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New methods for β-conjugate addition and β-hydroxyalkylation of enones
0040-4039/88 $3.00 + .OO Perqamon Press plc
Tetrahedron Letters.Vol.29.No.42,pp .__ 5413-5416,1988 Printed in Great Britain
NEWPQTH~DSFOR ~-CONJUGATEAODITIONMD
Sunggak
Kim* and Phil Ho Lee
Department Korea Advanced
S-Conjugate
Summary:
reaction
Institute
addition
olefins
and
and aldehydes
functionalization
namely, These is
the
conversion
approaches
capable
of
regenerate different
double
phoniosilylation
elimination
of enones
can be normally
anions
Although
methods
of enones
have
via
which
serve
at B-position
using triphenylphosphine
literature
and silylating
reversal
anion
groups
at
process,
equivalents.'
at &position,
beiny
easily
indicates
one of the promising
by the
activated
procedure.
as R-acylvinyl
as
with
in tetrahydrofuran
by dipole
functional as well
of the
developed,*
triflate
salts by one-pot
accomplished
of suitable
examination
been
Korea
phosphoniosilylation,
of trimethylsilyl
into adducts
stable
bonds.
enones
of phosphonium
of the introduction
generating
synthetic
from
Seoul 130-012,
of enones have been accomplished
5-hydroxyalkylation
of enones
consist
and Technology,
in the presence
-78 OC and subsequent
The
of Chemistry
of Science
derivated
of ylides,
p-HYWOXYALKYLATI~N0F ENONES+
ayents,
to
a number
of
that
methods
which
eliminated
involves
previously
phos-
developed
by Evans3 and Kozikowski.4
6
OTBDMS
TBDMSOTf PPh3, THF
n-BuLi
OTf- ;Ph3
Yk
(yIh,-
g
2
1. OTdijMS
0 n-BuqNF -
TMSOTf +&EwG
-
EWG
B-Conjugate Wittig
reagents
cyclopropane (2) derived in the
+Dedicated
to
of Enones
activated
derivatives
enones
salt
of trimethylsilyl (3) in good yields
to Professor
to Activated
olefins
proceeds
is of synthetic
from phosphonium
presence
alkylated
Addition
Olefins. by
importance.6
of silyl enol ether triflate
(TMSOTf)7
by one-pot
Although
several
the conjugate
pathways,b
However, (1) cleanly
5413
addition formation
we have found that react with
in tetrahydrofuran
procedure.
E.J. Corey on the occasion
the
of his 60th birthday.
of of
the ylide
activated
olefins
at -78 OC to yive
&
5414
Reaction vinyl
of the ylide
ketone
ammonium
fluoride
byproducts. Michael
gives
to another
conjugate
products.8*g
cyclohexenone
that the low yield enolate
addition
The addition
to some extent, yielding
from
at -78 OC for
via phosphoniosilylation
1 h followed
by the addition
3-(3-oxopentyl)-Z-cyclohexen-l-one
It is expected
adduct
further
(2) derived
in tetrahydrofuran
of
might
due to the presence
enolates
to
ethyl
of hexamethylphosphoric
the desired
product
in 21% yield
be resulted
vinyl
ketone
triamide
in 47% yield
to
ethyl
of an initial
vinyl
produce
(HMPA) improves
toyether
ethyl
alony with several
from tautomerism
of the unreacted
with
of tetra-n-butyl-
ketone
the
and
dialkylated
the present
reaction
with the dialkylated
products
in 20% yield. order to avoid the side reactions,
In Michael
adduct
TMSOTf
gives
with best
silylating results
ineffective
for this purpose.
and TMSOTf
in tetrahydrofuran
tetra-n-butylammonium the contamination derived
fran
agents.
and
is
Amony
gives
of dialkylated enones
of the premixed
solution
procedure,
carbonyl
compounds
olefins
results are given in Table
compounds
such
as
is
vinyl ketone
by the addition
the reaction proceeds
and
the efficiency
study,
chloride
in 7Y% yield
in hiyh yields.")
acrylonitrile
1 and illustrate
an initial
in this
of ethyl
(2) at -78 'C followed
a modified
other
activated
tested
trimethylsilyl
Using
works
with
ayents
while
o,@unsaturated
2,3-unsaturated-1,6-dicarbonyl
well
silylating
of trappiny
3-(3-oxopentyl)-2-cyclohexene-l-one
products.
with
the possibility
recommended,
at -78 OC to the ylide
rapidly, yielding
experimental
several
generally
Thus, the addition
fluoride
several
we considered
The
vinyl
of
without
of ylides
cleanly present
and
method
sulfone.
some
and the applicability
of
the present method.
