Bioanalytical Instrumentation - František Foret

Research areas

• Capillary separations
• Mass spectrometry coupling
• Miniaturisation
• Single cell analysis

Main objectives

Development of novel techniques for the separation and analysis of nucleic acids, proteins, small bio active molecules & drugs and their complexes based on electrophoretic and microfluidic systems, electrochemical and optical methods and nanotechnologies.

Content of research

Exploring new ways of achieving enhancements in resolution, sensitivity and selectivity of analyses. Utilization of theoretical and instrumental approaches for the development and applications of microfluidics, nanotechnologies and novel chemistries. Research of novel techniques for the separation and analysis of nucleic acids, proteins, small bioactive molecules and drugs and their complexes using electrophoretic and microfluidic systems coupled with electrochemical, optical and mass spectrometric methods.

• Microseparation systems for the analysis of biomolecules will be developed utilising combination of microfluidic chips and structured nanoparticles including quantum dots, magnetically activated tags; enzymatic and nanoparticle modified monolithic supports.
• New detection principles, based on surface signal enhancement (e.g. surface plasmon, Raman, fluorescence, electrochemistry) will be combined with the newly developed separations. These technologies and instrumentation will be developed for joint applications with other investigators at CEITEC.
• Technologies for microanalyses of proteins and their glycosylation will be focused on the combination of electrochemistry, microfludic biosensors and mass spectrometry for analysis of limited sample quantities. The ultimate goal of single-cell analysis will be aimed at potential application in cancer detection.

list / cards

Name and position	E-mail	Phone
František Foret Research Group Leader		+420 532 290 242
Petr Kubáň, Ph.D. Researcher		+420 532 290 142
Lucie Němcová Assistant		+420 54949 4482
Júlia Lačná PhD Student		+420 532 290 232
Pavol Ďurč PhD Student		+420 532 290 232
Michal Greguš PhD student		+420 532 290 232

SELECTED PUBLICATIONS

2017

• LACNA, J; FORET, F; KUBAN, P, 2017:Sensitive determination of malondialdehyde in exhaled breath condensate and biological fluids by capillary electrophoresis with laser induced fluorescence detection. Talanta 169 , p. 85 - 90.

2016

• GREGUS, M; FORET, F; KUBAN, P, 2016:Portable capillary electrophoresis instrument with contactless conductivity detection for on-site analysis of small volumes of biological fluids. JOURNAL OF CHROMATOGRAPHY A 1427 , p. 177 - 185.
• JURIK, T; PODESVA, P; FARKA, Z; KOVAR, D; SKLADAL, P; FORET, F, 2016:Nanostructured gold deposited in gelatin template applied for electrochemical assay of glucose in serum. ELECTROCHIMICA ACTA 188 , p. 277 - 285.
• TYCOVA, A; VIDO, M; KOVARIKOVA, P; FORET, F, 2016:Interface-free capillary electrophoresis-mass spectrometry system with nanospray ionization Analysis of dexrazoxane in blood plasma. JOURNAL OF CHROMATOGRAPHY A 1466 , p. 173 - 179.

2015

• BASOVA, EY; FORET, F, 2015:Droplet microfluidics in (bio)chemical analysis. ANALYST 140 (1), p. 22 - 38.
• HODAKOVA, J; PREISLER, J; FORET, F; KUBAN, P, 2015:Sensitive determination of glutathione in biological samples by capillary electrophoresis with green (515 nm) laser-induced fluorescence detection. JOURNAL OF CHROMATOGRAPHY A 1391 , p. 102 - 108.
• JARVAS, G; GUTTMAN, A; FORET, F, 2015:Numerical modeling of capillary electrophoresis - electrospray mass spectrometry interface design. MASS SPECTROMETRY REVIEWS 34 (5), p. 558 - 569.
• KARASEK, P; GRYM, J; ROTH, M; PLANETA, J; FORET, F, 2015:Etching of glass microchips with supercritical water. LAB ON A CHIP 15 (1), p. 311 - 318.
• TYCOVA, A; FORET, F, 2015:Capillary electrophoresis in an extended nanospray tip-electrospray as an electrophoretic column. JOURNAL OF CHROMATOGRAPHY A 1388 , p. 274 - 279.

2014

• KUBAN, P; DURC, P; BITTOVA, M; FORET, F, 2014:Separation of oxalate, formate and glycolate in human body fluid samples by capillary electrophoresis with contactless conductometric detection. JOURNAL OF CHROMATOGRAPHY A 1325 , p. 241 - 246.
• KUBAN, P; GREGUS, M; POKOJOVA, E; SKRICKOVA, J; FORET, F, 2014:Double opposite end injection capillary electrophoresis with contactless conductometric detection for simultaneous determination of chloride, sodium and potassium in cystic fibrosis diagnosis. JOURNAL OF CHROMATOGRAPHY A 1358 , p. 293 - 298.
• KUBAN, P; TIMERBAEV, AR, 2014:Inorganic analysis using CE: Advanced methodologies to face old challenges. ELECTROPHORESIS 35 (1), p. 225 - 233.

