Online coupling of microchip electrophoresis with ion mobility spectrometry for direct analysis of complex liquid samples. Masár M., Hradski J., Nováková M., Szucs R., Sabo M., Matejčík Š., Sensors and Actuators B: Chemical 2020, 302, 127183. (2019: 7.100 - IF, Q1 – JCR, Q1 – SJR)

Sequential Determination of Inorganic Cations and Anions in Cerebrospinal Fluid by Microchip Electrophoresis. Hradski J., Masár M., Bodor R., Chromatographia 2014, 77, 1461-1468. (2014: 1.411 - IF, Q3 – JCR, Q2 – SJR)

Quantitative aspects of microchip isotachophoresis for high precision determination of main components in pharmaceuticals. Hradski J., Chorváthová Drusková M., Bodor R., Sabo M., Matejčík Š., Masár M., Analytical and Bioanalytical Chemistry 2016, 408, 8669-8679. (2016: 3,431 - IF, Q1 - JCR, Q1 - SJR)

Direct liquid sampling for corona discharge ion mobility spectrometry. Sabo M., Malásková M., Harmathová O., Hradski J., Masár M., Radjenović B., Matejčík Š., Analytical Chemistry 2015, 87, 7389-7394. (2015: 5.886 - IF, Q1 -JCR, Q1 - SJR)

Advantages and pitfalls of capillary electrophoresis of pharmaceutical compounds and their enantiomers in complex samples: Comparison of hydrodynamically opened and closed systems. Masár M., Hradski J., Schmid M.G., Szucs R., International Journal of Molecular Sciences 2020, 21, 6852. (2019: 4.556 - IF, Q1 – JCR, Q1 – SJR)

Development of microchip isotachophoresis coupled with ion mobility spectrometry and evaluation of its potential for the analysis of food, biological and pharmaceutical samples. Hradski J., Ďuriš M., Szücs R., Moravský L., Matejčík Š., Masár M., Molecules 2021, 26, 6094. (2021: 4.927 - IF, Q2 - JCR, Q2 - SJR)

Microchip isotachophoresis for green and sustainable pharmaceutical quality control: Method validation and application to complex pharmaceutical formulations. Ďuriš M., Hradski J., Szücs R., Masár M., Journal of Chromatography A 2024, 1729, 465055. (2023: 3.8, Q1 - JCR, Q1 - SJR)

Online coupling of microchip electrophoresis with ion mobility spectrometry for direct analysis of complex liquid samples. Masár M., Hradski J., Nováková M., Szucs R., Sabo M., Matejčík Š. Sensors and Actuators B: Chemical 2020, 302, 127183. (2019: 7.100 - IF, Q1 – JCR, Q1 – SJR)

Development of microchip isotachophoresis coupled with ion mobility spectrometry and evaluation of its potential for the analysis of food, biological and pharmaceutical samples. Hradski J., Ďuriš M., Szucs R., Moravský L., Matejčík Š., Masár M. Molecules 2021, 26, 6094. (2021: 4,927 - IF, Q1 - JCR, Q1 - SJR)

Advantages and pitfalls of capillary electrophoresis of pharmaceutical compounds and their enantiomers in complex samples: Comparison of hydrodynamically opened and closed systems. Masár M., Hradski J., Schmid M.G., Szucs R. International Journal of Molecular Sciences 2020, 21, 6852. (2019: 4.556 - IF, Q1 – JCR, Q1 – SJR)

Microchip isotachophoresis coupled to surface-enhanced Raman spectroscopy for pharmaceutical analysis. Masár M., Troška P., Hradski J., Talian I. Microchimica Acta 2020, 187, 448. (2019: 6.232 - IF, Q1 – JCR, Q1 – SJR)

Determination of carminic acid in foodstuffs and pharmaceuticals by microchip electrophoresis with photometric detection. Masár M., Hradski J., Vargová E., Miškovčiková A., Božek P., Ševčík J., Szucs R. Separations 2020, 7, 72. (2020: 1.900 – IF, Q3 – JCR, Q3 – SJR)

Development of microchip isotachophoresis coupled with ion mobility spectrometry and evaluation of its potential for the analysis of food, biological and pharmaceutical samples. Hradski J., Ďuriš M., Szücs R., Moravský L., Matejčík Š., Masár M., Molecules 2021, 26, 6094. (2021: 4.927 - IF, Q2 - JCR, Q2 - SJR)

Microchip isotachophoresis for green and sustainable pharmaceutical quality control: Method validation and application to complex pharmaceutical formulations. Ďuriš M., Hradski J., Szücs R., Masár M., Journal of Chromatography A 2024, 1729, 465055. (2023: 3.8, Q1 - JCR, Q1 - SJR)

Online coupling of microchip electrophoresis with ion mobility spectrometry for direct analysis of complex liquid samples. Masár M., Hradski J., Nováková M., Szucs R., Sabo M., Matejčík Š., Sensors and Actuators B: Chemical 2020, 302, 127183. Citácia/citation: On-line coupling of chip-electrochromatography and ion mobility spectrometry. Hartner N.T., Raddatz C.-R., Thoben C., Piendl S.K., Analytical Chemistry 2020, 92, 15129-15136.

