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Intramolecular cyclization of N-sulfonyl substituted α-bromoamidines and guanidines
Tetrahedron Letters No. 1, pp 49 - 52. Ltd. 1979. Printed in Great Britain.
%,F’ergamon Press
INTRAMOLECULAR
CYCLIZATION
a-BROMOAMIDINES
Gerrit Department
L'abbe
the reaction a second Thus,
when
yield -2a.
which The
in ether gave
with
-la
spectral
IR spectrum
data
'c-c
strong
t
/
recently
azide.
was
treated
c: R
non-equivalent function. at 6 96.4 peak
(S=O)
absorptions
fragment
(50%, Me2C=C=NBut'+
to afford
158.6
of potassium
was obtained
consistent
at 1685,
with
1650
in 83%
structure
(doublet,
C=N)
\\90 ) CH3./ 1/C\o/SlR3 R
1
=
Me,
R2 = tB~, R3 = Ph
1
R3 = Me
= H, R2 = tBu, R3 = Ph (CDC13)
the two methyl
(at 6 1.52 and 1.7) due to the anisotropic
(C') and
two equiv
R2N+ C-N
BuOK
In the 'H NMR spectrum
The ring carbon
(5%) and
Similarly,
.
from
to report
(mp 67-68')
b: R1 = Me, R2 = p-CH3C6H4,
-1
obtained
2
a: R
1050 cm
been
We now wish
with
analysis
1
and
1
system.
‘\,S02R3
Br
have
and elemental
NHR2
CH3
Belgium
for 2 h, a compound
(KBr) shows
R"l
Heverlee,
(mp 85-86")2
at O'C
of Leuven
methanesulfonyl
to this new ring
a-bromoamidine
tert-butoxide
Verbruggen
University
3-oxathiazol-2-ones
of ketenimines
approach
and Andre
200F, B-3030
4-Imino-4,5-dihydro-1,2A6,
SUBSTITUTED
AND GUANIDINES
of Chemistry,
Celestijnenlaan
OF N-SULFONYL
absorptions (C4).
peaks
in the
The mass
at m/e
222
13
C NMR
spectrum
effect
spectrum
exhibits
(7%, M'+ - Me2CO),
groups
are
of the sulfinyl (CDC13) are found
a weak molecular 141
ion
(90%, PhS02+),
125
) and 77 (lOO%, Ph+).
_lb (mp 128-129O) respectively
-2b
and -lc
(mp 83-84')
(40%, mp 96-97') 49
reacted
and -2c
with
tBuOK
(50%, colourless
in ether oil).
at O'C
Compound
No.
50
-2b was
identical
in all respects
N-tolylketenimine shows
and methanesulfonyl
the presence
4 in steady-state sure and
because
2a,b isomerize --
3a,b on warming. --
(i) a concerted
1
aside.
mixture
smoothly
shift,
equilibrium
1,5-sigmatropic
with
R2N\.H-CH2,/C
and
The mixture
could
of 2
of -2a and -3a during gration order
concerted
A kinetic
activation Since
the reaction
parameters:
the dipole
trend
but
not found. when
in a stepwise
manner
estimated signals.
in benzene),
b
of
CH2=ClCcNR2
I NHS02R3
reproducible.
solvents. from
was
in Table
1.
and AS
*
H NMR
than that of 2
were
giving
by inte-
strictly
The experiments
first-
in ben-
the following
(3.6 and 5.0 D for 2
for the concerted
substituted
spectra
amounts
= -32 e.u.
mechanism
of the solvent
in chloroform
does
we may
increases.
for acetonitrile
If, on the contrary,
via decomposition
1
the
temperatures
observed
The relative
The reactions
as the polarity
benzene
The rate acceleration is indeed
were
in several
of 2 is smaller
in rate constant
sulfoxide.
out
out at different
a small
was
slow
II N 'S02R3
are summarized
determined
however,
study
2
CH3\ Rl/C\C/NR
tB~ proton
-3b respectively, increase
ring clo-
3
Ea = 16.3 kcal/mol
moment
of dipole
CH2=C=C_NHR2 II 7 NS02R=
p
Lx
T-
was carried
also carried
isomerization:
5
and the rate constants
zene-d 6 were
ami-
,l K
2
of the CH3 and/or
the acrylic
undergoes
into the amidines.
