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Molecular structure by two-dimensional NMR spectroscopy
Journal of Molecular Structure, 173 (1988)17-30 Elsevier Science Publishers B.V.,Amsterdam -Printedin The Netherlands
17
MOLECULAR SMtLICTUREBY TWO-DIMENSIONALNMRSPECIR~PY
R. FREEMAN Department of Physical Chemistry, Cambridge University, Lensfield Road, Cambridge CB2 lEP, England. SUMMARY
Two examples are presented of the use of two-dimensionalNMR spectroscopy to solve molecular structure problems. The first is called correlation spectroscopy (COSY) and it allows us to disentangle a complex network of spin-spin couplings. By dispersing the NMR information in two frequency dimensions, it facilitates the analysis of very complex spectra of organic and biochemical molecules, normally too crowded to be tractable. The second application exploits the special properties of multiple-quantum coherence to explore the molecular framework one C-C linkage at a time. The natural product panamine is used as a test example: with some supplementary evidence, the structure of this six-ringed heterocyclic molecule is elucidated from the double-quantum filtered two-dimensionalspectrum.
INTRODUCl'ION It often happens that an NMR spectrum contains too much information for the purposes of structure determination and then special techniques must be found to simplify the spectrum and separate out the useful data. This is particularly true of large organic molecules and most molecules of biochemical interest. Fortunately there are many useful tricks we can play on the nuclear spins so that they yield their secrets in a simple form. This is what distinguishes NMR from most other forms of spectroscopy; it is seldom sufficient to take away a spectrum and make no further demands on the spectrometer: more usually we have to devise a whole range of supplementary experiments to make a complete assignment. Double resonance is one such technique. By irradiating the sample with a second radiofrequency field we can often identify nuclei that are spin-coupled, even though the network of coupled spins may be very complex indeed. These decoupling experiments were usually carried out by the operator setting the frequency of the second radiofrequencysource at some suitable point in the spectrum. but in modern spectometers. it
is perfectly feasible to
conduct a systematic search throughout the entire spectrum under computer control. A second powerful double resonance technique is provided by the nuclear Overhauser effect - the enhancement of the intensity of a given resonance line when a close neighbour in the molecule has its resonance response saturated.
0022-2860/88/$03.50 0 1988ElsevierSciencePublishersB.V.
18 The magnitude
of
this
the appropriate structural acids
questions
or folding
exchange,
Now it
turns
(ref.
introduction
nuclear
conditions
during
-
The process
are
signal
but it
is
NMR experiment
is performed
written
F, may be thought of
experiment
where the perturbing
that certain
the entire
two-dimensional double
involves
steps
conditions
manner from the which normally receiver
on during
t,.
inactive
The raw S(t,,t,).
transformation
In Jeener’s
respect
as a two-dimensional
follows is
matrix,
a Fourier
spectrum. with
by
the
in small
the physical
(te)
to both
ti
and t,.
transform
W-1 .F,)
-
dimensions.
in terms of an equivalent radiofrequency
The “new” double
has been varied
range of NMR responses.
resonance in a stepwise
Indeed we shall
see below
spectra
are virtually
indistinguishable
resonance
experiments.
However two-dimensional
spectroscopy
has the advantage
are
at each stage
gathered
It
incremented
we would perform
is an NMR spectrum in two frequency
computer-controlled
2).
period
switched
resonance
in two-dimensional
The spectrometer
a frequency-domain
transformation
may be formally
to cover
of double
idea was proposed
(ref.
acquisition
period.
on NMR
exchange.
categories
which is this
of atoms
the same
effect
thus in the form of a two-dimensional
dimension
fashion
by their
revolutionary
(ti)
for
by the second radiofrequency
by Ernst
During
S(t*.t,) The result
for
of amino
of some atom or group
changed in some significant
to give
Fourier
This
period
period,
data are
S(F,)
experiment
power of useful
evidence
changes within
each have analogues
generalized
during
Now in a conventional S(t,)
extremely
direct
by chemical
three broad
in 1971.
the evolution
the evolution
experimental
site
range of values.
after
transfer
of populations
these
of an evolution
precession
provides
are monitored
in the 1960’s,
introduced
prevailing
immediately
to the sixth
such as sequencing
or conformational
to another
1) and later
over a suitable
resonance
the physical
out that
developed
spectroscopy,
proportional
and it has proved
molecules,
spin populations
transferred
experiment,
for
either
and a perturbation
gets
Jeener
double
molecules,
Nuclear
intensities, field
inversely
in biochemical
fashion
between different molecule.
is
distance,
of proteins.
In a similar chemical
effect
internuclear
of
of higher
sensitivity,
since
from
strong
NMR signals
the experiment.
CDRRELATION SPECIROSCOPY Before information,
a high
resolution
NMR spectrum can be used
there has to be an assignment
of
to derive
the resonance
lines.
structural This
may
19
be based on chemical shift information or relaxation times or on the form of the multiplet fine structure. If there is a resonance A which already has a firm assignment, then it is often possible to assign another resonance X on the basis of a. spin-spin interaction JAx. The evidence might be a double resonance "decoupling" experiment where the fine structure on A is modified by strong irradiation of the X resonance. Alternatively. coherence may be transferred from A to X and from X to A in a two-dimensionalexperiment. During the evolution period. nuclei precess at frequencies fA and fX Hz. During the acquisition period, these frequencies persist, but there is also The two-dimensional some coherence transfer f -fXand fX.f A' A spectrum thus contains two types of response, signals that lie on the principal diagonal (Fig. 1) where F, = Fe, and off-diagonal signals or "cross-peaks" arising from coherence transfer.
