TY - JOUR
T1 - Self-folding polymeric containers for encapsulation and delivery of drugs
AU - Fernandes, Rohan
AU - Gracias, David H.
N1 - Funding Information:
This work was supported by the NSF CBET-1066898 grant and the NIH Director's New Innovator Award Program , part of the NIH Roadmap for Medical Research, through grant number 1-DP2-OD004346-01 . Information about the NIH Roadmap can be found at http://nihroadmap.nih.gov . The authors acknowledge helpful suggestions from Yevgeniy V. Kalinin and thank Kate Laflin for suggestions and help with the illustrations.
PY - 2012/11
Y1 - 2012/11
N2 - Self-folding broadly refers to self-assembly processes wherein thin films or interconnected planar templates curve, roll-up or fold into three dimensional (3D) structures such as cylindrical tubes, spirals, corrugated sheets or polyhedra. The process has been demonstrated with metallic, semiconducting and polymeric films and has been used to curve tubes with diameters as small as 2. nm and fold polyhedra as small as 100. nm, with a surface patterning resolution of 15. nm. Self-folding methods are important for drug delivery applications since they provide a means to realize 3D, biocompatible, all-polymeric containers with well-tailored composition, size, shape, wall thickness, porosity, surface patterns and chemistry. Self-folding is also a highly parallel process, and it is possible to encapsulate or self-load therapeutic cargo during assembly. A variety of therapeutic cargos such as small molecules, peptides, proteins, bacteria, fungi and mammalian cells have been encapsulated in self-folded polymeric containers. In this review, we focus on self-folding of all-polymeric containers. We discuss the mechanistic aspects of self-folding of polymeric containers driven by differential stresses or surface tension forces, the applications of self-folding polymers in drug delivery and we outline future challenges.
AB - Self-folding broadly refers to self-assembly processes wherein thin films or interconnected planar templates curve, roll-up or fold into three dimensional (3D) structures such as cylindrical tubes, spirals, corrugated sheets or polyhedra. The process has been demonstrated with metallic, semiconducting and polymeric films and has been used to curve tubes with diameters as small as 2. nm and fold polyhedra as small as 100. nm, with a surface patterning resolution of 15. nm. Self-folding methods are important for drug delivery applications since they provide a means to realize 3D, biocompatible, all-polymeric containers with well-tailored composition, size, shape, wall thickness, porosity, surface patterns and chemistry. Self-folding is also a highly parallel process, and it is possible to encapsulate or self-load therapeutic cargo during assembly. A variety of therapeutic cargos such as small molecules, peptides, proteins, bacteria, fungi and mammalian cells have been encapsulated in self-folded polymeric containers. In this review, we focus on self-folding of all-polymeric containers. We discuss the mechanistic aspects of self-folding of polymeric containers driven by differential stresses or surface tension forces, the applications of self-folding polymers in drug delivery and we outline future challenges.
KW - Controlled release
KW - Hydrogels
KW - Lithography
KW - Origami
KW - Spatio-temporal
KW - Three dimensional
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U2 - 10.1016/j.addr.2012.02.012
DO - 10.1016/j.addr.2012.02.012
M3 - Review article
C2 - 22425612
AN - SCOPUS:84868212801
SN - 0169-409X
VL - 64
SP - 1579
EP - 1589
JO - Advanced Drug Delivery Reviews
JF - Advanced Drug Delivery Reviews
IS - 14
ER -