2013

• KRENKOVA, J; SZEKRENYES, A; KERESZTESSY, Z; FORET, F; GUTTMAN, A, 2013:Oriented immobilization of peptide-N-glycosidase F on a monolithic support for glycosylation analysis. JOURNAL OF CHROMATOGRAPHY A 1322 , p. 54 - 61.
• KUBAN, P; FORET, F, 2013:Exhaled breath condensate: Determination of non-volatile compounds and their potential for clinical diagnosis and monitoring. A review. ANALYTICA CHIMICA ACTA 805 , p. 1 - 18.

2012

• HEZINOVA, V; ATURKI, Z; KLEPARNIK, K; D'ORAZIO, G; FORET, F; FANALI, S, 2012:Simultaneous analysis of cocaine and its metabolites in urine by capillary electrophoresis-electrospray mass spectrometry using a pressurized liquid junction nanoflow interface. ELECTROPHORESIS 33 (4), p. 653 - 660.
• KRENKOVA, J; FORET, F; SVEC, F, 2012:Less common applications of monoliths: V. Monolithic scaffolds modified with nanostructures for chromatographic separations and tissue engineering. JOURNAL OF SEPARATION SCIENCE 35 (42318), p. 1266 - 1283.
• PRIKRYL, J; KLEPARNIK, K; FORET, F, 2012:Photodeposited silver nanoparticles for on-column surface-enhanced Raman spectrometry detection in capillary electrophoresis. JOURNAL OF CHROMATOGRAPHY A 1226 , p. 43 - 47.

2011

• JUSKOVA, P; FORET, F, 2011:Application of thin metal film elements in bioanalysis. JOURNAL OF SEPARATION SCIENCE 34 (20), p. 2779 - 2789.
• KLEPARNIK, K; VORACOVA, I; LISKOVA, M; PRIKRYL, J; HEZINOVA, V; FORET, F, 2011:Capillary electrophoresis immunoassays with conjugated quantum dots. ELECTROPHORESIS 32 (10), p. 1217 - 1223.

GRANTY

• Center for advanced bioanalytical technologies (GBP206/12/G014), Czech Science Foundation - Projects for promotion of excellence in basic research, 2012 - 2018
• New methods of analysis of proteins and their glycosylation in cancer – combination of electrochemistry, microfludic biosensors and mass spectrometry (GAP301/11/2055), Czech Science Foundation - Standard Grants, 2011 - 2015
• Development of Multidisciplinary Research and Educational Centrum for Bioanalytical Technologies (CZ.1.07/2.3.00/20.0182), MEYS - OP Education for Competiteveness, 2012 - 2014
• OnkoDetect – system for early detection of cancer markers in peripheral blood of patients (TA02010672), Technology Agency of the Czech Rep. - ALFA, 2012 - 2016

CURRENT RESEARCH INFRASTRUCTURE

The current research infrastructure includes instrumentation for mass spectrometry and the separation and characterization of biomolecules.

1. Application of modern microcolumn separation methods coupled to mass spectrometry for analysis of non-invasive biological samples

Supervisor: doc. RNDr. Petr Kubáň, Ph.D.
Consultants: Ing. František Foret, CSc.

Annotation:

Current clinical analysis relies mainly on the analysis of invasively acquired samples, such as blood, blood serum, blood plasma, cerebrospinal fluid etc. In recent years, the use of non-invasively acquired, alternative samples has seen a significant scientific interest since such a sample can be obtained easily and does not cause stress to the patient. Non-ivasive samples, such as saliva, sweat or exhaled breath condensate can serve as pools of selected biomarkers used to diagnose various disease conditions. For instance use of exhaled breath condensate samples the microdroplets of alveolar lining fluid that can contain information on the lung status. Recently there is an increased interest in the use of exosomes, that are in all bodily fluids including the non-invasive samples and carry along significant information. The use of highly selective microcolumn separation methods coupled to MS allow screening for these biomarkers in selected body fluid samples. The research of this PhD. topic will focus on developemnt of highly selective methods for isolation and analysis of various body samples, with emphasis on noninvasive samples and targeting biomarkers for disease daignostics and monitoring.

Keywords: non-invasive samples, microcolumn separation methods, targeting biomarkers, mass spectrometry