Fig. 1 Schematic correlation spectrum of a system of two protons A and X.
The positions of these cross-peaks indicate which resonances are related by spin-spin coupling because as JAx -0
the cross-peaks disappear. This
correlation spectroscopy (CD%) is a powerful method of assignment (ref. 3). It may be used in homonuclear systems, relating different protons in the same molecule, or in heteronuclear systems, relating (say) carbon-13 resonance to proton resonances.
A Practical Illustration Proton-proton correlation spectroscopymay be illustrated by reference to the hydroxytricyclodecanedionederivative shown in Fig. 2, which contains eleven protons exhibiting a complex network of couplings.
The
20 two-dimensional is
spectrum is also
the principal
diagonal
one-dimensional of
cross-peaks
is
projection
proton-proton
facilitated
the COSY spectrum: was obtained
There is a wealth
spectrum.
the 28 observable
it
onto one of
The first
2.
of cross-peaks,
chemical
the frequency
shifts
of
followed
H
45
proton
Some of they are
the proton-proton
the envelopes
of
couplings
H
H “t H
be observed
in this
network derived
manner are
H
inset
molecule
OH
A
on the right.
are
small
because
the instrumental
from these
signals
“.H
0
the top margin.
in this
of the CXBY experiment
the two time-domain
to light
the molecule
along
and they may be hidden within
may nevertheless
the timing parameters
were brought
COSY spectrum of
spectrum is displayed
long-range,
Cross-peaks
coupling
. .. H H
H/’
Two-dimensional
by
axes.
I
2.
This
but no J-splittings.
of the CDSY experiment
H
decoupled
some
the various
the top margin of
0
Fig.
to notice
reflecting
Identification
couplings.
modification
thing
the conventional
by the spectrum which runs across
has proton
by a slight
shown in Fig.
(where Fl = F2) which carries
tiny
couplings
linewidth. by altering
(ref.
3) and by suitably
S(t1)
and S(t,).
shown dotted
from the two-dimensional
shaping
Coup1 ings
in the schematic
CCSY spectra
(Fig.
3).
that
21 COSY spectra
have been extensively
Often
spectra.
the detection
identifiable
protons
once and for
all.
Fig.
Schematic
3.
Solid
lines
will
be enough to solve
diagram
indicate
used to disentangle
of an appreciable
of
the couplings
resolvable
complicated
coupling
between
a particular
chemical
in the molecule
couplings;
dashed lines
proton
two problem
shown in Fig.
long-range
2.
couplings.
Pseudo-CDSY One disadvantage data matrix otherwise
finer
is
sampling
on protons
digital
ruled
indeed,
out because
it
in order
involving
t,
one
structure In practice
increments
and an
unrealistically
resonance
experiment
long experiment
a homonuclear
to examine the fine
would make the number of
a very
the final’
to have appreciably
caused by overlap.
ambiguities
that
Typically
is violated.
4kHz x 4kHz in 4Hz steps.
than this
or to resolve
is
NMR spectrum in both dimensions
Sometimes we would like
storage.
resolution
entailing
condition
might cover
words of data
the cross-peaks
COSY experiment
must encompass the entire
the Nyquist
experiment million
of the two-dimensional
S(F,,Fe)
very
on this
large
large
data
matrix. This
is where the analogous
advantage.
Since
than by Fourier
transformation
to examine a narrow is
involved.
excite
only
is already across
double
the Fi domain is explored
region
A selective one resonance known from prior
the chemical
shift
of a time-domain
in very
small
radiofrequency line
by incrementing
pulse
is used
is
quite
sampling
(ref.4)
pulse
and the rest
of
rather
feasible condition
calculated
the conventional
the selective
range of interest
it
no Nyquist
Since
at a time.
experiments,
signal,
steps;
can be used to a frequency
to
NMR spectrum
can be stepped the F, domain can
22
be ignored. This has the effect of a "zoom" operation, where a chosen cross-peak can be examined with very fine digital resolution, without having to perform an impossibly large number of experiments. We call this experiment pseudo-CDSY in order to distinguish it from a true two-dimensionalFourier transform experiment (ref. 5).
Fig. 4 shows one of the cross-peaks of the
pseudo-CQSY spectrum of a three-spin system (2.3-dibromopropanoicacid) examined under high digital resolution.
:::: ::::
/
::: :::
00
00 /
...** ... . .
. / .,I
. .
,
,
G .I
I
.
.
//
‘::: .:::
. . ::: . .
. .
