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The conversion of furans to 2(3H)-butenolides
Tetrahedron Letters,Vol.28,No.ll,pp Printed in Great Britain
THE CONVERSION
Andrew Department
of Chemistry,
Z-Aryl- and 2-alkylfurans butenolides
Due to our interest fadyenolides2 synthesis4
elaboration.
procedures
and Martin
Rowlands.
University College of Swansea, Swansea SA2 8PP, U.K.
into the corresponding
in butenolides,I
those related
based on 2-organylfurans,
prior to a mild controlled
We first accomplished shown in equation
oxidation
the synthesis
of a wide variety
to the
for further ,J,seemed desirable,
through
to the required
acid.
for lignan
of 5-organylbutenolides
,$,should be stable enough to be safely carried
Park,
5-organyl-2(3H)-
of our need for synthons
preparation
a synthesis
Singleton
with m-chloroperbenzoic
particularly
and because
a general
In particular
as compounds
Pelter*
of boron derivatives
and piperolides3
we required
OF FURANS TO 2(3H)-BUTENOLIDES
are converted
by the oxidation
0040-4039/87 $3.00 + .( Pergamon Journals Ltd.
1203-1206,1987
a variety
of
butenolides.
of furans J, by the process
(1).
PdW,), MetX
-
(11
THF, SO’C, 20h
R
( Met X = ZnBr, Li)
We could find no example This paper describes substituted
of the direct conversion
of & to 5-organylbutenolides.
such a process which can give rise to a large number of + Of relevance to our work is the conversion by oxygen of
buteno1ides.o
Z-trimethylsilylfurans
to the corresponding
oxidation
and 2-ethyl-5-(dimethoxyboryl)thiophenes
peroxide
of Z-methyl-
5-hydroxy-2(5H)-butenolides7
and the
by alkaline
hydrogen
to the 5-alkyl-1-thio-2(3H)-butenolides.8
We felt that the sequence route, though we were unable J or 2(5H)-butenolides,
shown in equation
to predict
,j or mixtures,
(2) held promise
in any specific would
result.
1203
of being a general
case whether
2(3H)-butenolides,
1205
Oxidation
with oxygen
Oxidation
lack of reaction. unsuccessful
in a Brown hydrogenatorl' with alkaline
due to preferential
reagents
(exp.2,3)lZ
furan.
Lithiation
(MCPBA) was also ineffective, Sodium
carbonate
(exp.7).
Finally,
lowering
necessary Again,
advantageous,
with @-chloroperbenzoic
lowering
&
butenolide
(exp.5,6).
the temperature yield
the yield
hydrolysis
added
of the oxidation
and ring
furan ,&, and this
used 100% MCPBA14
was previously
acid
at 0°C. in order to
based on starting
we generally
Although
sodium carbonate
an excellent
in ether
to -78°C inhibited
the temperature
procedure.
when anhydrous
although
by oxidation
of recovered
acid as it formed and this increased
to give 94% of isolated
became our favoured
with chromium
and gave low yields
was added to the ether prior to oxidation
the meta-chlorobenzoic
(exp.4) due to
(exp.1) was also
oxidation
but some product was obtained
neutralise
opening13
to control
in THF followed
peroxide
Anhydrous
hydrolysis.
proved difficult of &
hydrogen
was ineffective
this was not
(exp.8,10,13,14).
to -78°C was generally
of 5-octyl-2(3H)-butenolide
was obtained
at 0°C
(exp.15). Of particular product was always distinguishable mixture
the 2(3H)-butenolide,
2(5H)-butenolide,
in the presence
any equilibration, The sequence complex
note is that in every case, even when R = alkyl
of sodium carbonate,
in the conditions high yield,
into 5-organyl-2(3H)-butenolides
n-Butyl to a stirred under argon.
lithium solution
and &, tried.
one-pot
Boron trichloride
were allowed
chlorodimethoxyborane
at C-3 only
in each case because With these exceptions
sequence
for the conversion
&
from 2-phenylfuran
(6.4 ml of 1.57M, 10 mm01
of Z-phenylfuran
mixtures
occurs
without
lithiation
the process of 2-organylfurans
(1.449,
in hexane
10 mmol)
(3.33 ml,
(25 ml) in dry ether
1 was
&. slowly added by syringe
n dry ether
(50 ml) at 0°C
lM, 3.33 mmol) was added with
(50 ml
at 0°C under argon.
to stir for 3h at room temperature
and then the
solution
needle to the stirred
of 2-phenyl-5-lithiofuran
was added by double-ended
at 0°C.
to stir for a further
was
, and as such should find wide application.
in hexane
to trimethoxyborane
protonation
is added to the reaction
products.
of 5-phenyl-2(3H)-butenolide,
stirring
allowed
Thus, when water
failed with furans &
is a mild,
Preparation
2, and no trace was found of the readily
even for the 5-alkyl
or difficult
described
$,.
