Recycling Materials for Sustainable DNA Origami Manufacturing

Overview

Journal Nano Lett

Publisher American Chemical Society

Specialty Biotechnology

Date 2024 Sep 24

PMID 39315689

Authors

Michael J Neuhoff

Yuchen Wang

Nicholas J Vantangoli

Michael G Poirier

Carlos E Castro

Wolfgang G Pfeifer

Affiliations

Soon will be listed here.

Abstract

DNA origami nanotechnology has great potential in multiple fields including biomedical, biophysical, and nanofabrication applications. However, current production pipelines lead to single-use devices incorporating a small fraction of initial reactants, resulting in a wasteful manufacturing process. Here, we introduce two complementary approaches to overcome these limitations by recycling the strand components of DNA origami nanostructures (DONs). We demonstrate reprogramming entire DONs into new devices, reusing scaffold strands. We validate this approach by reprogramming DONs with complex geometries into each other, using their distinct geometries to verify successful scaffold recycling. We reprogram one DON into a dynamic structure and show both pristine and recycled structures display similar properties. Second, we demonstrate the recovery of excess staple strands postassembly and fold DONs with these recycled strands, showing these structures exhibit the expected geometry and dynamic properties. Finally, we demonstrate the combination of both approaches, successfully fabricating DONs solely from recycled DNA components.

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