:::: ::::
30 Hi
\
a 0
b
0” l
0
00
00
/
20 Hz 475 Hz x 475 Hz Fig. 4. Zoom operation on a cross-peak in a pseudo-CDSY spectrum.
MULTIPLE-QUANTUM COHERENCE
The selection rule for NMR spectroscopy is that the magnetic quantum number should change by only one unit, Am = k 1. Multiple-quantum transitions are formally forbidden. When we examine this restriction in more detail, we find that with pulse excitation schemes the selection rule can be violated in as much as a coherence can be excited between states differing in quantum number by more (or less) than one unit, provided more than one excitation pulse is used. The catch is that these multiple-quantumcoherences induce no detectable signal in the spectrometer. Whereas normal signals can be thought of as arising from the alternating voltage induced in a coil by a rotating magnetic dipole, multiple-quantumcoherences behave more like quadrupoles and induce no signal at all.
23
-Two-dimensionalspectroscopy provides the key to this problem. The evolution period ten now be put to good use. We can excite multiple-quantum coherence and allow it to precess during the evolution period: it may be reconverted to observable nuclear magnetization detected in the normal manner. The multiple-quantum frequency is never observed directly but is deduced by its indirect effect on the observed NMR signal. It is "sampled" by varying the evolution period (when the spectrometer receiver is inactive).
CARBON-CARBON CONNEClIVI'lY
There is one application of double-quantum coherence which provides a powerful tool for molecular structure determination. If the carbon framework of a molecule can be established, the molecular structure is virtually determined because linkages through heteroatoms (nitrogen or oxygen) are relatively infrequent and can usually be inferred from other evidence. Now it turns out to be quite fortunate that Nature provides carbon-13 in low abundance (1%). In one molecule in lo* we would therefore expect to find adjacent carbon-13 nuclei. Directly-bonded carbon-13 atoms show a spin-spin coupling of 30-40 Hz whereas all longer-rangecouplings are much smaller and can be neglected. If we can detect these carbon-carbon couplings we can therefore establish connectiviteand thus follow the carbon chain step-by-step, identifying chain branching and ring formation. We may therefore trace out the entire carbon framework of the molecule, reaching a 'dead-end' only when the chain terminates or connects to a heteroatom such as nitrogen, oxygen or sulphur. The evidence is direct and unequivocal; if a carbon-carbon coupling of appreciable magnitude is detected, the two carbon atoms must be immediately adjacent in the molecule. If a given carbon atom shows three such couplings, this indicates chain branching. If a given carbon atom gives evidence of a chain of n such linkages which loop back to the original site, then an n-membered ring is present. The important point is that each piece of evidence for carbon-carbon coupling is independent of all others; molecules with three or more carbon-13 spins are of such low abundance that they can be safely neglected. The principal disadvantage of the method is the poor inherent sensitivity since only one molecule in lo* contains the useful information. Fortunately, technical improvements in NMR probes and magnets are steadily increasing the intrinsic sensitivity of the spectrometer.
The great advantage of the
two-dimensionaldouble-quantum experiment is that the connectivity information is unequivocal.
24 Exnerimental Method The first step is to extract the useful carbon-carbon coupling information from under a much stronger carbon-13 signal from molecules containing a single carbon-13 spin. This is where double-quantum coherence is useful. Two coupled spins can generate double-quantum coherence but isolated spins cannot. Since a radiofrequencyphase shift affects double-quantum coherence twice as much as single-quantumcoherence, it is possible to set up a phase-cycling scheme which suppresses the unwanted signal components very effectively leaving behind the signals that have passed through double-quantum coherence. This leaves a four-line AX or AB-type subspectrum for each pair of directly-bonded carbon atoms. These subspectra are then separated in the F, dimension according to the frequency of the double-quantum coherence which evolves during t, (ref.6). This double-quantum frequency is given by (6A + 6X) Hz and is essentially unique to each pair of coupled carbon-13 spins. We can therefore simulate a typical two-dimensionalspectrum viewed as a contour map (Fig. 5).
Fig. 5
A typical subspectrum from a two-dimensionaldouble-quantum
experiment.
There is a four-line spectrum running horizontally, showing chemical shift 6A and 6X and splittings JAx, with its centre-of-gravityat (LjA+ bX)/2. The Fi ordinate is the double-quantum frequency (hA + 6X). All other subspectra must have their centres-of-gravityon the diagonal line of slope 2.
These
restrictions impose a characteristicpattern on the two dimensional spectra, allowing connectivities to be deduced even the
presence of a great deal of
noise.
The Structure of Panamine The method is illustrated by consideration of a real case of structure determination, the natural product panamine, one of the Ormosia alkaloids
(ref.
7).
The conventional
a through start
t in order
tracing
resonance of
of
out the carbon
with a very
reducing
at a rate
which allows
too distant
for
this
relaxation
d
II
1
!
to site
ef
The conventional dimension). lines;
four
chemical
represents
(indicated
of
carbon-13
of
the carbon-13
are
on the diagonal
by the dotted
region
hi
providing
J’klmn
04
double-quantum
centres
the diagram
i.
It
is
therefore
carbon d, carbon
(the
F,
by horizontal of gravity
The ordinates
in the Fi dimension.
to carbon a, lines).
the top of
their
dashed line.
to site
spectrum of panamine.
have been highlighted
shown, with
(6A + ox)
i -' i'
41
spectrum runs along
frequencies
attached
This
protons
spectrum of panamine is
the relevant
k y' 0'i 'i / 0/ /' ,;,' i,
subspectra
one connectivity
atom is directly
the nearest
relaxation.
