Bioanalytical chemistry
Doctoral degree in full-time or combined form. The language of instruction is Czech.
The programme can be studied only as a single subject.
What will you learn?
The goal of study is the preparation of highly-qualified specialists for research work in the field of Bioanalytical Chemistry in academic and company environments including the accredited laboratories. The student will get necessary theoretical background and skills to realize his/her own research project in a research group under the guidance of a supervisor and be able to evaluate the obtained results. Modern instrumentation and experienced personnel at the Department of Biochemistry and at cooperating institutions create unique opportunities for student to be involved in numerous research activities concerning development of instrumental bioanalytical methods (separation methods with various types of detectors; biosensors combining different biological components with divergent detection principles) and immunochemistry and molecular biology based methods. Simultaneously, the student will be performing literature search using all resources of Masaryk University libraries. The research covers a wide spectrum of biological levels from whole organisms to tissues, cells and individual proteins. The palette of possibilities is broadened through long-term cooperation with several research institutions at home and abroad. Biochemistry is marked by its open and interdisciplinary character, the classical biochemical approaches being frequently combined with methodology from other disciplines such as microbiology, molecular biology, informatics, and biophysics. This increases graduates’ adaptability and their ability to apply acquired skills in working life. He/she will be ready to prepare the scientific presentations and publications using modern software tools.
“Biomacromolecules help to detect and determine other biologically important molecules.”
Practical training
Bioanalytical chemistry is dynamically developing field covering from biochemical, molecular biological and analytical approaches up the advanced experimental data evaluation. As many of the recent instrumentations and techniques are not available at the Department of Biochemistry, the students should during the doctoral studies spent some time at cooperating laboratories in Czech Republic or abroad. It should be taken as a form of practical training.
Further information
The Office for Doctoral Studies, Quality, Academic Affairs and Internationalization takes care of doctoral students SCI MU
https://www.sci.muni.cz/en/students/phd
On the department's website, you can find the following information:
- Forms (application forms for state examinations and defences, various applications, etc. )
- Legislation (links to: MU Study and Examination Regulations, Scholarship Regulations of MU, Terms of Scholarship Programmes of the Faculty of Science)
- Dissertations (Guidelines for dissertations, templates)
- Manuals (guidelines for Individual Study Plans, study and research obligations in DSP, etc.)
- Doctoral study programmes (recommended study plans, examination committees, overview of accredited programmes)
- Deadlines for the doctoral state examinations and defences
- Enrolment (information needed for the enrolment to the next semester)
- Graduation
but also office hours, contacts, news, information on skills development and scholarships.
Detailed information on stays abroad can be found on this website:
https://www.sci.muni.cz/en/students/phd/develop-your-skills/stay-abroad
Career opportunities
Graduates of this doctoral degree program will be prepared for the work in the biochemical, pharmaceutical, medicinal and veterinary laboratories with the orientation both on the basic and applied research. They can work in the specialised accredited laboratories, that increase their possibilities of the perspective employment in Czech Republic and abroad.
They may continue their academic career at universities and research institutions both in the Czech Republic and abroad. They will be qualified for team member and leadership positions in scientific research and development at private firms and biochemical laboratories at a broad range of institutions specializing in human or veterinary medicine, pharmaceuticals, agriculture, and biotechnology. The professional specialization of the graduates is also compatible with further work in the field of environmental protection and with environmental movements and initiatives.
Admission requirements
Data from the previous admission procedure (2 Jan – 15 Dec 2024)
the admission procedure for this programme aims to search and select the best-motivated candidates. The entrance exam has the form of an online interview. a committee of three academic staff evaluates professional experience, the ability to communicate in English and the motivation and readiness of the candidates.
The committee verifies and evaluates the level of professional knowledge and prerequisites of the candidate for independent scientific work in the field of doctoral research (0-200 points) and English language skills (0-100 points). Before submitting the application, the candidate must consult with the potential supervisor on the focus of his/her doctoral thesis. Its topic is then specified during the first semester of study.
More information about admission process for international applicants in general can be found in the section Admission Process.
Date of the entrance exam
The applicants will receive information about the entrance exam by e-mail usually at least 10 days before the exam.
