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Development of Complex Curricula for Molecular Bionics and Infobionics Programs within a consortial* framework**
Consortium leader
PETER PAZMANY CATHOLIC  UNIVERSITY
Consortium members
SEMMELWEIS UNIVERSITY, DIALOG CAMPUS PUBLISHER
The Project has been realised with the support of the European Union and has been co-financed by the European Social Fund ***

**Molekuláris bionika és Infobionika Szakok tananyagának komplex fejlesztése konzorciumi keretben
***A projekt az Európai Unió támogatásával, az Európai Szociális Alap társfinanszírozásával valósul meg.

PETER PAZMANY
CATHOLIC UNIVERSITY

SEMMELWEIS
UNIVERSITY

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INFOBLOKK

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Peter Pazmany Catholic University  
Faculty of Information Technology

BASICS OF NEUROBIOLOGY

QUOVADIS –NEUROBIOLOGY?

www.itk.ppke.hu

Neurobiológia alapjai

Quovadis-Neurobiológia?

ZSOLT LIPOSITS


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ARS POETICA
The complexity of components has reached a level, where their utilization overpasses the architectural capabilities of artificial systems developed so far and requires solutions applied also by nature.
The development of neurosciences and genetics have reached a level where the exactness of models allows us creating Neuromorphic or nature inspired systems and the application of the knowledge about our cognitive properties as a communicator and consumer of information becomes possible.
As a consequence of the “sensory revolution” cheap artificial sensing arrays and activating devices provide for acquiring an incredibly rich information base of the spatial-temporal reality that surround us, and at the same time require the immediate processing of millions of analogue signals.
The biomedical industry needs and uses the latest achievements of information technologies, including noninvasive imaging devices and systems, it also calls for the reliable interaction between electronics and living cells.

www.itk.ppke.hu


Basics of Neurobiology: Qui vadis-Neurobiology?

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ARS POETICA
The limits of classical microelectronic components have been reached; the nanotechnologies have appeared in information processing both for artificial as well as for living systems.
The emergence of cheap, broadly used and global mobile telecommunication services enables the application of tele-presence in broad scale.
The expansion of the European Union and the globalization of division of labor increased the importance of human language technologies in the variety of languages. In order to face the above challenges our students need:

a new structure of multidisciplinary studies 


a good theoretical formation via the effective application of information technologies


specializations that are based on well founded theoretical knowledge


a skill based training, included from the start of the program 



www.itk.ppke.hu


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www.itk.ppke.hu

MATHEMATICS
PHYSICS
MICROELECTRONICS
INFORMATION TECHNOLOGY
COMPUTING
PROGRAMING

BIOCHEMISTRY
MOLECULAR BIOLOGY
NEUROBIOLOGY
NEURONAL NETWORKS
SYSTEM BIOLOGY
MODELLING          




SYNTHESIS OF  LIFE SCIENCE DISCIPLINES



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RECOMMENDED COURSES AND STUDIES

www.itk.ppke.hu

BIOPHYSICS, MOLECULAR BIOLOGY

BASICS OF NEUROBIOLOGY

INTRODUCTION TO FUNCTIONAL NEUROBIOLOGY

IMMUNOLOGY, GENETICS

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PhD studies



Diploma




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1.
Quo vadis-Neurobiology?

2.
Organ systems

3.
Organization of the nervous systems

4.
The cell

5.
Cell organelles I.

6.
Cell organelles II.

7.
Nervoustissue

8.
The neuron

9.
Nerve fibers

10.
The neuroglia

11.
Nerve endings

12.
Synaptic communication

13.
Neurotransmitters I.

14.
Neurotransmitters II.



www.itk.ppke.hu

LECTURES OF THE COURSE

110

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15. Release of neurotransmitters
16. Ionotropicreceptors
17. Metabotropicreceptors
18. Neurodegeneration
19. Developmentof the nervous system
20. Spinal cord
21. Internal structure of the spinal cord
22. Tracts of the spinal cord 
23. Stretch reflex
24. The flexor and autonomic reflexes
25. Brain stem
26. Structure of cerebellum
27. Networking of cerebellum  
28.Organization of the brain stem
29. Networking of brain stem

www.itk.ppke.hu


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30. Cranial nerves
31. Diencephalon
32. Divisions of the telencephalon
33. Cytoarchitectureof cerebral cortex
34. Sensory systems
35. Motor systems
36. Hippocampal formation
37. Olfactory system
38. Visual system
39. Cochlear and vestibular systems

www.itk.ppke.hu


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www.itk.ppke.hu

b
a
RECOMMENDEDTEXTBOOKS




FINAL EXAM

1.
Written exam at the end of the semester: max.  70 points

2.
Written mid-term exam:max.  20 points

3.
Activity at the practicals:max.  10 points




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„Scientia et conscientia”
WAYS OF LEARNING
1.
GENUINE INTEREST, HIGH MOTIVATION

2.
ACTIVE PRESENCE AND PARTICIPATION

3.
WORKING = LEARNING

4.
CONTINUOUS LEARNING

5.
ANALYSIS  OF CAUSE AND ITS EFFECT

6.
ABSTRACTION

7.
REALIZE YOUR  SCIENTIFIC DREAMS

8.
RAISE QUESTIONS,  WORK  IN AN INTERACTIVE MANNER

9.
BIOLOGICALEVENTS AREPLASTICIN NATURE

10.
STRUCTURE-FUNCTION-MODELLING-TRANSLATION-INNOVATION

11.
3D APPROACH AND PERSPECTIVE OF BIOLOGICAL STRUCTURES

12.
LEARN FROM TEXTBOOKS AND USE PUBMED




www.itk.ppke.hu


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CONTEMPERARY RESEARCH METHODS OF NEUROBIOLOGY
1.
CLONING

2.
GENETIC ENGINEERING

3.
GENE EXPRESSION PROFILING

4.
QUANTITATIVE REAL-TIME POLYMERASE CHAIN REACTION (PCR)

5.
PROMOTER ASSAYS

6.
DNA, RNA AND PROTEIN MEASUREMENTS

7.
IMMUNOCYTOCHEMISTRY

8.
CONFOCAL LASER  MICROSCOPY

9.
2-PHOTON LASER  MICROSCOPY

10.
RADIOIMMUNOASSAY

11.
PATCH CLAMP ELECTROPHYSIOLOGY

12.
IN VIVO ELECTROPHYSIOLOGY

13.
IMAGING  AND RECONSTRUCTION TECHNIQUES 

14.
MONITORING OF BEHAVIOR



www.itk.ppke.hu