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636-0016-00L 4 Credits BSC , DR , MSC , NDS D-BSSE , D-INFK , D-PHYS , D-MATH
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Computational Systems Biology: Stochastic Approaches

Lecturers & Examiners: Prof. Dr. Mustafa Hani Khammash, Dr. Ankit Gupta
VVZ CR n/a

Last Updated: 2026-02-05 16:07:57

Abstract

This course is concerned with the development of computational methods for modeling, simulation, and analysis of stochasticity in living cells. Using these tools, the course explores the richness of stochastic phenomena, how it arises from the interactions of dynamics and noise, and its biological implications.

Objective

To understand the origins and implications of stochastic noise in living cells, and to learn the computational tools for the modeling, simulation, analysis, and identification of stochastic biochemical reaction networks.

Content

The cellular environment is abuzz with noise. A key source of this noise is the randomness that characterizes the motion of cellular constituents at the molecular level. Cellular noise not only results in random fluctuations (over time) within individual cells, but it is also a main source of phenotypic variability among clonal cell populations. Review of basic probability and stochastic processes; Introduction to stochastic gene expression; deterministic vs. stochastic models; the stochastic chemical kinetics framework; a rigorous derivation of the chemical master equation; moment computations; linear vs. nonlinear propensities; linear noise approximations; Monte Carlo simulations; Gillespie's Stochastic Simulation Algorithm (SSA) and variants; direct methods for the solution of the Chemical Master Equation; moment closure methods; intrinsic and extrinsic noise in gene expression; parameter identification from noise; propagation of noise in cell networks; noise suppression in cells; the role of feedback; exploiting noise; bimodality and stochastic switches.

Resources

Literature

Literature will be distributed during the course as needed.

General Information

Language
English
Levels
BSC , DR , MSC , NDS
Frequency
Yearly recurring

Examination

Type
session examination
Mode
written 180 minutes
Aids
None

Course Components

Type Title Time & Place Hours
lecture with exercise Computational Systems Biology: Stochastic Approaches
This lecture will take place online only (via Zoom). Link will be send to registered students in due time. Room reserved in Basel: Oppenheim Room reserved in ZH: HG D 16.2
  • Mon 12:15-15:00 (BSD G 205)
  • Mon 12:15-15:00 (HG D 16.2)
3 h weekly

Offered In

  • Computational Science and Engineering Bachelor
    • Electives (In the ‘electives’ subcategory, at least two course units must be successfully completed.)
  • Computational Science and Engineering Master
    • Electives (In the ‘electives’ subcategory, at least two course units must be successfully completed.)
  • Biotechnology Master
    • Electives (The electives list in the ETH course catalogue is an open list, and the courses listed in the ETH course catalogue provide just examples for possible elective courses, e.g. a selection of eligible courses. Students are expected to look for relevant courses in the ETH and University of Basel course catalogue and ask their mentor for approval. Courses from the advanced course category may also be taken as electives. We particularly recommend browsing the University of Basel course catalogue for elective courses of relevant master's degree programes (using the filter "programe structure" on the course catalogue website), such as for example: Biomedical Engineering, Chemistry, Drug Sciences, Epidemiology, Infection Biology, Molecular Biology, Nanosciences.)
  • Computational Biology and Bioinformatics Master (More informations at: )
    • Core Courses (Please note that the list of core courses is a closed list. Other courses cannot be added to the core course category in the study plan. Also the assignments of courses to core subcategories cannot be changed. Students need to pass at least one course in each core subcategory. A total of 40 ECTS needs to be acquired in the core course category.)
  • MAS in Medical Physics
  • Doctorate Biosystems Science and Engineering (More Information at: )
    • Subject Specialisation (The courses on offer below are a selection out of a much larger available number of courses. You may look for other courses too. If you are uncertain about the creditability and assessment of the course unit you wish to take, please consult the D-​BSSE Doctoral Administration. This should be done before registering the course unit.)