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Regio- and stereocontrol in the intramolecular nitrile oxide cycloaddition to 2-furylthiol- and 2-furylmethanethiol derivatives.
Tetdcdron Vol. 47. No. 23, pp. 3869-3886.1991 Rmted in Great Edin
AND
REGIO-
oo4o4020/91 $3.00+.00 0 1991 Pergamon Press p
STEREWONTROL
IN
ME
2-FURYLTHIOL-
Rita Annunziata, Centro C.N.R.
INTRMOLECULAR
AND E-FURYLWTHANETHIOL
Mauro Cinquini,
and Dipartimento
Organica
and Giulia
Via Marzolo
CYCLOADDITION
TO
DERIVATIVES.
Laura Raimondi
e Industriale
19, 20133 Milano,
and Dipartimenco
OXIDE
Franc0 Cozzi,
di Chimica
Via Golgi
Centro C.N.R.
NITRILE
dell'tlniversita,
Italy
Licini
di Chimica
Organica
1, 35131 Padova,
dell'llniversita,
Italy.
(Received in UK 22 January 1991)
Abstract.
A series of 2-fury1 and 2-furylmethyl substituted length were prepared and showed to undergo
chain
nitrosulphides with a proper a totally regiocontrolled
intramolecular furan-nitrile oxide cycloaddition to give cis-fused products in high yield. Insertion of a stereocenter on the cycloaddends did not allow satisfactory Enantiomerically enriched control of the absolute stereochemistry of the reaction. products of the
(e.e.<95%1
sulphide
The proteiform into organic result tne
molecules
of
especially
reports
variety
is to use furan
role
enhance
were
either
regio-
and
deal
withstanding dipolarophile, furan-nitrile
7-10
as a reagent
oxide
entry to C-4 oxygen
goal.'
can
help
intramolecular
the
cycloaddition.8
stereoselective
synthesis
stereoselective
nitrone
and nitrile
of
problems
of
to
bonus
in the
important
oxide cycloadditions,
reactivity
limited to
number furan,
particularly most
building
this
can play
intermolecularly
react
offered
8,ll
to
processes
poor
very
is indeed
a very
sugars.
a
its insertion
approach
intramolecular
cycloadditions
11
oxidation
heterocycle
dipolar
reaction
3869
this
only
tendency
amino
popular
since
line
makes
However,
synthetic This
involving
by furan
the most
overcome 2
isoxazolines,
of various
offered
this
1,3
scarce
obvious
substituted
to
control.
stereochemical
extremely
One
In
process
sulphoxides.
in cycloaddltions,
27r component.
as they
and
resolution
opportunities
an attractive
with
its
by a kinetic
to the corresponding
of synthetic
47r or
appealing,
3-6
obtained
cycloadducts
by
seem and of not as the
straightforward block for
the
In the course of our studies on 12
we became
interested
in
R. ANNUNZIATA et al.
designing
a
precursors
furan-nitrile
of acyclic
products.
jn this field,
we decided
dipolaropnile,
with
isoxazolines
into
2-Furylthiol The
Lithiation
a functionalized
to
17
1, that was treated
the
followed
(58-62%
the
unreacted
in
alkylation in
57%
compounds
alcohols
recovery 8-10
in
respectively,
only
reagent
nicrile was
assigned
on
hand 19
we
comparison
assignment.
dipole
COnVetXing
This
and tne
manuscript
to
Scheme
P-fury1
alcohols of
overall
the
(94-100%
iodides
yield),
under
nitrous
recycled,
An alternative
nitroethylene
esters
While
and
of
the
could
of compound
Compound
generaced
oui
in DMF
the former
synthesis
(40% yield).
PTC
could be carried
or with sodium nirrice
the
1.
thiolate
2-5, in 68-77%
This reaction
of
in
to the nitro derivatives
intramolecular
of the nitro compounds
were refluxed
examined
basis
unchanged. to which high
any intramolecular
Two stereocenters
to give
purification
in
6
10 was
also
situ
from
the
by flash
products Tricyclic
-1 field
H
20
be detected,
and
13
C
NMR 3-6
11
cycloadduct
lends additional
of defined
relative
and
spectroscopic
systems.
of
while
indicated
for related
6
and
(that also allowed
In the reaction
structure
Only compound
11 and 12 in 79
chromatography
could
Dilute
for 24h in the presence
crlethylamine.
derivatives
fused
CIS-
cycloaddition.
isoxazolines
nitrosulphide).
self-addition
of
and catalytic
cycloaddition
with the data reported
did not afford
experience
and on the regio- and
lithium
their
after
oxide
products the
the
(48-56% yleldj amounts
1
gave
synthesis
upon reduction.
10% of the starting
recovered
regioisomeric
to
The latter were
adding
intramolecular
of about
and 11
reported
IS
Conversion
1-iodo-3-nitropropane
by
18
to give compound
exchange.
of 3 mol equiv of p-chlorophenylisocyanate
75% yield,
sulphur
yield),
variable
also obtained.
solutions
and 7 underwent
tether
to
13
6-10
(0.02M) benzene
cases
yield
2-acetoxynitroethane. With
(80-83%
of 1 with
series
reduction
and iodine-nitro
both
iodides were
prepared
involving
tosylates
afford the corresponding entailed
with
ether with silver nitrite
yield);
previous
lead
reaction.
one pot procedure.
steps
(86-913 yield),
in diethyl
the
could
connecting
a y -aminoalcohol.
this
in situ withw-bromoesters
in four
either
of
by reaction
6-9 was
of
in the chain
of two series of cycloaddends
cycloaddends
in a convenient
preparation
or
that
and other's14
cleaving
of their cycloaddition
yield from furan,
conditions
atom
15
fl -ketol
13
16
route
achieved
a sulphur
on the synthesis
series.
of furan
cycloaddition
On the basis of ours
to insert
implications
synthetic
intramolecular
the goal of simultaneously
reports our results stereochemical
oxide
12
cycloaddends most were
of
the
single
in Scheme
1 was
evidences,
The fact that nicrosulphide
and 10
support to ihe structural
stereochemistry
are formed
in the syn-
3871 Nitrile oxide cycloaddition
Scheme 1
0/ \
I\ (x
ati
0
0
SLi 2, 4.
1
4x\
S/\/No2
6, 8,
6.
(CH2)n s' d
0
10
n=2; n-4;
7, 9,
3, 5.
n=3
n-5
NO2
n=3 n-5
i
7
11, n=l;
12, n-2
i
h 6.7
n-2; n-4;
-
5332
)
n\/NO2
-
0
13, n=2;
15a,b, 16a,b,
14, n=3
n=l n=2
O, l-
jrerf
NO2
&
Me
%
17
w:
a, n-BuLi;
IN
I
then Ss; b, Br(CHZ),,COOEt; C. LiAlH4; d, TosCl,
OS 18a.b
TEA;
e, KI, Bu@+I-;
f, AgNO2 or NaNO2; g, I(CH2)3NO2; h, AcOCH~CH~NO~;
i, p-ClCsH4NC0,
TEA; h, NaIOq; jr BrCH2CHWe)CHzCl
Me
3872
R.
ANNUWUTA~~al.
thesis of 11 and 12 from 6 and 7. The control introduction 7 was
of a stereocenter
oxidized
with
sodium
12
on the reagent.
metaperiodate
to give
the
corresponding
13 and 14 in 82 and 87% yield,
respectively.
mixture
diastereoisomeric
15a,b
of
for compound not
ratio was evaluated
15a,b
and
dipolarophile
stereoselection alkene.
an allylic was
reportedL'
disappointing
respect
to
stereochemical in
a
66:34
the
nitrile
outcome
and
cycloaddition
prompted
enantiomerically
The
the
commercially
of
available
sodium ethoxide
gave compound
isoxazolines
followed
the
Also
the -cis-fused
above
was
is
yield.
decomposition.
in
some
of
the
(73% yield)
precedents outcome
to isoxazolines
in
position extent
obtained
stereochemical
two
straightforward
way by condensing
in the presence
of piperidine,
Scheme
Alkylation
in
the
of
the
as 11 or 12 in
experimental
on the basis
were of
sulphoxide
racemic
sodium
single
report
stereochemistry was
analogues
to give nitrosulphides
of
of
in DMF
24
intramolecular give
cricyclic by flash
regioisomers,
to which
on
analogy
a virtually
was
resulted 20
of
purlflcation
accomplished
cycloaddition
19 with nirromethane
to
evidences, 23
nitrite
underwent
after
NMR
Addition
in the presence
conditions,
and literature
however,
with
respectively,
2.
of the sodium salt of 19
two cycloaddends
of absolute
chiral
in
exchange
the cycloadduccs
series,
oxidation:
Next,
being
extent
limited
19 to E-acetoxynitroethane
These
described
20 to the corresponding
25
very
has
the
described
by bromide-nitro
in this case control
metaperiodate
result
20 in 85% yield.
assigned
of the 2-furylthiol
system. Also of compound
products
in this case
structure
18a,b
new approaches
22 and 23 in 77 and 76% yield,
chromatography.
usual
required
21 in 44% overall in
this
of controlling
a
connecting
17, prepared
In this case a stereocenter to
was
an E-configurated
of nitrosulphide
dictate
The
to be 75:25
chain
on
a
23
gave nitrosulphide
cycloaddition,
60% yield.
identical
cycloaddition
gave
stereocontrol
the
practically
compound
Also
ratio.
and
of
inside
racemic
of these
and determined
low extent
located
oxide
can
2-furylmethanethiol
with 1,3-dibromopropane
in 63
the
form (see below).
series.
synthesis
1.
moiety
us to investigate
2-Furylmethanethiol
products
oxide
impossibility
enriched
This
promote
of tne cycloaddition,
the
16a,b,
the cycloaddition
in Scheme
diastereoisomeric
literature,22
to
nitrile
was
three steps from 1 as described with
16a,b.
stereocenter
in an intramolecular
Similarly
and
requires
atom of 6 and
chiral,
Cycloaddition
by 'H NMR spectroscopy
and 70:30 for compound
indeed,
unexpected:
dipole
cycloadducts
configuration
To this end, the sulphur
sulphoxides
diastereoisomeric
a
of the absolute
were
and propanal
attempted. in fair only
with
identical Oxidation
yield in
prepared
the
by the
extensive in
a
very
or 2-methylpropanal,
24 and 25 in 78 and 80% yield,
3873
Nitrile oxide cycloaddition
Schm
2
‘-NO, 20
m/
SW
0
19 S-NO2 21
0,
3
20
dl
O,N
FJ 2
5
N
d
21
0.z
0 .-\ S
‘S
22
19
23
d
S
e_
CH$Q
-
Y R 26a.b. b.
24, K=Et 25, Et-Pr-i
278,
R-Et K=Pr-i
Me
28
29
d
\
Reaaents:
a,AcOCH2CK2N02,
EtOUa: b, EtONa, Br(CH2)aBr; c, NaN02, DMF;
d, P-ClC#4NCO, TEA: e, CH3U02, RCHO, Piperidine; f, Br(CH2)~CoOEt, EtONa; 9, LiAlH,; h, t-BuMe2SiC1, Imidatole; j, LDA, KMPA, HaI; k, Bu,N+F-; 1, HsCl, TEA; m, KI, Bu,N+I-.
3874
R. ANNUNZIATA etal.
respectively. compounds
26
their
However,
cycloaddition
26a,b and 27a,b were obtained of two diastereoisomers.
of a cycloaddend
featuring
an allylic
28 was
in three
high
methylated
(72% yield)
yield),
by the usual
66:34 mixture structures isomer basis
The
poor
assigned
steric
on
of
cycloaddition
that
by
for
the
inserting
oxidation
sulphur
atom
of
tnese compounds
by some
(Table 11. The former,
preliminary
derivative
(87%
a 79% yield
of a
predominance
of
the
be
rationalized
on
the
in agreement
sulphoxide
detectable
16a,b was obtained
both cases the predominant of 13 or 14.2g Oxidation respectively)
with
previous
reagents
1. In kinetic
1.0 mol. equiv.
is
25,
and
29
stereochemistry
reagent.
We
represent
enriched 28
30
also
by
1 H NMR
out
therefore
and the rigid structure
on
compound
highly
11 and 12
from
the
(76% yield).
In
of the cycloaddition
since the products
(see below):
(31a.b
this prevented
of the mCPBA oxidation. sulphide
oxidation,
to secure
selective.
(0.5 mol.
of (+I-diethyl
23
process.
acid, gave
while
ratio
products
convenient
Indeed, a number
(70% yield),
in lower yield
that is known
conditions
form.
a
stereodifferentiating
carried
enantioselective
reagent,
resolution
could
was the major
Among
oxidation
the
in 85:15 diastereoisomeric
of the diastereoselectivity
mCPBA
24,
11. 12, 22, and 23.
some tendency to decompose
for
17,
oxidation with m-chloroperbenzoic
of 22 and 23 proceeded
of Sharpless's
on
of a highly
a safe determination available
center
14,
the absolute
has been reported,
isomer
isomer obtained
showed
13,
to control
experiments
upon low temperature
15a as a single
of
in enantiomerically
This was confirmed
of Ti(OPr-i14;
converted
alCOhO1
iodo
was
The
can
is
cycloadducts
the possibility
Table
and
of cycloadducts our
suggested
the analW3OUS
compound
approach.
of our isoxazolines
the
the
27
position
a stereogenic
of sulphides
modification
botn
reaction
3Da and 3Db, to which the indicated
reaction
be very difficult
oxidations
and 32a,b,
This
of 29 gave
of NOE experiments.
of enantioselective
latter
the
19, silyl derivatives
yield).
and
Cycloaddition
considerations,
to a different
the
handle for obtaining
sulphoxide
from
and the resulting
(76% yield)
in an equatorial
observed
and enantioselective
reasoned
co investigate
overall
isoxazolines
basis
interaction
that it would
turned our attention
Diastereo-
the
(71%
since
(82 and 76%, respectively),
starting
(91% yield),
(60% yield).
group
stereoselectivity
indicate
We
steps
stereoselective,
12
clearly the
procedure
non
We then decided
29, -via the mesylate
tne methyl
of simple
observations.
yielding
of two diastereoisomeric
were
having
"
stereocenter:
and deprotected
into the nitrosulphide
totally
in good yield
as 50:50 mixture
prepared
was
The
equiv.
tartrate)
good
results
of tBuOOH;
sulphide
we
selected
stereocontrol are
wnen
collected
0.25 mol.
a
in
equiv.
