Origami Biosystems: 3D Assembly Methods for Biomedical Applications

Conventional assembly of biosystems has relied on bottom‐up techniques, such as directed aggregation, or top‐down techniques, such as layer‐by‐layer integration, using advanced lithographic and additive manufacturing processes. However, these methods often fail to mimic the complex three dimensional...

Full description

Saved in:
Bibliographic Details
Published in:Advanced biosystems 2018-12, Vol.2 (12), p.n/a
Main Authors: Bolaños Quiñones, Vladimir A., Zhu, Hong, Solovev, Alexander A., Mei, Yongfeng, Gracias, David H.
Format: Article
Language:English
Subjects:
biosensors
bio‐MEMS
drug delivery
minimally invasive surgery
robotics
self‐folding
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Conventional assembly of biosystems has relied on bottom‐up techniques, such as directed aggregation, or top‐down techniques, such as layer‐by‐layer integration, using advanced lithographic and additive manufacturing processes. However, these methods often fail to mimic the complex three dimensional (3D) microstructure of naturally occurring biomachinery, cells, and organisms regarding assembly throughput, precision, material heterogeneity, and resolution. Pop‐up, buckling, and self‐folding methods, reminiscent of paper origami, allow the high‐throughput assembly of static or reconfigurable biosystems of relevance to biosensors, biomicrofluidics, cell and tissue engineering, drug delivery, and minimally invasive surgery. The universal principle in these assembly methods is the engineering of intrinsic or extrinsic forces to cause local or global shape changes via bending, curving, or folding resulting in the final 3D structure. The forces can result from stresses that are engineered either during or applied externally after synthesis or fabrication. The methods facilitate the high‐throughput assembly of biosystems in simultaneously micro or nanopatterned and layered geometries that can be challenging if not impossible to assemble by alternate methods. The authors classify methods based on length scale and biologically relevant applications; examples of significant advances and future challenges are highlighted. Origami biosystems are an emerging class of integrated, multifunctional devices that are based on curved and folded geometries. In this review, the field is classified into biosystems of relevance to biomolecular assembly, biosensors, biomicrofluidics, cell and tissue engineering, drug delivery, and biorobotics, and relevant advances and challenges are discussed.
ISSN:2366-7478
2366-7478
DOI:10.1002/adbi.201800230