8-Hydroxyalkylation reaction
of enones
of enones.
of
Enones.
to activated
Encouraged olefins,
As far as we are aware,
intermediates
prior to the formation
been
that the similar
reported
trimethylsilyl The betiane Reaction for
10
present
method
of the ylide followed
hydroxybenzylated yield.
TMSOTf
in quenching contamination
the
results
no successful
reports
of oxaphosphetane
intermediate
obtained
in
the possibility have appeared
with
silylatiny
in the boron-Wittiy
conjugate
addition
of 6-hydroxyalkylation for quenchiny
agents,
reaction
betaine
althouyh
it has
has been quenched
with
chloride."
intermediates
min
by
we have studied
is based
with TMSOTf, (2) with by
the
cyclohexenone
on the
Wittiy
an equimolar addition
of
amount
betaine
(4) in 29% yield
of the
intermediate,
Wittiy
pr0duct.l'
of ylides
yielding
with
of phosphonium
of benzaldehyde
tera-n-butylammonium
is found to be much more effective the
reaction
and facile elimination
together
with
aldehydes,4
in tetrahydrofuran
fluoride the
at
Wittiy
than t-butyldimethylsilyl the
desired
In the case of
product usiny
quenchiny
salts via desilylation.
-78
product triflate
in 72% yield
aliphatic
at -78 OC
OC
rives
B-
(5) in 21% (TBUMSUTP) without
aldehydes,
the it is
5415
Table 1. @-Conjugate Addition of Enones to Activated Olefins
enone
isolated yield, Xa
product
activated olefin
0
6
EWG CH2=CHCOCH2CH3
EWG=COCH2CH3
79 (21)b
CH2=CHCOC6H5
=COCgH5
CH2=CHCOOCH2CH3
=COOCH2CH3
58 (0)b
CH2=CH-SO2C6H5
=S02CgH5
68 (0)b
CH2=CH-CN
=CN
58
(wb
0
6/
WG CH2=CHCOCH2CH3
EWG=COCH2CH3
CH2=CHCOOCH2CH3
68
=COOCH2CH3
64
LEWG CH2=CHCOCH2CH3
EWG=COCH2CH3
CH2=CH-CN
73 (70:30)=
=CN
77 (85:15)'
a the yields are based on enones. b the reactions are performed in the absence of TMSOTf. 'the ratio of trans/cis isomer.
Table 2. B-Hydroxyalkylationof Enones
enone
RCHO
2-cyclopenten-l-one
C6H5CHO
2-cyclohexen-l-one
a
isolated yield, 'Za 57
CH3(CH2)7CH0
54
c-C6H11CH0
63
C6H5CHO
72
CH3(CH2)7CH0
63
carvone
C6H5CHO
48 (8)b
4-hexen-3-one
C6H5CHO
68
c-C6HllCHO
60
the yields of a-hydroxyalkylatedenones.
b
the yield of the recovered starting material
5416
preferred
to add an aldehyde
and TMSUTf
use of an equimolar
mixture
corresponding
enol ethers
Table
2.
aromatic
silyl
The
present
aldehydes.
Acknowledgment. support
method
well
and simultaneously results
that
results
and acyclic
the ylide
to steric
Institute
enones
(2) does
because
formation
the
of the
are summarized with
aliphatic
not react with
in and
ketones
reasons.
of Science
to Dr. Sung Soo Kim for experimental
References
in the
Some experimental
due possibly
the Korea Advanced
and we are grateful
separately
and TMSOTf
in both cyclic
it is noteworthy
and cyclohexanone
We thank
aldehydes
to some extent.13
works
However,
such as acetophenone
to the ylide
of aliphatic
and Technology
for financial
assistance.
and Notes
1. For reviews, see: (a) J. C. Stowell, Chem. Rev., 84, 409 (1984). (b) 0. Hoppe,Anyew. Chem. Int. Ed. Engl.,g, 2. (a) K. Kondo
and A. J. Mura, T.
F.
48,
Tetrahedron
Ibid.,
3187
and H. E. Morton,
Ginsberg,
Tetrahedron
Jr., J. Org. Chem., 41,
Weingartner,
Larcheveque, Piers
932 (1984).
and D. Tunemoto,
Ibid., 47,
Lett.,
1007
2506 (1976).
Lett.,
2506
(1975).
(1976).
(d)
A.
Uebal,
(1977).