Please, always check your e-mails, including spam folders.
Conditions of admission
To be accepted, the candidate must obtain at least 120 points in the expert part and at least 60 points in the language part of the examination.
Successful applicants are informed of their acceptance by e-mail and subsequently receive an invitation to the enrolment.
Programme capacity
The capacity of a given programme is not fixed; students are admitted based on a decision by the Doctoral Board after assessing their aptitude for study and motivation.
Study options
Single-subject studies
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Full-time studies in czech
What will you learn? -
Combined studies in czech
What will you learn?
Dissertation topics
Single-subject studies
Advanced immunochemical methods for clinical diagnostics
Supervisor: doc. Mgr. Zdeněk Farka, Ph.D.
OBJECTIVES: Immunochemical assays combine the specificity of antibodies with the sensitivity of various kinds of readout methods to allow detecting target molecules. The great flexibility, provided by the possibility to use antibodies specific to desired structure, allows detecting all sorts of analytes, from small molecules, through proteins, to viruses and bacteria. The aim of this thesis is the development of advanced immunochemical approaches for use in clinical diagnostics.
FOCUS: The research will focus on clinically relevant targets, including biomarkers (prostate cancer, breast cancer, acute myocardial infarction) and pathogens (Salmonella, SARS-CoV-2). In all these cases, the highly sensitive detection with low cross-reactivity is essential for rapid diagnosis, allowing early disease treatment.
METHODS: The particular choice of the detection method will be made with respect to the target analyte and sample matrix to maximize the potential for practical applications. The first tests will be carried out using conventional enzyme immunoassays due to their simplicity and robustness. Afterward, various ways to improve the assay performance will be explored. Nanoparticle-based labels will be exploited to allow detection based on their catalytic (e.g., Prussian blue nanoparticles) or luminescence (e.g., photon-upconversion nanoparticles or quantum dots) properties. The sample preconcentration will be carried out using magnetic micro- or nanoparticles. Furthermore, the potential for point-of-care analysis will be demonstrated on lateral flow immunoassays and optical or electrochemical biosensors. The close collaboration with the Faculty of Medicine and industrial partners promises that apart from writing scientific publications, the developed methods can also find commercial applications.
LITERATURE: https://www.muni.cz/en/people/357740-zdenek-farka/publications
PLEASE NOTE: Before initiating the formal application process to doctoral studies, the interested candidates should contact Zdeněk Farka (farka@mail.muni.cz) for an informal discussion.
Supervisor
Analysis of biologically important small molecules
Supervisor: Mgr. Marta Pelcová, Ph.D.
OBJECTIVES: Small molecules often regulate biological processes. Therefore such molecules with molecular weight up to 900 Da can be utilized as a research tool to study biological function. Some of them can modulate the function of specific proteins (e.g. enzymes), simply refer on protein activity (e.g. genomic variants and respective phenotypes), act as signal molecules in cell signalling pathways, or disrupt interactions protein-protein. Pharmacologically active molecules often behave as effectors changing the activity or function of its target. Thus drug metabolism studies can refer on a relevant enzyme activity which can be individually different. Many therapeutically active molecules have only narrow therapeutic range to be effective and safe as well. To evaluate their action any analytical method, which enables quantification of multiple targeted small molecules promotes research progress in many fields like biochemistry, pharmacology and clinical analysis. Contrary to large proteomic studies, this more traditional field of analysis has still its importance as many new effector molecules being developed.
FOCUS: Target small molecules will cover drugs of different classes, their metabolites or naturally occurring metabolites and clinically important markers in body fluids (blood, saliva, urine).
METHODS: Liquid separation methods (HPLC and capillary electrophoresis) with different detection techniques (UV-VIS, LIF and MS) or alternatively direct MS analysis will be employed. If possible, alternative sampling methods will be examined.
LITERATURE: https://is.muni.cz/auth/osoba/zeisbergerova#publikace
PLEASE NOTE: Before initiating the formal application process to doctoral studies, the candidate is required to contact Assistant Prof. Marta Pelcová for an informal discussion.
