Chapter 5 – Detection and Imaging Tools that Use Nonoptical Waves  191

XY plane. In this example, the 90° pulse is then applied, and the magnetization dephases

giving an FID response as before. Normally, an inversion recovery sequence is then repeated

every TR seconds to improve the signal-​to-​noise ratio, such that

(5.26)

S

k

T

T

T

T

I

=

−

−















^



^

−













ρ 1

2

1

1

exp

exp

R

5.4.7  MULTIDIMENSIONAL NMR

For complex biomolecules, often containing hundreds of atoms, overlapping peaks in a spec­

trum obtained using just a single magnetic atomic nucleus type, the so-​called 1D-​NMR, can

make interpretation of the relative spatial localization of each different atom challenging.

The correct assignment of atoms for structural determination of all the major classes of

biomolecules is substantially improved by acquiring NMR spectra for one and then another

type of magnetic atomic nuclei simultaneously, known as “multidimensional NMR” or “NMR

correlation spectroscopy” (COSY). For example, the use of 2D-​NMR with ¹³C and ¹⁵N isotopes

can be used to generate a 2D heat map plot for chemical shift for each isotope plotted on

each axis, with the 2D hotspots, as opposed to 1D peaks on their own, used to extract the

molecular signature, which is particularly useful for identify backbone structures in proteins,

a technique also referred to as “nuclear Overhauser effect spectroscopy” (NOESY). These

correlative NMR approaches can be adapted in several multichannel NMR machines for 3D-​

NMR and 4D-​NMR, with averaged spectra taking more like ~100 min to acquire.

Correlative NMR spectroscopy has been enormously successful in determining the

structures of several types of biomolecules. These include complex lipids, carbohydrates,

short nucleic acid sequences of ≲100 nucleotides, and peptides and proteins. The upper

molecular weight limit for proteins using these NMR methods is ~35 kDa, which is compara­

tively small (e.g., an IgG antibody has a molecular weight of ~150 kDa). Multidimensional

NMR can to a great extent overcome issues of overlapping chemical shift peaks associated

with larger proteins; however, a larger issue is that the sample magnetization relaxes faster

in large proteins, which ultimately sets a limit on the time to detect the NMR signal. Larger

proteins have longer rotational correlation times and shorter transverse (T2) relaxation times,

ultimately leading to line broadening in the NMR spectrum.

Transverse relaxation optimized spectroscopy (TROSY) has been used to overcome

much of this line broadening. TROSY suppresses T2 relaxation in multidimensional NMR

spectroscopy by using constructive interference between dipole–​dipole coupling and aniso­

tropic chemical shifts to produce much sharper chemical shift peaks. TROSY can also be

used in combination with deuteration of larger proteins, that is, replacing ¹H atoms with

2H, which further suppresses T2 relaxation. These improvements have allowed the struc­

tural determination of much larger proteins and protein complexes with nucleic acids, up

to ~90 kDa.

NMR spectroscopy in its modern cutting-​edge form has been used to great effect in

obtaining atomic-​level structures of several important biomolecules, especially of pro­

tein membranes. These are in general very difficult to crystallize, which is a requirement

of the competing atomic-​level structural determination technique of x-​ray crystallography.

A related spatially resolved technique used in biomedical in vivo diagnostics is magnetic res­

onance imaging (MRI), discussed in Chapter 7.

5.4.8  ELECTRON SPIN RESONANCE AND ELECTRON PARAMAGNETIC RESONANCE

ESR, also referred to as EPR, relies on similar principles to NMR. However, here the reson­

ance is from the absorption and emission of electromagnetic radiation due to transitions in

the spin states of the electrons as opposed to magnetic atomic nuclei. This only occurs for an

unpaired electron since paired electrons have a net spin of zero. ESR resonance peaks occur