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Directed resolution of enantiomers via liquid chromatography of diastereomeric derivatives III. A convenient method to determine the absolute configuration of carboxylic acids R1R2HCCOOH
l'etrahedron LettersNo. 16, pp 34.7 - 1420, 1977.
DIRECTED
RESOLUTION
DERIVATIVES
III.
CARBOXYLIC
ACIDS
OF ENANTIOMERS
A CONVENIENT
lnstitut
fur Organische Stuttgart
VIA LIQUID
METHOD
CHROMATOGRAPHY
TO DETERMINE
OF DIASTEREOMERIC
THE ABSOLUTE
CONFIGURATION
OF
RTR’HCCOOH’) Gunter
D-7000
Pergarnon Press. Printedin Great Britain.
Helmchen,
Chemie,
Helene V&her and Willi
Biochemie und lsotopenforschung
Schuhle der Universitllt,
Pfaffenwaldring
55,
80
(Receivedin UK 15 February1977;
accepted
for
publication
7
March 1977)
Some timeago we introduced the term “directed resolution of enantiomers” to denote a method capable of simultaneous (a) separation of enantiomers, absolute configuration solution
of chirol
(b) determination
compounds. In papers I
of corboxyiic acids and omines con generally
2)
of enontiomeric
tion of the diastereomers. group internally group2)
condition
(c) is fulfilied
Condition
by o model which correlates elution
This model was previously
of
restricted
secondary amides
(b) is met by high performance liquid order and configura-
to amides R’R2XCCONHCHA’A2,
hydrogen bonded to the amide proton and thereby determining
X being a
the conformation of the ocyl
.
We hove since extended our investigations (a) definition titative
and (c) determination
be achieved by forming diastereomeric
and separating them by liquid chromatogmphy on silica gel. chromatography (HPLC)‘,
purity
9 of this series it was shown that directed reond It
prediction
tion of enontiomers. R1R2HCCOOH,
method: (c) quon-
stereochemicol analogy model) and (d) prepamtive
We now report our observations
o class containing
aspects of the directed resolution
(b) measurement of precise separation focton by HPLC,
of separation factors (Ltgi-Ruth
macological and stereochemicol
concerning its application
numerous compounds which are frequently
to amides of corboxylic
sepamacids
encountered ond often of phar
importance. concepts 3
Our method is based on the following
(1) Secondary omides odopt essentially (on silica
to include the following
of the scope of opplicobility,
:
the same conformations
in polar solutions
and in the adsorbed state
gel).
(2) In the adsorbed state o parallel alignment of the planar amide group and the surface of the silica gel is preferred
(the latter is supposed to be planar in micro regions’).
(3) Apolor groups (alkyl, oryl) outside the omide plane cause o disturbance of this preferred arrangement in proportion
to their steric bulk in a direction
perpendicular
to the amide plane I)
. Such groups are classified
as large and small by indices L and S, respectively. (4) That member of a diostereomeric
pair in which both faces of the omide plane are more shielded thon the
least shielded face in the other member is eluted first.
la8
No. 16
(5) There is an attractive
intemction
between small polar groups and the silica
hydrogen bond donors not internally
bonded to the amide group. Formally,
gel, particularly,
if they ore
such groups are assigned to the
S (small) class. On the basis of these points,
specific rules can be formulated for various classes of secondary amides if their
conformations
can be defined independently
Fortunately,
the conformation of the carbinylimine
(la) Amides RCONHCHA1A2 tion characterized
of the individual
properties of the groups referred to under (3)-(5).
moiety is always the same:
(as well as corresponding esters) have invariably
by an approximately
This statement is substantiated
antiplanar
been found to adopt a conforma-
arrangement of the fmgment HNCH
by numerous experimental
observations
38)
(see the figures below).
and by quantum chemical calcula-
tions9). A statement of such genemlity variety of the functional constant conformations
is not possible with respect to the conformation
groups to be considered is much larger.