4 the thermolysis
at 20'.
formation
4 subsequently
2
R1/C\c&NR
even
for this
-N
”
CH3\+
(CDC13) of C
at 6 1.42 and
into
(ii) the intermediate
shift
from dimethyl-
not be separated
in solution
andquantitatively
Dipole
U//O ,lJ\,,S._3
Lx
two doublets
can be considered
with 2.
hydrogen
prepared
1H NMR spectrum
it decomposed
Two mechanisms
1,7-hydrogen
sample
The
at 6 4.96 and 5.12 ppm.
the two diastereoisomers
The oxathiazolines dines
an authentic
of an erythro-threo
1.6 and two quartets into
with
1
and expect This,
or dimethyl
not fit the general
the isomerization
of 2 in the rate-determining
proceeds
step, we may
No. 1
51
Table 1. Kinetics for the isomerization & Temp, OC
Solventa CgD6
+
3a
lo5 kl (set-'1
55
2.88
61
4.25
69
8.21
74.5
11.7
CDC13
60
11
CD3CN
60
4.95
DMSO-d6 60 -________-____-_-_-
1.45
a The solvents were treated with alumina in order to avoid acid-catalyzed isomerization
expect a similar kinetic behaviour to that reported by Quast (autocatalytic reaction!). 3
This was not found to be the case so that no definite conclusion can
be drawn on the mechanism at the present time. Attempts to synthesize the desired sulfonyl substituted aziridinimines were unsuccessful.
For instance, 2 proved to be unreactive towards tBuOK or
lithium 2,2,6,6_tetramethylpiperidide. of the tosyl
(e.g. 21
4
This contrasts sharply with the isolation
substituted diaziridinimine 8 (mp 80-81°) in 85% yield from the
guanidine l5 as shown below. tBu 1
NHBut / a NS02C6H5
/But
tBU
t tBuNH-C-NHBu1: 'Ts
'N-N \/
1) tBuOCl F 2) tBuOK
N-N
NC '
/" 'Ts
'Ts 9
-8
Compound g possesses an IR spectrum (KBr) with absorptions 1320 and 1160 cm -' (S02), while the 1H NMR spectrum
tert-butyl
\
- (CH3)2C=CH2
I
ce of one broad
tB~
h
tert-butyl
substituents
signal
is also
at 6 1.25 ppm.
apparent
6
at 1750 (broad s, C=N),
(CDC13)
indicates
The presence
from the 13C NMR
the presen-
of two identical
spectrum
(resonances
at
No.
52
6 26.8 and spectrum
The ring carbon
of 8 features
(6%, M'+Thermolysis needles
62.1 ppm).
2 Me2C=CH2),
peaks 168
of 8 in boiling
(mp 176-177')
The tosyl
7
toluene
(2%, M'+),
(348, Ts+)
The formation t
BuN=NH
then rearranges
yielding
is found at 6 157.9 ppm. 267
(20%, M'+-
and 91
for 5 h yielded
of 8 into
isonitrile8
to the azo compound,
323
(60%), 155
in 58% yield.
in terms of fragmentation tene.
at m/e
atom
The mass
Me2C=CH2),
211
(90%, CH3C6H4+).
the hydrazine
-9 as white
of this compound
and TsNC with to the more
1
is interpreted
elimination
stable
of isobu-
nitrile
and adds
2.
ACKNOWLEDGEMENT We thank R. Verbergt for experimental assistance. A. Verbruggen is indebted to the I.W.O.N.L. for a doctoral fellowship. Financial support from the Ministry of National Education and from the F.K.F.O. is gratefully acknowledged. REFERENCES 1.
AND NOTES
G. L'abbe, C-C. Yu, J-P. Declercq, G. Germain, and M. Van Meerssche, Angew. Chem., 90, 394 (1978); Angew. Chem. Int. Ed. Engl., II, 352 (1978).
2. The starting materials -la-c were prepared from the correspondingN-sulfonyl substituted a-bromoamides by treatment with PC15 and then with primary amines, analogous to the procedures described by J. v. Braun and W. Rudolph, Ber., 67, 1762 (1934). 3. H. Quast and P. Schifer, Tetrahedron Lett., 1057 (1977). 4. R. A. Olofson and C. M. Dougherty, J. Am. Chem. Sot., 95, 581 (1973). 5. W. V. Farrar, J. Chem. Sot., 856 (1965). 6. At lower temp. (-6') the tert-butyl groups become magnetically non-equivalent and give rise to two singlets. This is due to restricted isomerization at the C=N double bond, see also ref. 7. 7.
H. Quast and E. Schmitt, Angew. Chem., 81, 428 (1969); Angew. Chem. Int. Ed. Engl., S, 448 (1969).
8. Sulfonyl isonitriles are unknown but N-acyl and N-imidoyl substituted isonitriles have recently been prepared, see G. Hzfle and B. Lange, Angew. Chem., 2, Int. Ed. Engl., 16, 262 and 727 (1977).