Supervisor
Developments and applications of novel microextraction techniques in analyses of complex samples
Supervisor: RNDr. Pavel Kubáň, DSc.
Experimentální část práce bude zahrnovat vývoj nových mikroextrakčních technik, které jsou založeny na selektivních přechodech analytů přes semi-permeabilní fázová rozhraní [1,2]. Při přechodu analytů bude využito difuze [1] nebo bude přechod urychlen účinkem elektrického pole [2]. Výsledné mikroextrakční techniky budou spojeny off-line nebo in-line s vhodnými analytickými metodami (primárně s kapilární elektroforézou) a adekvátnost takového spojení bude demonstrována analýzami biologicky, klinicky a toxikologicky významných analytů v reálných komplexních vzorcích jako je moč, krevní sérum/plasma a plná krev. [1] Kubáň, P., Boček, P., J. Chromatogr. A 1234 (2012) 2-8. [2] Kubáň, P., Šlampová, A., Boček, P., Electrophoresis 31 (2010) 768-785.
Supervisor
František Foret - Micro- and mezzo-fluidic instrumentation for enrichment of biological samples
Supervisor: Ing. František Foret, DSc.
FOCUS: Proof of principles of epitachophoresis for biology related samples; design and construction/modification of instrumentation for large volume sample processing. The topic is based on entirely new procedures currently in the state of patent application in the USA.
METHODS: epitachophoresis, MS, capillary electrophoresis and HPLC in combination with different detection techniques
LITERATURE: see WOS.
PLEASE NOTE: before initiating the formal application process to doctoral studies, all interested candidates should contact Ing. František Foret, CSc., e-mail: foret@iach.cz at CEITEC or Instute of nalytical Chemistry Academy of Science Czech Republic for informal discussion.
Supervisor
Characterization of hyaluronidase isolated from the fungus Talaromyces stipitatus
Supervisor: prof. RNDr. Petr Skládal, CSc.
Hyaluronan(HA) je lineární polysacharid z disacharidických jednotek kyseliny D-glukuronové a D-N-acetylglukosaminem. HA je štěpen na kratší fragmenty dvěma typy enzymů. Savčí hyaluronidázy hydrolyticky štěpí řetězce za vzniku menších fragmentů z nezměněných monosacharidů. Mikroorganismy produkují hyaluronan lyázy, které rovněž štěpí řetězce hyaluronanu beta–eliminační reakcí, při které na neredukujícím konci fragmentu vzniká kyselina glukuronová s dvojnou vazbu mezi C4 a C5. Houba Talaromyces stipitatus produkuje hyaluronidázu (TsHr), která štěpí hydrolyticky 1,4 glykosidickou vazbu. Ačkoli svojí primární strukturou je savčím hyaluronidázám podobná jen vzdáleně, patří do rodiny hydroláz glykosidických vazeb GH16, konečnými produkty jsou krátké fragmenty ze 4 až 6 monosacharidů. Předběžné výsledky s rekombinantní TsHr ukazují, že dokáže štěpit deriváty HA savčím enzymem neštěpitelné. TsHr je strukturně příbuzný s transglykosylázami, které patří do stejné rodiny. To by mohlo být využitelná v chemoenzymatických syntézách derivátů HA s definovanou polohou substituentů.
Cílem první části studia bude přispět k poznání TsHr po stránce kinetiky i mechanismu enzymatické reakce a porovnat získané výsledky se savčí bovinní testikulární hyaluronidázou. Bude studována inhibice TsHr různě dlouhými a modifikovanými fragmenty hyaluronanu. Poté by mělo být rozhodnuto, zda enzym TsHr spolu s dalšími enzymy bude využitelný při stanovování rozložení substituentů na řetězci derivátů HA. U savčích hydroláz byla prokázána transglykosylační aktivita - spojování kratších fragmentů HA na delší řetězce. Nikdo však neprokázal, že je to možné u fragmentů substituovaných vybranými substituenty v určitých polohách. Pokud se prokáže, že enzym TsHr není tak citlivý na substituci hyaluronanu jako savčí enzymy, bude zkoumána transglykosylační aktivita a případně hledány podmínky pro využití při syntéze derivátů HA.