,
such subspectra
shifts)
repeated
between pulses.
0 ,. , , ,
The four-line
double-quan&m
is
1
: : i4
of part
has the effect
excitation
with
Q
;
A tracing
to
i.
i',
Fig.6
site
double-quantum
6 shows a tracing
This
time.
time for
spin-lattice
labelled place
i which has a carbon-13
the pulse
i is a quaternary
the connectivity
c
site
since
two-dimensional
20 resonances A convenient
shielding.
relaxation
line
efficient
but Fig.
ab
5
of
insufficient
The experimental
evidence
framework is
that carbon
to provide
complex,
spectrum contains
magnetic
long spin-lattice
the intensity
is good evidence
quite
carbon-13
increasing
(mean
represent
the
Each subspectrum clear
that
this
e and carbon n
carbon
26 We can therefore site
1 connected
Fig.
7.
First
stage
The next step chains
directly
is
8
site
(Fig.
the evidence
9).
One reason
of
Next it
spectrum to see if
these
a end site
m,
is noted that both m and j are
is
incomplete
for
atoms.
connectivities
finding
indicating
the presence
continues,
but since
the spectrum.
Now since
In fact
sites
and draw in a “partial”
write
“partial”
since
and four
unconnected
so many “dead ends” is
of carbon atoms attached
somewhere else.
7).
on penamine.
found between site
carbon atom h.
of following
case,
region
are
framework showing
end n (Fig.
of a
of a six membered ring.
(Fig.
resonances
a.d.e
8).
real
nitrogen
j.
to the m
Formation
contains
the molecular
sites
determination
Connectivities
n and site
ring
The process
of
to examine the two-dimensional
attached
six-membered
to draw part
of connectivity
ten be extended.
and between
Fig.
begin
to the four neighbouring
nitrogen
we can assign
nitrogen
segments are
is a found
that panamine
is electron-withdrawing,
to nitrogen
the same nitrogen
this
atom at
all
fall
in the low-field
resonances
a through g to such
the end of
these
atom may be terminating
chains.
We
another
chain
27
f 8P
Fig. 9
Four apparently unconnected segments of the panamine framework.
A second reason why a connectivity might be missed arises out of a shortcoming of the double-quantum experiment itself. The pulse sequence has to be set with a timing parameter chosen so as to optimize the creation of double-quantum coherence, based on the known range of J,, values. This adjustment occassionally proves to be incorrect if the two carbon chemical shifts are very similar, for the spectrum is then a strongly-coupledAB system rather than a weakly-coupled AX system. The corresponding subspectrum is of low intensity and may not be observed. Fortunately the strongly-coupledcase has been analysed (ref. 8) and it is known that the intensity of the AB subspectrum can be restored by repeating the experiment with a longer setting for the timing parameter. In the panamine example, carbons 1 and m form such a strongly coupled AB system, as do carbon atoms p and q.
These
connectivities are shown dotted on the next version of the molecular framework (Fig. 10).
From elemental analysis it is known that panamine contains three
heterocyclic nitrogens, so it is now possible to tie together the loose ends of the previous diagram. although of course this is no longer a unique
28 solution to the structural problem. Supplementary NMR evidence can now be used to check whether all the carbon valencies have been satisfied.
Fig. 10. Result of assigning attachments to nitrogen at carbon sites a through g on the basis of their low-field shifts.
It is relatively straightforward to determine the multiplicities of each carbon site, indicating the number of directly attached protons, so it is known how many C-C or C-N bonds to expect at each site. Consequently it turns out that site b is short of an attachment and it has to be concluded that this carbon atom is attached not to one nitrogen but to two. With this information it is possible to draw up possible molecular frameworks for panamine. one of which may be preferred because it contains only six-membered heterocyclic rings (Fig. 11).
One of the nitrogens must of
course be an NH group because it has only two C-N bonds. Although this shows the proposed connectivity, it is not the normal way that the structure would be presented.
The organic chemist might rearrange this drawing to emphasize
29 the cyclohexane-type
Fig.
11. Final
Fig.12
rings
as illustrated
framework proposed
The structure
for
in Fig.
12
panamine
of panamine as an organic
chemist might draw it.
30 REFERENCES 1.
J. Jeener, 1971.
Ampere International
2.
W. P. Aue,
E. Rartholdi
3.
A. Bax and R. Freeman,
4.
C. Rauer. R. Freeman, Reson. 58 (1984) 442.
5.
S. Davies.
6.
A. Rax, R. Freeman, ( 1981) 478-483.
7.
T. H. Mareci
8.
A. E&LXand R. Freeman,
J.
Friedrich T.
Summer School,
and R. R. Ernst, J. Mag,n. Reson. T. A. Frenkiel,
and R. Freeman,
J. Chem. Phys. 44 (1981)
J. Keeler
and R. Freeman, A. Frenkiel
Rasko Polje.
and A.
and H. H. Levitt,
J. Magn. Reson.
48 (1982)
41 (1980)
64 (1976)
2229.
542-561.
J. Magn. Reson.
J. Magn. Reson.
Yugoslavia,
597.
