An Unprecedented, Tandem Aldol-Grob Reaction Sequence

Full text of DOI:10.1021/jo981274w

6438
J . Org. Chem. 1998, 63, 6438-6439
Sch em e 1
An Un p r eced en ted , Ta n d em Ald ol-Gr ob
Rea ction Sequ en ce
George W. Kabalka,* David Tejedor, Nan-Sheng Li,
Rama R. Malladi, and Sarah Trotman
Departments of Chemistry and Radiology, The University of
Tennessee, Knoxville, Tennessee 37996-1600
Received J uly 1, 1998
Aldol chemistry has been extensively investigated since
the self-condensation of acetone was reported by Kane in
1838.¹ The initial product of the aldol condensation is a
â-hydroxy carbonyl compound, which is often transformed
into the corresponding R,â-unsaturated derivative² or a 1,3-
diol.³ All these products have proven to be valuable inter-
mediates in the syntheses of a wide variety of natural
products.⁴ Although many acids and bases can be utilized,
new boron reagents have been developed for use in mixed
aldol condensations because of their ability to efficiently
control the stereochemistry of the reactions.⁵ During the
course of an investigation involving the stereoselective
synthesis of 1,3-diols starting from â-hydroxy ketones,⁶ we
discovered an unprecedented boron trifluoride-initiated
cleavage reaction that resulted in the formation of (E)-1-
arylalkenes and carboxylic acids (eq 1).⁷ Since â-hydroxy
Readily available and inexpensive starting materials are
utilized, and the reaction conditions should tolerate a variety
of functional groups. The reaction may also be viewed as a
new route to carboxylic acids as well as a new method for
cleaving ketones. The overall sequence is rather remarkable
since the reaction conditions appear to be ideal for a
straightforward dehydration resulting in the formation of
R,â-unsaturated ketones. Apparently, the combination of a
powerful Lewis acid and a nonnucleophilic solvent are keys
to this unexpected behavior and, ultimately, to the success
of the reaction.
Although a detailed study of the reaction mechanism has
not yet been completed, the consistent formation of (E)-
alkene products,^9,10 as well as the fact that aromatic alde-
hydes appear to be required, would point toward the
intermediacy of a carbocation derivative. Hydrogen and
carbon NMR analyses reveal the expected olefinic and
carboxylic acid resonances prior to hydrolysis. A reasonable
mechanism would involve the formation of the mixed aldol
followed by the formation and subsequent nonsynchronous
ring opening of a lactol as shown in Scheme 1. The proposed
fragmentation is reminiscent of two-step Grob¹¹ fragmenta-
tions that have been reported for N-halo-R-amino acids¹² and
cyclobutane hemiacetals¹³ as well as the acid-catalyzed
fragmentation of â-hydroxy acetals.^14,15 Grob fragmenta-
tions have been reported in numerous syntheses including
the preparation of medium-sized carbocycles,¹⁶ hormones,¹⁷
pharmaceuticals,¹⁸ and carbohydrates.¹⁹
ketones are often prepared via acid-catalyzed aldol reactions,
we reasoned that the reaction sequence would be more syn-
thetically useful if it could be carried out in a tandem fashion
starting from aromatic aldehydes and appropriate ketones.
We wish to report an unprecedented, tandem Aldol-Grob
sequence involving the reaction of ketones with aromatic
aldehydes in nonnucleophilic solvents in the presence of
boron trifluoride. The reaction affords the corresponding
(E)-1-arylalkene (eq 2) and provides a versatile one-pot alter-
native to the Wittig, Heck, Peterson, and related syntheses.⁸
We examined the effect of various acids on the reaction
sequence in order to ascertain which would be most efficient.
The results are summarized in Table 1, and they reveal that
the formation of the alkene product is common to all the
acids examined. However, the rates of product formation
vary rather dramatically. Interestingly, p-toluenesulfonic
acid monohydrate was the only acid that afforded the aldol
product in moderate yields. We conclude that boron tri-
fluoride is the most effective of the acids studied in achieving
the new tandem condensation-cleavage sequence.
* To whom correspondence should be addressed. E-mail: Kabalka@utk.edu.
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(c) Nielsen, A. T.; Houlihan, W. J . Organic Reactions 1968, 16.
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Lett. 1997, 38, 761.
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New York, 1996.
(9) Control experiments reveal that (Z)-1-phenyl-1-alkenes do not isomer-
ize to the corresponding (E)-isomers under the reaction conditions.
(10) Isomeric mixtures of syn- and anti-â-aryl-â-hydroxy ketones consis-
tently yield (E)-alkenes.
(11) Grob, C. A. Angew. Chem., Int. Ed. Eng. 1969, 8, 535.
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(7) Presented in part at the 216th National Meeting of the American
Chemical Society, Boston, MA, August 23-27, 1998; ORGN #210.
S0022-3263(98)01274-2 CCC: $15.00 © 1998 American Chemical Society
Published on Web 08/28/1998