(Received in UK
30 October 1978)
272 and 742 (1977);
Angew. Chem.
%,F’ergamon Press
INTRAMOLECULAR
CYCLIZATION
a-BROMOAMIDINES
Gerrit Department
L'abbe
the reaction a second Thus,
when
yield -2a.
which The
in ether gave
with
-la
spectral
IR spectrum
data
'c-c
strong
t
/
recently
azide.
was
treated
c: R
non-equivalent function. at 6 96.4 peak
(S=O)
absorptions
fragment
(50%, Me2C=C=NBut'+
to afford
158.6
of potassium
was obtained
consistent
at 1685,
with
1650
in 83%
structure
(doublet,
C=N)
\\90 ) CH3./ 1/C\o/SlR3 R
1
=
Me,
R2 = tB~, R3 = Ph
1
R3 = Me
= H, R2 = tBu, R3 = Ph (CDC13)
the two methyl
(at 6 1.52 and 1.7) due to the anisotropic
(C') and
two equiv
R2N+ C-N
BuOK
In the 'H NMR spectrum
The ring carbon
(5%) and
Similarly,
.
from
to report
(mp 67-68')
b: R1 = Me, R2 = p-CH3C6H4,
-1
obtained
2
a: R
1050 cm
been
We now wish
with
analysis
1
and
1
system.
‘\,S02R3
Br
have
and elemental
NHR2
CH3
Belgium
for 2 h, a compound
(KBr) shows
R"l
Heverlee,
(mp 85-86")2
at O'C
of Leuven
methanesulfonyl
to this new ring
a-bromoamidine
tert-butoxide
Verbruggen
University
3-oxathiazol-2-ones
of ketenimines
approach
and Andre
200F, B-3030
4-Imino-4,5-dihydro-1,2A6,
SUBSTITUTED
AND GUANIDINES
of Chemistry,
Celestijnenlaan
OF N-SULFONYL
absorptions (C4).
peaks
in the
The mass
at m/e
222
13
C NMR
spectrum
effect
spectrum
exhibits
(7%, M'+ - Me2CO),
groups
are
of the sulfinyl (CDC13) are found
a weak molecular 141
ion
(90%, PhS02+),
125
) and 77 (lOO%, Ph+).
_lb (mp 128-129O) respectively
-2b
and -lc
(mp 83-84')
(40%, mp 96-97') 49
reacted
and -2c
with
tBuOK
(50%, colourless
in ether oil).
at O'C
Compound
No.
50
-2b was
identical
in all respects
N-tolylketenimine shows
and methanesulfonyl
the presence
4 in steady-state sure and
because
2a,b isomerize --
3a,b on warming. --
(i) a concerted
1
aside.
mixture
smoothly
shift,
equilibrium
1,5-sigmatropic
with
R2N\.H-CH2,/C
and
The mixture
could
of 2
of -2a and -3a during gration order
concerted
A kinetic
activation Since
the reaction
parameters:
the dipole
trend
but
not found. when
in a stepwise
manner
estimated signals.
in benzene),
b
of
CH2=ClCcNR2
I NHS02R3
reproducible.
solvents. from
was
in Table
1.
and AS
*
H NMR
than that of 2
were
giving
by inte-
strictly
The experiments
first-
in ben-
the following
(3.6 and 5.0 D for 2
for the concerted
substituted
spectra
amounts
= -32 e.u.
mechanism
of the solvent
in chloroform
does
we may
increases.
for acetonitrile
If, on the contrary,
via decomposition
1
the
temperatures
observed
The relative
The reactions
as the polarity
benzene
The rate acceleration is indeed
were
in several
of 2 is smaller
in rate constant
sulfoxide.
out
out at different
a small
was
slow
II N 'S02R3
are summarized
determined
however,
study
2
CH3\ Rl/C\C/NR
tB~ proton
-3b respectively, increase
ring clo-
3
Ea = 16.3 kcal/mol
moment
of dipole
CH2=C=C_NHR2 II 7 NS02R=
p
Lx
T-
was carried
also carried
isomerization:
5
and the rate constants
zene-d 6 were
ami-
,l K
2
of the CH3 and/or
the acrylic
undergoes
into the amidines.