However,
of the acyl group because the
for seveml types of acyl groups
are also found:
(lb) If there are no hydrogen bonds between R’ or R2 and the amide group the average conformation R’R’HCCONHR
is characterized
by an antiplanar
disposition
of the fragment HCC=O
of amides
(see the figures below).
la) and has since been corrobomted by extensive This conformational assignment has been discussed before NM
investigations
Combination
11)
, x-my crystallogmphy
of the concepts (l)-(S),
the foundation
to the rule illustmted
fore the enantiomer of B). This rule,
12) and quantum chemical calculations 9)
in conjunction
.
with the observations presented in (la) and (lb),
provides
by the figure: A is eluted before B (and the enantiomer of A is eluted beof course, also applies to diastereomen
derived from enantiomeric
amines:
A is eluted before the enantiomer of B (and the enantiomer of A is eluted before 8).
RESULTS.
B
1st eluted
A
The validity
configuration.
2nd
eluted
of this rule has been checked with a large number of diastereomeric
A subset is given in the table.
of known 13) configuration
were determined by synthesis
or by our recently developed PNMR
also been extended to corboxylic and by elemental onalysis.
Configurations
acids
method (PNMR)”
pairs of known (S) from components
which in the meantime hos
11). Each compound was chomcterized individually
by spectml doto
[f]
_
‘R(2) = retention
CH,
C,H, _
‘gH5
‘gH5
‘gH5
‘gH5
‘gH5
‘gH5
-
P-naphthyl
‘gH5 I-naphthyl
42 153 347
1.30 1.80
2.90
[f]
626
424
242
1.51
1.07 [d]
[e]
349
1.81
2.06
308
233
242
253
23.4
23.0
23.0
23.0
23.0
23.0
23.0
23.0
23.5
23.0
23.0
23.0
23.0
0 110
23.0
23.0
23.0
22.9
23.0
temp. [“Cl
173
1.69
1.48
1.51
1.54
1.21
1.0
1.34
349
312
1.70 1.81
313
(AG) [ca 1 [cl
1.70
-A 139
Ccl
1.27
a
l+l.
are rounded off sepamteiy.
[d] Pressure: 50 bar.
0.01
and 4 Cal.,
[e] Pressure: 200 bar.
for a and A (AG)
pressure: 100 bar; appamtw: as described in 3). [b] See text (Discussion). time of 1st and 2nd eluted component, respectively; to = ret. time of a non-ads. subst. (pentane);
8t2 if not otherwise stated;
-
CH3
CH3
CH3
CH3
CH3
CH3
CH3
CH3
CH3
‘gH5
CH2C6H5
COOCH3/CH3
‘gH5 Fermcenyl
“C4H9
!?C6H 13
C2H5
AL
amides A and B.
measurements were performed with each sample; maximal standard deviation
‘R(l)’
acetate
a
respectively; the values of a and A(AG) Eluens: I.b. petroleum ether-ethyl acetate
-RTln a; 5-10
a = tR(2)-to/‘R(l)-to’
[‘I
S/PNM
S/PNMR
PNMR
S/PNMR
PNMR
S/PNMR
S/PNMR
S/PN MR
S/PNMR
S/PNMR
Eluens: hexane-ethyl
A(AG)=
_
CH3
CH3
CH3
CH3
CH3
A
of diastereomeric
COOCH3
C,H,
RL
[a]
PNMR
CH,CH,OH
RS
sepamtion
COOCH3
[b]
liquid chromatogmphic
S/PNMR
PNMR
S/PNMR
S/PNtv’R
PNMR
S/PNMR
Config.
High performance
[a]
No.
Table.
1420
No. 16
DtSCUSSlON.
The results presented in the table are in excellent agreement with the concepk we have deline-
ated. A number of poink deserve special comment: (a) For the sake of convenience we have used hexane-ethyl acetate as the eluent throughout this investigation, tion.