(e) C. Shih and J. S. Swenton,
J. Org.
Chem., 3,
2229
(1982).
3437
(lY7Y).
(h) H. J. Cristau,
0. A. Bennett,
M. L. F. Bakuzis, T.
Cuviyny,
Ibid., 4217
(q) U.
M.
(1981).
(f) E.
U. Sunay,
and S.
and C. Nianyoran,
Ibid.,
Liotta,
B. Chabaud,
and
and
1527 (1983).
3. D. A. Evans,
K. M. Hurst, and J. M. Takacs, J. Am. Chem. Sot., I&l,
4. (a) A. P. Kozikowski
and S. H. Jung, J. Org. Chem., 51,
and S. H. Jung, Tetrahedron 5. G. M. Kosolapoff
6. (a) H. J. Bestman Finkelhor,
Lett.,
and L. Maier,
1973 and references
Phosphorous
Compounds",
Lett.,
Lett.,
Angew.
Chem.,
154
3781
(1972).
3,
in 68% yield 10. The ylide
(b) A. P. Kozikowski
Wiley
Intersciences,
Vol. 3,
(c) M. J.
ketone
(1962). Devos,
(b) P. A. Grieco L. Hevesi,
and R. S.
P. Bayet,
and A.
3911 (1986).
7. For an excellent review, see: H. Emde et al., Synthesis, vinyl
3467 (1978).
(1986).
3227 (1986).
"Organic
and F. Seng,
8. (a) M. E. Jung, Tetrahedron, phenyl
3402
cited therein.
Tetrahedron
Krief, Tetrahedron
9. When
(b) T. Cohen,
(c) P. Bakuzis,
32_, 3 (1976).
was used as an activated
in the absence
of TMSOTf,
1 (1982).
(b) R. E. tiawley, Synthesis, olefin,
as shown in Table
(2) did not react with ethyl acrylate
the desived
777 (1976). product
was obtained
1.
in the absence
of TMSUTP.
11. A. Pelter, D. Buss, and A. Pitchford, Tetahedron Lett., 5093 (1985). 12. The use of TBDMSOTf cyclohexenone 13. The formation
in
as a trapping
agent was totally
ineffective,
yieldiny
26% yield toyether with the Wittig product in 3Y% yield.
of a small amount
of aldol products was also observed.
(Received in Japan 22 August 19881
B-hydroxybenylated
Tetrahedron Letters.Vol.29.No.42,pp .__ 5413-5416,1988 Printed in Great Britain
NEWPQTH~DSFOR ~-CONJUGATEAODITIONMD
Sunggak
Kim* and Phil Ho Lee
Department Korea Advanced
S-Conjugate
Summary:
reaction
Institute
addition
olefins
and
and aldehydes
functionalization
namely, These is
the
conversion
approaches
capable
of
regenerate different
double
phoniosilylation
elimination
of enones
can be normally
anions
Although
methods
of enones
have
via
which
serve
at B-position
using triphenylphosphine
literature
and silylating
reversal
anion
groups
at
process,
equivalents.'
at &position,
beiny
easily
indicates
one of the promising
by the
activated
procedure.
as R-acylvinyl
as
with
in tetrahydrofuran
by dipole
functional as well
of the
developed,*
triflate
salts by one-pot
accomplished
of suitable
examination
been
Korea
phosphoniosilylation,
of trimethylsilyl
into adducts
stable
bonds.
enones
of phosphonium
of the introduction
generating
synthetic
from
Seoul 130-012,
of enones have been accomplished
5-hydroxyalkylation
of enones
consist
and Technology,
in the presence
-78 OC and subsequent
The
of Chemistry
of Science
derivated
of ylides,
p-HYWOXYALKYLATI~N0F ENONES+
ayents,
to
a number
of
that
methods
which
eliminated
involves
previously
phos-
developed
by Evans3 and Kozikowski.4
6
OTBDMS
TBDMSOTf PPh3, THF
n-BuLi
OTf- ;Ph3
Yk
(yIh,-
g
2
1. OTdijMS
0 n-BuqNF -
TMSOTf +&EwG
-
EWG
B-Conjugate Wittig
reagents
cyclopropane (2) derived in the
+Dedicated
to
of Enones
activated
derivatives
enones
salt
of trimethylsilyl (3) in good yields
to Professor
to Activated
olefins
proceeds
is of synthetic
from phosphonium
presence
alkylated
Addition
Olefins. by
importance.6
of silyl enol ether triflate
(TMSOTf)7
by one-pot
Although
several
the conjugate
pathways,b
However, (1) cleanly
5413
addition formation
we have found that react with
in tetrahydrofuran
procedure.
