Biomolecules, Biomaterials & Biointerfaces
Biomolecules, Biomaterials & Biointerfaces
Image of four DPN-patterned proteins, each tagged with a unique fluorophore |
Overview
NanoInk’s Dip Pen Nanolithography® (DPN®) technology is a direct write, tip based lithography technique that does not subject biological materials to destructive forces (such as compression, shear, harsh vacuum, or UV light) which might alter their structure and function. As such, DPN is ideal for printing proteins, DNA/RNA, aptamers, lipids, additional biopolymers and biocompatible polymers at micron and sub-micron scales. With the precision of DPN, these sub-cellular scaled features can be deposited at defined locations in a controlled and consistent manner. This allows for creation of scaffolds for in vitro cell culture studies or tissue engineering work.
Problem, Challenges & Un-Met Needs
Unlike DPN, most conventional deposition techniques are unable to pattern biomolecules, biopolymers or biocompatible polymers at biologically significant scales and dimensions. Many patterning platforms are limited in the sorts of material they can print and the ability to precisely pattern existing topographies. With this hindrance, traditional platforms experience difficulty when trying to conduct combinatorial studies that mimic physical and chemical cues, but DPN has proven to be a valuable tool for this type of work.
AFM image of DPN-deposited PEG hydrogel nanostructures |
Benefits of DPN
- Flexible patterning: deposit a wide range of materials onto surfaces that have regular, pre-fabricated topographies
- Rapid design, iteration and fabrication of biointerfaces: pattern various biomolecules and biomaterials
- Quick and easy mimicry of natural structures (in terms of form and function): create multi-level, multi-component patterns by printing in layers, with each new layer registered prior to successive layer deposition
- Biocompatible patterning: preserve structural integrity and function of deposited biomaterials
- Multiplexed deposition capabilities: print many biomaterials simultaneously
- Large-area patterning: print biomaterials over a 4 cm x 4 cm square area
Applications
The NanoInk DPN platform is ideal for:
- Biomolecular patterning applications that involve deposition of proteins, DNA, RNA, aptamers, and lipids
- Biomaterial patterning applications involving hydrogels and other biocompatible polymers
- Medical device functionalization
- Tissue engineering applications
Application Notes
Multiplexed Protein Arrays
Patterning Functional Hydrogels
Bioconjugation on Functional Hydrogels
Fabricating Large Scale Biomolecular Nanoarrays New!
Patterning Functional Hydrogels
Bioconjugation on Functional Hydrogels
Fabricating Large Scale Biomolecular Nanoarrays New!
Posters
Direct Deposition of Functional Hydrogels with Subcellular Resolution
Fabrication of Functional Hydrogel Nanostructures for Biomolecule Conjugations
Patterning and Topographical Control of PEG Hydrogel Micro/Nanostructure by Dip Pen Nanolithography
Tip Based Printing of Functionalized Hydrogels Microscale Patterns
Uniform Printing of PEG Hydrogel Arrays by Dip Pen Nanolithography
Fabrication of Functional Hydrogel Nanostructures for Biomolecule Conjugations
Patterning and Topographical Control of PEG Hydrogel Micro/Nanostructure by Dip Pen Nanolithography
Tip Based Printing of Functionalized Hydrogels Microscale Patterns
Uniform Printing of PEG Hydrogel Arrays by Dip Pen Nanolithography
Publications/References
Modifying network chemistry in thiol-acrylate photopolymers through postpolymerization functionalization to control cell-material interactions. Rydholm, Amber E., et al. 1, July 2007, Journal of Biomedical Materials Research Part A, Vol. 86, pp. 23-30
© Copyright 2012 NanoInk
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