4 the thermolysis
at 20'.
formation
4 subsequently
2
R1/C\c&NR
even
for this
-N
”
CH3\+
(CDC13) of C
at 6 1.42 and
into
(ii) the intermediate
shift
from dimethyl-
not be separated
in solution
andquantitatively
Dipole
U//O ,lJ\,,S._3
Lx
two doublets
can be considered
with 2.
hydrogen
prepared
1H NMR spectrum
it decomposed
Two mechanisms
1,7-hydrogen
sample
The
at 6 4.96 and 5.12 ppm.
the two diastereoisomers
The oxathiazolines dines
an authentic
of an erythro-threo
1.6 and two quartets into
with
1
and expect This,
or dimethyl
not fit the general
the isomerization
of 2 in the rate-determining
proceeds
step, we may
No. 1
51
Table 1. Kinetics for the isomerization & Temp, OC
Solventa CgD6
+
3a
lo5 kl (set-'1
55
2.88
61
4.25
69
8.21
74.5
11.7
CDC13
60
11
CD3CN
60
4.95
DMSO-d6 60 -________-____-_-_-
1.45
a The solvents were treated with alumina in order to avoid acid-catalyzed isomerization
expect a similar kinetic behaviour to that reported by Quast (autocatalytic reaction!). 3
This was not found to be the case so that no definite conclusion can
be drawn on the mechanism at the present time. Attempts to synthesize the desired sulfonyl substituted aziridinimines were unsuccessful.
For instance, 2 proved to be unreactive towards tBuOK or
lithium 2,2,6,6_tetramethylpiperidide. of the tosyl
(e.g. 21
4
This contrasts sharply with the isolation
substituted diaziridinimine 8 (mp 80-81°) in 85% yield from the
guanidine l5 as shown below. tBu 1
NHBut / a NS02C6H5
/But
tBU
t tBuNH-C-NHBu1: 'Ts
'N-N \/
1) tBuOCl F 2) tBuOK
N-N
NC '
/" 'Ts
'Ts 9
-8
Compound g possesses an IR spectrum (KBr) with absorptions 1320 and 1160 cm -' (S02), while the 1H NMR spectrum
tert-butyl
\
- (CH3)2C=CH2
I
ce of one broad
tB~
h
tert-butyl
substituents
signal
is also
at 6 1.25 ppm.
apparent
6
at 1750 (broad s, C=N),
(CDC13)
indicates
The presence
from the 13C NMR
the presen-
of two identical
spectrum
(resonances
at
No.
52
6 26.8 and spectrum
The ring carbon
of 8 features
(6%, M'+Thermolysis needles
62.1 ppm).
2 Me2C=CH2),
peaks 168
of 8 in boiling
(mp 176-177')
The tosyl
7
toluene
(2%, M'+),
(348, Ts+)
The formation t
BuN=NH
then rearranges
yielding
is found at 6 157.9 ppm. 267
(20%, M'+-
and 91
for 5 h yielded
of 8 into
isonitrile8
to the azo compound,
323
(60%), 155
in 58% yield.
in terms of fragmentation tene.
at m/e
atom
The mass
Me2C=CH2),
211
(90%, CH3C6H4+).
the hydrazine
-9 as white
of this compound
and TsNC with to the more
1
is interpreted
elimination
stable
of isobu-
nitrile
and adds
2.
ACKNOWLEDGEMENT We thank R. Verbergt for experimental assistance. A. Verbruggen is indebted to the I.W.O.N.L. for a doctoral fellowship. Financial support from the Ministry of National Education and from the F.K.F.O. is gratefully acknowledged. REFERENCES 1.
AND NOTES
G. L'abbe, C-C. Yu, J-P. Declercq, G. Germain, and M. Van Meerssche, Angew. Chem., 90, 394 (1978); Angew. Chem. Int. Ed. Engl., II, 352 (1978).
2. The starting materials -la-c were prepared from the correspondingN-sulfonyl substituted a-bromoamides by treatment with PC15 and then with primary amines, analogous to the procedures described by J. v. Braun and W. Rudolph, Ber., 67, 1762 (1934). 3. H. Quast and P. Schifer, Tetrahedron Lett., 1057 (1977). 4. R. A. Olofson and C. M. Dougherty, J. Am. Chem. Sot., 95, 581 (1973). 5. W. V. Farrar, J. Chem. Sot., 856 (1965). 6. At lower temp. (-6') the tert-butyl groups become magnetically non-equivalent and give rise to two singlets. This is due to restricted isomerization at the C=N double bond, see also ref. 7. 7.
H. Quast and E. Schmitt, Angew. Chem., 81, 428 (1969); Angew. Chem. Int. Ed. Engl., S, 448 (1969).
8. Sulfonyl isonitriles are unknown but N-acyl and N-imidoyl substituted isonitriles have recently been prepared, see G. Hzfle and B. Lange, Angew. Chem., 2, Int. Ed. Engl., 16, 262 and 727 (1977).
(Received in UK
30 October 1978)
272 and 742 (1977);
Angew. Chem.