E.J. Corey on the occasion
the
of his 60th birthday.
of of
the ylide
activated
olefins
at -78 OC to yive
&
5414
Reaction vinyl
of the ylide
ketone
ammonium
fluoride
byproducts. Michael
gives
to another
conjugate
products.8*g
cyclohexenone
that the low yield enolate
addition
The addition
to some extent, yielding
from
at -78 OC for
via phosphoniosilylation
1 h followed
by the addition
3-(3-oxopentyl)-Z-cyclohexen-l-one
It is expected
adduct
further
(2) derived
in tetrahydrofuran
of
might
due to the presence
enolates
to
ethyl
of hexamethylphosphoric
the desired
product
in 21% yield
be resulted
vinyl
ketone
triamide
in 47% yield
to
ethyl
of an initial
vinyl
produce
(HMPA) improves
toyether
ethyl
alony with several
from tautomerism
of the unreacted
with
of tetra-n-butyl-
ketone
the
and
dialkylated
the present
reaction
with the dialkylated
products
in 20% yield. order to avoid the side reactions,
In Michael
adduct
TMSOTf
gives
with best
silylating results
ineffective
for this purpose.
and TMSOTf
in tetrahydrofuran
tetra-n-butylammonium the contamination derived
fran
agents.
and
is
Amony
gives
of dialkylated enones
of the premixed
solution
procedure,
carbonyl
compounds
olefins
results are given in Table
compounds
such
as
is
vinyl ketone
by the addition
the reaction proceeds
and
the efficiency
study,
chloride
in 7Y% yield
in hiyh yields.")
acrylonitrile
1 and illustrate
an initial
in this
of ethyl
(2) at -78 'C followed
a modified
other
activated
tested
trimethylsilyl
Using
works
with
ayents
while
o,@unsaturated
2,3-unsaturated-1,6-dicarbonyl
well
silylating
of trappiny
3-(3-oxopentyl)-2-cyclohexene-l-one
products.
with
the possibility
recommended,
at -78 OC to the ylide
rapidly, yielding
experimental
several
generally
Thus, the addition
fluoride
several
we considered
The
vinyl
of
without
of ylides
cleanly present
and
method
sulfone.
some
and the applicability
of
the present method.
8-Hydroxyalkylation reaction
of enones
of enones.
of
Enones.
to activated
Encouraged olefins,
As far as we are aware,
intermediates
prior to the formation
been
that the similar
reported
trimethylsilyl The betiane Reaction for
10
present
method
of the ylide followed
hydroxybenzylated yield.
TMSOTf
in quenching contamination
the
results
no successful
reports
of oxaphosphetane
intermediate
obtained
in
the possibility have appeared
with
silylatiny
in the boron-Wittiy
conjugate
addition
of 6-hydroxyalkylation for quenchiny
agents,
reaction
betaine
althouyh
it has
has been quenched
with
chloride."
intermediates
min
by
we have studied
is based
with TMSOTf, (2) with by
the
cyclohexenone
on the
Wittiy
an equimolar addition
of
amount
betaine
(4) in 29% yield
of the
intermediate,
Wittiy
pr0duct.l'
of ylides
yielding
with
of phosphonium
of benzaldehyde
tera-n-butylammonium
is found to be much more effective the
reaction
and facile elimination
together
with
aldehydes,4
in tetrahydrofuran
fluoride the
at
Wittiy
than t-butyldimethylsilyl the
desired
In the case of
product usiny
quenchiny
salts via desilylation.
-78
product triflate
in 72% yield
aliphatic
at -78 OC
OC
rives
B-
(5) in 21% (TBUMSUTP) without
aldehydes,
the it is
5415
Table 1. @-Conjugate Addition of Enones to Activated Olefins
enone
isolated yield, Xa
product
activated olefin
0
6
EWG CH2=CHCOCH2CH3
EWG=COCH2CH3
79 (21)b
CH2=CHCOC6H5
=COCgH5
CH2=CHCOOCH2CH3
=COOCH2CH3
58 (0)b
CH2=CH-SO2C6H5
=S02CgH5
68 (0)b
CH2=CH-CN
=CN
58
(wb
0
6/
WG CH2=CHCOCH2CH3
EWG=COCH2CH3
CH2=CHCOOCH2CH3
68
=COOCH2CH3
64
LEWG CH2=CHCOCH2CH3
EWG=COCH2CH3
CH2=CH-CN
73 (70:30)=
=CN
77 (85:15)'
a the yields are based on enones. b the reactions are performed in the absence of TMSOTf. 'the ratio of trans/cis isomer.