J.
Shaka,
(in
J. Kagn
press).
J. Magn. Reson.
158-163.
43
17
MOLECULAR SMtLICTUREBY TWO-DIMENSIONALNMRSPECIR~PY
R. FREEMAN Department of Physical Chemistry, Cambridge University, Lensfield Road, Cambridge CB2 lEP, England. SUMMARY
Two examples are presented of the use of two-dimensionalNMR spectroscopy to solve molecular structure problems. The first is called correlation spectroscopy (COSY) and it allows us to disentangle a complex network of spin-spin couplings. By dispersing the NMR information in two frequency dimensions, it facilitates the analysis of very complex spectra of organic and biochemical molecules, normally too crowded to be tractable. The second application exploits the special properties of multiple-quantum coherence to explore the molecular framework one C-C linkage at a time. The natural product panamine is used as a test example: with some supplementary evidence, the structure of this six-ringed heterocyclic molecule is elucidated from the double-quantum filtered two-dimensionalspectrum.
INTRODUCl'ION It often happens that an NMR spectrum contains too much information for the purposes of structure determination and then special techniques must be found to simplify the spectrum and separate out the useful data. This is particularly true of large organic molecules and most molecules of biochemical interest. Fortunately there are many useful tricks we can play on the nuclear spins so that they yield their secrets in a simple form. This is what distinguishes NMR from most other forms of spectroscopy; it is seldom sufficient to take away a spectrum and make no further demands on the spectrometer: more usually we have to devise a whole range of supplementary experiments to make a complete assignment. Double resonance is one such technique. By irradiating the sample with a second radiofrequency field we can often identify nuclei that are spin-coupled, even though the network of coupled spins may be very complex indeed. These decoupling experiments were usually carried out by the operator setting the frequency of the second radiofrequencysource at some suitable point in the spectrum. but in modern spectometers. it
is perfectly feasible to
conduct a systematic search throughout the entire spectrum under computer control. A second powerful double resonance technique is provided by the nuclear Overhauser effect - the enhancement of the intensity of a given resonance line when a close neighbour in the molecule has its resonance response saturated.
0022-2860/88/$03.50 0 1988ElsevierSciencePublishersB.V.
18 The magnitude
of
this
the appropriate structural acids
questions
or folding
exchange,
Now it
turns
(ref.
introduction
nuclear
conditions
during
-
The process
are
signal
but it
is
NMR experiment
is performed
written
F, may be thought of
experiment
where the perturbing
that certain
the entire
two-dimensional double
involves
steps
conditions
manner from the which normally receiver
on during
t,.
inactive
The raw S(t,,t,).
transformation
In Jeener’s
respect
as a two-dimensional
follows is
matrix,
a Fourier
spectrum. with
by
the
in small
the physical
(te)
to both
ti
and t,.
transform
W-1 .F,)
-
dimensions.
in terms of an equivalent radiofrequency
The “new” double
has been varied
range of NMR responses.
resonance in a stepwise
Indeed we shall
see below
spectra
are virtually
indistinguishable
resonance
experiments.
However two-dimensional
spectroscopy
has the advantage
are
at each stage
gathered
It
incremented
we would perform
is an NMR spectrum in two frequency
computer-controlled
2).
period
switched
resonance
in two-dimensional
The spectrometer
a frequency-domain
transformation
may be formally
to cover
of double
idea was proposed
(ref.
acquisition
period.
on NMR
exchange.
categories
which is this
of atoms
the same
effect
thus in the form of a two-dimensional
dimension
fashion
by their
revolutionary
(ti)
for
by the second radiofrequency
by Ernst
During
S(t*.t,) The result
for
of amino
of some atom or group
changed in some significant
to give
Fourier
This
period
period,
data are
S(F,)
experiment
power of useful
evidence
changes within
each have analogues
generalized
during
Now in a conventional S(t,)
extremely
direct
by chemical
three broad
in 1971.
the evolution
the evolution
experimental
site
range of values.
after
transfer
of populations
these
of an evolution
precession
provides
are monitored
in the 1960’s,
introduced
prevailing
immediately
to the sixth
such as sequencing
or conformational
to another
1) and later
over a suitable
resonance
the physical
out that
developed
spectroscopy,
proportional
and it has proved
molecules,
spin populations
transferred
experiment,
for
either
and a perturbation
gets
Jeener
double
molecules,
Nuclear
intensities, field
inversely
in biochemical
fashion
between different molecule.
is
distance,
of proteins.
In a similar chemical
effect
internuclear
of
of higher
sensitivity,
since
from
strong
NMR signals
the experiment.
CDRRELATION SPECIROSCOPY Before information,
a high
resolution
NMR spectrum can be used
there has to be an assignment
of
to derive
the resonance
lines.
structural This
may
19
be based on chemical shift information or relaxation times or on the form of the multiplet fine structure. If there is a resonance A which already has a firm assignment, then it is often possible to assign another resonance X on the basis of a. spin-spin interaction JAx. The evidence might be a double resonance "decoupling" experiment where the fine structure on A is modified by strong irradiation of the X resonance. Alternatively. coherence may be transferred from A to X and from X to A in a two-dimensionalexperiment. During the evolution period. nuclei precess at frequencies fA and fX Hz. During the acquisition period, these frequencies persist, but there is also The two-dimensional some coherence transfer f -fXand fX.f A' A spectrum thus contains two types of response, signals that lie on the principal diagonal (Fig. 1) where F, = Fe, and off-diagonal signals or "cross-peaks" arising from coherence transfer.