(exp.14 and 15) the
Lithium
chloride
precipitated
hour at room temperature.
Both
solution
and the mixture
was
1206
MCPBA containing
(3.45 g of 1001, 20 mmol) was added to a 250 ml round bottomed anhydrous
sodium carbonate
(75 ml) was added and the mixture whilst
the solution
solution
of &
was allowed
The organic The combined
100 mnol) under argon.
cooled to -78°C and maintained
was rapidly
added by double-ended
to warm to 0°C and then water
layer was removed
organic
sodium bicarbonate
and the aqueous
and dried
(MgS04).
(50 ml)
Filtration
1M sodium
support
After
layer washed with ether sodium sulphite
5 min.,
the
m.p. 91-92"C,
(2 x 25 ml).
(50 ml),
(50 ml), water
of solvent was followed
mn Hg to give 5-phenyl-2(3H)-butenolide
We thank the SERC for financial
at this temperature
needle.
bicarbonate
and evaporation
Dry ether
(50 ml) added.
phases were washed with saturated
saturated
at 75"C/O.O05
(10.59,
flask
(3 x 50 ml)
by sublimation
(1.45 g, 90.6%).
of this work.
References
.
1.
A.Pelter,
R.Al-Bayati
and P.Pushpani,
A.Pelter
and R.Al-Bayati,
W.Lewis,
ibid, 1982, a,
D.Reinhardt,
e,
1978, m.
Z.Naturforsch.,
3.
Chem.Ber.,
A.Pelter,
R.Al-Bayati,
1981, g,
1545.
A.Pelter 8,
A.Pelter,
1979, ,$&,
1976, m
R.Al-Bayati
M.T.Ayoub
and
R.H&isel
and
J.Chem.Soc.Perkin
1,
and R. Reinhardt,
J.Schultz,
A.Pelter
1576; R.Hinsel,
A.Pelter,
and J.Schu1t.z
1617.
R.H&sel,
and R.H&isel,
1986, ,Q,, 749;
M.T. Ayoub, J.Schultz, and M.T.Ayoub,
1020; R.H&sel,
Z.Naturforsch.,
and C.Hille, 2.
J.Schultz,
Lett.,
5229; A.Pelter,
A.Pelter,
353;
1979, 1627; A.Pelter
1981, 1173; R.Hansel,
M.T.Ayoub,
Tetrahedron
ibid, 1982, a,
H.Dinter
Z.Naturforsch.,
and B.Burke,
1972, m,
Tetrahedron
1186; Phytochem.,
Lett.,
1971,
1627.
4.
A.Pelter,
R.S.Ward,
1983, a,
523; J.Chem.Soc.Perkin
5.
A.Pelter,
M.Rowlands
6.
R.Al-Bayati,
Ph.D. Thesis,
K.Hori, S.Fujiwara
7.
S.Katsumura,
8.
R.T. Hawkins,
9.
A.Pelter,
P.Collins,
R.Venkateswarlu
B.Singaram,
Synthesis,
Univ.College
Tetrahedron
and J.W.Wilson,
E.Wiberg
11.
C.A.Brown
and H.C.Brown,
J.Org.Chem.,
12.
E.J.Corey
and J.W.Suggs,
Tetrahedron
13.
J.Jurczak
14.
N.N.Schwartz
1966, a, Lett.,
and J.H.Blumbergs,
1985, 4625.
Lett.,
1983, @,, 623
204.
2647; C.Gundu
1979, m,
1985, a,
J.Org.Chem.,
(Received in UK 19 January 1987)
1935, m,
Lett.,
3989.
1975, a,
J.Organomet.Chem.,
Tetrahedron
Lett.,
Tetrahedron
Zeit.anorg.u.allg.chem.,
and H.C.Brown,
and S.Pikul,
1983.
1974, ,$$, 291.
10.
S.V.Kulkarni
1987, 51.
of Swansea,
and S.Isoe,
Chem.,
L.Williams
and H.Smedsrud,
Lett.,
1, 1985, 587.
and G.Clements,
J.Heterocyclic
and I.T.Kay, Tetrahedron
C20-22.