11 gave exclusively
3875
Nitrileoxidecycloaddition
Table
1. Stereoselective
Sulphide
oxidation
of 11, 12, 22, and 23.
Sulphoxide
Oxidant
D1astereoisomer,ca a:b ratio
11
mCPBA
15a.b
12
mCPBA
16a,b
Q D
%
22c
3
85:15
11
TBHP/Ti(OPr-l),/(+)DET
15a,b
397:
3
85
-561.1
12
TBHP/Ti(OPr-i)4/(+)DET
16a,b
297:
3
95
-511.5
lid
TBHP/VO(acac)2
15a,b
397:
3
36
t233.1
12d
TBHP/VO(acac)2
16a,b
>/97: 3
43
t223.3
22
TBHP/Ti(OPr-i)4/(+)DET
31a,b
28
tl85.3
23
TBHP/Ti(OPr-i)4/(+)DET
32a,b
64
-151.6
aAs determined 1 H
297:
[I
E.e.b
NMR
in
pre-established
solution,
397:
b
by 300 MHz 'H NMR spectroscopy.
spectroscopy
conditions
Ei0:20e
c
the
presence
of
3
As determined
for a isomers
(-)-trifluoromethyl-9-anthrylcarbinol
on racemic compound. 'As determined d Sulphide recovered from
0.5-1.0.
TBHP/Ti(OPr-i)4/(t)-DET.
by 300 MHz
for a isomers the
in
in CHC13 with
oxidation
e31b had e.e. 35%.
sulphoxide (-)-15a in 60% yield based on the oxidant. The e.e. was determined as 85% by 1 H NMR spectroscopy in the presence of (-)-trifluoromethyl-9-anthrylcarbinol, in conditions product
pre-established (-I-16a
enantiomerically sulphides
11
(48%
yield
pure
by
and
tBuOOH/VO(acac12 yield,
12,
to
43% e.e.1,
give
being
was
obtained
Compound
obtained
recovered
the
sulphoxides
the
(+I-15a
kinetic
31
(based on the
sulphoxide
a single shown
sake
resolution, 36%
The oxidation
oxidant)
the
by the
(-)-32a
of
were
e.e.1
From compound
pure, as evaluated
isomeric
was
For
(50% yield,
diastereoisomers.
afforded
that
technique.
series was then examined.
a single
of 12
oxidant),
described from
in 48% yield
as 64%.
15a. Oxidation
on
above
28% enantiomerically
23 afforded
was determined
the
based
both as single
of the E-furylmethanethiol of 31a,b
on racemic
and
to
isomeric be
95%
completeness, treated (+I-16a
with (36%
of the cycloadducts 22 a 80:20 mixture
major usual
(52% yield),
isomer,
32
(+I-3la,
1 H NMR technique. the e.e. of which
R. ANNUNZIATA~~ al.
The
stereochemical The
comments. definitely
outcome
of
enantiomeric
higher
than
the
kinetic
excesses
those
resolution
observed
obtained
for
with the
showed
differentiated
more
stereoselective
ligands. The greater
difference
for
in 11 and 12 than in 22 and 23 can account
are the
reasons
any reasonable
understand reports. In
lower enantioselection
this
explanation
result.
A
for
similar
that,
with
is
sterically
a
at
Less evident
of tetrahydrothiophene
experimental
not
33
well
of the substituent
of the oxidation
behaviour
reactions,
for this observation.
and more
few were
12 and 23. We do not work
common
is necessary
feature
of
to
literature
30,33
conclusion
we
2-furylthiolfashion
for similar
sulphides
a
derivatives
E-furylmethanethiol
11 and 22 with respect to that of thiopyran derivatives
derivatives have
the
in steric bulkiness
sulphur
for the
of
observations
oxidations
requires
P-furyltniol
compounds
series: this is in line with a number of previous that always
experiments
the
showed
that
intramolecular
and 2-furylmethanethiol
derivatives
to give high yield of -cis-fused
number of synthetically stereochemistry locations
on
stereocontrol. established sulphide
chain
An
connecting
alternative
by a kinetic
to sulphoxide
approach
to
oxide
cycloadditions
in a completely
that in principle
Various
reaction dipole
resolution
occur
products,
useful transformations.
of tne cycloaddition the
furan-nitrile
attempts
by inserting
on
reigocontrolled
are amenable
to control
a stereocenter
to a
the absolute in different
and dipolarophile
resulted
in poor
to
fair
enantiomerically
enriched
cycloadducts
was
process
involving
a diastereo-
and enantioselective
oxidation.
Experimental. 1 H and l3 C NMR spectra were recorded
with
on CDC13
are
solutions.
were measured a
Perkin
Chemical
shifts
on a Perkin-Elmer
Elmer
chromatography;
DMF
employing
and
240
instrument.
organic
extracts
CH2C12
anhydrous
from
in ppm
Silica were
gel
dried
from
from
Elemental was
over
pressure.
CaH2;benzene
WP 80 or a Varian
downfield
241 spectrometer.
removal of the solvent under' reduced HMPA,
a Bruker
used
sodium
Et3N
Optical
rotations
were performed
analytical
sulphate
THF and Et20 were sodium;
TMS.
analyses for
XL 300 instrument
and
and filtered
distilled
from
KOH.
from All
with flash
before LiAlH4;
reactions
solvents were run under Argon.
General procedure for the synthesis of esters 2-5. To a stirred
solution
of 2-furyllithium l7 (50 mnol) in THF (250 ml),
mmol) was added portionwise then treated
with
at 0°C. The dark red solution
ethyl w-bromo
alkanoate
(45 mmol).
The
sulphur
(1.6 g, 50
was kept at 0°C for mixture
was
stirred
1.5 h and at room
3877
Nitrileoxidecycloaddition
temperature then
overnight, the
added;
hydroxide,
and the reaction
organic
phase
washed
twice
and then with brine. The products
chromatography
with 90:10 hexanes:diethyl
requires:
C, 53.98;
by addition
with
5%
ether mixture
of water. aqueous
Diethyl
ether was
solution
as pale yellow
of
sodium
oils by flash
as eluant.
in 68% yield.
1 H NMR: a
H, 6.04.
a
were isolated
2 was obtained
Ethyl 3-(P-furylthio)propanoate CgH1203S
quenched
6.31-7.46
Found:
C, 54.06;
(m, 3H); 4.09
H, 6.12.
(q, ZH);
2.93
(t, ZH); 2.56 (t, 2H); 1.21 (t, 3H).
Ethyl
3 was obtained
4-(2-furylthio)butanoate
C10H1403S
requires:
requires:
4 was obtained
requires:
(t, 2H); 2.27 (t, 2H); 1.37-1.71
O"C,
ether
a diethyl
dropwise.
The reaction
(5 ml/mm01
15-30 min. After cooling 15% aqueous
NaOH
The precipitate
quantitative
dissolved
in dry CH2C12
were
reaction
added
mixture
concentrated chromatography
to
ester)
solution
then warmed
H20
and
of
ester
ether (3 ml/g
of LiAlH4)
(1.2 mol equiv)
the
with crude
acid
H, 5.15.
H,
7.57.
(q, 2H); 2.73
After H20
purity
overnight and
products
the that
ether mixture
C14H1604S2
requires:
C, 53.83;
added
NMR).
at
phase
room
was
added for
in this order.
To
in
the
alcohol,
chloride
(1.0 mol
temperature,
as
at
of LiAlH4),
separated,
isolated
dried,
oils
by
the and flash
as eluant. was
3-(2-furylthio)propylester
(1 ml/g
and tosyl
stirring
were
were
1 H
(by
organic
H20
mm011
and refluxed
to give the crude alcohol
Et3N
order.
(20-30
(ca. 100 ml),
(10 ml/mmol),
give
59.18;
of ester) cooled
up to room temperature
high
washed
C,
Found:
(10 ml/mm01
very
with a 70:30 hexanes:diethyl
C, 54.01;
(m, 7H); 4.13
of
ether
in
was
H, 7.00.
(q, 2H); 2.78
(m, 3H); 4.10
6.30-7.46
and the solvent was evaporated
yield
in this
4Aethylphenylsulphonic Found:
was
of LiA1H4),
was filtered
virtually
equiv)
in 76% yield.
in diethyl
at 0°C wet diethyl
(1 ml/g
C, 57.88;
Found:
of the tosylates.
(3 mol equiv)
mixture
6.66.
(m, 6H); 1.21 It, 3H).
General procedure for the synthesis of LiAlH4
H,
(q, 2H); 2.73
(m, 3H); 4.12
6.25-7.43
C, 59.48; H, 7.49. 'H NMR: a
To a suspension
55.93;
(m, 4H); 1.26 (t, 3H).
5 was obtained
6-(P-furylthio)hexanoate
C12H1803S
C,
(m, 3H); 4.04
in 75%*yield.
'H NMR:a
C, 57.87; H, 7.06.
(t, 2H); 2.35 (t, 2H); 1.57-1.95
Ethyl
6.22-7.40
Found:
(m, 2H); 1.15 (t, 3H).
Ethyl 5-(2-furylthio)pentanoate C,,H1603S
'H NMR:a
C, 56.05; H, 6.58.
(t, 2H); 2.35 (t, 2H); 1.80-2.05
in 77% yield.
obtained
H, 5.16.
in
82%
'H NMR:a
yield.
6.29-7.81
(t, 2H); 2.71 it, 2H); 2.43 (s, 3H); 1.87 (m, 2H).
4-Methylphenylsulphonic
acid 4-(2-furylthio)butylester
C, 55.11; H, 5.61. C15H,804S2
requires:
was obtained
C, 55.19; H, 5.56. 'H NMR: a
4.05 (t, 2H); 2.74 (t, 2H); 2.47 (s, 3H); 1.55-1.92
(m, 4H).
in 80% yield.
6.29-7.82
Found:
(m, 7~1;
3878
R. ANNUNZIATAetal.
4+4ethylphenylsulphonic
acid
was
5-(2-furylthio)pentylester
Found: C, 56.30; H, 5.87. C,6H2004S2
requires:
acid 6-(2-furylthio)hexylester
C, 57.70; H, 6.18. C,7H2204S2
requires:
3.98 (t, 2Hl; 2.68 (t, 2Hl; 2.41 (s, 3H); 1.20-1.65 General
procedure
for the synthesis
of the iodides.
To a solution
and K2C03
(1.2 mol equiv)
in benzene
(50 ml)
was
added.
The
two-phase
of the tosylate
(100 ml),
mixture
etner was added, the phases were separated; .
aqueous
solution
gave the crude 80:2D
of sodium thiosulphate, iodides
that were
hexanes:diethyl
(20 mmol),
by
mixture
as eluant.
oils, that were used without
further
purification.
path
The
Bu4N+I-
stirred
cne organic
short
ether
(m, 7H);
(1 mol equiv)
of KI (3 mol equiv)
and then with water.
purified
6.25-7.78
Found:
6-9.
vigorously
Diethyl
: 6.30-7.81
in 83% yield.
'H NflR: a
a solution
was
yield.
(m, 8Hl.
of the nitrosulphides
Synthesis
82%
(m, 6H).
was obtained
C, 57.60; H, 6.26.
in
'H NMR a
H, 5.92.
C, 56.45;
(m, 7H); 3.99 (t, 2H); 2.66 (t, 2H); 2.43 (s, 3H); 1.20-1.77 4-lkthylphenylsulphonic
obtained
at
60°C
in water
overnight.
layer was washed
Evaporation
column
products
with an
of the solvent
chromatography
were
pale
with
yellow
a
mobile
Synthesis of the nitrosulphides.
Method A. To a solution of the iodide (l-3 mm011 in dry
diethyl
(3 mol equiv)
ether
The resulting and
the
(5 ml/mmol), suspension
filtrate
hexanes:diethyl
AgN02
added
portionwise
over
was stirred for 24-48 h at RT, then was filtered
concentrated
ether
was
mixture
and
purified
as eluant.
by
Yields
flash were
through
chromatography
48-56%
a 2h period.
with
in yellow
oily
celire
a
75:25
products.
Method B. The iodide (l-3 mm011 was added to a solution of NaN02 (2 mol equiv) in DMF (2 ml/mmolI,
and
the
mixture
product was extracted
several
by flash chromatography
44.91;
2H); 2.07-2.41
24-48
times with diethyl
6.