Enzym štěpí vysokomolekulární hyaluronan na kratší fragmenty, čímž vytváří koktejl kratších fragmentů hyaluronanu v reakční směsi. Tyto nově vzniklé fragmenty jsou rovněž štěpeny hyaluronidázou, avšak pravděpodobně s jinými kinetickými parametry. Ve výsledku by se tento stav mohl jevit jako inhibice substrátem/produktem. V savčích organismech by toto mohla být cesta regulující rychlost degradace hyaluronanu ve tkáních. Toto by mohlo přispět jednak k potvrzení potenciální regulační role fragmentů a k poznání rozdílů mezi houbovým a savčím enzymem. Navíc v literatuře se popisují interakce různých fragmentů HA se savčím enzymem, které se odehrávají mimo aktivní centrum - projevuje se změnou kinetických parametrů.
Literatura:
L. Bobková, D. Smirnou, M. Krčmář, J. Kulhák, M. Hermannová, L. Franke, V. Velebný (2018) Discovery and characteristic of hyaluronidases from filamentous fungi. Current Biotechnology 7: 2.
Supervisor
Identification of changes in glutamatergic pathways specific for sporadic form of Alzheimer's disease in human astrocytes
Supervisor: doc. Mgr. Jan Lochman, Ph.D.
OBJECTIVE: Neurodegenerative foldopathies represent a group of human protein-misfolding disorders that are characterized by a pathological alteration in conformation of a native protein which makes it resistant to degradation and leads to pathological gain and loss of function. These are followed by aggregation of the misfolded proteins into insoluble deposits. One of the most prominent protein-misfolding disorders is AD. The number of patients suffering dementia in the Czech Republic is estimated at 160 thousand. Up to two-thirds of cases are due to Alzheimer's disease, others include, for example, vascular dementia, Parkinson's disease or other degenerative brain disorders.
FOCUS: In neurodegenerative disorders (including Alzheimer's disease, AD) astrocytes/astroglia undergo complex changes that range from atrophy with loss of function to accumulation of reactive cells around disease-specific lesions (senile plaques in the case of AD). The cellular pathology of astrocytes in the context of human AD remains enigmatic; mainly because of severe limitations of animal models, which, although reproducing some pathological features of the disease, do not mimic its progression in full. The human induced pluripotent stem cells (hiPSCs) technology creates a novel and potentially revolutionizing platform for studying fundamental mechanisms of the disease and for screening to identify new therapeutic compounds.
EXAMPLE of a potential doctoral project - the student will focus on: Suitable procedures for studying early pathology of Alzheimer's disease (AD) are currently being sought. The main aim of the project is to create a model of cell cultures suitable for monitoring changes in the biology of nerve cells (neurons and astrocytes) in patients with AD. Using the induced pluripotent cell method (iPSC), the role of nerve cells in the formation of sporadic form of AD will be studied.
- The specific aims are following:
- Analysis of DEGs (differently expressed genes) between patients and controls and measured physiological parameters in and between groups.
- Analysis of DEGs (differently expressed genes) between patients and controls and measured physiological parameters in and between groups.
- Verification of selected differences in genes expression by qPCR analysis.
- Verification of very promising candidate genes expression by Western Blot.
- Analysis of selected neurotransmitters by LC-MS/MS.
PLEASE NOTE: Before initiating the formal application process to doctoral studies, the candidate is required to contact Assoc. Prof. Jan Lochman for an informal discussion.
Supervisor
Jan Preisler - Applications of nanoparticles in mass spectrometry imaging
Supervisor: prof. Mgr. Jan Preisler, Ph.D.
EXAMPLES of doctoral projects:
- Development of sample preparation protocol for specific detection of selected markers on sections of 3D cell aggregates or other tissues.
- Optimization of specific labelling with nanoparticles. The specificity will be based on antibody-antigen and avidin-biotin interactions, aptamer bindings etc.
- Development of nanoparticle detection schemes using inductively coupled plasma (ICP) and matrix-assisted laser desorption/ionization (MALDI) techniques.
