Abstract
Designing nanoparticles with desired properties is a challenging endeavor, due to the large combinatorial space and complex structure–function relationships. High throughput methodologies and machine learning approaches are attractive and emergent strategies to accelerate nanoparticle composition design. To date, how to combine nanoparticle formulation, screening, and computational decision-making into a single effective workflow is underexplored. In this study, we showcase the integration of three key technologies, namely microfluidic-based formulation, high content imaging, and active machine learning. As a case study, we apply our approach for designing PLGA-PEG nanoparticles with high uptake in human breast cancer cells. Starting from a small set of nanoparticles for model training, our approach led to an increase in uptake from ∼5-fold to ∼15-fold in only two machine learning guided iterations, taking one week each. To the best of our knowledge, this is the first time that these three technologies have been successfully integrated to optimize a biological response through nanoparticle composition. Our results underscore the potential of the proposed platform for rapid and unbiased nanoparticle optimization.
| Original language | English |
|---|---|
| Pages (from-to) | 1280-1291 |
| Number of pages | 12 |
| Journal | Digital Discovery |
| Volume | 3 |
| Issue number | 7 |
| Early online date | 3 Jun 2024 |
| DOIs | |
| Publication status | Published - 1 Jul 2024 |
Funding
We would like to thank Emiel Visser for providing the MATLAB script to automate the LSPOne pump and for an Eppendorf holder CAD design. We would also like to thank Stijn Haenen for 3D printing the Eppendorf holders. AOP and LA are supported by NWO through a Vidi Grant (192.028). RvdM is supported by a Vidi grant (19861) from the Dutch Research Council (NWO). FG acknowledges the support of the Centre for Living Technologies.