Found:
H, 4.85; N, 7.48. 'H NMR:a
h. Water
was
then
added
ether. The crude products
and
the
were purified
C,
44.99; 6.34-7.51
H,
4.79;
N,
(m, 3H); 4.70
7.53.
C7HgN03S
(t, 2H); 2.81 (t,
(m, 2H).
4-(2-FurylthioI-1-nitrobutane C, 47.75;
H, 5.51;
1.43-2.33
(m, 4H).
N, 6.96.
5-(2-FurylthioI-1-nitropentane C, 50.22;
H, 6.09;
1.17-2.07
(m, 6H).
N, 6.51.
6-(2-Furylthiol-1-nitrohexane C, 52.38;
at RT for
as above. Yield were 58-62%.
3-(2-Furylthiol-l-nitropropane requires:C,
stirred
H, 6.59;
N, 6.11.
7. Found: C, 47.85; H, 5.50; N, 7.00. C8H11N03S 'H NMR: a
6.31-7.46
(m, 3H); 4.30
(t, 2HI; 2.81
8. Found: C, 50.15; H, 6.01; N, 6.51. CgH13N03S 'H NMR: a
6.31-7.48
(m, 3H); 4.36
(t, 2H);
2.73
9. Found: C, 52.42; H, 6.61; N, 6.04. C10H15N03S 'H NMR: a
6.31-7.47
(m, 3H); 4.34
It, 2H);
2.71
requires: (t, 2H);
requires: (t, 2Hl;
requires: (t, 2H);
3879
Nihileoxiclccycloa&iition
1.18-2.14
(m, 8H).
2-(2-Furylthio)-l-nitroethane
10. To a solution
O"C,
(0.266
Z-acetoxy-1-nitroethane
stirred
at 0°C for
and the organic
g,
3h; the reaction
phase was
mnol)
The products
ether mixture N, 8.02.
was
was
as eluant,
Found:
C, 41.51;
H, 4.13;
NMR:a
6.36-7.53
(m, 3H); 4.54 (t, 2Hj; 3.24 (t, 2H).
C6H7N03S
3-(2-Furylthio)-2-methyl-1-nitropropane with
alkylation conditions experimental (60% yield, H, 5.51;
synthesis
conditions method
N, 6.96.
of esters
stirred
13 and
at O"C, NaI04
by flash chromatography
(m, 3H); 4.15-4.67
(0.428 g, 2 mm011 Usual
41.44;
requires:
H,
6.41-7.60
4.53;
N, 6.96.
C7HgN04S
(m, 3H); 4.41-4.60
H, 5.12;
6.55-7.69
N,
(10 ml),
stirring
as described
3H); 4.45
2-acetoxy-1-nirroethane
C7HgN03S
the
requires:
experimental
conditions)
and
47.87; H, 5.57; N, 6.87. C8H11N03S
C, 47.75; (m, 2H);
in 87%
of
added
g, 2 mm011
product
in 85%
H, 4.85;
was
N, 7.48.
N, 6.45.
NMR:a
Found:
C,
'H NMR:a
(m, 4H). etnoxide at 0°C.
(2 mmol) After
added dropwise.
yield.
C,
(m, 2H).
5.10;
dropwise
were
Found: 'H
as on oil.
sodium
that
and
as eluant.
N, 6.89.
yield
H,
products
in
Found:
1 H NMR:a
C,
in
10 min Work-up
45.01;
6.25-7.37
H, (m,
(t, 2H).
nitropropane
salt of 19 by alkylation
for
(2 mm011
as an oil.
4.46;
(m, 2H); 1.80-2.25
(0.266
C, 44.91;
H,
by
exchange
2.68-2.78
mixture
in 82% yield
a solution
the only
(t, 2H); 3.83 (s, 2H); 3.15
3- C(2+urylnethyl)thio]-lthe sodium
10 gave
ether:methanol
C, 44.23;
was
1
(79% yield,
requires:
crude
'I-!
experimental
of sulphide
(m, 2H); 2.30-2.56
(m, 2H); 3.06-3.34 20. To
the
41.37;
obtained
19 (0.228 g, 2 mmol)
for compound
4.76; N, 7.53.
C,
requires:
-I-nitroethane
compound
at O"C,
14 was
C8HllN04S
(m, 3H); 4.43-4.63
2-[(Furylmethyl)thio] EtOH
6.37.
obtained
(m, 2H); 2.92-3.45
4-(P-FurylsulphinylI-1-nitrobutane 44.40;
gave
with a 98:2 diethyl 13 was
solution
from
in H20 (3 ml) was added dropwise
work-up
3-(2-FurylsulphinylI-1-nitropropane
steps
iodine-nitro
(m, 2H);
NH4Cl
N, 8.09.
for
C8H11N03S
was
chromatography
4.07;
exchange and
at
oil in 57% yield.
yield,
of the iodides),
mixture
of saturated
H,
three
2-5), chlorine-iodine
14. To a stirred
at RT overnight.
in
(70%
6.25-7.41
(10 ml) cooled
purified
prepared
'H NMR: a
of nitrosulphoxides
The
by flash
C, 41.61;
C, 47.83; H, 5.57; N, 7.00.
Synthesis
dropwise.
to give a yellow
B). Found:
(m, 1H); 1.12 (d, 3H).
the mixture
was
(10 ml) cooled
by addition
propane
see the synthesis
2.32-2.52
MeOH
17
in THF
purified
requires:
1-bromo-3-chloro-2-methyl
see the
added
was then quenched
separated.
with a 70:30 hexanes:diethyl
2
of 1 (2 mmol)
21 was
with
obtained
, as an oil, in two steps from
1,3-dibromopropane
bromine-nitro requires:
exchange
C, 47.75;
(73% yield, (61%,
method
H, 5.51; N, 6.96.
see 8).
above Found:
'H NMR:a
for C,
6.15-
3880
R. ANMJNZIATA et al.
-7.39 (m, 3H); 4.48
2H); 3.83 (s, 2H); 2.05-2.80
(t,
-nitrobutane
2-[(Z-Furylmethyl)thio]-1 of 25 in 78% yield.
’ H NMR:a
lH1; 1.40-1.82
(m, 2H), 0.95
6.15-7.32
CgH13N03S
for the synthesis
requires:
(d, 2H); 3.71
imethylethyl)dimethylsilyi]
from the sodium
(83%), reduction
(m, 3H); 4.37
23
as described
C, 50.22;
(s, 2H); 3.05-3.38
H, (m,
(t, 3H).
3-[(2-Furylmethyl)thio]-1-[[(1,1-d steps
(m, 4H).
prepared
Found: C, 50.09; H, 6.01; N, 6.58.
6.09; N, 6.51.
in three
24 was
with LiAlH4
salt
of 19 -via alkylation
(loo%), and standard
oxylpropane with
silylation
ethyl
with
28 was prepared
3-bromopropanoate
TBOMSCl
and imidazole
H 0 SSi requires: C, 58.69; H, 9.15. 'H NMR: 14 26 2 2.46-2.73 (m, 2H); 1.70-1.96 (m, 2H); 0.95 (s,
in DMF (85%). Found: C, 58.78; H, 9.23. C d6.257.33
(m, 3H); 3.61-3.84
9H); 0.05
(m, 4H);
(s, 6H).
3-[[1-(2-Furyl)ethyl]-l-thio]-lsolution
of LDA
(1.7 mm011
mm011 was added dropwise. after 10 min., temperature
yield
was of
flash
starting
of
obtained
product
the
mixture
that were 3H20
These
were
hexanes:
the
mmol),
in benzene
C, 50.22;
mixtures
as
was
by flash
refluxed
to allow
eluants
to
ether see
mixture above),
(method
give
the
91%
mesylates
separation
as
eluant).
from
'H NMR: a
The
to give
the
which
B). Found:
N, 6.51.
to room
chromatography.
enough
by The
29 was
C, 50.36; 6.15-7.32
H, (m,
(m, 2H1; 1.60 (d, 3H). A
mol
24 h under
purified
1.61
(72% by NMR)
conditions into
(3
g,
to warm-up
of product
cycloaddition.
and the residue
stirred equiv), nitrogen.
by flash
cycloadducts.
solution and The
catalytic urea
chromatography
Relevant
NMR
of
was with
data
are
2 and 3.
11, m.p. 76-77"C, was obtained as eluant.
H, 6.09;
(0.46
converted
(87%,
4-chlorophenylisocyanate
(50 ml/mmol)
allowed
(t, 2H); 1.90-2.30
intramolecular
was evaporated
in Tables
diethyl
28
(0.8 ml) was added, followed,
was
not separable
into the iodide
requires:
sulphide
in THF in the standard
alcohols.
50:50
in five steps from 28. To a
gave a mixture
as an oil in the usual conditions
for
(l-3
benzene
indicated
Compound
a
was converted
procedure
triethylamine
collected
Usual work-up
(t, 2H); 4.00 (q, 1H); 2.45-2.67
nitrosulphide
filtered,
at -78"C, HMPA
3.2 mmol). The reaction
two
(with
6.03; N, 6.58. CgH13N03S
General
at -78"C,
Et20, Et3N, O"C, 30 min, 76%) that were stable
in 60% yield
3H); 4.41
(10 ml) cooled
by Bu4NtFthe
29 was prepared
lh stirring
material,
deprotected
chromatography
methylated
After
Me1 (0.200ml,
a mixture
(CH3S02Cl,
in THF
and stirred overnight.
and unreacted mixture
by
nitropropane
Found:
C, 49.77;
in 79% yield
H, 4.24;
with
N, 8.31.
a 85:15
C7H7N02S
hexanes:diethyl requires:
ether
C, 49.69;
H,
4.17; N, 8.28. Compound
12, nD25 1.5578,
was
obtained
in 75% yield
with
a 80:20
hexanes:diethyl
ether
3881
Nitrile oxide cycloaddition
Table 2. Relevant
'H NMR data of cycloadducts
11, 12. 15, 16, 18, 22, 23, 26, 30a (see
Schemes for numbering).
H-C,
H-C2
H-C3
11
6.61
5.43
5.80
12
6.54
5.26
5.50
Compound
a Typical
15a
6.63
5.67
6.00
15b
6.86
5.56
6.05
16a
6.51
5.56
5.96
16b
6.76
5.46
6.12
18a
6.58
5.36
5.76
18b
6.61
5.37
5.73
22
6.66
5.35
5.65
23
6.58
5.38
5.38
26a
6.63
5.30
5.60
266
6.65
5.33
5.60
3Oa
6.63
5.28
5.43
3ab
6.56
5.25
5.50
31a
6.59
5.44
5.84
31b
6.72
5.42
5.75
32a
6.61
5.38
5.68
J, 92 and J2 93 values were 2.5-3.0 Hz for all cycloadducts.
J, , 3 was
less than
1.0 Hz.
mixture 4.95;
as eluant.
Found:
C, 52.49;
H, 5.00;
N, 7.59. C H NO S requires: 89 2
C, 52.44;
H,
N, 7.64.
Compounds
15a,b
were
obtained
dichloromethane:methanol
mixture
obtained
impure of 15a. Found:
H, 3.81;
N, 7.56.
in as
a
75:25
eluant.
15a
ratio
in
had
m.p.
63%
yield
150-151°C
C, 45.31; H, 3.86; N, 7.66. C7H7N03S
with (dec).
requires:
a 15b
97:3 was
C, 45.40;
R. ANNUNZJATACIal.
were
Compounds 16a.b ether:methanol C, 48.11;
obtained
mixture
in
as eluant.
a
70:30
no-- 1.5561, were obtained
requires:
ether mixture
as eluant.
with
yield
a
94:6
diethyl
16b had m.p. 120-121°C.
Found:
in a 66:34
Found:
C,
ratio
52.47;
in 73% yield H,
5.04;
N,
with
a 80:20
7.58.
C8HgN02S
C, 52.44; H, 4.95, N, 7.64.
Coqmund 22, m.p. 76-77"C, was obtained mixture
60%
C, 48.23; H, 4.55; N, 7.03.
requires:
76
hexanes:diethyl
in
16a had m.p. 128-129°C;
H, 4.46; N, 7.11. C8HgN03S
Conpounds 18a,b,
ratio
as eluant.
Found:
C, 49.78;
in 77% yield
H, 4.23;
w1t.h a 70:30
N, 8.36.
C7H7N02S
hexanes:diethyl requires:
ether
C, 49.69;
H,
4.17; N, 8.28.
Coqmund 23,
m.p.
102-103"C,
ether mixture
as eluant.
was
obtained
in 76% yield
with
a 75:25
Found: C, 52.31; H, 4.86; N, 7.69. C8HgN02S
hexanes:diethyl
requires:
C, 52.44;
H, 4.95; N, 7.64.
Compounds26a,b were obtained in 78% yield as a 50:50 mixture of diastereoisomers 80:20 hexanes:diethyl
ether mixture
as eluant.
appeared
solid.
C, 54.69;
as a waxeous
Found:
The two products H, 5.70;
were
N, 7.17;
with a
not separated
CgH11N02S
and
requires:
C,
54.80; H, 5.62; N, 7.10.
Compounds27a,b were obtained 70:30
hexanes:diethyl
ether
as 50:50 mixture mixture
of diastereoisomers
as eluanc.