- Study of nanoparticle transport efficiency in ICP MS. Confocal fluorescence or electron microscopy will be used as a reference method.
MORE INFORMATION: bart.chemi.muni.cz
Supervisor
Jan Preisler - Mass spectrometry imaging
Supervisor: prof. Mgr. Jan Preisler, Ph.D.
EXAMPLES of doctoral projects:
- Development of sample preparation protocols for MALDI MSI. Samples may include 3D cell aggregates or other biological tissues.
- MALDI MSI of perifosine and other antitumor agents in 3D cell aggregates.
- Optimization of reactions on tissue sections. The aim will be, e.g., determination of double bond position in fatty acid chains in lipids.
MORE INFORMATION: bart.chemi.muni.cz
Supervisor
Petr Skládal - Nanoparticles for optical biosensors
Supervisor: prof. RNDr. Petr Skládal, CSc.
FOCUS: The target analytes will include metabolites and clinical markers in body fluids (serum, saliva), food and drinks (allergens, contaminants, toxins) and infectious microbes (honey bee pathogens, Salmonella, Enterobacteria).
METHODS: Bioconjugation and immobilization of biomolecules, characterization of bioconjugates and biointerfaces, ink-jet based microarrays, scanning probe microscopies, design of biosensing devices, advanced optical techniques, scanning probe microscopy, signal acquisition and processing, chemometrics, software development.
LITERATURE: https://www.muni.cz/en/people/2202-petr-skladal/publications
PLEASE NOTE: before initiating the formal application process to doctoral studies, all interested candidates should contact Petr Skladal (skladal@chemi.muni.cz) for informal discussion.
Supervisor
Preparation, study and detection of new palladium and ruthenium catalysts and fluorescent probes for bioorthogonal cancer therapy
Supervisor: Mgr. Vladimír Pekařík, Dr.
Bioortogonální aktivace pro-léčiv je nový přístup v terapii nádorových onemocnění. Spočívá v katalytické aktivaci léčiva se zablokovanou funkční skupinou přímo v nádorové tkáni. V naší laboratoři se zabýváme aktivitou organokovových komplexu paladia a ruthenia v biologicky relevantních podmínkách. Pro studium katalytické aktivity jsou často využívány fluorescenční sondy, které lze také využít pro detekci paládiové kontaminace ve farmaceutických přípravcích. Z různých důvodů (buněčná toxicita, buněčný efflux) je mnoho standardních fluorescenčních látek nepoužitelných pro dlouhodobé studium katalytické aktivity organokovových sloučenin. Úkolem studenta bude podílet se na přípravě modifikovaných fluorescenčních sond se sníženou toxicitou a zvýšenou retenci v buňkách. Bude studovat citlivost vyvinutých sond k paladiu a dalším kovovým komplexům. Dále se bude podílet na syntéze a charakterizaci nových organokovových katalytických komplexů a evaluaci jejich katalytické aktivity v buňkách. Práce bude metodologicky obšírná a bude zahrnovat techniky organické syntézy, purifikace látek, biochemické analýzy a techniky tkáňových kultur.
Supervisor
Two-color colocalization for improving the sensitivity of single molecule (digital) immunoassays
Supervisor: Dr. rer. nat. habil. Hans-Heiner Gorris
Our research is focused on the development of new experimental methods in bioanalytical chemistry that enable highly sensitive measurements. We employ surface-modified photon-up-converting nanoparticles, which can be detected under near-infrared excitation light without any background interference even at the single nanoparticle level. With our broad repertoire of methods, we detect pathogens, cancer markers and environmental toxins and analyze the function of enzymes.
Objectives: We will use UCNPs as a detection label for single-molecule (digital) immunoassays. While UCNPs enable the detection of analytes without any optical background noise, non-specific binding is still a challenge because it lowers the sensitivity of the immunoassays. Non-specific binding has conventionally been reduced by optimizing the surface architecture of UCNP labels and coating of microtiter plates. In this project, we will investigate an entirely new approach for the reduction of non-specific binding, which is only possible by using single-molecule immunoassays: If we use two labels showing different colors for the detection of one analyte, the presence of the analyte can be verified by two-color detection under the microscope; however, if there is only one color detectable, the signal can be attributed to non-specific binding. In this way, we aim to achieve the highest possible sensitivity for the detection of cancer markers and virus particles such as Covid-19.
