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Chapter 1: Introduction
Heterocyclic or carbocyclic rings are common scaffolds found in the natural products and
bioactive molecules. Due to the importance of these bioactive molecules, organic chemists
are involved in development of efficient, economical and short routes for their synthesis from
ancient time. In this context, strained molecules like cyclopropanes, epoxides, aziridines and
1,3-dipolar species like azomethine ylides are used as synthetic precursor for synthesis of
heterocyclic or carbocyclic moieties. In this chapter, structure, bonding, reactivity, and some
selected examples of cyclopropane, epoxide, and aziridine are explained in detail. The effect
of substituents, Lewis acids, temperature, and solvents on mode of activation of these
synthons is also highlighted in their respective part.
Chapter 2: [3+2]-Annulation of Epoxide with Donor-Acceptor Cyclopropane
Ring cleavage and mode of rearrangement of epoxide
Epoxides are one of the most common synthetic equivalents in organic synthesis. Due to its
easy handling, widespread preparation methods and predictable reactivity epoxides are
frequently used in development of new methodologies for synthesis of natural products and
bioactive molecules. Generally, it undergoes strain-induced and/or Lewis acid promoted
selective C-O bond cleavage to give ring open intermediate (IM). Due to availability of lone
pair of electrons on oxygen atom, IM has tendency to undergo rearrangement into new
synthetic equivalent (Scheme 1). In presence of Lewis acid IM undergo Meinwald
rearrangement i.e. hydride shift (route A, Scheme 1) and silicon assisted thermal
rearrangement of epoxide into silyl enol ether i.e. Brook-type rearrangement (route B,
Scheme 1) depending upon the reaction conditions. These types of rearrangements of
epoxide entirely depend upon presence of substituents in it and applied reaction conditions.
These extra advantages of epoxides further enhanced their utility in organic synthesis in
greater extent for construction of pharmacologically and biologically active molecules.
Meinwald rearrangement is most common in epoxide and it readily takes place in presence
of Lewis acids in reaction medium. In this rearrangement 1,2-hydride shift takes place with the help of captodative effect of lone pair of electrons of oxygen atom in IM. Brook et al. has
reported another type of rearrangement in thermal condition. This Brook-type rearrangement
of epoxide via route B demands silicon assistance (Scheme 1). Silicon stabilized the β-
carbocation (intermediate, IM) generated after C-O bond cleavage and also facilitated the
rearrangement to produce silyl enol ether. In our investigations, we have developed a
reaction conditions for Lewis acid control enolization of epoxide into enolate via
deprotonation pathway (route C, Scheme 1). Section A contains a new synthetic approach for
synthesis of tetrahydrofuran from [3+2]-cycloaddition reaction of epoxide with donoracceptor
cyclopropane through Meinwald rearrangement. Furthermore, possible application
of newly synthesized THF and asymmetric transformation of the titled methodology also
presented. In section B, a new synthetic approach for enolization of epoxide and its
implementation for synthesis of cyclopentane via [3+2]-annulation with donor-acceptor
cyclopropane is documented. The plausible mechanism for this transformation is also
proposed.
Section A: Lewis Acid Catalyzed Tandem Meinwald Rearrangement/Intermolecular
[3+2]-cycloaddition of Epoxides with Donor-Acceptor Cyclopropanes: Synthesis of
Functionalized Tetrahydrofurans Tetrahydrofuran ring system is an important heterocyclic constituent in many bioactive
natural products. Particularly, cis-2,5-disubstituted tetrahydrofurans are found in lignans,
polyether antibiotics, fragrances (1), antibacterial terpenes (2) and Sclerophytin A (3) with
potency against mouse leukemia cells (cytotoxic at 1 ng/mL versus L1210 cell line) (Figure
1). Several methods have been explored for synthesis of terahydrofuran (THF). Specially,
cis-2,5-disubstituted tetrahydrofurans have attracted organic chemists for their synthesis due
to importance in bioactive molecules.
In this section, we have demonstrated a methodology for synthesis of varieties of cis-2,5-
disubstituted tetrahydrofurans. In this context, epoxides are used as aldehyde reservoir due to
its Lewis acid promoted Meinwald rearrangement and intimated to cycloaddition reaction
with donor-acceptor cyclopropane under same Lewis acids catalyzed reaction condition. This
method involved [3+2]-cycloaddition reaction of donor-acceptor cyclopropanes (DACs, 4)
and epoxides (5) for synthesis of cis-2,5-tetrahydrofuran (6) (Scheme 2). This methodology
is optimized with varieties of Lewis acids, solvents and also by temperature variation. It was
observed that transformation worked well with InCl3 in dichloroethane at 60 °C. In this
method, temperature and solvents played vital role. It was noticed that reactants decomposed
at higher temperature and yield of product reduced at lower temperature. However,
decomposition of reactants was slowed down at lower temperature.