Spectral
data
in 80% yield
were
in
Compounds30a,b were obtained as a 66:34 mixture of dlastereoisomers 70:30 hexanes:diethyl
ether
mixture
as a thick oil that
H, 5.68; N, 7.14. CgH11N02S
as eluant.
solidifies requires:
upon
(5 ml) cooled
The reaction aqueous
at -78"C, 80% mCPBA
was warmed-up
solution
and concentrated
of NaHC03
to 0°C
to give the crude
11, sulphoxide
compound
12,
a
agreement
with those reported
85:15
General
procedure for
stirred
solution
the
of freshly (2 ml),
in 79% yield with a
were
not separated
in the freezer.
Found:
and
C, 54.71;
at this
and
of sulphide was
the organic
was
as
added
temperature
a single
obtained
in
for
layer was
that was purified
obtained
16a,b
solution
in
in one portion. 5h. A
saturated
separated,
by flash isomer
(0.05 mmol)
dried,
chromatography.
in 70% yield.
76%
yield.
M.p.'s
22,
23 via
oxidation.
(0.260 ml,
1.5 mmol)
From
were
in
above.
kinetic
resolution
distilled
Ti(OPrij4
added at RT under vigorous
standing
(0.215 g, 0.5 mmol)
product
of
two products
A stirred
added,
15a was
mixture
The
and stirred
was then
From compound
dichloroethane
with
C, 54.80; N, 5.62; N, 7.10.
General procedure for the mCPBAoxidation. CH2C12
agreement
a
23
those reported.
appeared
with
(+I-diethyl
(0.110
stirring.
of
ml,
0.38
The resulting
11,
12,
tartrate mmol) yellow
in dichloroethane solution
To
in dry
(2 ml)
was stlrred
a
was
at RT for
3883
Nitrile oxide cycloaddition
12, 18, 22, 23, 26. 30 (see Schemes
11,
13C NMR data for cycloadducts
3. Relevant
Table
for numbering).
Compound
C-l
c-2
c-3
C-N
11
149.6
102.1
91.5
110.8
161.0
12
148.9
102.1
90.4
99.6
153.2
l&
149.6
102.1
92.5
110.7
163.9
18b
149.9
101.7
92.5
111.3
164.0
22
149.5
101.5
89.5
106.2
160.3
23
148.9
101.2
86.6
95.3
153.7
26a
149.4
101.2
89.6
106.7
162.4
c-4
26b
149.4
101.5
90.3
107.2
162.3
30aa
150.1
101.9
87.0
98.4
154.4
30ba
148.7
101.7
85.9
99.4
152.8
a In DMSO.
5 min.
and then was cooled down at -20°C.
mnoll was added, followed
after additional
sulphide
(1.5 mnol). The yellow
addition
of H20 (5 ml), warmed-up
filtered
through
then
washed
brine.
celite,
with
chromatography
of
to
diastereoisomeric
to RT,
and the filtrate
10% aqueous
Evaporation
solution
the
give
ratios,
sodium
unreacted
were reported
in the Table
Compound
(+I-31a,
28%,
C7H7N03S
requires:
Compound
(-I-32a,
C8HgN03S
requires:
e.e.
gave
and enantiomeric
rotations
had
64%,
had
TBHP
(0.079 ml,
(3 ml) solution
of
17-20 h, quenched
by
was
stirred
at -20°C for
and
stirred
for lh. The resulting
extracted
with CHC13.
a
yellow
oil
sulphide excesses
The organic
5% aqueous that
and
sodium was
the
were mentioned
0.75
mixture
was
layers
were
hydroxide,
and
purified
by
flash
sulphoxide.
Yields,
in the text,
optical
1.
m.p.
m.p.
C, 48.23; H, 4.55;
at -2O"C,
5 min by a dichloroethane
122-124X.
C, 45.40; H, 3.81; N, 7.56. e.e.
5 min.
metabisulphite,
solvent the
After
C, 45.48;
31b was obtained
152-154°C. N, 7.03.
Found:
Found:
H,
3.90;
N,
7.55.
N,
7.09.
impure of 31a.
C, 48.43;
H,
4.63;
3884
R. ANNUNZIATA~~ al.
References and Notes.
1. -.M.
Dean,
Advances
in
Heterocyclic
Chemistry,
A.R.
Katrizky
Ed.;
vol.
30,
pp.
167-238; vol. 31, pp. 238-344.
2. iecent examples of intramolecular
Diels-Alder
zhem. Rev., 86, 795, 1986; 0. Craig, D.M. Rossana, 107,
k,
Jenkert, IHenkel,
K.D. Onan,
2573,
1985;
J. Org. M.E.
Chem. Sot. Rev.,
Jung,
V.C.
S.R.
Plettre,
J. Org. Chem.,
Chem.,
Int. Ed. Engl.,
K. Kanematsu,
J. Chem.
Keay, Tetrahedron
Lett.,
5469,
Harwood,
1989;
L.M.
sot., Chem.
Thomas, F.J. Witt, cycloadditions: T.J. Wisnieff,
3428,
True,
28,
Sot.,
G.
Jones,
1990;
J.Chem.
Chem.
1989.
L.L.
Klein,
Lett.,
470,
K.M.
608,
Commun.,
1989;
J. Am.
E. G.
Tatsuta,
K.
Rogers,
G. Jones,
K.
E.J. Walsh, J. Org. Chem., 54, 299, 1989; E. Wenkert,
111,
J. Chem.
Prout,
examples
53, 6154,
B.A.
Sot.,
D. Watkin,
1990. Recent
J. Org. Chem.,
1988;
N. C.
Chem.
P. Metz,
J. Am. Chem.
Thomas,
B. Jackson,
Sternbach,
6059,
Y. Yamaguchi,
J. Gervay,
Pickard,
C.B. Gamlath,
1984;
Commun.,
L.M. Harwood,
Sot.,
H. Harmata,
J.
16, 187, 1987; D.D.
1988; E. Bovenschulte,
202,
Chem.
to furan: B.H. Lipshutz;
Tetrahedron
53, 5850,
1349, 1989; M. E. Jung,
605,
Commun.,
49,
Chem.,
Angew.
Hayakawa,
cycloadditions
1988;
R.M.
of other A.
Padwa,
R. Decorzant,
F.
NBf. Helv. Chim. Acta. 72. 756. 1989.
3. 0.
Tsuge,
K. Ueno, S. Kanemasa,
4. D. Prajapati,
Chemistry
P. Bhuyan, J.S. Sandhu,
Lett., 285, 1984.
J. Chem. Sot., Perkin Trans.
1, 607, 1988.
5. I. Heinze, K. Knoll, R. MUller, W. Eberbach, Chem. Ber., 122, 2147, 1989. 6. A. Hassner,
K.S.K.
Org. Chem.,
7. A.
Murthy,
A. Padwa,
Coda,
Caramella,
P.
Griinanger,
P. Cellerino,
Houk, F. Marinone
A.
Albini,
9. P. Caramella,
10. L. Fisera, J.
J. Kovac, Lesko,
1980; A. Vasella, 11. For other application Franz,
A.M.
Schoffstall,
J-
Tetrahedron
A. Gamba
Leet.,
2911,
P.
Invernizzi,
1966;
P. Griinanger, K.N.
41, 3519, 1985.
Lett.,
743,
1968;
L.
Fisera,
J.
Kovac,
J.
Lesko,
V.
35, 93, 1981.
Damdariva,
R. Voeffray,
J. Lesko,
J.
Kovac,
Bull.
H. Grund,
Chim.
Monatsh.
Coll.
Czecn.
Chem., Chem.
111, 909, Commun.,
1980; 45,
L.
3546,
Helv. Chim. Acta, 65, 1134, 1982.
of C-4 oxygenated
see: V. Jager,
R. Ehrler,
Coda,
J. Poliacikova,
M.
synthesis
Vernesi,
J. Org. Chem., 41, 3349, 1976.
Tetrahedron
Chem. Zvesti,
6.
Corsica
8. V. Jlger, I. MLller, Tetranedron,
Fisera,
D.C. Dean,
54, 5277, 1989.
Corsica
Smahovsky,
U. Chiacchio,
Sot.
isoxazolines, V. Buss,
Belg.,
and reviews
W. Schawb,
92, 1039,
1983;
on their
synthetic
I. Miiller, R. Schohe, V.
Jlger,
R. Franz,
R. W.
3885
Nitrile oxide cycloaddition
Schwab,
B.
Chemistry
Hlfele,
0.
Schrdter,
of Heterocyclic
Cl. Schafer,
Compounds,
W.
J. Kovac
HUmner,
E.
Gunrrum,
and P. Zalupsky
Eds.;
B.
Seidel,
Elsevier
1988,
pp. 58-75. 12. R. Annunziata,
M.
Cinquini,
F.
Cozzi,
L. Raimondi,
Gazz.
Cnim.
Ital.,
119,
257,
1989. 13. R. Annunziata,
F. Cozzi, G. Dondio,
M. Cinquini,
L. Raimondi,
Tetrahedron,
43, 2369,
1987. 14. P.N. Confalone, 6291, Am.
E.D.
Lollar,
1978; P.N. Confalone, Chem.
Tetrahedron,
G. Pizzolato,
M.R.
Uskokovic,
E.D. Lollar Confalone,
Sot.,
102,
1954,
43,
4087,
1987;
1980; H.G.
H.E.
Lee,
Aurich,
J. Am. Chem.
G. Pizzolato, E.G.
K.-D.
100,
M.R. Uskokovic,
Baggiolini,
MUbus,
Sot.,
M.R.
Tetrahedron
2J
Uskokovic,
Lett.,
5755,
1988. 15. D.P. Curran,
in Advances
in Cycloaddition,
JAI Press, vol. 1, pp. 129-189.
16. Part of this section has been preliminarily Cozzi,
L. Raimondi,
Tetrahedron
17. N.D. Ly, M. Schlosser,
R. Lanz,
R. Annunziata,
M. Cinquini,
F.
Lett., 5013, 1989.
Helv. Chim. Acta, 68, 2085, 1977.
18. E. Niwa, H. Aoki, H. Tanaka, Cederlund,
reported:
A.B.
K. Munakata,
M. Namiki,
Yiirnfeldt, 0. Thorstad,
Chem.
Ber.,
K. Undheim,
99, 3215,
Acta
Chem.
1966; B. Stand.
B,
31, 198, 1977. 19. The use of higher concentrations 20. For a review on regiochemistry Padwa,
1,3-Dipolar
led to tne formation of intramolecular
Cycloaddition
Chemistry;
of nitrile
1,3-dipolar
oxide dimers.
cycloadditions
A. Padwa, Ed.; Wiley
see: A.
Interscience,
1984,
vol. 2, pp. 277-406. 21. A.P. Kozikowski, 22. W. Dehaen, 23. During
Y.Y. Chen, Tetrahedron
A. Hassner,
the preparazion
identical
Tetrahedron
Lett., 2081, 1982.
Letc., 743, 1990; and references
of this manuscript,
to one here described
an intramolecular
(25 to 27a,b)
tnerein.
cycloaddition
was published:
A. Hassner,
reaction W. Dehaen,
J. Org. Chem., 55, 5505, 1990.
24. The alternative
procedure
tAgNO
in diethylether)
gave
much
lower
yields
in this
case. 25. We Could
not establish
intrinsic
cycloaddend
thermal
if decomposition
lability
to undergo
occurs at reagent
of a benzyl-type
a retro-Michael
sulphoxide
reaction
or
or cycloadduct the
in the presence
for this observation. 26. W.E. Parham, F.L. Ramp, J. Am. Chem. Sot., 73, 1293, 1951.
level.
possibility
for
The
the
of base can account
R.
27. The minor
isomer 30b showed a
HC-5 of the isoxazoline. 28. Review: and
J. Drabowicz,
Sulphoxides,
Interscience, 29. This could
Patai,
S.
position;
the
mCP8A
the e.e.
presence
Conference
of the
and
The
Chemistry Stirling,
C.J.M.
of
Sulphones
Eds.;
Wiley
15a and 16a have the
of molecular
models
sulphoxide
the equatorial
than the axial one. Moreover occur
on the
equatorial
lone
oxygen
lone pair
the furan pair,
in
oxygen
closer
in
bonding. 0. De Lucchi,
and (+I-16a, (35.3
of optical
of
base.
For
the oxidation
as evaluated and
Tetrahedron
Lett.,
2575,
1989; and
41.5
for
reaction
basic of
22
W. Bastmann
of Organic
improved
5964, 1989; and references
and
(see text) (+I-16a,
therein.
&he
instability, sodium
very
nicely
respectively)
especially
hydroxide
diastereoisomeric
the minor diastereoisomer
and Bioorganic
and K.B. Sharpless,
17, pp. 31-48; F.A. Davis, R. ThimmaReddy,
some
(5% aqueous
by prefereni,ially decomposing
Hoecnst,
1 H NMR
(+I-15a
31 and 32 showed
instance
in Scereochemlscry
by
rotations.
in the text compound
31a,b to 90:10, Kagan,
to
hydrogen
values
by comparison
32. As mentioned
33. H.B.
isomers
6. Licini, G. Modena,
of (+)-15a
agree with
of
irradiation
therein.
31. The e.e.'s
work-up
Rappoport,
accessible
oxydation
space, -via intermolecular 30. F. Di Furia,
M. Mikolajczyk,
by inspection
can
direct
upon
1988, pp. 233-378.
12 seems more
the
Z.
signal
isomer 30a NOE was 4% (DMSO solution).
P. Kielbasinski,
of sulphide
obtained
10% NOE of the methyl
For the major
suggest that the major
an equatorial
references
ANNUNZ~ATA et al.
ratio
of
31b.
Transformations.
