enabled synergistic pattern formation for both osteogenesis and proliferation activities on the same interface, which is difficult to perform using conventional cell attachment patterns. Because of the versatility of the coating, which can be applied to a wide range of materials and on curved and complex devices, the proposed technology is extendable to other prospective biomaterial designs and material interface modifications.

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Electrically charged selectivity of poly-para-xylylene deposition

Sun

Liang

et al. 2016

Chem. Commun.

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The bottom-up patterning approach provides intrinsic advantages associated with unlimited resolution but is limited by the materials available for selection. A general and simple approach towards the selective deposition of poly-para-xylylenes is introduced in this communication. The chemical vapour deposition (CVD) of poly-para-xylylenes is inhibited on the high-energy surfaces of electrically charged conducting substrates. This technology provides an approach to selectively deposit poly-para-xylylenes irrespective of the substituted functionality and to pattern these polymer thin films from the bottom up.

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Fabrication of multipotent poly-para-xylylene particles in controlled nanoscopic dimensions

Yuan

Sun

et al. 2016

Colloids and Surfaces B: Biointerfaces

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Ho-Yi Sun

Construction and control of 3D porous structure based on vapor deposition on sublimation solids

Thiol‐Reactive Parylenes as a Robust Coating for Biomedical Materials

Topologically Controlled Cell Differentiation Based on Vapor-Deposited Polymer Coatings

Electrically charged selectivity of poly-para-xylylene deposition

Fabrication of multipotent poly-para-xylylene particles in controlled nanoscopic dimensions

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