Probing temperature-responsivity of microgels and its interplay with a solid surface by superresolution microscopy and numerical simulations

TL;DR

This study combines superresolution microscopy and simulations to explore how microgels respond to temperature changes when anchored on different surfaces, revealing surface-dependent structural behaviors and validating a high-resolution monitoring approach.

Contribution

It is the first to investigate microgel temperature response on hydrophilic and hydrophobic surfaces using combined microscopy and simulations, establishing a new platform for complex system analysis.

Findings

Microgels on hydrophilic surfaces show unperturbed structure and match bulk simulations.

On hydrophobic surfaces, microgels spread and compete at the interface based on hydrophobic strengths.

Experiments and simulations show remarkable agreement, validating the methodology.

Abstract

Superresolution microscopy has become a powerful tool to investigate the internal structure of complex colloidal and polymeric systems, such as microgels, at the nanometer scale. The ability to monitor microgels response to temperature changes in situ opens new and exciting opportunities to design and precisely control their behaviour for various applications. When performing advanced microscopy experiments, interactions between the particle and the environment can be important. Often microgels are deposited on a substrate since they have to remain still for several minutes during the experiment. This study uses dSTORM microscopy and advanced coarse-grained molecular dynamics simulations to investigate, for the first time, how individual microgels anchored on hydrophilic and hydrophobic surfaces undergo their volume phase transition in temperature. We find that, in the presence of a hydrophilic substrate, the structure of the microgel is unperturbed and the resulting density profiles quantitatively agree with simulations performed in bulk conditions. Instead, when a hydrophobic surface is used, the microgel spreads at the interface and an interesting competition between the two hydrophobic strengths -- monomer-monomer vs monomer-surface -- comes into play at high temperatures. The remarkable agreement between experiments and simulations makes the present study a fundamental step to establish this high-resolution monitoring technique as a platform for investigating more complex systems, being these either macromolecules with peculiar internal structure or nanocomplexes where molecules of interest can be encapsulated in the microgel network and controllably released with temperature.