Eds.; VCH, Wheinneim,
M.C. Weismiller,
in
solution)
J. Am. Cnem.
Workshop 1987, vol. Sot.,
111,
AND
REGIO-
oo4o4020/91 $3.00+.00 0 1991 Pergamon Press p
STEREWONTROL
IN
ME
2-FURYLTHIOL-
Rita Annunziata, Centro C.N.R.
INTRMOLECULAR
AND E-FURYLWTHANETHIOL
Mauro Cinquini,
and Dipartimento
Organica
and Giulia
Via Marzolo
CYCLOADDITION
TO
DERIVATIVES.
Laura Raimondi
e Industriale
19, 20133 Milano,
and Dipartimenco
OXIDE
Franc0 Cozzi,
di Chimica
Via Golgi
Centro C.N.R.
NITRILE
dell'tlniversita,
Italy
Licini
di Chimica
Organica
1, 35131 Padova,
dell'llniversita,
Italy.
(Received in UK 22 January 1991)
Abstract.
A series of 2-fury1 and 2-furylmethyl substituted length were prepared and showed to undergo
chain
nitrosulphides with a proper a totally regiocontrolled
intramolecular furan-nitrile oxide cycloaddition to give cis-fused products in high yield. Insertion of a stereocenter on the cycloaddends did not allow satisfactory Enantiomerically enriched control of the absolute stereochemistry of the reaction. products of the
(e.e.<95%1
sulphide
The proteiform into organic result tne
molecules
of
especially
reports
variety
is to use furan
role
enhance
were
either
regio-
and
deal
withstanding dipolarophile, furan-nitrile
7-10
as a reagent
oxide
entry to C-4 oxygen
goal.'
can
help
intramolecular
the
cycloaddition.8
stereoselective
synthesis
stereoselective
nitrone
and nitrile
of
problems
of
to
bonus
in the
important
oxide cycloadditions,
reactivity
limited to
number furan,
particularly most
building
this
can play
intermolecularly
react
offered
8,ll
to
processes
poor
very
is indeed
a very
sugars.
a
its insertion
approach
intramolecular
cycloadditions
11
oxidation
heterocycle
dipolar
reaction
3869
this
only
tendency
amino
popular
since
line
makes
However,
synthetic This
involving
by furan
the most
overcome 2
isoxazolines,
of various
offered
this
1,3
scarce
obvious
substituted
to
control.
stereochemical
extremely
One
In
process
sulphoxides.
in cycloaddltions,
27r component.
as they
and
resolution
opportunities
an attractive
with
its
by a kinetic
to the corresponding
of synthetic
47r or
appealing,
3-6
obtained
cycloadducts
by
seem and of not as the
straightforward block for
the
In the course of our studies on 12
we became
interested
in
R. ANNUNZIATA et al.
designing
a
precursors
furan-nitrile
of acyclic
products.
jn this field,
we decided
dipolaropnile,
with
isoxazolines
into
2-Furylthiol The
Lithiation
a functionalized
to
17
1, that was treated
the
followed
(58-62%
the
unreacted
in
alkylation in
57%
compounds
alcohols
recovery 8-10
in
respectively,
only
reagent
nicrile was
assigned
on
hand 19
we
comparison
assignment.
dipole
COnVetXing
This
and tne
manuscript
to
Scheme
P-fury1
alcohols of
overall
the
(94-100%
iodides
yield),
under
nitrous
recycled,
An alternative
nitroethylene
esters
While
and
of
the
could
of compound
Compound
generaced
oui
in DMF
the former
synthesis
(40% yield).
PTC
could be carried
or with sodium nirrice
the
1.
thiolate
2-5, in 68-77%
This reaction
of
in
to the nitro derivatives
intramolecular
of the nitro compounds
were refluxed
examined
basis
unchanged. to which high
any intramolecular
Two stereocenters
to give
purification
in
6
10 was
also
situ
from
the
by flash
products Tricyclic
-1 field
H
20
be detected,
and
13
C
NMR 3-6
11
cycloadduct
lends additional
of defined
relative
and
spectroscopic
systems.
of
while
indicated
for related
6
and
(that also allowed
In the reaction
structure
Only compound
11 and 12 in 79
chromatography
could
Dilute
for 24h in the presence
crlethylamine.
derivatives
fused
CIS-
cycloaddition.
isoxazolines
nitrosulphide).
self-addition
of
and catalytic
cycloaddition
with the data reported
did not afford
experience
and on the regio- and
lithium
their
after
oxide
products the
the
(48-56% yleldj amounts
1
gave
synthesis
upon reduction.
10% of the starting
recovered
regioisomeric
to
The latter were
adding
intramolecular
of about
and 11
reported
IS
Conversion
1-iodo-3-nitropropane
by
18
to give compound
exchange.
of 3 mol equiv of p-chlorophenylisocyanate
75% yield,
sulphur
yield),
variable
also obtained.
solutions
and 7 underwent
tether
to
13
6-10
(0.02M) benzene
cases
yield
2-acetoxynitroethane. With
(80-83%
of 1 with
series
reduction
and iodine-nitro
both
iodides were
prepared
involving
tosylates
afford the corresponding entailed
with
ether with silver nitrite
yield);
previous
lead
reaction.
one pot procedure.
steps
(86-913 yield),
in diethyl
the
could
connecting
a y -aminoalcohol.
this
in situ withw-bromoesters
in four
either
of
by reaction
6-9 was
of
in the chain
of two series of cycloaddends
cycloaddends
in a convenient
preparation
or
that
and other's14
cleaving
of their cycloaddition
yield from furan,
conditions
atom
15
fl -ketol
13
16
route
achieved
a sulphur
on the synthesis
series.
of furan
cycloaddition
On the basis of ours
to insert
implications
synthetic
intramolecular
the goal of simultaneously
reports our results stereochemical
oxide
12
cycloaddends most were
of
the
single
in Scheme
1 was
evidences,
The fact that nicrosulphide
and 10
support to ihe structural
stereochemistry
are formed
in the syn-
3871 Nitrile oxide cycloaddition
Scheme 1
0/ \
I\ (x
ati
0
0
SLi 2, 4.
1
4x\
S/\/No2
6, 8,
6.
(CH2)n s' d
0
10
n=2; n-4;
7, 9,
3, 5.
n=3
n-5
NO2
n=3 n-5
i
7
11, n=l;
12, n-2
i
h 6.7
n-2; n-4;
-
5332
)
n\/NO2
-
0
13, n=2;
15a,b, 16a,b,
14, n=3
n=l n=2
O, l-
jrerf
NO2
&
Me
%
17
w:
a, n-BuLi;
IN
I
then Ss; b, Br(CHZ),,COOEt; C. LiAlH4; d, TosCl,
OS 18a.b
TEA;
e, KI, Bu@+I-;
f, AgNO2 or NaNO2; g, I(CH2)3NO2; h, AcOCH~CH~NO~;
i, p-ClCsH4NC0,
TEA; h, NaIOq; jr BrCH2CHWe)CHzCl
Me
3872
R.
ANNUWUTA~~al.
thesis of 11 and 12 from 6 and 7. The control introduction 7 was
of a stereocenter
oxidized
with
sodium
12
on the reagent.
metaperiodate
to give
the
corresponding
13 and 14 in 82 and 87% yield,
respectively.
mixture
diastereoisomeric
15a,b
of
for compound not
ratio was evaluated
15a,b
and
dipolarophile
stereoselection alkene.
an allylic was
reportedL'
disappointing
respect
to
stereochemical in
a
66:34
the
nitrile
outcome
and
cycloaddition
prompted
enantiomerically
The
the
commercially
of
available
sodium ethoxide
gave compound
isoxazolines
followed
the
Also
the -cis-fused
above
was
is
yield.
decomposition.
in
some
of
the
(73% yield)
precedents outcome
to isoxazolines
in
position extent
obtained
stereochemical
two
straightforward
way by condensing
in the presence
of piperidine,
Scheme
Alkylation
in
the
of
the
as 11 or 12 in
experimental
on the basis
were of
sulphoxide
racemic
sodium
single
report
stereochemistry was
analogues
to give nitrosulphides
of
of
in DMF
24
intramolecular give
cricyclic by flash
regioisomers,
to which
on
analogy
a virtually
was
resulted 20
of
purlflcation
accomplished
cycloaddition
19 with nirromethane
to
evidences, 23
nitrite
underwent
after
NMR
Addition
in the presence
conditions,
and literature
however,
with
respectively,
2.
of the sodium salt of 19
two cycloaddends
of absolute
chiral
in
exchange
the cycloadduccs
series,
oxidation:
Next,
being
extent
limited
19 to E-acetoxynitroethane
These
described
20 to the corresponding
25
very
has
the
described
by bromide-nitro
in this case control
metaperiodate
result
20 in 85% yield.
assigned
of the 2-furylthiol
system. Also of compound
products
in this case
structure
18a,b
new approaches
22 and 23 in 77 and 76% yield,
chromatography.
usual
required
21 in 44% overall in
this
of controlling
a
connecting
17, prepared
In this case a stereocenter to
was
an E-configurated
of nitrosulphide
dictate
The
to be 75:25
chain
on
a
23
gave nitrosulphide
cycloaddition,
60% yield.
identical
cycloaddition
gave
stereocontrol
the
practically
compound
Also
ratio.
and
of
inside
racemic
of these
and determined
low extent
located
oxide
can
2-furylmethanethiol
with 1,3-dibromopropane
in 63
the
form (see below).
series.
synthesis
1.
moiety
us to investigate
2-Furylmethanethiol
products
oxide
impossibility
enriched
This
promote
of tne cycloaddition,
the
16a,b,
the cycloaddition
in Scheme
diastereoisomeric
literature,22
to
nitrile
was
three steps from 1 as described with
16a,b.
stereocenter
in an intramolecular
Similarly
and
requires
atom of 6 and
chiral,
Cycloaddition
by 'H NMR spectroscopy
and 70:30 for compound
indeed,
unexpected:
dipole
cycloadducts
configuration
To this end, the sulphur
sulphoxides
diastereoisomeric
a
of the absolute
were
and propanal
attempted. in fair only
with
identical Oxidation
yield in
prepared
the
by the
extensive in
a
very
or 2-methylpropanal,
24 and 25 in 78 and 80% yield,
3873
Nitrile oxide cycloaddition
Schm
2
‘-NO, 20
m/
SW
0
19 S-NO2 21
0,
3
20
dl
O,N
FJ 2
5
N
d
21
0.z
0 .-\ S
‘S
22
19
23
d
S
e_
CH$Q
-
Y R 26a.b. b.
24, K=Et 25, Et-Pr-i
278,
R-Et K=Pr-i
Me
28
29
d
\
Reaaents:
a,AcOCH2CK2N02,
EtOUa: b, EtONa, Br(CH2)aBr; c, NaN02, DMF;
d, P-ClC#4NCO, TEA: e, CH3U02, RCHO, Piperidine; f, Br(CH2)~CoOEt, EtONa; 9, LiAlH,; h, t-BuMe2SiC1, Imidatole; j, LDA, KMPA, HaI; k, Bu,N+F-; 1, HsCl, TEA; m, KI, Bu,N+I-.
3874
R. ANNUNZIATA etal.
respectively. compounds
26
their
However,
cycloaddition
26a,b and 27a,b were obtained of two diastereoisomers.
of a cycloaddend
featuring
an allylic
28 was
in three
high
methylated
(72% yield)
yield),
by the usual
66:34 mixture structures isomer basis
The
poor
assigned
steric
on
of
cycloaddition
that
by
for
the
inserting
oxidation
sulphur
atom
of
tnese compounds
by some
(Table 11. The former,
preliminary
derivative
(87%
a 79% yield
of a
predominance
of
the
be
rationalized
on
the
in agreement
sulphoxide
detectable
16a,b was obtained
both cases the predominant of 13 or 14.2g Oxidation respectively)
with
previous
reagents
1. In kinetic
1.0 mol. equiv.
is
25,
and
29
stereochemistry
reagent.
We
represent
enriched 28
30
also
by
1 H NMR
out
therefore
and the rigid structure
on
compound
highly
11 and 12
from
the
(76% yield).
In
of the cycloaddition
since the products
(see below):
(31a.b
this prevented
of the mCPBA oxidation. sulphide
oxidation,
to secure
selective.
(0.5 mol.
of (+I-diethyl
23
process.
acid, gave
while
ratio
products
convenient
Indeed, a number
(70% yield),
in lower yield
that is known
conditions
form.
a
stereodifferentiating
carried
enantioselective
reagent,
resolution
could
was the major
Among
oxidation
the
in 85:15 diastereoisomeric
of the diastereoselectivity
mCPBA
24,
11. 12, 22, and 23.
some tendency to decompose
for
17,
oxidation with m-chloroperbenzoic
of 22 and 23 proceeded
of Sharpless's
on
of a highly
a safe determination available
center
14,
the absolute
has been reported,
isomer
isomer obtained
showed
13,
to control
experiments
upon low temperature
15a as a single
of
in enantiomerically
This was confirmed
of Ti(OPr-i14;
converted
alCOhO1
iodo
was
The
can
is
cycloadducts
the possibility
Table
and
of cycloadducts our
suggested
the analW3OUS
compound
approach.
of our isoxazolines
the
the
27
position
a stereogenic
of sulphides
modification
botn
reaction
3Da and 3Db, to which the indicated
reaction
be very difficult
oxidations
and 32a,b,
This
of 29 gave
of NOE experiments.
of enantioselective
latter
the
19, silyl derivatives
yield).
and
Cycloaddition
considerations,
to a different
the
handle for obtaining
sulphoxide
from
and the resulting
(76% yield)
in an equatorial
observed
and enantioselective
reasoned
co investigate
overall
isoxazolines
basis
interaction
that it would
turned our attention
Diastereo-
the
(71%
since
(82 and 76%, respectively),
starting
(91% yield),
(60% yield).
group
stereoselectivity
indicate
We
steps
stereoselective,
12
clearly the
procedure
non
We then decided
29, -via the mesylate
tne methyl
of simple
observations.
yielding
of two diastereoisomeric
were
having
"
stereocenter:
and deprotected
into the nitrosulphide
totally
in good yield
as 50:50 mixture
prepared
was
The
equiv.
tartrate)
good
results
of tBuOOH;
sulphide
we
selected
stereocontrol are
wnen
collected
0.25 mol.
a
in
equiv.