Communications
J . Org. Chem., Vol. 63, No. 19, 1998 6439
Ta ble 1. Rea ction of 5-Non a n on e a n d
2-Ch lor oben za ld eh yd e in th e P r esen ce of Va r iou s Acid s^a
Ta ble 3. Rea ction of Ald eh yd e 1 w ith Keton e 2 in th e
P r esen ce of BF 3^a
entry
acid^c
alkene^b (%)
aldol products^d (%)
aldehyde,
product (3),^b yield
X ), R )
entry
X )
ketone
T (h)
(%) (E/Z)^c
1
BF₃
74
trace
2^e
3^e
4^e
5^e
6^e
7
BCl₃
BBr₃
AlCl₃
TiCl₄
ZnCl₂
p-tolyl-SO₃H‚H₂O
CF₃CO₂H
C₇F₁₅CO₂H
trace
trace
30
0
0
0
0
1
2
3
4
5
6
H
BuCOBu
BuCOBu
BuCOBu
BuCOBu
MeCOBu 2.5
PhCOBu
1
4
2.5
2.5
H, Pr
78
91
66
89
52
50
97:3
98:2
98:2
95:5
98:2
96:4
o-Cl
p-CH₃
m-Cl
m-Cl
o-Cl
o-Cl, Pr
p-CH₃, Pr
m-Cl,Pr
m-Cl,Pr
o-Cl, Pr
9
trace
32
<5
trace
0
60
trace
<5
4
8^e
9^e
a
b
Reactions were carried out in hexane at reflux. All products
exhibited physical and spectral characteristics in accord with
literature values. ^c Isomer ratios were determined by integration
of nonoverlapping signals in the ¹H NMR spectrum.
a
Reaction carried out in refluxing CCl₄ for 2 h using 10% excess
b
2-chlorobenzaldehyde. Isolated yields of (E)-1-(2-chlorophenyl)-
1-pentene. ^c Excess BF₃ bubbled into reaction mixture (entry 1).
d
Three equivalents of acid utilized (entries 2-9). R,â-Unsaturated
Several features of this reaction make it synthetically
useful: (1) The starting materials are readily available and
inexpensive. (2) The reaction is stereoselective and the
yields of (E)-alkenes are very good. (3) Moderate reaction
temperatures and nonnucleophilic solvents are effective. (4)
The reactions are relatively rapid. (5) The initial results
indicate that methylene groups react more efficiently than
methyl groups, which permits the use of readily available
methyl ketones. (6) The reaction may provide a useful
alternative to the Baeyer-Villiger,²⁰ Wittig, Heck, Peterson,
and related reactions.
ketone. ^e GC/MS analysis revealed unreacted starting material
remaining.
Ta ble 2. Rea ction of 5-Non a n on e w ith
3-Ch lor oben za ld eh yd e in Va r iou s Solven ts^a
entry
solvent
time^b (h)
T (°C)
yield^c (%)
1
2
3
4
5
ether
hexane
CCl₄
CH₂Cl₂
toluene
12
2.5
6
3
4
rt
0
89
91
75
84
68-70
76-77
40
110
a
Reactions were carried out using 30% molar excess of alde-
The synthesis of (E)-1-phenyl-1-pentene is representa-
tive: a small excess of BF₃ was bubbled into a solution of
5-nonanone (4.26 mmol) in hexane (10 mL). The reaction
flask was flushed with nitrogen to remove excess BF₃.
Benzaldehyde (5.54 mmol) was then added to the reaction
mixture and the solution heated to reflux for 1 h. The
reaction was quenched with distilled water (10 mL), the
product extracted into ether (3 × 10 mL), and the combined
ether layers dried over anhydrous MgSO₄. The solvent was
removed under reduced pressure and the product isolated
by flash chromatography (silica gel using hexanes as the
eluant) to yield 0.49 g (78%) of (E)-1-phenyl-1-pentene.
hyde. Reaction time required to obtain optimum yield. ^c Isolated
yields of (E)-1-(3-chlorophenyl)-1-pentene.
b
We then examined the reaction of 5-nonanone with
3-chlorobenzaldehyde in the presence of boron trifluoride in
various solvents. The results are summarized in Table 2.
The most significant observation is that a nonnucleophilic
solvent is required for the reaction to take place. A donor
solvent such as ethyl ether completely inhibits the formation
of product. Apparently, the Lewis acidity of boron trifluoride
is moderated sufficiently by complexation to ethyl ether such
that it is ineffective as an aldol catalyst. In fact, in ethyl
ether, 5-nonanone and 3-chlorobenzaldehyde were recovered
unchanged after 12 h. The yield of (E)-1-(3-chlorophenyl)-
1-pentene was significantly lower in CH₂Cl₂ than in the
other nonnucleophilic solvents studied. It is possible that
the polar nature of CH₂Cl₂ enhances the polymerization of
the styrene product under the reaction conditions. The use
of hexane, CCl₄, and toluene leads to excellent results. The
only appreciable difference in these solvents is an enhanced
reaction rate when hexane is used. For safety and economic
reasons, we conclude that hexane is the ideal solvent for the
reaction. Representative reactions are summarized in Table
3.
Ack n ow led gm en t. We wish to thank the Department
of Energy and the Robert H. Cole Foundation for their
support of this research. We wish to thank Professor Scott
Denmark for his insightful comments.
Su p p or tin g In for m a tion Ava ila ble: Compound character-
ization (6 pages).
J O981274W
(20) As a representative example, 84% of pentanoic acid was isolated
from the reaction of 5-nonanone and benzaldehyde in the presence of BF₃.