Rational Polymer Design Gives Access to Soft Matter Nanoparticle Libraries
Team of international researchers of molecular materials combined theoretical and experimental expertise to develop design rules for complex self-assembled nanosystems.
Collaboration between Aalto University, Department of Applied Physics (Prof. Olli Ikkala, Dr. André Gröshel and coworkers), University of Pau, France (Dr. Oleg Borisov) and University of Mainz, Germany (Prof. Axel Müller), created highly uniform particle species with predictable and defined geometries as well as controlled surface pattern.
As working horse for the study, they used ABC Triblock Terpolymers, i.e. polymers consisting of three chemically different polymer segments. In the segments each block was assigned to a distinct function: one block forms the particle core, one the surface patch, and one stabilizes the superstructure. Synthetic variation of the block lengths allowed the independent combinatorial screening of micelle geometries and surface patch morphology. In this way, the researchers could reveal a library of 13 mostly unknown nanostructures including spotted spherical nanoparticles, cylindrical double helices, perforated discs and striped vesicles (polymersomes), amongst others (see Figure 1) using advanced 3D transmission electron microscopy techniques.
Figure 1: Overview of nanoparticle library with distinct patch geometries.Scale bars are 200 nanometers.
Knowledge of the underlying assembly mechanisms might open the door for future applications, where particles or templates are required with controlled geometry and nanoscale resolution.
For instance, vesicular polymer structures with perforated membrane might be useful as transport vehicles for the simultaneous storage of multiple drugs, vitamins or preserving agents, and the selective release at specific target sites (e.g. tumour environment). Spherical particles with precise number of addressable surface spots could function as virus mimics or for controlled co-assembly with plasmonic particles, while helical cylinders could even lead to chiral plasmonics.
Research article:
Rational design of ABC triblock terpolymer solution nanostructures with controlled patch morphology.
Tina I. Löbling, Oleg Borisov, Johannes S. Haataja, Olli Ikkala, André H. Gröschel, Axel H. E. Müller.
Nature Communications, Volume 7.
More Information
Academy Professor Olli Ikkala
Department of Applied Physics, Aalto University
olli.ikkala@aalto.fi
Professor Dr. André Gröschel
Physical Chemistry and Centre for Nanointegration Duisburg-Essen
University of Duisburg-Essen
andre.groeschel@uni-due.de
Read more news
Finnish wood-based innovations on display in London
The exhibition showcases Finnish bioeconomy solutions for both industry and everyday consumer life. Origami-based FOLD materials offer more sustainable solutions not only for packaging but also for many other applications.
Energy poverty is not recognized in Finland
According to a recent study by Aalto University and the Finnish Environment Institute, about 7–15 percent of Finnish households are energy poor, which at most means around 300,000 homes.
The exhibition "Our land, for all" explores personal and national identity
The 20th anniversary exhibition of the Association of Finnish Fine Arts Foundations, opened at Kunsthalle Helsinki, asks: whose stories is Finland built from? The exhibition has been curated by PhD, docent Annamari Vänskä.