Description

Type

Master
Location

Maynard (USA)

Start date

Different dates available

This course introduces the mathematical modeling techniques needed to address key questions in modern biology. An overview of modeling techniques in molecular biology and genetics, cell biology and developmental biology is covered. Key experiments that validate mathematical models are also discussed, as well as molecular, cellular, and developmental systems biology, bacterial chemotaxis, genetic oscillators, control theory and genetic networks, and gradient sensing systems. Additional specific topics include: constructing and modeling of genetic networks, lambda phage as a genetic switch, synthetic genetic switches, circadian rhythms, reaction diffusion equations, local activation and global inhibition models, center finding networks, general pattern formation models, modeling cell-cell communication, quorum sensing, and finally, models for Drosophila development.

Facilities

Maynard (USA)

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02139

Start date

Different dates availableEnrolment now open

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Subjects

Systems
Cell Biology
Molecular Biology
Biology
Switches
Networks

Course programme

Lectures: 2 sessions / week, 1.5 hours / session

The goal of this course is to help students develop a quantitative understanding of the biological function of genetic and biochemical networks. Students will be provided with the essential mathematical tools needed to model network modules, such as biological switches, oscillators, filters, amplifiers, etc. An array of example biological problems that can be successfully tackled with a systems biology approach will be introduced by discussing recent papers on the subject. The intrinsic challenge of this class is that students are coming in with wildly different backgrounds. Read up on your biology or math if needed. Use time in the recitations to help close some of the knowledge gaps and to help you prepare for the homework.

There are three levels of complexity to Systems Biology:

The course notes serve as the text. For good biology reference texts, see:

Alberts, Bruce, et. al. Molecular Biology of the Cell. 4th ed. New York: Garland Science, 2002. ISBN: 9780815332183.

Lodish, Harvey, et al. Molecular Cell Biology. 5th ed. New York: W. H. Freeman and Company, 2003. ISBN: 9780716743668.

MATLAB® will be used intensively during the course. Make sure you know or learn how to use it as it is necessary for the problem sets.

There are 5 problem sets and one take home final for the course. The grading breakdown is as follows:

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Systems biology

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Systems biology

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