18:46

Dynamic Nuclear Polarization Part 2: Biomolecular Applications

41:58

Dynamic Nuclear Polarization Part 1: Introduction and Principles

39:48

Biomolecular Solid-State NMR Part 2: Protein Structure and Dynamics

34:28

Biomolecular Solid-State NMR Part 1: Introduction and Principles

56:49

SpinDynamica Lecture 2: Superoperators in SpinDynamica

42:06

SpinDynamica Lecture 5: Relaxation in SpinDynamica I

53:53

SpinDynamica Lecture 3: More on SpinDynamica

50:08

SpinDynamica Lecture 4: Simulation Routines in SpinDynamica

01:17:51

SpinDynamica Lecture 6: Relaxation in SpinDynamica II

01:07:27

SpinDynamica Lecture 1: Introduction to SpinDynamica

01:35:20

NMR Relaxation Lecture 5: Practical Aspects of Spin Relaxation

01:19:54

NMR Relaxation Lecture 4: Rotating Frame Relaxation

01:47:14

NMR Relaxation Lecture 3: Redfield Equations Part II

01:18:54

NMR Relaxation Lecture 2: Redfield Equations Part I

01:27:52

NMR Relaxation Lecture 1: Introduction to Spin Relaxation and The Solomon Equations

48:06

Lecture 12: Using MetaboAnalyst Part 1

45:00

Lecture 5: Statistical NMR Spectroscopy

44:30

Lecture 3: Software & DBs for NMR-based Metabolomics

55:13

Lecture 6: Novel NMR Methods

48:39

Lecture 7: NMR & Metabolite Imaging

01:01:31

Lecture 11: Introduction to Stats Part 2

55:20

Lecture 1: Introduction to Metabolomics

44:31

Lecture 10: Introduction to Stats Part 1

58:05

Lecture 8: Discoveries & Applications

58:03

Lecture 2: NMR-based Metabolomics

43:45

Lecture 14: The Future of Metabolomics

49:52

Lecture 9: Analyzing Metabolomic data

43:19

Lecture 4: Spectral Deconvolution Methods

52:01

Lecture 13: Using MetaboAnalyst Part 2

01:18:06

Lecture 1: Introduction to EPR spectroscopy by Prof. Daniella Goldfarb

01:29:10

Lecture 2: The EPR interactions and EPR in the solid state by Prof. Daniella Goldfarb

01:06:04

Lecture 4: Double resonance techniques, DEER and CW ENDOR (liquids) by Prof. Daniella Goldfarb

01:19:37

Lecture 5: Pulse ENDOR by Prof. Daniella Goldfarb

01:22:26

Lecture 6: ELDOR detected NMR and ESEEM by Prof. Daniella Goldfarb

01:10:51

Lecture 3: Nitroxide spin labels and Pulse EPR by Prof. Daniella Goldfarb

45:52

Lecture 1 - Residual Dipolar Couplings: Theory and Applications by Dr Ad Bax: Part 1

01:03:13

Lecture 2 - Residual Dipolar Couplings: Theory and Applications by Dr Ad Bax: Part 2

43:10

Lecture 10 - Chapter 9: Relaxation (II) by Dr James Keeler: "Understanding NMR spectroscopy"

36:29

Lecture 8 - Chapter 8: Two-dimensional NMR (II) by Dr James Keeler: "Understanding NMR spectroscopy"

47:28

Lecture 4 - Chapter 7: Product operators (I) by Dr James Keeler: "Understanding NMR spectroscopy"

01:10:07

Lecture 2 - Chapter 4: The vector model by Dr James Keeler: "Understanding NMR spectroscopy"

53:48

Lecture 12 - Chapter 11: Coherence selection (I) by Dr J Keeler: "Understanding NMR spectroscopy"

36:51

Lecture 6 - Chapter 7: Product operators (III) by Dr James Keeler: "Understanding NMR spectroscopy"

29:02

Lecture 14 - Chapter 11: Coherence selection (III) by Dr J Keeler: "Understanding NMR spectroscopy"

55:53

Lecture 9 - Chapter 9: Relaxation (I) by Dr James Keeler: "Understanding NMR spectroscopy"

44:28

Lecture 13 - Chapter 11: Coherence selection (II) by Dr J Keeler: "Understanding NMR spectroscopy"

51:11

Lecture 11 - Chapter 9: Relaxation (III) by Dr James Keeler: "Understanding NMR spectroscopy"

57:58

Lecture 7 - Chapter 8: Two-dimensional NMR (I) by Dr James Keeler: "Understanding NMR spectroscopy"

47:25

Lecture 5 - Chapter 7: Product operators (II) by Dr James Keeler: "Understanding NMR spectroscopy"

02:01

Introduction to the lectures series "Understanding NMR spectroscopy" by Dr James Keeler

42:40

Lecture 3 - Chapter 5: Fourier transformation by Dr James Keeler: "Understanding NMR spectroscopy"

46:05

Lecture 1 - Chapter 3: Energy levels by Dr James Keeler: "Understanding NMR spectroscopy"