17.1 Introduction
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along with lignin ([C9H10O3(OCH3)0.9−1.7]x), and an insignificant quantity of
proteins, ash, pectin, and other compounds [8]. Studies so far have revealed that cel-
lulose, hemicellulose, and lignin contents account to 30–60%, 20–40%, and 15–25%
of dry weight of LCB, respectively [9]. Cellulose is the major structural subunit of
LCB. It is a linear polysaccharide with β-(1, 4)-glycosidic bonds linking individual
subunits of D-glucose [10]. It is soluble in water when the pH is drastically low or
high but easily miscible with N-methylmorpholine-N-oxide (NMMO) as well as
ionic liquids (ILs) [11]. Cellulose is biocompatible, structurally stable, hydrophilic,
possesses reactive hydroxyl group which makes it suitable for the manufacture of
fibers, films, composites, fuels, and high value chemicals [12]. Hemicellulose is the
second constituent of LCB, composed of various polysaccharides, some of which
include arabinoxylan, galactomannan, glucomannan, glucuronoxylan, xylan, and
xyloglucan. These polysaccharides are present in the form of short chains, linked
by β-(1,4)- or β-(1,3) glycosidic bonds [13]. Cellulose and hemicellulose exhibit
decreased levels of polymerization and are non-crystalline in nature; therefore,
they can easily degrade to monosaccharides and are considered commercially
important [14]. Lignin acts as a protecting barrier by covalently bonding to other
subunits of LCB which enhances its recalcitrance. The complex three-dimensional
structure shows cross-linked polymers of phenyl propane that are bound to each
other by carbon–carbon (5–5, β–β) and aryl-ether bonds (β-O-4, α-O-4). The poly-
mers are known to be altered when the methoxyl groups located on the aromatic
rings are substituted. For example, the three key units of lignin are guaiacyl (G),
p-hydroxyphenyl (H), and syringyl (S) [15].
17.1.4
Challenges in Bioethanol Production from LCB
Ethanol which is derived from LCB is one of the most preferred fuel candidates in
the present world. Not only this, but also biomass obtained from ethanol can act as
a precursor to the different materials that are currently obtained from sources that
are unsustainable. But, the drawback of this novel concept is that the treatment cost
for ethanol is higher which hinders the process to be commercially replicable and
profitable. Several technologies are coming up to give rise to high product yields
with overall low cost [1]. Bioethanol is one of the renewable sources along with
eco-friendly characteristics which is a promising alternative to fossil fuels. Although
practically ethanol is created from edible sources, LCB has attracted a lot of attention
lately. In any case, the transformation efficiency of the biomass varies enormously
concerning the origin furthermore, nature of LCB, essentially because of the variety
in lignocellulosic composition. The two polysaccharides in LCB, cellulose and hemi-
cellulose, are firmly connected to lignin and make a lignocellulosic network that is
exceptionally vigorous and difficult to depolymerize. To introduce LCBs into com-
mercial ethanol creation, ongoing exploration endeavors have been dedicated to the
techno-monetary upgrades of the general change process [2].
The main objective of the book chapter is to study the potential role of different
microorganisms and efficiency in enhancing bioethanol production from LCB as a
substrate.