TECHNIQUES FOR ANALYSIS OF BIOMOLECULES
Academic Year 2018/2019 - 1° Year
Teaching Staff: Graziella VECCHIO
Credit Value: 6
Scientific field: CHIM/03 - General and inorganic chemistry
Taught classes: 35 hours
Exercise: 12 hours
Term / Semester: 2°
Credit Value: 6
Scientific field: CHIM/03 - General and inorganic chemistry
Taught classes: 35 hours
Exercise: 12 hours
Term / Semester: 2°
Learning Objectives
Learning of the techniques (NMR, CD and XAS) used for the characterization of biomolecules (small molecules, proteins, nucleic acids)
Detailed Course Content
- The physical basis of NMR spectroscopy. Nuclear Angular Moment and magnetic moment. Nuclei in a magnetic field.
- Basic Principles of the NMR experiment. The resonance condition. The pulse. Relaxation. Fourier transformation.
- The Chemical Shift. Nuclear shielding.
- Coupling. Spin-Spin coupling. Equivalent neighboring nuclei. Dependence of bond angle.
- Experimental aspects. The pulse angle. FID. Quadrature detection. Window functions
- Double resonance experiments. Simplification of spectra by selective spin decoupling. NOE. effect. Decoupling in 13C NMR spectra.
- NMR 2D. Basic Principles. COSY. TOCSY, ETCOR, NOESY e ROESY. 3D and 4D NMR. Exercises.
- Dynamic NMR. Exchange processes. DOSY.
- MRI. Basic Principles. Contrast agents used in clinic.
- Circular dichroism spectroscopy. Physical basis of CD. Selection rules. Exciton coupling. Static and dynamic coupling. Octant rule. CD sepctra of biomolecules.
- XAS spectroscopy. Physical bases. Application for the study of metalloporteins.
Textbook Information
The Basics of NMR by J.P. Hornak Hypertext based NMR course http://www.cis.rit.edu/htbooks/nmr/nmr-main.htm
Horst Friebolin Basic One- and Two-Dimensional NMR Spectroscopy Wiley.VCH
Alison Rodger, Bengt Nordén Circular Dichroism and Linear Dichroism Oxford University Press