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NMR spectroscopy of starch systems
Accepted Manuscript NMR spectroscopy of starch systems Fan Zhu PII:
S0268-005X(16)30555-0
DOI:
10.1016/j.foodhyd.2016.10.015
Reference:
FOOHYD 3633
To appear in:
Food Hydrocolloids
Received Date: 26 June 2016 Revised Date:
4 October 2016
Accepted Date: 7 October 2016
Please cite this article as: Zhu, F., NMR spectroscopy of starch systems, Food Hydrocolloids (2016), doi: 10.1016/j.foodhyd.2016.10.015. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
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NMR spectroscopy of starch systems
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Fan Zhu*
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School of Chemical Sciences, University of Auckland, Private Bag 92019, Auckland, New
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Zealand
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* Correspondence, e-mail: [email protected]
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Running title: starch NMR
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Abstract
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NMR spectroscopy is used to study the structure and composition of diverse food materials
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including starch, which is utilised in food and other industries. NMR spectroscopy has been
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used to investigate the properties of various starch systems. These include chemical
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composition, physical and chemical structures, gelatinization, retrogradation, enzyme
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hydrolysis, and modifications of starches from diverse botanical origins. The interactions of
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starch with other food components in complex systems have also been studied by NMR
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spectroscopy. Both solid and liquid state NMR techniques have been used, including 1H
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NMR, 13C NMR, 31P NMR, and 17O NMR. These techniques can be non-destructive, and
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provide novel insights into the structure of starch systems. NMR spectroscopy is
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complementary to other analytical techniques such as X-ray diffraction and calorimetry for
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the characterization of simple and complex starch systems.
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Keywords: NMR spectroscopy; starch; structure; property; modification; interaction
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1. Introduction NMR (nuclear magnetic resonance) spectroscopy has been widely used for the analysis of
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food materials such as dairy products, fats and oils, and wine and beverages (Spyros & Dais,
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2012). The first use of NMR in food science was in the 1950s when the moisture of foods
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was measured by low resolution NMR. The applications of NMR for food characterisation
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have become widespread in the 1980s. NMR spectroscopy is a major analytical tool of food
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science in recent years (Spyros & Dais, 2012; Marcone et al., 2013). This is due to the
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development of user-friendly instrumentation, the need of effective analytical methods for
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quality control and food authentication, and the increasing demand from food industry to
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innovate the processes and products (Spyros & Dais, 2012; Marcone et al., 2013).
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NMR phenomena have the origins within the nucleus of certain atom types such as C and P.
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The individual atoms have a net “nuclear” spin. The effects can be noted in a magnetic field,
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involving the energy exchange between two levels at least (resonance) (Gidley, 2014). For
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one sample, different nuclei, such as 1H, 13C, 31P, can be chosen to study different aspects of
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the samples and to extract the relevant information under the natural/industrial conditions
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(Laws et al., 2002; Spyros & Dais, 2012). Some NMR experiments need no separation of
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diverse food components, and require relatively a small amount of efforts for sample pre-
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treatment and preparation as compared with traditional methods (Spyros & Dais, 2012). The
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food samples can be lipid, semi-solid, and solid. The obtained complex NMR spectra can be
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further treated with multivariate statistical analysis to gain additional structural information
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of food systems (Flanagan et al., 2015).
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Starch is a major component of our diet. It is also an important industrial ingredient for
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various food and non-food applications. The two types of starch molecules are the amylose
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(linear and smaller) and the amylopectin (branched and larger). Starch molecules are simply
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ACCEPTED MANUSCRIPT consisted of glucose units linked by α-(1-4) linkages and branched by α-(1-6) linkages (Pérez
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& Bertoft, 2010). The molecules are naturally assembled in the form of semi-crystalline
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granules with sizes ranging from ~1 to 100 µm (Pérez & Bertoft, 2010). Understanding the
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structural changes of starch during various processing (e.g., retrogradation and modification)
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would be critical for better uses of starch in various scenarios. Different methods have been
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used for starch structural characterisation. An advantage of NMR over other techniques such
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as wide-angle X-ray diffraction (XRD) (an abbreviation list of instruments used is presented
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in supplementary Table 1) is that the other components such as lipids, polyphenols, and
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protein do not interfere with the starch spectra (Flanagan et al., 2015).
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Numerous publications have well documented the background and principles of NMR
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spectroscopy (Laws et al., 2002; Spyros & Dais, 2012; Gidley, 2014). The theoretical
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principles of starch NMR has also been detailed (Gidley, 2014). The basics of starch structure
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and functional properties have been systematically reviewed in detail (BeMiller & Whistler,
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2009; Pérez & Bertoft, 2010). Therefore, the basics of NMR spectroscopy and starch are not
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covered in the review. This review focuses on the applications of NMR-based techniques for
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structural characterization of various starch systems. These include the chemical composition,
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molecular order, interactions, gelatinization, retrogradation, and modifications. Due to the
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large amount of literature published, representative references have been selected to cover
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specific topics.
