Module Number BIOINF4372 (entspricht BIO-4372)	Module Title Cheminformatics	Lecture Type(s) Lecture, Tutorial
ECTS	6
Work load - Contact time - Self study	Workload: 180 h Class time: 60 h / 4 SWS Self study: 120 h
Duration	1 Semester
Frequency	Irregular
Language of instruction	English
Type of Exam	Oral exam or, in case of too many students, written exam. 50% of the achievable points from the assignments and the project, individually, are required for exam admission. Points achieved in excess of 50% serve as a bonus for the final exam.
Content	Starting with an overview of its main application area, namely drug design, the lecture teaches how computer science methods can be used to work with chemical data, strongly focusing on small organic molecules (compounds). Representation of compounds (graphs, line notations, file formats) is followed by most important ways of topological comparison (identity, substructure, similarity). Relevant applications of topological similarity are introduced (searching, clustering, library generation). Quantitative Structure-Activity Relationship (QSAR) is introduced as the cheminformatics branch for predictive modeling of chemical properties. Finally, the prediction of 3D-structures from topology and similarity methods for compounds with 3D coordinates are introduced.
Objectives	Students know how different kinds of chemical data can be handled with computers, how to represent and to analyse that data with methods from computer science, and they have an overview of the main application area drug design. Having understood the fundamental SSimilar Property Principlethey are able to handle and to analyse experimental screening data and to implement and apply ligand-based screening methods. Students have a solid knowledge on standard tools and software libraries for cheminformatics. Project work strengthened their ability to work in a team and to write down and to present scientific work.
Allocation of credits / grading	Type of Class Status SWS Credits Type of Exam Exam duration Evaluation Calculation of Module (%)
Prerequisite for participation	There are no specific prerequisites.
Lecturer / Other	Kohlbacher
Literature	Lecture slides and additional materials will be provided digitally. Basic knowledge of organic chemistry, graph theory, and programming skills in Python are recommended. Recommended textbooks: 1) Leach A., Gillet V. An Introduction To Chemoinformatics", Springer 2007 2) Faulon J.-L., Bender A. (Eds.) "Handbook Of Chemoinformatics Algorithms", CRC Press 2010 3) Engel T., Gasteiger J. (Eds.) Chemoinformatics", Wiley-VCH 2018 4) Optional: Klebe G. "Wirkstoffdesign", Springer 2009
Last offered	Wintersemester 2022
Planned for	Wintersemester 2024
Assigned Study Areas	BIO-BIO, INFO-INFO, INFO-PRAK, MEDI-APPL, MEDI-INFO, MEDZ-BIOMED, MEDZ-RES, ML-CS

Module Number

BIOINF4372 (entspricht BIO-4372)

Module Title

Cheminformatics

Lecture Type(s)

Lecture, Tutorial

ECTS

Work load
- Contact time
- Self study

Workload:
180 h

Class time:
60 h / 4 SWS

Self study:
120 h

Duration

1 Semester

Frequency

Irregular

Language of instruction

English

Type of Exam

Oral exam or, in case of too many students, written exam. 50% of the achievable points from the assignments and the project, individually, are required for exam admission. Points achieved in excess of 50% serve as a bonus for the final exam.

Content

Starting with an overview of its main application area, namely drug design, the
lecture teaches how computer science methods can be used to work with chemical
data, strongly focusing on small organic molecules (compounds). Representation
of compounds (graphs, line notations, file formats) is followed by most
important ways of topological comparison (identity, substructure, similarity).
Relevant applications of topological similarity are introduced (searching, clustering,
library generation). Quantitative Structure-Activity Relationship (QSAR)
is introduced as the cheminformatics branch for predictive modeling of chemical
properties. Finally, the prediction of 3D-structures from topology and similarity
methods for compounds with 3D coordinates are introduced.

Objectives

Students know how different kinds of chemical data can be handled with computers,
how to represent and to analyse that data with methods from computer
science, and they have an overview of the main application area drug design.
Having understood the fundamental SSimilar Property Principlethey are able
to handle and to analyse experimental screening data and to implement
and apply ligand-based screening methods. Students have a solid knowledge on
standard tools and software libraries for cheminformatics. Project work strengthened
their ability to work in a team and to write down and to present scientific
work.

Allocation of credits / grading

Prerequisite for participation

There are no specific prerequisites.

Lecturer / Other

Kohlbacher

Literature

Lecture slides and additional materials will be provided digitally. Basic knowledge of organic chemistry, graph theory, and programming skills in Python are recommended.

Recommended textbooks:
1) Leach A., Gillet V. An Introduction To Chemoinformatics", Springer 2007
2) Faulon J.-L., Bender A. (Eds.) "Handbook Of Chemoinformatics Algorithms", CRC Press 2010
3) Engel T., Gasteiger J. (Eds.) Chemoinformatics", Wiley-VCH 2018
4) Optional: Klebe G. "Wirkstoffdesign", Springer 2009

Last offered

Wintersemester 2022

Planned for

Wintersemester 2024

Assigned Study Areas

BIO-BIO, INFO-INFO, INFO-PRAK, MEDI-APPL, MEDI-INFO, MEDZ-BIOMED, MEDZ-RES, ML-CS