Scope and limitation of this methodology is also studied by varying substrates with respect
to both epoxides and DACs. Electron rich aryl substituent in both epoxides and DACs
favored good yield of the product. While yield of product was decrease when partially
electron poor substrates were employed and progress of THF generation was completely
ceased with electron poor substrates. Possible scope and limitation for asymmetric transformation of this tandem cyclization was also manifested with the help of InCl3-PyBOX
catalytic system (7). Section B: Substituent and Lewis Acid Promoted Dual Behavior of Epoxides towards
[3+2]-Annulation with Donor–Acceptor Cyclopropane: Synthesis of Functionalized
Cyclopentane and Tetrahydrofuran
In this section, a new route for epoxide rearrangement into enolate depending upon the use
of varieties of Lewis acids in reaction medium and presence of substituents at geminal
position of epoxide (8) is disclosed. This in situ generated enolate trapped with varieties of
DACs (9) to produce cyclopentane derivatives (10). However, tetrahydrofuran (11) formation
is also observed as a side product of the reaction (Scheme 3). In some cases only
cyclopentane derivatives was observed and in some cases tetrahydrofuran was detected.
These observations depend upon substituent present in epoxides and Lewis acids present in
reaction medium. Lewis acids like MgI2, Yb(OTf)3, Sn(OTf)2, and TiCl4 were found
effective catalysts for cyclopentane synthesis. However, BF3.OEt2, Sc(OTf)3, AlCl3, SnCl4
and GaCl3 gave both cyclopentane and tetrahydrofuran. BF3.OEt2 was found good catalysts
for substrate variations as maximum amount of yield of the product was achieved with it.
Therefore, deprotonation and hydride shift were found to be competitive with each other
depending upon reaction conditions. Temperature also played important role for product. Scheme 3. Cycloaddition reaction of DAC (9) with in situ generated enol and aldehyde from
epoxide formation and reaction worked well at room temperature.
The newly synthesized cyclopentanes (12) and tetrahydrofuran (15) further converted into
more demanding cyclopentanone (13), cyclopentene (14), and trisubstituted tetrahydrofuran
(16) (Scheme 4). Chapter 3: One-pot Synthesis of Oxazolidine Derivatives via [3+2]-Cycloaddition
Reaction of 1-Tosyl-2-phenyl/alkylaziridines with Epoxides
Oxazolidines are important heterocyclic compounds and found as core structure in several
natural products like opioid receptors, an antinociceptive SYK-146 (12), alkaloid
Densiflorine (13), antitumor antibiotic Quinocarine (14) (Figure-2). Application of
oxazolidine derivatives as chiral auxiliaries in asymmetric synthesis or as chiral ligands for transition metal catalysis further enhances their importance in large extent.
In this chapter, one-pot synthesis of functionalized oxazolidine is described. In this context,
aziridine (17) and epoxide (18) were taken as reactants and employed under Lewis acid
catalyzed reaction condition. Due to strain in epoxide and aziridine ring opening became
more facile under the given reaction condition and produced oxazolidine (19, 20) in excellent
yield. In this transformation, epoxide underwent Meinwald rearrangement followed by [3+2]-
cycloaddition reaction with aziridine (Scheme 5). BF3.OEt2 was found efficient catalyst for
the reaction and worked well with all types of substrate employed in this study. Both electron
rich and electron poor epoxides react efficiently with aziridine under BF3.OEt2 reaction
conditions. However, reaction time is increased and yield of product decreased when 1-alkylN-tosylaziridine
was subjected in reaction with epoxide. Chapter 4: Synthesis of Functionalized Dispiro-oxindoles through [3+3]-
Cyclodimerization of Azomethine Ylide and Mechanistic Studies to Explain their
Diastereoslectivity
In continuation of our interest in synthesis of heterocyclic scaffolds, we further attempted
to synthesize pharmacologically active piperazine derivatives9 and polycyclic fused dispirooxindole
derivatives (23, 24). In this regard, a method of generation of azomethine ylide
from condensation of isatin (21) and proline (22) is taken in consideration. The synthetic
method proceeded in absence of dipolarophile due to its possibility of dimerization. In this
chapter, optimization of reaction conditions, and substituent effects on in situ generated
AMY dimerization is disclosed (Scheme 7). In this transformation, two diastereomers of the
product viz, trans and cis are formed in quantitative yield, although trans was found as
major. It is reported that trans isomer has anti-tuberculosis activity that escalated the importance of this methodology. Reaction underwent efficiently in polar solvent like
methanol:dioxane (1:1) and reaction time was reduced (1 h) in compare to non polar solvent
like toluene (4 h). Effect of substituent at nitrogen atom of isatin on dimerization of AMY is
also studied. Steric hindrance and electron withdrawing character of substituent completely
alter the dimerization of AMY. For better understanding of the this transformation,
computational method (Density Functional Theory; DFT) is applied and found that
substituent present at nitrogen atom of isatin changed activation energy (Ea) of the reaction
in greater extent. Scheme 7. Dimerization of azomethine ylide |
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