Fig. 1 Schematic correlation spectrum of a system of two protons A and X.
The positions of these cross-peaks indicate which resonances are related by spin-spin coupling because as JAx -0
the cross-peaks disappear. This
correlation spectroscopy (CD%) is a powerful method of assignment (ref. 3). It may be used in homonuclear systems, relating different protons in the same molecule, or in heteronuclear systems, relating (say) carbon-13 resonance to proton resonances.
A Practical Illustration Proton-proton correlation spectroscopymay be illustrated by reference to the hydroxytricyclodecanedionederivative shown in Fig. 2, which contains eleven protons exhibiting a complex network of couplings.
The
20 two-dimensional is
spectrum is also
the principal
diagonal
one-dimensional of
cross-peaks
is
projection
proton-proton
facilitated
the COSY spectrum: was obtained
There is a wealth
spectrum.
the 28 observable
it
onto one of
The first
2.
of cross-peaks,
chemical
the frequency
shifts
of
followed
H
45
proton
Some of they are
the proton-proton
the envelopes
of
couplings
H
H “t H
be observed
in this
network derived
manner are
H
inset
molecule
OH
A
on the right.
are
small
because
the instrumental
from these
signals
“.H
0
the top margin.
in this
of the CXBY experiment
the two time-domain
to light
the molecule
along
and they may be hidden within
may nevertheless
the timing parameters
were brought
COSY spectrum of
spectrum is displayed
long-range,
Cross-peaks
coupling
. .. H H
H/’
Two-dimensional
by
axes.
I
2.
This
but no J-splittings.
of the CDSY experiment
H
decoupled
some
the various
the top margin of
0
Fig.
to notice
reflecting
Identification
couplings.
modification
thing
the conventional
by the spectrum which runs across
has proton
by a slight
shown in Fig.
(where Fl = F2) which carries
tiny
couplings
linewidth. by altering
(ref.
3) and by suitably
S(t1)
and S(t,).
shown dotted
from the two-dimensional
shaping
Coup1 ings
in the schematic
CCSY spectra
(Fig.
3).
that
21 COSY spectra
have been extensively
Often
spectra.
the detection
identifiable
protons
once and for
all.
Fig.
Schematic
3.
Solid
lines
will
be enough to solve
diagram
indicate
used to disentangle
of an appreciable
of
the couplings
resolvable
complicated
coupling
between
a particular
chemical
in the molecule
couplings;
dashed lines
proton
two problem
shown in Fig.
long-range
2.
couplings.
Pseudo-CDSY One disadvantage data matrix otherwise
finer
is
sampling
on protons
digital
ruled
indeed,
out because
it
in order
involving
t,
one
structure In practice
increments
and an
unrealistically
resonance
experiment
long experiment
a homonuclear
to examine the fine
would make the number of
a very
the final’
to have appreciably
caused by overlap.
ambiguities
that
Typically
is violated.
4kHz x 4kHz in 4Hz steps.
than this
or to resolve
is
NMR spectrum in both dimensions
Sometimes we would like
storage.
resolution
entailing
condition
might cover
words of data
the cross-peaks
COSY experiment
must encompass the entire
the Nyquist
experiment million
of the two-dimensional
S(F,,Fe)
very
on this
large
large
data
matrix. This
is where the analogous
advantage.
Since
than by Fourier
transformation
to examine a narrow is
involved.
excite
only
is already across
double
the Fi domain is explored
region
A selective one resonance known from prior
the chemical
shift
of a time-domain
in very
small
radiofrequency line
by incrementing
pulse
is used
is
quite
sampling
(ref.4)
pulse
and the rest
of
rather
feasible condition
calculated
the conventional
the selective
range of interest
it
no Nyquist
Since
at a time.
experiments,
signal,
steps;
can be used to a frequency
to
NMR spectrum
can be stepped the F, domain can
22
be ignored. This has the effect of a "zoom" operation, where a chosen cross-peak can be examined with very fine digital resolution, without having to perform an impossibly large number of experiments. We call this experiment pseudo-CDSY in order to distinguish it from a true two-dimensionalFourier transform experiment (ref. 5).
Fig. 4 shows one of the cross-peaks of the
pseudo-CQSY spectrum of a three-spin system (2.3-dibromopropanoicacid) examined under high digital resolution.
:::: ::::
/
::: :::
00
00 /
...** ... . .
. / .,I
. .
,
,
G .I
I
.
.
//
‘::: .:::
. . ::: . .
. .