Of particular
acetate,
tetmhydrofumne).
cessary for the determination
amine.
in many cases other solvents give better separa-
value are mixtures of hydrocarbons (alkones,
chloroform,
and optimization
however,
purity.
reagent as it is crystalline,
pure state.
tionally
Because of their ready availibi lity
advantageous and possible on a micro scale.
The development of enantiomer
investigation
order
phenylglycine
the determination
of ab-
and the order of TLC spots has to be es(oxalylic
chloride) or imidazoli-
(e) The pairs -150, b and -16a, b show excepamides of type ‘6 are easily hydrolized
separation reagents on the basis of these findings
by us 14). (f) I n order to examine the efficiency
the pairs of the table with MERCK-LOBAR
of elution
I-Q-naphthyl)-ethyl-
I-phenylethylamine,
(d) Experimentally,
active components, respectively,
high sepamtion effects (see concept (5)). Furthermore,
lute acids.
is only ne-
has a high UV absorption and is easily pre-
Our experience shows that prepamtion of amides via acid chlorides
des is particularly
(ethyl
is extremely simple: A mixture of diastereomeres and a pure or enriched sample has to be
prepared from mcemic and optically tablished.
(b) HPLC
TLC is adequate for the determination
methyl ester and other amino acid esters are also useful reagents. solute configumtion
effect.
(c) Highest separation factors have been obtained with
This compound is an excellent
pared in an enantiomerically
Rotic solvents seem to have a detrimental
of enantiomeric
of sepamtions.
benzene) with polar aprotic solvenk
of our method for enantiomer
a > 1.05 were separated on a preparative scale (l-20
columns or a similar prepamtive
by di-
is under active separations
15) all
g) by chromatogmphy with
low pressure technique developed in our laboratory
14 .
1) Support of this research by the Deukche Forschungsgemeinschaft is gratefully acknowledged. This work has been presented in part in lectures (Regensburg, 22.4.75 and 31.3.76 (Chemiedozenten-Tagung); Aachen, 20.1.77). 2) G. Helmchen, R. Ott, K. Sauber, Tetmhedron Lett. 1972, 3873. 3) G. Helmchen, W. Strubert, Chromatogmphia 7, 713 m. 4) 3) and footnote 13 of 2); for applications of thE method see: 4a) R. Eberhordt, C. G lotzmann, H. Lehner, K. Schlgl, Tetrahedron Lett. 1974, 4365, 4b) C.G. Scott, M.J. Petrin, T. McCorkle, J. Chromatogmphy 125, 157 (1976). 5) It is tobe emphasized that these concepts are based only on experience with silica gel. 6) L.R. Snyder, “Principles of Adsorption Chromatography, Marcel Dekker, New York, 1968, p. 159. 7) We assume that this arrangement is due to double hydrogen bonding of the type: Si-OH ***O=C-N-H*** O(H)-Si . This assumption is supported by the observation that sepamtion factors of diastereomeric esters are generally smaller than those of corresponding amides. 8) W.H. Pirkle, J.R. Hauske, J. Org. Chem. 41, 801 (1976). 9) L. Pavlidou, G. Helmchen, to be published FCILO method). 10) G. Helmchen, Tetmhedron Lett. 1974, 1527. 11) G. Helmchen, to be published. 12) A.T. Hagler, L. Leiserowitz, M. Tuval, J. Am. Chem. Sot. 98, 4600 (1976). 13 Contrary to a statement in 4a), the absolute configumtion of lql-naphthyl)-ethylamine is securely known: M.G.B. Drew, Acta Cryst. B 25, 1320 (1969). 14) G. Nill, Diplomarbeit, Stutts 1976. 15) To date, the cleavage of amides has been proven to be mther difficult. The best method for obtaining the acid appears to be the ni trosamide rearrangement: G . Helmchen, V. Relog, Helv. Chim. Acta 2, 2599 (1972). The amine can only be genemted easily from amides of type 16. 16) B. G latz, Dissertation, Stuttgart 1976. 5000-10000 theoretical plateTm (naphthaline) are achieved routinely with this technique.