11 gave exclusively
3875
Nitrileoxidecycloaddition
Table
1. Stereoselective
Sulphide
oxidation
of 11, 12, 22, and 23.
Sulphoxide
Oxidant
D1astereoisomer,ca a:b ratio
11
mCPBA
15a.b
12
mCPBA
16a,b
Q D
%
22c
3
85:15
11
TBHP/Ti(OPr-l),/(+)DET
15a,b
397:
3
85
-561.1
12
TBHP/Ti(OPr-i)4/(+)DET
16a,b
297:
3
95
-511.5
lid
TBHP/VO(acac)2
15a,b
397:
3
36
t233.1
12d
TBHP/VO(acac)2
16a,b
>/97: 3
43
t223.3
22
TBHP/Ti(OPr-i)4/(+)DET
31a,b
28
tl85.3
23
TBHP/Ti(OPr-i)4/(+)DET
32a,b
64
-151.6
aAs determined 1 H
297:
[I
E.e.b
NMR
in
pre-established
solution,
397:
b
by 300 MHz 'H NMR spectroscopy.
spectroscopy
conditions
Ei0:20e
c
the
presence
of
3
As determined
for a isomers
(-)-trifluoromethyl-9-anthrylcarbinol
on racemic compound. 'As determined d Sulphide recovered from
0.5-1.0.
TBHP/Ti(OPr-i)4/(t)-DET.
by 300 MHz
for a isomers the
in
in CHC13 with
oxidation
e31b had e.e. 35%.
sulphoxide (-)-15a in 60% yield based on the oxidant. The e.e. was determined as 85% by 1 H NMR spectroscopy in the presence of (-)-trifluoromethyl-9-anthrylcarbinol, in conditions product
pre-established (-I-16a
enantiomerically sulphides
11
(48%
yield
pure
by
and
tBuOOH/VO(acac12 yield,
12,
to
43% e.e.1,
give
being
was
obtained
Compound
obtained
recovered
the
sulphoxides
the
(+I-15a
kinetic
31
(based on the
sulphoxide
a single shown
sake
resolution, 36%
The oxidation
oxidant)
the
by the
(-)-32a
of
were
e.e.1
From compound
pure, as evaluated
isomeric
was
For
(50% yield,
diastereoisomers.
afforded
that
technique.
series was then examined.
a single
of 12
oxidant),
described from
in 48% yield
as 64%.
15a. Oxidation
on
above
28% enantiomerically
23 afforded
was determined
the
based
both as single
of the E-furylmethanethiol of 31a,b
on racemic
and
to
isomeric be
95%
completeness, treated (+I-16a
with (36%
of the cycloadducts 22 a 80:20 mixture
major usual
(52% yield),
isomer,
32
(+I-3la,
1 H NMR technique. the e.e. of which
R. ANNUNZIATA~~ al.
The
stereochemical The
comments. definitely
outcome
of
enantiomeric
higher
than
the
kinetic
excesses
those
resolution
observed
obtained
for
with the
showed
differentiated
more
stereoselective
ligands. The greater
difference
for
in 11 and 12 than in 22 and 23 can account
are the
reasons
any reasonable
understand reports. In
lower enantioselection
this
explanation
result.
A
for
similar
that,
with
is
sterically
a
at
Less evident
of tetrahydrothiophene
experimental
not
33
well
of the substituent
of the oxidation
behaviour
reactions,
for this observation.
and more
few were
12 and 23. We do not work
common
is necessary
feature
of
to
literature
30,33
conclusion
we
2-furylthiolfashion
for similar
sulphides
a
derivatives
E-furylmethanethiol
11 and 22 with respect to that of thiopyran derivatives
derivatives have
the
in steric bulkiness
sulphur
for the
of
observations
oxidations
requires
P-furyltniol
compounds
series: this is in line with a number of previous that always
experiments
the
showed
that
intramolecular
and 2-furylmethanethiol
derivatives
to give high yield of -cis-fused
number of synthetically stereochemistry locations
on
stereocontrol. established sulphide
chain
An
connecting
alternative
by a kinetic
to sulphoxide
approach
to
oxide
cycloadditions
in a completely
that in principle
Various
reaction dipole
resolution
occur
products,
useful transformations.
of tne cycloaddition the
furan-nitrile
attempts
by inserting
on
reigocontrolled
are amenable
to control
a stereocenter
to a
the absolute in different
and dipolarophile
resulted
in poor
to
fair
enantiomerically
enriched
cycloadducts
was
process
involving
a diastereo-
and enantioselective
oxidation.
Experimental. 1 H and l3 C NMR spectra were recorded
with
on CDC13
are
solutions.
were measured a
Perkin
Chemical
shifts
on a Perkin-Elmer
Elmer
chromatography;
DMF
employing
and
240
instrument.
organic
extracts
CH2C12
anhydrous
from
in ppm
Silica were
gel
dried
from
from
Elemental was
over
pressure.
CaH2;benzene
WP 80 or a Varian
downfield
241 spectrometer.
removal of the solvent under' reduced HMPA,
a Bruker
used
sodium
Et3N
Optical
rotations
were performed
analytical
sulphate
THF and Et20 were sodium;
TMS.
analyses for
XL 300 instrument
and
and filtered
distilled
from
KOH.
from All
with flash
before LiAlH4;
reactions
solvents were run under Argon.
General procedure for the synthesis of esters 2-5. To a stirred
solution
of 2-furyllithium l7 (50 mnol) in THF (250 ml),
mmol) was added portionwise then treated
with
at 0°C. The dark red solution
ethyl w-bromo
alkanoate
(45 mmol).
The
sulphur
(1.6 g, 50
was kept at 0°C for mixture
was
stirred
1.5 h and at room
3877
Nitrileoxidecycloaddition
temperature then
overnight, the
added;
hydroxide,
and the reaction
organic
phase
washed
twice
and then with brine. The products
chromatography
with 90:10 hexanes:diethyl
requires:
C, 53.98;
by addition
with
5%
ether mixture
of water. aqueous
Diethyl
ether was
solution
as pale yellow
of
sodium
oils by flash
as eluant.
in 68% yield.
1 H NMR: a
H, 6.04.
a
were isolated
2 was obtained
Ethyl 3-(P-furylthio)propanoate CgH1203S
quenched
6.31-7.46
Found:
C, 54.06;
(m, 3H); 4.09
H, 6.12.
(q, ZH);
2.93
(t, ZH); 2.56 (t, 2H); 1.21 (t, 3H).
Ethyl
3 was obtained
4-(2-furylthio)butanoate
C10H1403S
requires:
requires:
4 was obtained
requires:
(t, 2H); 2.27 (t, 2H); 1.37-1.71
O"C,
ether
a diethyl
dropwise.
The reaction
(5 ml/mm01
15-30 min. After cooling 15% aqueous
NaOH
The precipitate
quantitative
dissolved
in dry CH2C12
were
reaction
added
mixture
concentrated chromatography
to
ester)
solution
then warmed
H20
and
of
ester
ether (3 ml/g
of LiAlH4)
(1.2 mol equiv)
the
with crude
acid
H, 5.15.
H,
7.57.
(q, 2H); 2.73
After H20
purity
overnight and
products
the that
ether mixture
C14H1604S2
requires:
C, 53.83;
added
NMR).
at
phase
room
was
added for
in this order.
To
in
the
alcohol,
chloride
(1.0 mol
temperature,
as
at
of LiAlH4),
separated,
isolated
dried,
oils
by
the and flash
as eluant. was
3-(2-furylthio)propylester
(1 ml/g
and tosyl
stirring
were
were
1 H
(by
organic
H20
mm011
and refluxed
to give the crude alcohol
Et3N
order.
(20-30
(ca. 100 ml),
(10 ml/mmol),
give
59.18;
of ester) cooled
up to room temperature
high
washed
C,
Found:
(10 ml/mm01
very
with a 70:30 hexanes:diethyl
C, 54.01;
(m, 7H); 4.13
of
ether
in
was
H, 7.00.
(q, 2H); 2.78
(m, 3H); 4.10
6.30-7.46
and the solvent was evaporated
yield
in this
4Aethylphenylsulphonic Found:
was
of LiA1H4),
was filtered
virtually
equiv)
in 76% yield.
in diethyl
at 0°C wet diethyl
(1 ml/g
C, 57.88;
Found:
of the tosylates.
(3 mol equiv)
mixture
6.66.
(m, 6H); 1.21 It, 3H).
General procedure for the synthesis of LiAlH4
H,
(q, 2H); 2.73
(m, 3H); 4.12
6.25-7.43
C, 59.48; H, 7.49. 'H NMR: a
To a suspension
55.93;
(m, 4H); 1.26 (t, 3H).
5 was obtained
6-(P-furylthio)hexanoate
C12H1803S
C,
(m, 3H); 4.04
in 75%*yield.
'H NMR:a
C, 57.87; H, 7.06.
(t, 2H); 2.35 (t, 2H); 1.57-1.95
Ethyl
6.22-7.40
Found:
(m, 2H); 1.15 (t, 3H).
Ethyl 5-(2-furylthio)pentanoate C,,H1603S
'H NMR:a
C, 56.05; H, 6.58.
(t, 2H); 2.35 (t, 2H); 1.80-2.05
in 77% yield.
obtained
H, 5.16.
in
82%
'H NMR:a
yield.
6.29-7.81
(t, 2H); 2.71 it, 2H); 2.43 (s, 3H); 1.87 (m, 2H).
4-Methylphenylsulphonic
acid 4-(2-furylthio)butylester
C, 55.11; H, 5.61. C15H,804S2
requires:
was obtained
C, 55.19; H, 5.56. 'H NMR: a
4.05 (t, 2H); 2.74 (t, 2H); 2.47 (s, 3H); 1.55-1.92
(m, 4H).
in 80% yield.
6.29-7.82
Found:
(m, 7~1;
3878
R. ANNUNZIATAetal.
4+4ethylphenylsulphonic
acid
was
5-(2-furylthio)pentylester
Found: C, 56.30; H, 5.87. C,6H2004S2
requires:
acid 6-(2-furylthio)hexylester
C, 57.70; H, 6.18. C,7H2204S2
requires:
3.98 (t, 2Hl; 2.68 (t, 2Hl; 2.41 (s, 3H); 1.20-1.65 General
procedure
for the synthesis
of the iodides.
To a solution
and K2C03
(1.2 mol equiv)
in benzene
(50 ml)
was
added.
The
two-phase
of the tosylate
(100 ml),
mixture
etner was added, the phases were separated; .
aqueous
solution
gave the crude 80:2D
of sodium thiosulphate, iodides
that were
hexanes:diethyl
(20 mmol),
by
mixture
as eluant.
oils, that were used without
further
purification.
path
The
Bu4N+I-
stirred
cne organic
short
ether
(m, 7H);
(1 mol equiv)
of KI (3 mol equiv)
and then with water.
purified
6.25-7.78
Found:
6-9.
vigorously
Diethyl
: 6.30-7.81
in 83% yield.
'H NflR: a
a solution
was
yield.
(m, 8Hl.
of the nitrosulphides
Synthesis
82%
(m, 6H).
was obtained
C, 57.60; H, 6.26.
in
'H NMR a
H, 5.92.
C, 56.45;
(m, 7H); 3.99 (t, 2H); 2.66 (t, 2H); 2.43 (s, 3H); 1.20-1.77 4-lkthylphenylsulphonic
obtained
at
60°C
in water
overnight.
layer was washed
Evaporation
column
products
with an
of the solvent
chromatography
were
pale
with
yellow
a
mobile
Synthesis of the nitrosulphides.
Method A. To a solution of the iodide (l-3 mm011 in dry
diethyl
(3 mol equiv)
ether
The resulting and
the
(5 ml/mmol), suspension
filtrate
hexanes:diethyl
AgN02
added
portionwise
over
was stirred for 24-48 h at RT, then was filtered
concentrated
ether
was
mixture
and
purified
as eluant.
by
Yields
flash were
through
chromatography
48-56%
a 2h period.
with
in yellow
oily
celire
a
75:25
products.
Method B. The iodide (l-3 mm011 was added to a solution of NaN02 (2 mol equiv) in DMF (2 ml/mmolI,
and
the
mixture
product was extracted
several
by flash chromatography
44.91;
2H); 2.07-2.41
24-48
times with diethyl
6.
Found:
H, 4.85; N, 7.48. 'H NMR:a
h. Water
was
then
added
ether. The crude products
and
the
were purified
C,
44.99; 6.34-7.51
H,
4.79;
N,
(m, 3H); 4.70
7.53.