:::: ::::
30 Hi
\
a 0
b
0” l
0
00
00
/
20 Hz 475 Hz x 475 Hz Fig. 4. Zoom operation on a cross-peak in a pseudo-CDSY spectrum.
MULTIPLE-QUANTUM COHERENCE
The selection rule for NMR spectroscopy is that the magnetic quantum number should change by only one unit, Am = k 1. Multiple-quantum transitions are formally forbidden. When we examine this restriction in more detail, we find that with pulse excitation schemes the selection rule can be violated in as much as a coherence can be excited between states differing in quantum number by more (or less) than one unit, provided more than one excitation pulse is used. The catch is that these multiple-quantumcoherences induce no detectable signal in the spectrometer. Whereas normal signals can be thought of as arising from the alternating voltage induced in a coil by a rotating magnetic dipole, multiple-quantumcoherences behave more like quadrupoles and induce no signal at all.
23
-Two-dimensionalspectroscopy provides the key to this problem. The evolution period ten now be put to good use. We can excite multiple-quantum coherence and allow it to precess during the evolution period: it may be reconverted to observable nuclear magnetization detected in the normal manner. The multiple-quantum frequency is never observed directly but is deduced by its indirect effect on the observed NMR signal. It is "sampled" by varying the evolution period (when the spectrometer receiver is inactive).
CARBON-CARBON CONNEClIVI'lY
There is one application of double-quantum coherence which provides a powerful tool for molecular structure determination. If the carbon framework of a molecule can be established, the molecular structure is virtually determined because linkages through heteroatoms (nitrogen or oxygen) are relatively infrequent and can usually be inferred from other evidence. Now it turns out to be quite fortunate that Nature provides carbon-13 in low abundance (1%). In one molecule in lo* we would therefore expect to find adjacent carbon-13 nuclei. Directly-bonded carbon-13 atoms show a spin-spin coupling of 30-40 Hz whereas all longer-rangecouplings are much smaller and can be neglected. If we can detect these carbon-carbon couplings we can therefore establish connectiviteand thus follow the carbon chain step-by-step, identifying chain branching and ring formation. We may therefore trace out the entire carbon framework of the molecule, reaching a 'dead-end' only when the chain terminates or connects to a heteroatom such as nitrogen, oxygen or sulphur. The evidence is direct and unequivocal; if a carbon-carbon coupling of appreciable magnitude is detected, the two carbon atoms must be immediately adjacent in the molecule. If a given carbon atom shows three such couplings, this indicates chain branching. If a given carbon atom gives evidence of a chain of n such linkages which loop back to the original site, then an n-membered ring is present. The important point is that each piece of evidence for carbon-carbon coupling is independent of all others; molecules with three or more carbon-13 spins are of such low abundance that they can be safely neglected. The principal disadvantage of the method is the poor inherent sensitivity since only one molecule in lo* contains the useful information. Fortunately, technical improvements in NMR probes and magnets are steadily increasing the intrinsic sensitivity of the spectrometer.
The great advantage of the
two-dimensionaldouble-quantum experiment is that the connectivity information is unequivocal.
24 Exnerimental Method The first step is to extract the useful carbon-carbon coupling information from under a much stronger carbon-13 signal from molecules containing a single carbon-13 spin. This is where double-quantum coherence is useful. Two coupled spins can generate double-quantum coherence but isolated spins cannot. Since a radiofrequencyphase shift affects double-quantum coherence twice as much as single-quantumcoherence, it is possible to set up a phase-cycling scheme which suppresses the unwanted signal components very effectively leaving behind the signals that have passed through double-quantum coherence. This leaves a four-line AX or AB-type subspectrum for each pair of directly-bonded carbon atoms. These subspectra are then separated in the F, dimension according to the frequency of the double-quantum coherence which evolves during t, (ref.6). This double-quantum frequency is given by (6A + 6X) Hz and is essentially unique to each pair of coupled carbon-13 spins. We can therefore simulate a typical two-dimensionalspectrum viewed as a contour map (Fig. 5).
Fig. 5
A typical subspectrum from a two-dimensionaldouble-quantum
experiment.
There is a four-line spectrum running horizontally, showing chemical shift 6A and 6X and splittings JAx, with its centre-of-gravityat (LjA+ bX)/2. The Fi ordinate is the double-quantum frequency (hA + 6X). All other subspectra must have their centres-of-gravityon the diagonal line of slope 2.
These
restrictions impose a characteristicpattern on the two dimensional spectra, allowing connectivities to be deduced even the
presence of a great deal of
noise.
The Structure of Panamine The method is illustrated by consideration of a real case of structure determination, the natural product panamine, one of the Ormosia alkaloids
(ref.
7).
The conventional
a through start
t in order
tracing
resonance of
of
out the carbon
with a very
reducing
at a rate
which allows
too distant
for
this
relaxation
d
II
1
!
to site
ef
The conventional dimension). lines;
four
chemical
represents
(indicated
of
carbon-13
of
the carbon-13
are
on the diagonal
by the dotted
region
hi
providing
J’klmn
04
double-quantum
centres
the diagram
i.
It
is
therefore
carbon d, carbon
(the
F,
by horizontal of gravity
The ordinates
in the Fi dimension.
to carbon a, lines).
the top of
their
dashed line.
to site
spectrum of panamine.
have been highlighted
shown, with
(6A + ox)
i -' i'
41
spectrum runs along
frequencies
attached
This
protons
spectrum of panamine is
the relevant
k y' 0'i 'i / 0/ /' ,;,' i,
subspectra
one connectivity
atom is directly
the nearest
relaxation.