DIRECTED
RESOLUTION
DERIVATIVES
III.
CARBOXYLIC
ACIDS
OF ENANTIOMERS
A CONVENIENT
lnstitut
fur Organische Stuttgart
VIA LIQUID
METHOD
CHROMATOGRAPHY
TO DETERMINE
OF DIASTEREOMERIC
THE ABSOLUTE
CONFIGURATION
OF
RTR’HCCOOH’) Gunter
D-7000
Pergarnon Press. Printedin Great Britain.
Helmchen,
Chemie,
Helene V&her and Willi
Biochemie und lsotopenforschung
Schuhle der Universitllt,
Pfaffenwaldring
55,
80
(Receivedin UK 15 February1977;
accepted
for
publication
7
March 1977)
Some timeago we introduced the term “directed resolution of enantiomers” to denote a method capable of simultaneous (a) separation of enantiomers, absolute configuration solution
of chirol
(b) determination
compounds. In papers I
of corboxyiic acids and omines con generally
2)
of enontiomeric
tion of the diastereomers. group internally group2)
condition
(c) is fulfilied
Condition
by o model which correlates elution
This model was previously
of
restricted
secondary amides
(b) is met by high performance liquid order and configura-
to amides R’R2XCCONHCHA’A2,
hydrogen bonded to the amide proton and thereby determining
X being a
the conformation of the ocyl
.
We hove since extended our investigations (a) definition titative
and (c) determination
be achieved by forming diastereomeric
and separating them by liquid chromatogmphy on silica gel. chromatography (HPLC)‘,
purity
9 of this series it was shown that directed reond It
prediction
tion of enontiomers. R1R2HCCOOH,
method: (c) quon-
stereochemicol analogy model) and (d) prepamtive
We now report our observations
o class containing
aspects of the directed resolution
(b) measurement of precise separation focton by HPLC,
of separation factors (Ltgi-Ruth
macological and stereochemicol
concerning its application
numerous compounds which are frequently
to amides of corboxylic
sepamacids
encountered ond often of phar
importance. concepts 3
Our method is based on the following
(1) Secondary omides odopt essentially (on silica
to include the following
of the scope of opplicobility,
:
the same conformations
in polar solutions
and in the adsorbed state
gel).
(2) In the adsorbed state o parallel alignment of the planar amide group and the surface of the silica gel is preferred
(the latter is supposed to be planar in micro regions’).
(3) Apolor groups (alkyl, oryl) outside the omide plane cause o disturbance of this preferred arrangement in proportion
to their steric bulk in a direction
perpendicular
to the amide plane I)
. Such groups are classified
as large and small by indices L and S, respectively. (4) That member of a diostereomeric
pair in which both faces of the omide plane are more shielded thon the
least shielded face in the other member is eluted first.
la8
No. 16
(5) There is an attractive
intemction
between small polar groups and the silica
hydrogen bond donors not internally
bonded to the amide group. Formally,
gel, particularly,
if they ore
such groups are assigned to the
S (small) class. On the basis of these points,
specific rules can be formulated for various classes of secondary amides if their
conformations
can be defined independently
Fortunately,
the conformation of the carbinylimine
(la) Amides RCONHCHA1A2 tion characterized
of the individual
properties of the groups referred to under (3)-(5).
moiety is always the same:
(as well as corresponding esters) have invariably
by an approximately
This statement is substantiated
antiplanar
been found to adopt a conforma-
arrangement of the fmgment HNCH
by numerous experimental
observations
38)
(see the figures below).
and by quantum chemical calcula-
tions9). A statement of such genemlity variety of the functional constant conformations
is not possible with respect to the conformation
groups to be considered is much larger.