C7HgN03S
(t, 2H); 2.81 (t,
(m, 2H).
4-(2-FurylthioI-1-nitrobutane C, 47.75;
H, 5.51;
1.43-2.33
(m, 4H).
N, 6.96.
5-(2-FurylthioI-1-nitropentane C, 50.22;
H, 6.09;
1.17-2.07
(m, 6H).
N, 6.51.
6-(2-Furylthiol-1-nitrohexane C, 52.38;
at RT for
as above. Yield were 58-62%.
3-(2-Furylthiol-l-nitropropane requires:C,
stirred
H, 6.59;
N, 6.11.
7. Found: C, 47.85; H, 5.50; N, 7.00. C8H11N03S 'H NMR: a
6.31-7.46
(m, 3H); 4.30
(t, 2HI; 2.81
8. Found: C, 50.15; H, 6.01; N, 6.51. CgH13N03S 'H NMR: a
6.31-7.48
(m, 3H); 4.36
(t, 2H);
2.73
9. Found: C, 52.42; H, 6.61; N, 6.04. C10H15N03S 'H NMR: a
6.31-7.47
(m, 3H); 4.34
It, 2H);
2.71
requires: (t, 2H);
requires: (t, 2Hl;
requires: (t, 2H);
3879
Nihileoxiclccycloa&iition
1.18-2.14
(m, 8H).
2-(2-Furylthio)-l-nitroethane
10. To a solution
O"C,
(0.266
Z-acetoxy-1-nitroethane
stirred
at 0°C for
and the organic
g,
3h; the reaction
phase was
mnol)
The products
ether mixture N, 8.02.
was
was
as eluant,
Found:
C, 41.51;
H, 4.13;
NMR:a
6.36-7.53
(m, 3H); 4.54 (t, 2Hj; 3.24 (t, 2H).
C6H7N03S
3-(2-Furylthio)-2-methyl-1-nitropropane with
alkylation conditions experimental (60% yield, H, 5.51;
synthesis
conditions method
N, 6.96.
of esters
stirred
13 and
at O"C, NaI04
by flash chromatography
(m, 3H); 4.15-4.67
(0.428 g, 2 mm011 Usual
41.44;
requires:
H,
6.41-7.60
4.53;
N, 6.96.
C7HgN04S
(m, 3H); 4.41-4.60
H, 5.12;
6.55-7.69
N,
(10 ml),
stirring
as described
3H); 4.45
2-acetoxy-1-nirroethane
C7HgN03S
the
requires:
experimental
conditions)
and
47.87; H, 5.57; N, 6.87. C8H11N03S
C, 47.75; (m, 2H);
in 87%
of
added
g, 2 mm011
product
in 85%
H, 4.85;
was
N, 7.48.
N, 6.45.
NMR:a
Found:
C,
'H NMR:a
(m, 4H). etnoxide at 0°C.
(2 mmol) After
added dropwise.
yield.
C,
(m, 2H).
5.10;
dropwise
were
Found: 'H
as on oil.
sodium
that
and
as eluant.
N, 6.89.
yield
H,
products
in
Found:
1 H NMR:a
C,
in
10 min Work-up
45.01;
6.25-7.37
H, (m,
(t, 2H).
nitropropane
salt of 19 by alkylation
for
(2 mm011
as an oil.
4.46;
(m, 2H); 1.80-2.25
(0.266
C, 44.91;
H,
by
exchange
2.68-2.78
mixture
in 82% yield
a solution
the only
(t, 2H); 3.83 (s, 2H); 3.15
3- C(2+urylnethyl)thio]-lthe sodium
10 gave
ether:methanol
C, 44.23;
was
1
(79% yield,
requires:
crude
'I-!
experimental
of sulphide
(m, 2H); 2.30-2.56
(m, 2H); 3.06-3.34 20. To
the
41.37;
obtained
19 (0.228 g, 2 mmol)
for compound
4.76; N, 7.53.
C,
requires:
-I-nitroethane
compound
at O"C,
14 was
C8HllN04S
(m, 3H); 4.43-4.63
2-[(Furylmethyl)thio] EtOH
6.37.
obtained
(m, 2H); 2.92-3.45
4-(P-FurylsulphinylI-1-nitrobutane 44.40;
gave
with a 98:2 diethyl 13 was
solution
from
in H20 (3 ml) was added dropwise
work-up
3-(2-FurylsulphinylI-1-nitropropane
steps
iodine-nitro
(m, 2H);
NH4Cl
N, 8.09.
for
C8H11N03S
was
chromatography
4.07;
exchange and
at
oil in 57% yield.
yield,
of the iodides),
mixture
of saturated
H,
three
2-5), chlorine-iodine
14. To a stirred
at RT overnight.
in
(70%
6.25-7.41
(10 ml) cooled
purified
prepared
'H NMR: a
of nitrosulphoxides
The
by flash
C, 41.61;
C, 47.83; H, 5.57; N, 7.00.
Synthesis
dropwise.
to give a yellow
B). Found:
(m, 1H); 1.12 (d, 3H).
the mixture
was
(10 ml) cooled
by addition
propane
see the synthesis
2.32-2.52
MeOH
17
in THF
purified
requires:
1-bromo-3-chloro-2-methyl
see the
added
was then quenched
separated.
with a 70:30 hexanes:diethyl
2
of 1 (2 mmol)
21 was
with
obtained
, as an oil, in two steps from
1,3-dibromopropane
bromine-nitro requires:
exchange
C, 47.75;
(73% yield, (61%,
method
H, 5.51; N, 6.96.
see 8).
above Found:
'H NMR:a
for C,
6.15-
3880
R. ANMJNZIATA et al.
-7.39 (m, 3H); 4.48
2H); 3.83 (s, 2H); 2.05-2.80
(t,
-nitrobutane
2-[(Z-Furylmethyl)thio]-1 of 25 in 78% yield.
’ H NMR:a
lH1; 1.40-1.82
(m, 2H), 0.95
6.15-7.32
CgH13N03S
for the synthesis
requires:
(d, 2H); 3.71
imethylethyl)dimethylsilyi]
from the sodium
(83%), reduction
(m, 3H); 4.37
23
as described
C, 50.22;
(s, 2H); 3.05-3.38
H, (m,
(t, 3H).
3-[(2-Furylmethyl)thio]-1-[[(1,1-d steps
(m, 4H).
prepared
Found: C, 50.09; H, 6.01; N, 6.58.
6.09; N, 6.51.
in three
24 was
with LiAlH4
salt
of 19 -via alkylation
(loo%), and standard
oxylpropane with
silylation
ethyl
with
28 was prepared
3-bromopropanoate
TBOMSCl
and imidazole
H 0 SSi requires: C, 58.69; H, 9.15. 'H NMR: 14 26 2 2.46-2.73 (m, 2H); 1.70-1.96 (m, 2H); 0.95 (s,
in DMF (85%). Found: C, 58.78; H, 9.23. C d6.257.33
(m, 3H); 3.61-3.84
9H); 0.05
(m, 4H);
(s, 6H).
3-[[1-(2-Furyl)ethyl]-l-thio]-lsolution
of LDA
(1.7 mm011
mm011 was added dropwise. after 10 min., temperature
yield
was of
flash
starting
of
obtained
product
the
mixture
that were 3H20
These
were
hexanes:
the
mmol),
in benzene
C, 50.22;
mixtures
as
was
by flash
refluxed
to allow
eluants
to
ether see
mixture above),
(method
give
the
91%
mesylates
separation
as
eluant).
from
'H NMR: a
The
to give
the
which
B). Found:
N, 6.51.
to room
chromatography.
enough
by The
29 was
C, 50.36; 6.15-7.32
H, (m,
(m, 2H1; 1.60 (d, 3H). A
mol
24 h under
purified
1.61
(72% by NMR)
conditions into
(3
g,
to warm-up
of product
cycloaddition.
and the residue
stirred equiv), nitrogen.
by flash
cycloadducts.
solution and The
catalytic urea
chromatography
Relevant
NMR
of
was with
data
are
2 and 3.
11, m.p. 76-77"C, was obtained as eluant.
H, 6.09;
(0.46
converted
(87%,
4-chlorophenylisocyanate
(50 ml/mmol)
allowed
(t, 2H); 1.90-2.30
intramolecular
was evaporated
in Tables
diethyl
28
(0.8 ml) was added, followed,
was
not separable
into the iodide
requires:
sulphide
in THF in the standard
alcohols.
50:50
in five steps from 28. To a
gave a mixture
as an oil in the usual conditions
for
(l-3
benzene
indicated
Compound
a
was converted
procedure
triethylamine
collected
Usual work-up
(t, 2H); 4.00 (q, 1H); 2.45-2.67
nitrosulphide
filtered,
at -78"C, HMPA
3.2 mmol). The reaction
two
(with
6.03; N, 6.58. CgH13N03S
General
at -78"C,
Et20, Et3N, O"C, 30 min, 76%) that were stable
in 60% yield
3H); 4.41
(10 ml) cooled
by Bu4NtFthe
29 was prepared
lh stirring
material,
deprotected
chromatography
methylated
After
Me1 (0.200ml,
a mixture
(CH3S02Cl,
in THF
and stirred overnight.
and unreacted mixture
by
nitropropane
Found:
C, 49.77;
in 79% yield
H, 4.24;
with
N, 8.31.
a 85:15
C7H7N02S
hexanes:diethyl requires:
ether
C, 49.69;
H,
4.17; N, 8.28. Compound
12, nD25 1.5578,
was
obtained
in 75% yield
with
a 80:20
hexanes:diethyl
ether
3881
Nitrile oxide cycloaddition
Table 2. Relevant
'H NMR data of cycloadducts
11, 12. 15, 16, 18, 22, 23, 26, 30a (see
Schemes for numbering).
H-C,
H-C2
H-C3
11
6.61
5.43
5.80
12
6.54
5.26
5.50
Compound
a Typical
15a
6.63
5.67
6.00
15b
6.86
5.56
6.05
16a
6.51
5.56
5.96
16b
6.76
5.46
6.12
18a
6.58
5.36
5.76
18b
6.61
5.37
5.73
22
6.66
5.35
5.65
23
6.58
5.38
5.38
26a
6.63
5.30
5.60
266
6.65
5.33
5.60
3Oa
6.63
5.28
5.43
3ab
6.56
5.25
5.50
31a
6.59
5.44
5.84
31b
6.72
5.42
5.75
32a
6.61
5.38
5.68
J, 92 and J2 93 values were 2.5-3.0 Hz for all cycloadducts.
J, , 3 was
less than
1.0 Hz.
mixture 4.95;
as eluant.
Found:
C, 52.49;
H, 5.00;
N, 7.59. C H NO S requires: 89 2
C, 52.44;
H,
N, 7.64.
Compounds
15a,b
were
obtained
dichloromethane:methanol
mixture
obtained
impure of 15a. Found:
H, 3.81;
N, 7.56.
in as
a
75:25
eluant.
15a
ratio
in
had
m.p.
63%
yield
150-151°C
C, 45.31; H, 3.86; N, 7.66. C7H7N03S
with (dec).
requires:
a 15b
97:3 was
C, 45.40;
R. ANNUNZJATACIal.
were
Compounds 16a.b ether:methanol C, 48.11;
obtained
mixture
in
as eluant.
a
70:30
no-- 1.5561, were obtained
requires:
ether mixture
as eluant.
with
yield
a
94:6
diethyl
16b had m.p. 120-121°C.
Found:
in a 66:34
Found:
C,
ratio
52.47;
in 73% yield H,
5.04;
N,
with
a 80:20
7.58.
C8HgN02S
C, 52.44; H, 4.95, N, 7.64.
Coqmund 22, m.p. 76-77"C, was obtained mixture
60%
C, 48.23; H, 4.55; N, 7.03.
requires:
76
hexanes:diethyl
in
16a had m.p. 128-129°C;
H, 4.46; N, 7.11. C8HgN03S
Conpounds 18a,b,
ratio
as eluant.
Found:
C, 49.78;
in 77% yield
H, 4.23;
w1t.h a 70:30
N, 8.36.
C7H7N02S
hexanes:diethyl requires:
ether
C, 49.69;
H,
4.17; N, 8.28.
Coqmund 23,
m.p.
102-103"C,
ether mixture
as eluant.
was
obtained
in 76% yield
with
a 75:25
Found: C, 52.31; H, 4.86; N, 7.69. C8HgN02S
hexanes:diethyl
requires:
C, 52.44;
H, 4.95; N, 7.64.
Compounds26a,b were obtained in 78% yield as a 50:50 mixture of diastereoisomers 80:20 hexanes:diethyl
ether mixture
as eluant.
appeared
solid.
C, 54.69;
as a waxeous
Found:
The two products H, 5.70;
were
N, 7.17;
with a
not separated
CgH11N02S
and
requires:
C,
54.80; H, 5.62; N, 7.10.
Compounds27a,b were obtained 70:30
hexanes:diethyl
ether
as 50:50 mixture mixture
of diastereoisomers
as eluanc.
Spectral
data
in 80% yield
were
in
Compounds30a,b were obtained as a 66:34 mixture of dlastereoisomers 70:30 hexanes:diethyl
ether
mixture
as a thick oil that
H, 5.68; N, 7.14. CgH11N02S
as eluant.
solidifies requires:
upon
(5 ml) cooled
The reaction aqueous
at -78"C, 80% mCPBA
was warmed-up
solution
and concentrated
of NaHC03
to 0°C
to give the crude
11, sulphoxide
compound
12,
a
agreement
with those reported
85:15
General
procedure for
stirred
solution
the
of freshly (2 ml),
in 79% yield with a
were
not separated
in the freezer.