,
such subspectra
shifts)
repeated
between pulses.
0 ,. , , ,
The four-line
double-quan&m
is
1
: : i4
of part
has the effect
excitation
with
Q
;
A tracing
to
i.
i',
Fig.6
site
double-quantum
6 shows a tracing
This
time.
time for
spin-lattice
labelled place
i which has a carbon-13
the pulse
i is a quaternary
the connectivity
c
site
since
two-dimensional
20 resonances A convenient
shielding.
relaxation
line
efficient
but Fig.
ab
5
of
insufficient
The experimental
evidence
framework is
that carbon
to provide
complex,
spectrum contains
magnetic
long spin-lattice
the intensity
is good evidence
quite
carbon-13
increasing
(mean
represent
the
Each subspectrum clear
that
this
e and carbon n
carbon
26 We can therefore site
1 connected
Fig.
7.
First
stage
The next step chains
directly
is
8
site
(Fig.
the evidence
9).
One reason
of
Next it
spectrum to see if
these
a end site
m,
is noted that both m and j are
is
incomplete
for
atoms.
connectivities
finding
indicating
the presence
continues,
but since
the spectrum.
Now since
In fact
sites
and draw in a “partial”
write
“partial”
since
and four
unconnected
so many “dead ends” is
of carbon atoms attached
somewhere else.
7).
on penamine.
found between site
carbon atom h.
of following
case,
region
are
framework showing
end n (Fig.
of a
of a six membered ring.
(Fig.
resonances
a.d.e
8).
real
nitrogen
j.
to the m
Formation
contains
the molecular
sites
determination
Connectivities
n and site
ring
The process
of
to examine the two-dimensional
attached
six-membered
to draw part
of connectivity
ten be extended.
and between
Fig.
begin
to the four neighbouring
nitrogen
we can assign
nitrogen
segments are
is a found
that panamine
is electron-withdrawing,
to nitrogen
the same nitrogen
this
atom at
all
fall
in the low-field
resonances
a through g to such
the end of
these
atom may be terminating
chains.
We
another
chain
27
f 8P
Fig. 9
Four apparently unconnected segments of the panamine framework.
A second reason why a connectivity might be missed arises out of a shortcoming of the double-quantum experiment itself. The pulse sequence has to be set with a timing parameter chosen so as to optimize the creation of double-quantum coherence, based on the known range of J,, values. This adjustment occassionally proves to be incorrect if the two carbon chemical shifts are very similar, for the spectrum is then a strongly-coupledAB system rather than a weakly-coupled AX system. The corresponding subspectrum is of low intensity and may not be observed. Fortunately the strongly-coupledcase has been analysed (ref. 8) and it is known that the intensity of the AB subspectrum can be restored by repeating the experiment with a longer setting for the timing parameter. In the panamine example, carbons 1 and m form such a strongly coupled AB system, as do carbon atoms p and q.
These
connectivities are shown dotted on the next version of the molecular framework (Fig. 10).
From elemental analysis it is known that panamine contains three
heterocyclic nitrogens, so it is now possible to tie together the loose ends of the previous diagram. although of course this is no longer a unique
28 solution to the structural problem. Supplementary NMR evidence can now be used to check whether all the carbon valencies have been satisfied.
Fig. 10. Result of assigning attachments to nitrogen at carbon sites a through g on the basis of their low-field shifts.
It is relatively straightforward to determine the multiplicities of each carbon site, indicating the number of directly attached protons, so it is known how many C-C or C-N bonds to expect at each site. Consequently it turns out that site b is short of an attachment and it has to be concluded that this carbon atom is attached not to one nitrogen but to two. With this information it is possible to draw up possible molecular frameworks for panamine. one of which may be preferred because it contains only six-membered heterocyclic rings (Fig. 11).
One of the nitrogens must of
course be an NH group because it has only two C-N bonds. Although this shows the proposed connectivity, it is not the normal way that the structure would be presented.
The organic chemist might rearrange this drawing to emphasize
29 the cyclohexane-type
Fig.
11. Final
Fig.12
rings
as illustrated
framework proposed
The structure
for
in Fig.
12
panamine
of panamine as an organic
chemist might draw it.
30 REFERENCES 1.
J. Jeener, 1971.
Ampere International
2.
W. P. Aue,
E. Rartholdi
3.
A. Bax and R. Freeman,
4.
C. Rauer. R. Freeman, Reson. 58 (1984) 442.
5.
S. Davies.
6.
A. Rax, R. Freeman, ( 1981) 478-483.
7.
T. H. Mareci
8.
A. E&LXand R. Freeman,
J.
Friedrich T.
Summer School,
and R. R. Ernst, J. Mag,n. Reson. T. A. Frenkiel,
and R. Freeman,
J. Chem. Phys. 44 (1981)
J. Keeler
and R. Freeman, A. Frenkiel
Rasko Polje.
and A.
and H. H. Levitt,
J. Magn. Reson.
48 (1982)
41 (1980)
64 (1976)
2229.
542-561.
J. Magn. Reson.
J. Magn. Reson.
Yugoslavia,
597.
J.
Shaka,
(in
J. Kagn
press).
J. Magn. Reson.
158-163.
43