However,
of the acyl group because the
for seveml types of acyl groups
are also found:
(lb) If there are no hydrogen bonds between R’ or R2 and the amide group the average conformation R’R’HCCONHR
is characterized
by an antiplanar
disposition
of the fragment HCC=O
of amides
(see the figures below).
la) and has since been corrobomted by extensive This conformational assignment has been discussed before NM
investigations
Combination
11)
, x-my crystallogmphy
of the concepts (l)-(S),
the foundation
to the rule illustmted
fore the enantiomer of B). This rule,
12) and quantum chemical calculations 9)
in conjunction
.
with the observations presented in (la) and (lb),
provides
by the figure: A is eluted before B (and the enantiomer of A is eluted beof course, also applies to diastereomen
derived from enantiomeric
amines:
A is eluted before the enantiomer of B (and the enantiomer of A is eluted before 8).
RESULTS.
B
1st eluted
A
The validity
configuration.
2nd
eluted
of this rule has been checked with a large number of diastereomeric
A subset is given in the table.
of known 13) configuration
were determined by synthesis
or by our recently developed PNMR
also been extended to corboxylic and by elemental onalysis.
Configurations
acids
method (PNMR)”
pairs of known (S) from components
which in the meantime hos
11). Each compound was chomcterized individually
by spectml doto
[f]
_
‘R(2) = retention
CH,
C,H, _
‘gH5
‘gH5
‘gH5
‘gH5
‘gH5
‘gH5
-
P-naphthyl
‘gH5 I-naphthyl
42 153 347
1.30 1.80
2.90
[f]
626
424
242
1.51
1.07 [d]
[e]
349
1.81
2.06
308
233
242
253
23.4
23.0
23.0
23.0
23.0
23.0
23.0
23.0
23.5
23.0
23.0
23.0
23.0
0 110
23.0
23.0
23.0
22.9
23.0
temp. [“Cl
173
1.69
1.48
1.51
1.54
1.21
1.0
1.34
349
312
1.70 1.81
313
(AG) [ca 1 [cl
1.70
-A 139
Ccl
1.27
a
l+l.
are rounded off sepamteiy.
[d] Pressure: 50 bar.
0.01
and 4 Cal.,
[e] Pressure: 200 bar.
for a and A (AG)
pressure: 100 bar; appamtw: as described in 3). [b] See text (Discussion). time of 1st and 2nd eluted component, respectively; to = ret. time of a non-ads. subst. (pentane);
8t2 if not otherwise stated;
-
CH3
CH3
CH3
CH3
CH3
CH3
CH3
CH3
CH3
‘gH5
CH2C6H5
COOCH3/CH3
‘gH5 Fermcenyl
“C4H9
!?C6H 13
C2H5
AL
amides A and B.
measurements were performed with each sample; maximal standard deviation
‘R(l)’
acetate
a
respectively; the values of a and A(AG) Eluens: I.b. petroleum ether-ethyl acetate
-RTln a; 5-10
a = tR(2)-to/‘R(l)-to’
[‘I
S/PNM
S/PNMR
PNMR
S/PNMR
PNMR
S/PNMR
S/PNMR
S/PN MR
S/PNMR
S/PNMR
Eluens: hexane-ethyl
A(AG)=
_
CH3
CH3
CH3
CH3
CH3
A
of diastereomeric
COOCH3
C,H,
RL
[a]
PNMR
CH,CH,OH
RS
sepamtion
COOCH3
[b]
liquid chromatogmphic
S/PNMR
PNMR
S/PNMR
S/PNtv’R
PNMR
S/PNMR
Config.
High performance
[a]
No.
Table.
1420
No. 16
DtSCUSSlON.
The results presented in the table are in excellent agreement with the concepk we have deline-
ated. A number of poink deserve special comment: (a) For the sake of convenience we have used hexane-ethyl acetate as the eluent throughout this investigation, tion.