Found:
and
C, 54.71;
at this
and
of sulphide was
the organic
was
as
added
temperature
a single
obtained
in
for
layer was
that was purified
obtained
16a,b
solution
in
in one portion. 5h. A
saturated
separated,
by flash isomer
(0.05 mmol)
dried,
chromatography.
in 70% yield.
76%
yield.
M.p.'s
22,
23 via
oxidation.
(0.260 ml,
1.5 mmol)
From
were
in
above.
kinetic
resolution
distilled
Ti(OPrij4
added at RT under vigorous
standing
(0.215 g, 0.5 mmol)
product
of
two products
A stirred
added,
15a was
mixture
The
and stirred
was then
From compound
dichloroethane
with
C, 54.80; N, 5.62; N, 7.10.
General procedure for the mCPBAoxidation. CH2C12
agreement
a
23
those reported.
appeared
with
(+I-diethyl
(0.110
stirring.
of
ml,
0.38
The resulting
11,
12,
tartrate mmol) yellow
in dichloroethane solution
To
in dry
(2 ml)
was stlrred
a
was
at RT for
3883
Nitrile oxide cycloaddition
12, 18, 22, 23, 26. 30 (see Schemes
11,
13C NMR data for cycloadducts
3. Relevant
Table
for numbering).
Compound
C-l
c-2
c-3
C-N
11
149.6
102.1
91.5
110.8
161.0
12
148.9
102.1
90.4
99.6
153.2
l&
149.6
102.1
92.5
110.7
163.9
18b
149.9
101.7
92.5
111.3
164.0
22
149.5
101.5
89.5
106.2
160.3
23
148.9
101.2
86.6
95.3
153.7
26a
149.4
101.2
89.6
106.7
162.4
c-4
26b
149.4
101.5
90.3
107.2
162.3
30aa
150.1
101.9
87.0
98.4
154.4
30ba
148.7
101.7
85.9
99.4
152.8
a In DMSO.
5 min.
and then was cooled down at -20°C.
mnoll was added, followed
after additional
sulphide
(1.5 mnol). The yellow
addition
of H20 (5 ml), warmed-up
filtered
through
then
washed
brine.
celite,
with
chromatography
of
to
diastereoisomeric
to RT,
and the filtrate
10% aqueous
Evaporation
solution
the
give
ratios,
sodium
unreacted
were reported
in the Table
Compound
(+I-31a,
28%,
C7H7N03S
requires:
Compound
(-I-32a,
C8HgN03S
requires:
e.e.
gave
and enantiomeric
rotations
had
64%,
had
TBHP
(0.079 ml,
(3 ml) solution
of
17-20 h, quenched
by
was
stirred
at -20°C for
and
stirred
for lh. The resulting
extracted
with CHC13.
a
yellow
oil
sulphide excesses
The organic
5% aqueous that
and
sodium was
the
were mentioned
0.75
mixture
was
layers
were
hydroxide,
and
purified
by
flash
sulphoxide.
Yields,
in the text,
optical
1.
m.p.
m.p.
C, 48.23; H, 4.55;
at -2O"C,
5 min by a dichloroethane
122-124X.
C, 45.40; H, 3.81; N, 7.56. e.e.
5 min.
metabisulphite,
solvent the
After
C, 45.48;
31b was obtained
152-154°C. N, 7.03.
Found:
Found:
H,
3.90;
N,
7.55.
N,
7.09.
impure of 31a.
C, 48.43;
H,
4.63;
3884
R. ANNUNZIATA~~ al.
References and Notes.
1. -.M.
Dean,
Advances
in
Heterocyclic
Chemistry,
A.R.
Katrizky
Ed.;
vol.
30,
pp.
167-238; vol. 31, pp. 238-344.
2. iecent examples of intramolecular
Diels-Alder
zhem. Rev., 86, 795, 1986; 0. Craig, D.M. Rossana, 107,
k,
Jenkert, IHenkel,
K.D. Onan,
2573,
1985;
J. Org. M.E.
Chem. Sot. Rev.,
Jung,
V.C.
S.R.
Plettre,
J. Org. Chem.,
Chem.,
Int. Ed. Engl.,
K. Kanematsu,
J. Chem.
Keay, Tetrahedron
Lett.,
5469,
Harwood,
1989;
L.M.
sot., Chem.
Thomas, F.J. Witt, cycloadditions: T.J. Wisnieff,
3428,
True,
28,
Sot.,
G.
Jones,
1990;
J.Chem.
Chem.
1989.
L.L.
Klein,
Lett.,
470,
K.M.
608,
Commun.,
1989;
J. Am.
E. G.
Tatsuta,
K.
Rogers,
G. Jones,
K.
E.J. Walsh, J. Org. Chem., 54, 299, 1989; E. Wenkert,
111,
J. Chem.
Prout,
examples
53, 6154,
B.A.
Sot.,
D. Watkin,
1990. Recent
J. Org. Chem.,
1988;
N. C.
Chem.
P. Metz,
J. Am. Chem.
Thomas,
B. Jackson,
Sternbach,
6059,
Y. Yamaguchi,
J. Gervay,
Pickard,
C.B. Gamlath,
1984;
Commun.,
L.M. Harwood,
Sot.,
H. Harmata,
J.
16, 187, 1987; D.D.
1988; E. Bovenschulte,
202,
Chem.
to furan: B.H. Lipshutz;
Tetrahedron
53, 5850,
1349, 1989; M. E. Jung,
605,
Commun.,
49,
Chem.,
Angew.
Hayakawa,
cycloadditions
1988;
R.M.
of other A.
Padwa,
R. Decorzant,
F.
NBf. Helv. Chim. Acta. 72. 756. 1989.
3. 0.
Tsuge,
K. Ueno, S. Kanemasa,
4. D. Prajapati,
Chemistry
P. Bhuyan, J.S. Sandhu,
Lett., 285, 1984.
J. Chem. Sot., Perkin Trans.
1, 607, 1988.
5. I. Heinze, K. Knoll, R. MUller, W. Eberbach, Chem. Ber., 122, 2147, 1989. 6. A. Hassner,
K.S.K.
Org. Chem.,
7. A.
Murthy,
A. Padwa,
Coda,
Caramella,
P.
Griinanger,
P. Cellerino,
Houk, F. Marinone
A.
Albini,
9. P. Caramella,
10. L. Fisera, J.
J. Kovac, Lesko,
1980; A. Vasella, 11. For other application Franz,
A.M.
Schoffstall,
J-
Tetrahedron
A. Gamba
Leet.,
2911,
P.
Invernizzi,
1966;
P. Griinanger, K.N.
41, 3519, 1985.
Lett.,
743,
1968;
L.
Fisera,
J.
Kovac,
J.
Lesko,
V.
35, 93, 1981.
Damdariva,
R. Voeffray,
J. Lesko,
J.
Kovac,
Bull.
H. Grund,
Chim.
Monatsh.
Coll.
Czecn.
Chem., Chem.
111, 909, Commun.,
1980; 45,
L.
3546,
Helv. Chim. Acta, 65, 1134, 1982.
of C-4 oxygenated
see: V. Jager,
R. Ehrler,
Coda,
J. Poliacikova,
M.
synthesis
Vernesi,
J. Org. Chem., 41, 3349, 1976.
Tetrahedron
Chem. Zvesti,
6.
Corsica
8. V. Jlger, I. MLller, Tetranedron,
Fisera,
D.C. Dean,
54, 5277, 1989.
Corsica
Smahovsky,
U. Chiacchio,
Sot.
isoxazolines, V. Buss,
Belg.,
and reviews
W. Schawb,
92, 1039,
1983;
on their
synthetic
I. Miiller, R. Schohe, V.
Jlger,
R. Franz,
R. W.
3885
Nitrile oxide cycloaddition
Schwab,
B.
Chemistry
Hlfele,
0.
Schrdter,
of Heterocyclic
Cl. Schafer,
Compounds,
W.
J. Kovac
HUmner,
E.
Gunrrum,
and P. Zalupsky
Eds.;
B.
Seidel,
Elsevier
1988,
pp. 58-75. 12. R. Annunziata,
M.
Cinquini,
F.
Cozzi,
L. Raimondi,
Gazz.
Cnim.
Ital.,
119,
257,
1989. 13. R. Annunziata,
F. Cozzi, G. Dondio,
M. Cinquini,
L. Raimondi,
Tetrahedron,
43, 2369,
1987. 14. P.N. Confalone, 6291, Am.
E.D.
Lollar,
1978; P.N. Confalone, Chem.
Tetrahedron,
G. Pizzolato,
M.R.
Uskokovic,
E.D. Lollar Confalone,
Sot.,
102,
1954,
43,
4087,
1987;
1980; H.G.
H.E.
Lee,
Aurich,
J. Am. Chem.
G. Pizzolato, E.G.
K.-D.
100,
M.R. Uskokovic,
Baggiolini,
MUbus,
Sot.,
M.R.
Tetrahedron
2J
Uskokovic,
Lett.,
5755,
1988. 15. D.P. Curran,
in Advances
in Cycloaddition,
JAI Press, vol. 1, pp. 129-189.
16. Part of this section has been preliminarily Cozzi,
L. Raimondi,
Tetrahedron
17. N.D. Ly, M. Schlosser,
R. Lanz,
R. Annunziata,
M. Cinquini,
F.
Lett., 5013, 1989.
Helv. Chim. Acta, 68, 2085, 1977.
18. E. Niwa, H. Aoki, H. Tanaka, Cederlund,
reported:
A.B.
K. Munakata,
M. Namiki,
Yiirnfeldt, 0. Thorstad,
Chem.
Ber.,
K. Undheim,
99, 3215,
Acta
Chem.
1966; B. Stand.
B,
31, 198, 1977. 19. The use of higher concentrations 20. For a review on regiochemistry Padwa,
1,3-Dipolar
led to tne formation of intramolecular
Cycloaddition
Chemistry;
of nitrile
1,3-dipolar
oxide dimers.
cycloadditions
A. Padwa, Ed.; Wiley
see: A.
Interscience,
1984,
vol. 2, pp. 277-406. 21. A.P. Kozikowski, 22. W. Dehaen, 23. During
Y.Y. Chen, Tetrahedron
A. Hassner,
the preparazion
identical
Tetrahedron
Lett., 2081, 1982.
Letc., 743, 1990; and references
of this manuscript,
to one here described
an intramolecular
(25 to 27a,b)
tnerein.
cycloaddition
was published:
A. Hassner,
reaction W. Dehaen,
J. Org. Chem., 55, 5505, 1990.
24. The alternative
procedure
tAgNO
in diethylether)
gave
much
lower
yields
in this
case. 25. We Could
not establish
intrinsic
cycloaddend
thermal
if decomposition
lability
to undergo
occurs at reagent
of a benzyl-type
a retro-Michael
sulphoxide
reaction
or
or cycloadduct the
in the presence
for this observation. 26. W.E. Parham, F.L. Ramp, J. Am. Chem. Sot., 73, 1293, 1951.
level.
possibility
for
The
the
of base can account
R.
27. The minor
isomer 30b showed a
HC-5 of the isoxazoline. 28. Review: and
J. Drabowicz,
Sulphoxides,
Interscience, 29. This could
Patai,
S.
position;
the
mCP8A
the e.e.
presence
Conference
of the
and
The
Chemistry Stirling,
C.J.M.
of
Sulphones
Eds.;
Wiley
15a and 16a have the
of molecular
models
sulphoxide
the equatorial
than the axial one. Moreover occur
on the
equatorial
lone
oxygen
lone pair
the furan pair,
in
oxygen
closer
in
bonding. 0. De Lucchi,
and (+I-16a, (35.3
of optical
of
base.
For
the oxidation
as evaluated and
Tetrahedron
Lett.,
2575,
1989; and
41.5
for
reaction
basic of
22
W. Bastmann
of Organic
improved
5964, 1989; and references
and
(see text) (+I-16a,
therein.
&he
instability, sodium
very
nicely
respectively)
especially
hydroxide
diastereoisomeric
the minor diastereoisomer
and Bioorganic
and K.B. Sharpless,
17, pp. 31-48; F.A. Davis, R. ThimmaReddy,
some
(5% aqueous
by prefereni,ially decomposing
Hoecnst,
1 H NMR
(+I-15a
31 and 32 showed
instance
in Scereochemlscry
by
rotations.
in the text compound
31a,b to 90:10, Kagan,
to
hydrogen
values
by comparison
32. As mentioned
33. H.B.
isomers
6. Licini, G. Modena,
of (+)-15a
agree with
of
irradiation
therein.
31. The e.e.'s
work-up
Rappoport,
accessible
oxydation
space, -via intermolecular 30. F. Di Furia,
M. Mikolajczyk,
by inspection
can
direct
upon
1988, pp. 233-378.
12 seems more
the
Z.
signal
isomer 30a NOE was 4% (DMSO solution).
P. Kielbasinski,
of sulphide
obtained
10% NOE of the methyl
For the major
suggest that the major
an equatorial
references
ANNUNZ~ATA et al.
ratio
of
31b.
Transformations.
Eds.; VCH, Wheinneim,
M.C. Weismiller,
in
solution)
J. Am. Cnem.
Workshop 1987, vol. Sot.,
111,