3039.
1964, 2.
1976.
Rae,
THE CONVERSION
Andrew Department
of Chemistry,
Z-Aryl- and 2-alkylfurans butenolides
Due to our interest fadyenolides2 synthesis4
elaboration.
procedures
and Martin
Rowlands.
University College of Swansea, Swansea SA2 8PP, U.K.
into the corresponding
in butenolides,I
those related
based on 2-organylfurans,
prior to a mild controlled
We first accomplished shown in equation
oxidation
the synthesis
of a wide variety
to the
for further ,J,seemed desirable,
through
to the required
acid.
for lignan
of 5-organylbutenolides
,$,should be stable enough to be safely carried
Park,
5-organyl-2(3H)-
of our need for synthons
preparation
a synthesis
Singleton
with m-chloroperbenzoic
particularly
and because
a general
In particular
as compounds
Pelter*
of boron derivatives
and piperolides3
we required
OF FURANS TO 2(3H)-BUTENOLIDES
are converted
by the oxidation
0040-4039/87 $3.00 + .( Pergamon Journals Ltd.
1203-1206,1987
a variety
of
butenolides.
of furans J, by the process
(1).
PdW,), MetX
-
(11
THF, SO’C, 20h
R
( Met X = ZnBr, Li)
We could find no example This paper describes substituted
of the direct conversion
of & to 5-organylbutenolides.
such a process which can give rise to a large number of + Of relevance to our work is the conversion by oxygen of
buteno1ides.o
Z-trimethylsilylfurans
to the corresponding
oxidation
and 2-ethyl-5-(dimethoxyboryl)thiophenes
peroxide
of Z-methyl-
5-hydroxy-2(5H)-butenolides7
and the
by alkaline
hydrogen
to the 5-alkyl-1-thio-2(3H)-butenolides.8
We felt that the sequence route, though we were unable J or 2(5H)-butenolides,
shown in equation
to predict
,j or mixtures,
(2) held promise
in any specific would
result.
1203
of being a general
case whether
2(3H)-butenolides,
1205
Oxidation
with oxygen
Oxidation
lack of reaction. unsuccessful
in a Brown hydrogenatorl' with alkaline
due to preferential
reagents
(exp.2,3)lZ
furan.
Lithiation
(MCPBA) was also ineffective, Sodium
carbonate
(exp.7).
Finally,
lowering
necessary Again,
advantageous,
with @-chloroperbenzoic
lowering
&
butenolide
(exp.5,6).
the temperature yield
the yield
hydrolysis
added
of the oxidation
and ring
furan ,&, and this
used 100% MCPBA14
was previously
acid
at 0°C. in order to
based on starting
we generally
Although
sodium carbonate
an excellent
in ether
to -78°C inhibited
the temperature
procedure.
when anhydrous
although
by oxidation
of recovered
acid as it formed and this increased
to give 94% of isolated
became our favoured
with chromium
and gave low yields
was added to the ether prior to oxidation
the meta-chlorobenzoic
(exp.4) due to
(exp.1) was also
oxidation
but some product was obtained
neutralise
opening13
to control
in THF followed
peroxide
Anhydrous
hydrolysis.
proved difficult of &
hydrogen
was ineffective
this was not
(exp.8,10,13,14).
to -78°C was generally
of 5-octyl-2(3H)-butenolide
was obtained
at 0°C
(exp.15). Of particular product was always distinguishable mixture
the 2(3H)-butenolide,
2(5H)-butenolide,
in the presence
any equilibration, The sequence complex
note is that in every case, even when R = alkyl
of sodium carbonate,
in the conditions high yield,
into 5-organyl-2(3H)-butenolides
n-Butyl to a stirred under argon.
lithium solution
and &, tried.
one-pot
Boron trichloride
were allowed
chlorodimethoxyborane
at C-3 only
in each case because With these exceptions
sequence
for the conversion
&
from 2-phenylfuran
(6.4 ml of 1.57M, 10 mm01
of Z-phenylfuran
mixtures
occurs
without
lithiation
the process of 2-organylfurans
(1.449,
in hexane
10 mmol)
(3.33 ml,
(25 ml) in dry ether
1 was
&. slowly added by syringe
n dry ether
(50 ml) at 0°C
lM, 3.33 mmol) was added with
(50 ml
at 0°C under argon.
to stir for 3h at room temperature
and then the
solution
needle to the stirred
of 2-phenyl-5-lithiofuran
was added by double-ended
at 0°C.
to stir for a further
was
, and as such should find wide application.
in hexane
to trimethoxyborane
protonation
is added to the reaction
products.
of 5-phenyl-2(3H)-butenolide,
stirring
allowed
Thus, when water
failed with furans &
is a mild,
Preparation
2, and no trace was found of the readily
even for the 5-alkyl
or difficult
described
$,.
