Food Biochemistry and Food Processing (2 edition)

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656 Part 5: Fruits, Vegetables, and Cereals

ring contains amylose and probably less-ordered amylopectin
(Morrison 1995). The semicrystalline growth ring consists of
alternating crystalline and amorphous lamellae. The crystalline
lamellae are built from amylopectin double helices, whereas
the amorphous lamellae contain the branch points of the amy-
lopectin side chains (Andreev et al. 1999, Gallant et al. 1997).
Evidence has been provided that the crystalline and amorphous
lamellae of the amylopectin are organized into larger, more or
less spherical blocklets (Gallant et al. 1997).
The structure of starch can be studied at different levels by
several techniques such as optical microscopy, scanning elec-
tron microscopy, transmission electron microscopy, and X-ray
diffraction. X-ray diffraction provides information about the
crystal structure of the starch polymers, but also about the rel-
ative amounts of the crystalline and amorphous phases. Cereal
starches have an A-type X-ray diffraction pattern, while B-type
and C-type X-ray diffraction patterns are characteristic for tuber
and root starches and for legume starches, respectively. C-type
starches are considered to be mixtures of A-type and B-type
starches. In general, rye starches show A-type X-ray diffraction
patterns, but some researchers (Gernat et al. 1993, Schierbaum
et al. 1991) also reported a significant B-type portion.

Starch Physicochemical Properties

The physicochemical gelatinization, pasting, gelation, and ret-
rogradation properties of starches are important parameters in
determining the behavior of cereals in food systems.
When a starch suspension is heated above a characteristic
temperature (the gelatinization temperature) in the presence
of a sufficient amount of water, the starch granules undergo
an order-disorder transition known as gelatinization. The phe-
nomenon is accompanied by melting of the crystallites (loss
of X-ray pattern), irreversible swelling of the granules, and
solubilization of the amylose. Gelatinization can be studied
by measuring the loss of birefringence of the starch granules
when observed under polarized light. The end point and the
range of temperatures at which gelatinization occurs can be
determined. For rye starch, birefringence end point tempera-
tures of 59.6◦C (Klassen and Hill 1971) and 58.0◦C(Liiand
Lineback 1977) were reported. These birefringence end point
temperatures were somewhat lower than those observed for
wheat starches by the same authors. Another technique often
used to study gelatinization-associated phenomena is differen-
tial scanning calorimetry (DSC). DSC enables determination of
onset, peak, and conclusion gelatinization temperatures, gela-
tinization temperature ranges, and gelatinization enthalpy. The
gelatinization temperature is a qualitative index of crystal struc-
ture, whereas gelatinization enthalpy is a quantitative measure
of order. The DSC technique also measures the temperature and
enthalpy of the dissociation of the amylose-lipid complexes. Rye
starches show an onset of gelatinization at rather low temper-
atures. Gudmundsson and Eliasson (1991) reported onset gela-
tinization temperatures of 54.8–60.3◦C, Radosta et al. (1992) of
53.5◦C, and Verwimp et al. (2004) of 49.2–51.4◦C. Rye starch
has somewhat lower gelatinization temperatures and enthalpies
than wheat starch (Gudmundsson and Eliasson 1991, Radosta
et al. 1992, Verwimp et al. 2004). Lower dissociation enthalpies

of the amylose-lipid complexes for rye starch than for wheat
starch were observed by Gudmundsson and Eliasson (1991) and
Verwimp et al. (2004), indicating lower levels of lipids in rye
starch.
When starch suspensions are heated beyond their gelatiniza-
tion temperature, granule swelling and amylose and/or amy-
lopectin leaching continue. Eventually, total disruption of the
granules occurs, and a starch paste with viscoelastic properties
is formed. This process is called pasting. Upon cooling, gelation
occurs. During gelation, at sufficiently high starch concentra-
tions (>6%, w/w), the starch paste is converted into a gel. The
gel consists of an amylose matrix enriched with swollen gran-
ules. During gelation and storage of starch gels, retrogradation
occurs. This is a process whereby the starch molecules begin to
reassociate in an ordered structure, without regaining the original
molecular order. Initially, starch retrogradation is dominated by
gelation and crystallization of the amylose molecules. In a longer
time frame, amylopectin molecules recrystallize. Rye starch ex-
hibits a unique, typical swelling behavior with a high pasting
temperature (79–87◦C according to Schierbaum and Kettlitz
1994; 75◦C according to Verwimp et al. 2004), a stable con-
sistency during cooking, and a high viscosity increase during
cooling (Schierbaum and Kettlitz 1994, Verwimp et al. 2004). It
has lower pasting temperatures than wheat starch (Schierbaum
and Kettlitz 1994, Verwimp et al. 2004). Fredriksson et al. (1998)
and Gudmundsson and Eliasson (1991) showed that rye starches
retrograde to a lesser extent than starches from wheat or corn and
ascribed this to differences in the structure of the amylopectin
polymers.

Nonstarch Polysaccharides

Rye contains, on average, 13.0–15.0% nonstarch polysaccha-
rides, which serve mainly as cell wall components and the ma-
jority of which are arabinoxylans (Table 34.1). Other nonstarch
polysaccharide constituents of rye are mixed-linkedβ-glucan,
cellulose, arabinogalactan peptides, and fructans (Table 34.1).
The variation in nonstarch polysaccharide content and compo-
sition is significantly influenced by both harvest year and rye
genotype (Hansen et al. 2003, 2004). Most of the nonstarch
polysaccharides are classified as dietary fiber because of their
resistance to digestion by human digestive enzymes. In view of
the major importance of arabinoxylans in rye, these components
will be further discussed in detail.

Arabinoxylan Occurrence and Structure

Arabinoxylans consist of a backbone of 1,4-linked β-d-
xylopyranose residues, unsubstituted or mono- or disubstituted
with singleα-l-arabinofuranose residues at the O-2- and/or O-
3-position. To some of these arabinose residues, a ferulic acid
moiety is ester bound at the O-5 position. In rye, as in other
cereals, two types of arabinoxylans can be distinguished: water
extractable and water unextractable. Water-unextractable arabi-
noxylans, representing approximately 75% of the total arabi-
noxylan population of the rye kernel, are unextractable because
they are retained in the cell walls by covalent and noncovalent in-
teractions among arabinoxylans and between arabinoxylans and
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