Of particular
acetate,
tetmhydrofumne).
cessary for the determination
amine.
in many cases other solvents give better separa-
value are mixtures of hydrocarbons (alkones,
chloroform,
and optimization
however,
purity.
reagent as it is crystalline,
pure state.
tionally
Because of their ready availibi lity
advantageous and possible on a micro scale.
The development of enantiomer
investigation
order
phenylglycine
the determination
of ab-
and the order of TLC spots has to be es(oxalylic
chloride) or imidazoli-
(e) The pairs -150, b and -16a, b show excepamides of type ‘6 are easily hydrolized
separation reagents on the basis of these findings
by us 14). (f) I n order to examine the efficiency
the pairs of the table with MERCK-LOBAR
of elution
I-Q-naphthyl)-ethyl-
I-phenylethylamine,
(d) Experimentally,
active components, respectively,
high sepamtion effects (see concept (5)). Furthermore,
lute acids.
is only ne-
has a high UV absorption and is easily pre-
Our experience shows that prepamtion of amides via acid chlorides
des is particularly
(ethyl
is extremely simple: A mixture of diastereomeres and a pure or enriched sample has to be
prepared from mcemic and optically tablished.
(b) HPLC
TLC is adequate for the determination
methyl ester and other amino acid esters are also useful reagents. solute configumtion
effect.
(c) Highest separation factors have been obtained with
This compound is an excellent
pared in an enantiomerically
Rotic solvents seem to have a detrimental
of enantiomeric
of sepamtions.
benzene) with polar aprotic solvenk
of our method for enantiomer
a > 1.05 were separated on a preparative scale (l-20
columns or a similar prepamtive
by di-
is under active separations
15) all
g) by chromatogmphy with
low pressure technique developed in our laboratory
14 .
1) Support of this research by the Deukche Forschungsgemeinschaft is gratefully acknowledged. This work has been presented in part in lectures (Regensburg, 22.4.75 and 31.3.76 (Chemiedozenten-Tagung); Aachen, 20.1.77). 2) G. Helmchen, R. Ott, K. Sauber, Tetmhedron Lett. 1972, 3873. 3) G. Helmchen, W. Strubert, Chromatogmphia 7, 713 m. 4) 3) and footnote 13 of 2); for applications of thE method see: 4a) R. Eberhordt, C. G lotzmann, H. Lehner, K. Schlgl, Tetrahedron Lett. 1974, 4365, 4b) C.G. Scott, M.J. Petrin, T. McCorkle, J. Chromatogmphy 125, 157 (1976). 5) It is tobe emphasized that these concepts are based only on experience with silica gel. 6) L.R. Snyder, “Principles of Adsorption Chromatography, Marcel Dekker, New York, 1968, p. 159. 7) We assume that this arrangement is due to double hydrogen bonding of the type: Si-OH ***O=C-N-H*** O(H)-Si . This assumption is supported by the observation that sepamtion factors of diastereomeric esters are generally smaller than those of corresponding amides. 8) W.H. Pirkle, J.R. Hauske, J. Org. Chem. 41, 801 (1976). 9) L. Pavlidou, G. Helmchen, to be published FCILO method). 10) G. Helmchen, Tetmhedron Lett. 1974, 1527. 11) G. Helmchen, to be published. 12) A.T. Hagler, L. Leiserowitz, M. Tuval, J. Am. Chem. Sot. 98, 4600 (1976). 13 Contrary to a statement in 4a), the absolute configumtion of lql-naphthyl)-ethylamine is securely known: M.G.B. Drew, Acta Cryst. B 25, 1320 (1969). 14) G. Nill, Diplomarbeit, Stutts 1976. 15) To date, the cleavage of amides has been proven to be mther difficult. The best method for obtaining the acid appears to be the ni trosamide rearrangement: G . Helmchen, V. Relog, Helv. Chim. Acta 2, 2599 (1972). The amine can only be genemted easily from amides of type 16. 16) B. G latz, Dissertation, Stuttgart 1976. 5000-10000 theoretical plateTm (naphthaline) are achieved routinely with this technique.