Profile: High motivation and joy in working on new experimental approaches in bioanalytical chemistry. Willingness to use English communication in an international team.
We offer: Supportive environment for Interdisciplinary work in an international team. Work on state-of-the-art projects with high societal relevance. Publications in high-impact journals. Building an international network with various European groups.
Supervisor
Zdeněk Glatz - Application of modern ambient ionization techniques mass spektrometry – DART a DESI v bioanalytical chemistry
Supervisor: prof. RNDr. Zdeněk Glatz, CSc.
FOCUS: The target analytes will include drugs and their metabolites and clinical markers in body fluids (blood, serum, saliva).
METHODS: DART-MS and DESI-MS, capillary electrophoresis and HPLC in combination with different detection techniques – MS, UV-VIS, LIF, C4CD. A new sampling technique based on the dry blood spot will be used.
LITERATURE: https://www.sci.muni.cz/en/about-us/faculty-staff/1865-zdenek-glatz/publications
GRANT PROJECTS: https://www.sci.muni.cz/en/about-us/faculty-staff/1865-zdenek-glatz/projects
PLEASE NOTE: before initiating the formal application process to doctoral studies, all interested candidates should contact Zdenek Glatz(glatz@chemi.muni.cz) for informal discussion.
Notes
Only one of the proposed theme will be finally occupied.
Supervisor
Zdeněk Glatz - Droplet mikrofluidics and its application in bioanalytical chemistry
Supervisor: prof. RNDr. Zdeněk Glatz, CSc.
FOCUS: The subjects of the study will be medicinally and pharmacologically important enzymes and the screening of their enzymes.
METHODS: droplet microfluidic system with the LIF detection, MS, UV-VIS, LIF, C4CD. A new sampling technique based on the dry blood spot will be used. Capillary electrophoresis and HPLC in combination with different detection techniques – MS, UV-VIS, LIF, C4CD will be used as supporting methods.
LITERATURE: https://www.sci.muni.cz/en/about-us/faculty-staff/1865-zdenek-glatz/publications
GRANT PROJECTS: https://www.sci.muni.cz/en/about-us/faculty-staff/1865-zdenek-glatz/projects
PLEASE NOTE: before initiating the formal application process to doctoral studies, all interested candidates should contact Zdenek Glatz (glatz@chemi.muni.cz) for informal discussion.
Notes
Only one of the proposed theme will be finally occupied.
Supervisor
Supervisors
- doc. RNDr. Petra Bořilová Linhartová, Ph.D., MBA
- doc. Mgr. Pavel Bouchal, Ph.D.
- doc. Mgr. Zdeněk Farka, Ph.D.
- Ing. František Foret, DSc.
- prof. RNDr. Zdeněk Glatz, CSc.
- Dr. rer. nat. habil. Hans-Heiner Gorris
- doc. PharmDr. Jan Juřica, Ph.D.
- RNDr. Pavel Kubáň, DSc.
- doc. Mgr. Jan Lochman, Ph.D.
- Mgr. Marta Pelcová, Ph.D.
- prof. Mgr. Jan Preisler, Ph.D.
- prof. RNDr. Zbyněk Prokop, Ph.D.
- prof. RNDr. Petr Skládal, CSc.
- prof. RNDr. Ondřej Slabý, Ph.D.
- doc. Mgr. Jiří Šána, Ph.D.
- doc. RNDr. Josef Tomandl, Ph.D.
- prof. RNDr. Zbyněk Zdráhal, Dr.
Study information
Provided by | Faculty of Science | |
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Type of studies | Doctoral | |
Mode | full-time | Yes |
combined | Yes | |
distance | No | |
Study options | single-subject studies | Yes |
single-subject studies with specialization | No | |
major/minor studies | No | |
Standard length of studies | 4 years | |
Language of instruction | Czech | |
Collaborating institutions |
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Doctoral board and doctoral committees |
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prof. RNDr. Zdeněk Glatz, CSc.
Consultant
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