Sequential Determination of Inorganic Cations and Anions in Cerebrospinal Fluid by Microchip Electrophoresis. Hradski J., Masár M., Bodor R., Chromatographia 2014, 77, 1461-1468. Citácia/citation: Capillary electrophoresis of small ions and molecules in less conventional human body fluid samples: A review. Kubáň P., Dvořák M., Kubáň P., Analytica Chimica Acta 2019, 1075, 1-26.

Sequential Determination of Inorganic Cations and Anions in Cerebrospinal Fluid by Microchip Electrophoresis. Hradski J., Masár M., Bodor R., Chromatographia 2014, 77, 1461-1468. Citácia/citation: Triple-channel portable capillary electrophoresis instrument with individual background electrolytes for the concurrent separations of anionic and cationic species. Mai T.D., Le M.D., Saiz J., Duong H.A., Koenka I.J., Pham H.V., Hauser P.C., Analytica Chimica Acta 2016, 911, 121-128.

Quantitative aspects of microchip isotachophoresis for high precision determination of main components in pharmaceuticals. Hradski J., Chorváthová Drusková M., Bodor R., Sabo M., Matejčík Š., Masár M., Analytical and Bioanalytical Chemistry 2016, 408, 8669-8679. Citácia/citation: Recent advances in enhancing the sensitivity of electrophoresis and electrochromatography in capillaries and microchips (2016–2018). Breadmore M.C., Grochocki W., Kalsoom U. et al., Electrophoresis 2019, 40, 17-39. 

Quantitative aspects of microchip isotachophoresis for high precision determination of main components in pharmaceuticals. Hradski J., Chorváthová Drusková M., Bodor R., Sabo M., Matejčík Š., Masár M., Analytical and Bioanalytical Chemistry 2016, 408, 8669-8679. Citácia/citation: Analysis of small molecule drugs, excipients and counter ions in pharmaceuticals by capillary electromigration methods – recent developments. Zhu Q., Scriba G.K.E., Journal of Pharmaceutical and Biomedical Analysis 2018, 147, 425-438.

VEGA 1/0787/18: Development of new techniques for the treatment of biomedical and environmental samples for advanced combined analytical methods, 2019-2020, researcher. Basic research project, solved in cooperation with the Institute of Chemistry of the Slovak Academy of Sciences in Bratislava, focused on the development of new sample preparation techniques for advanced combined analytical methods based on electroseparations, liquid chromatography, mass spectrometry and nuclear magnetic resonance for trace analysis of low- and high-molecular ionogenic substances in biomedical and environmental samples.

APVV-17-0318: Application possibilities of new orthogonal miniaturized and microseparation analytical systems for rapid monitoring of biological, environmental and forensic samples, 2018-2022, researcher. Application-oriented project, solved in cooperation with the Department of Experimental Physics at the Faculty of Mathematics, Physics and Informatics, Comenius University in Bratislava, focused on studying the application possibilities of new orthogonal miniaturized and microseparation analytical systems for rapid monitoring of biological, environmental and forensic samples and creating a new concept of combined microseparation. techniques based on liquid chromatography and electrophoresis with ion mobility spectrometry.

VEGA 1/0116/22: Integration of new miniaturized analytical systems in the treatment, analysis and preparation of complex biological, environmental and pharmaceutical samples, 2022-2024, researcher. The project deals with the development of new miniaturized analytical systems for treatment, analysis and preparation of biological, environmental and pharmaceutical samples. The goal of the project is the implementation of originally developed microextraction techniques for sample preparation and minorly used miniaturized detection techniques in microseparation analytical systems to improve the detection and identification possibilities for the determination of trace analytes in ionogenic matrices. Based on electrokinetic and chromatographic fractionation, experimental protocols will be developed to simplify the analysis of complex samples. The project also includes the development of new computer protocols for predicting the chromatographic and mobility characteristics of selected environmental contaminants, active components of pharmaceutical preparations with antiviral and antibacterial effects, and biomarkers of various diseases in body fluids.

APVV-22-0133: Green laboratory for the analysis and characterization of pharmaceuticals and

bioactive substances, 2023-2027, researcher. A project focused on the development of an analytical methodology for the overall characterization of active pharmaceutical substances, pharmaceutical products and other bioactive substances, which meets the conditions of green analytical chemistry and will help contribute to the achievement of "Net Zero" goals. As part of the project, key miniaturized analytical technologies based on electrokinetic phenomena and associated with highly sensitive and selective detection systems, ion mobility spectrometry and Raman spectrometry will be optimized. These technologies will meet the conditions of international recommendations for the performance of analytical methods intended for the control of medicinal products for human consumption, e.g. ICH. Complex samples of a biological nature will also be analyzed by multidimensional separation systems, combining various separation mechanisms, including sample preparation and concentration procedures.