Bob Pirok wins Csaba Horváth Young Scientist Award 2017

Using the MANIAC method for nanoparticle analysis

27 June 2017

At the HPLC2017 international symposium on high performance liquid-phase separations, held 18-22 June in Prague, PhD researcher Bob Pirok of the Van 't Hoff Institute for Molecular Sciences has won the Csaba Horváth Young Scientist Award, an important prize in the field of Analytical Chemistry.

Pirok outcompeted nine other finalists with his lecture on “Extended multi-dimensional liquid-chromatography systems for comprehensive analysis of complex polymeric nanoparticles”. He presented the use of the novel, comprehensive MANIAC analysis method for the characterization of complex nanoparticles. MANIAC, an acronym for Making Analytically Incompatible Approaches Compatible, was developed at HIMS and CASA, the Centre for Analytical Sciences Amsterdam.

Making the incompatible compatible

MANIAC aims to combine completely different and (seemingly) incompatible separation and characterization systems into a single highly efficient and extensively optimized instrument. It encompasses the integration of various chemical, physical and microbial processes with (multi-dimensional) separation systems. At HPLC2017, Bob Pirok discussed its application in the field of complex polymeric nanoparticles that are, for example, encountered in various coatings (decorative, antireflective and anti-microbial), and drug delivery systems.

Gallery of different types of nanoparticles, distinguished by composition and and surface charge. Image: HIMS.

Samples containing nanoparticles feature a multitude of parameters, such as particle-size distribution, surface composition, molecular weight and chemical composition. A successful technique for the separation of such complex mixtures is comprehensive two-dimensional liquid chromatography (LC×LC). In LC×LC, a modulator is used to couple the two separation dimensions with different time scales (spanning about two orders of magnitude). The potential of modulators can be further enhanced by allowing fast, controlled chemical reactions to take place.

Proof of principle

Pirok and co-workers first use hydrodynamic chromatography (HDC) to separate the nanoparticles based on size. Next, the modulator is used to dissolve the nanoparticles, yielding a homogeneous molecular solution for each separated fraction. The molecules are then separated in the second dimension based on their chemical composition, by liquid chromatography (LC) or two-dimensional liquid chromatography (LC×LC), in combination with MS detection when appropriate.

Proof of principle: separation of polystyrene and PMMA nanoparticle samples. Image: HIMS.

A successful application of the complex interplay of the above-mentioned techniques faces a number of challenges (including solvent and sample incompatibility between the two dimensions). As Pirok demonstrated, these can be overcome by applying the MANIAC approach. He presented proof-of-principle with the analysis of polystyrene and PMMA nanoparticle samples.


The MANIAC project is part of the Technology Area “Comprehensive Analytical Science and Technology” (COAST), a public-private partnership of the Netherlands Organisation for Scientific Research NWO with industrial partners. Prof. Peter Schoenmakers (UvA-HIMS) is the principal investigator and Prof. Ron Peters (DSM, part-time professor at the UvA) acts as MANIAC project manager.

Other academic institutions involved are Radboud University (Prof. Arno Kentgens), VU University Amsterdam (Prof. Govert Somsen) and the University of Groningen (Prof. Elisabeth Verpoorte). Private partners are Heineken, Shell, DSM en Micronit Microfluidics. The total project budget is 1,065,000 euro.

Simultaneous determination of multiple sample properties often involves combining incompatible techniques. In the MANIAC project, interfaces are developed to solve these compatibility issues. Several examples are shown here. Image: HIMS.

Published by  HIMS