(exp.14 and 15) the
Lithium
chloride
precipitated
hour at room temperature.
Both
solution
and the mixture
was
1206
MCPBA containing
(3.45 g of 1001, 20 mmol) was added to a 250 ml round bottomed anhydrous
sodium carbonate
(75 ml) was added and the mixture whilst
the solution
solution
of &
was allowed
The organic The combined
100 mnol) under argon.
cooled to -78°C and maintained
was rapidly
added by double-ended
to warm to 0°C and then water
layer was removed
organic
sodium bicarbonate
and the aqueous
and dried
(MgS04).
(50 ml)
Filtration
1M sodium
support
After
layer washed with ether sodium sulphite
5 min.,
the
m.p. 91-92"C,
(2 x 25 ml).
(50 ml),
(50 ml), water
of solvent was followed
mn Hg to give 5-phenyl-2(3H)-butenolide
We thank the SERC for financial
at this temperature
needle.
bicarbonate
and evaporation
Dry ether
(50 ml) added.
phases were washed with saturated
saturated
at 75"C/O.O05
(10.59,
flask
(3 x 50 ml)
by sublimation
(1.45 g, 90.6%).
of this work.
References
.
1.
A.Pelter,
R.Al-Bayati
and P.Pushpani,
A.Pelter
and R.Al-Bayati,
W.Lewis,
ibid, 1982, a,
D.Reinhardt,
e,
1978, m.
Z.Naturforsch.,
3.
Chem.Ber.,
A.Pelter,
R.Al-Bayati,
1981, g,
1545.
A.Pelter 8,
A.Pelter,
1979, ,$&,
1976, m
R.Al-Bayati
M.T.Ayoub
and
R.H&isel
and
J.Chem.Soc.Perkin
1,
and R. Reinhardt,
J.Schultz,
A.Pelter
1576; R.Hinsel,
A.Pelter,
and J.Schu1t.z
1617.
R.H&sel,
and R.H&isel,
1986, ,Q,, 749;
M.T. Ayoub, J.Schultz, and M.T.Ayoub,
1020; R.H&sel,
Z.Naturforsch.,
and C.Hille, 2.
J.Schultz,
Lett.,
5229; A.Pelter,
A.Pelter,
353;
1979, 1627; A.Pelter
1981, 1173; R.Hansel,
M.T.Ayoub,
Tetrahedron
ibid, 1982, a,
H.Dinter
Z.Naturforsch.,
and B.Burke,
1972, m,
Tetrahedron
1186; Phytochem.,
Lett.,
1971,
1627.
4.
A.Pelter,
R.S.Ward,
1983, a,
523; J.Chem.Soc.Perkin
5.
A.Pelter,
M.Rowlands
6.
R.Al-Bayati,
Ph.D. Thesis,
K.Hori, S.Fujiwara
7.
S.Katsumura,
8.
R.T. Hawkins,
9.
A.Pelter,
P.Collins,
R.Venkateswarlu
B.Singaram,
Synthesis,
Univ.College
Tetrahedron
and J.W.Wilson,
E.Wiberg
11.
C.A.Brown
and H.C.Brown,
J.Org.Chem.,
12.
E.J.Corey
and J.W.Suggs,
Tetrahedron
13.
J.Jurczak
14.
N.N.Schwartz
1966, a, Lett.,
and J.H.Blumbergs,
1985, 4625.
Lett.,
1983, @,, 623
204.
2647; C.Gundu
1979, m,
1985, a,
J.Org.Chem.,
(Received in UK 19 January 1987)
1935, m,
Lett.,
3989.
1975, a,
J.Organomet.Chem.,
Tetrahedron
Lett.,
Tetrahedron
Zeit.anorg.u.allg.chem.,
and H.C.Brown,
and S.Pikul,
1983.
1974, ,$$, 291.
10.
S.V.Kulkarni
1987, 51.
of Swansea,
and S.Isoe,
Chem.,
L.Williams
and H.Smedsrud,
Lett.,
1, 1985, 587.
and G.Clements,
J.Heterocyclic
and I.T.Kay, Tetrahedron
C20-22.
3039.
1964, 2.
1976.
Rae,