Table 2. B-Hydroxyalkylationof Enones
enone
RCHO
2-cyclopenten-l-one
C6H5CHO
2-cyclohexen-l-one
a
isolated yield, 'Za 57
CH3(CH2)7CH0
54
c-C6H11CH0
63
C6H5CHO
72
CH3(CH2)7CH0
63
carvone
C6H5CHO
48 (8)b
4-hexen-3-one
C6H5CHO
68
c-C6HllCHO
60
the yields of a-hydroxyalkylatedenones.
b
the yield of the recovered starting material
5416
preferred
to add an aldehyde
and TMSUTf
use of an equimolar
mixture
corresponding
enol ethers
Table
2.
aromatic
silyl
The
present
aldehydes.
Acknowledgment. support
method
well
and simultaneously results
that
results
and acyclic
the ylide
to steric
Institute
enones
(2) does
because
formation
the
of the
are summarized with
aliphatic
not react with
in and
ketones
reasons.
of Science
to Dr. Sung Soo Kim for experimental
References
in the
Some experimental
due possibly
the Korea Advanced
and we are grateful
separately
and TMSOTf
in both cyclic
it is noteworthy
and cyclohexanone
We thank
aldehydes
to some extent.13
works
However,
such as acetophenone
to the ylide
of aliphatic
and Technology
for financial
assistance.
and Notes
1. For reviews, see: (a) J. C. Stowell, Chem. Rev., 84, 409 (1984). (b) 0. Hoppe,Anyew. Chem. Int. Ed. Engl.,g, 2. (a) K. Kondo
and A. J. Mura, T.
F.
48,
Tetrahedron
Ibid.,
3187
and H. E. Morton,
Ginsberg,
Tetrahedron
Jr., J. Org. Chem., 41,
Weingartner,
Larcheveque, Piers
932 (1984).
and D. Tunemoto,
Ibid., 47,
Lett.,
1007
2506 (1976).
Lett.,
2506
(1975).
(1976).
(d)
A.
Uebal,
(1977).
(e) C. Shih and J. S. Swenton,
J. Org.
Chem., 3,
2229
(1982).
3437
(lY7Y).
(h) H. J. Cristau,
0. A. Bennett,
M. L. F. Bakuzis, T.
Cuviyny,
Ibid., 4217
(q) U.
M.
(1981).
(f) E.
U. Sunay,
and S.
and C. Nianyoran,
Ibid.,
Liotta,
B. Chabaud,
and
and
1527 (1983).
3. D. A. Evans,
K. M. Hurst, and J. M. Takacs, J. Am. Chem. Sot., I&l,
4. (a) A. P. Kozikowski
and S. H. Jung, J. Org. Chem., 51,
and S. H. Jung, Tetrahedron 5. G. M. Kosolapoff
6. (a) H. J. Bestman Finkelhor,
Lett.,
and L. Maier,
1973 and references
Phosphorous
Compounds",
Lett.,
Lett.,
Angew.
Chem.,
154
3781
(1972).
3,
in 68% yield 10. The ylide
(b) A. P. Kozikowski
Wiley
Intersciences,
Vol. 3,
(c) M. J.
ketone
(1962). Devos,
(b) P. A. Grieco L. Hevesi,
and R. S.
P. Bayet,
and A.
3911 (1986).
7. For an excellent review, see: H. Emde et al., Synthesis, vinyl
3467 (1978).
(1986).
3227 (1986).
"Organic
and F. Seng,
8. (a) M. E. Jung, Tetrahedron, phenyl
3402
cited therein.
Tetrahedron
Krief, Tetrahedron
9. When
(b) T. Cohen,
(c) P. Bakuzis,
32_, 3 (1976).
was used as an activated
in the absence
of TMSOTf,
1 (1982).
(b) R. E. tiawley, Synthesis, olefin,
as shown in Table
(2) did not react with ethyl acrylate
the desived
777 (1976). product
was obtained
1.
in the absence
of TMSUTP.
11. A. Pelter, D. Buss, and A. Pitchford, Tetahedron Lett., 5093 (1985). 12. The use of TBDMSOTf cyclohexenone 13. The formation
in
as a trapping
agent was totally
ineffective,
yieldiny
26% yield toyether with the Wittig product in 3Y% yield.
of a small amount
of aldol products was also observed.
(Received in Japan 22 August 19881
B-hydroxybenylated