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2. Chemical composition
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Chemical compositional parameters, including the contents of amylose and phosphorus-
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containing compounds in starch, have been measured by different NMR techniques (Table 1).
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Compared with the traditional methods for compositional analysis, NMR-based methods can
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ACCEPTED MANUSCRIPT be more efficient and time-saving (Tabata & Hizukuri, 1971). The anomeric protons
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involving in the α-(1,4) and α-(1,6) linkages give rise to different signals in the 1H NMR
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spectra. Based on this principle, Dunn and Krueger (1999) analysed the amylose contents of
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starches from various botanical sources using 1H NMR. The results of amylose contents
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(ranging from 12−76%) agreed well with those measured by the iodine affinity-
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spectrophotometry-based method. 31P NMR has been used to characterize the nature and
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composition of phosphorus-containing compounds in starch (Muhrbeck & Tellier, 1991; Lim
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et al., 1994; Genkina & Kurkovskaya, 2013; Kasemsuwan & Jane, 1996). DMSO was used to
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increase the solubility of starch α-dextrins for better quantification. Phosphate monoester,
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inorganic phosphate, and phospholipids of starch in DMSO solution were resolved and
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quantified (Kasemsuwan & Jane, 1996). The position and degree of phosphorylation on
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starch chains can be determined (Muhrbeck & Tellier, 1991). The normal cereal starches
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mostly possess phospholipids. The legume and potato starches mostly contain phosphate
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monoesters. And the tuber and root starches are free of phospholipids. Phosphate monoesters
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of all starches were mostly found on the C-6 than on the C-3 of the glucose unit (Lim et al.,
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1994). Phosphorylation on the C-3 position was independent of potato variety, while that on
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the C-6 position was found variety-dependent (Muhrbeck & Tellier, 1991). Schmieder et al.
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(2013) employed a combination of heteronuclear 1H, 13C double, 1H, 13C, 31P triple NMR
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techniques, and successfully determined the phosphorylation sites of both the starch and
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glycogen in heterogeneous samples. A full assignment of the resonances of carbohydrates
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was archived by analysing a set of reference compounds.
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3. Structural characterization
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3.1. Impact of hydration extent
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ACCEPTED MANUSCRIPT The 13C CP/MAS NMR spectrum is very sensitive to the hydration of starch (Veregin et al.,
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1986; Cheetham & Tao, 1998b; Paris et al., 1999) (supplementary material Fig. 1). The
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increasing moisture content of starch increased the peak sharpness to various degrees,
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depending on the polymorph type and starch composition (Paris et al., 1999; Cheetham &
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Tao, 1998b) (supplementary material Fig. 1). The increasing peak resolution was attributed to
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the increased mobility of the amorphous regions in the starch granules. The masking effects
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of resonances from the amorphous region are lost (Morgan et al., 1995). Therefore, the
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moisture content of the systems should be calibrated for the correct estimation of starch
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structure.
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3.2.Starch physical structure
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Solid state 13C CP/MAS NMR has been used to quantify the molecular order of granular
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starch (Flanagan et al., 2015; Man et al., 2013) (Table 2). Each carbon of the glycosyl unit in
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starch is assigned for specific peak in the spectrum (supplementary material Fig. 2). 13C
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CP/MAS NMR spectra of A-type starches differs from those of B-type starches in some
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detail. The peak of C-1 with chemical shift of ~100 ppm is a triplet for A-type starches, and a
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doublet for B-type starches (Veregin et al., 1986). This difference is readily attributed to the
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specific arrangement of the crystals in the granules (Gidley & Bociek, 1985). The spectrum
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of the native starch was compared with that of the amorphous starch. The contents of the
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double and single helices as well as the amorphous material in the granules can be quantified,
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and the degree of crystallinity can be calculated (supplementary material Fig. 2) (Gidley &
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Bociek, 1985; Flanagan et al., 2015). For example, Man et al. (2013) quantified the molecular
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order of starches from rice mutants deficient in SBE I (SBE represents starch branching
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enzyme) and SBE IIb genes. The mutation decreased the degree of crystallinity, the
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proportion of double helix, while increasing the proportion of single helix. Therefore, the
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solid state 13C CP/MAS NMR technique can readily provide information on the physical
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partial least squares model to rapidly quantify the amount of ordered double helices directly
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from the 13C CP/MAS NMR spectrum of starch. This approach removes the procedures of
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curve fitting and does not need any amorphous standard, while giving accurate results.
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Amorphous starch has been characterised by various NMR techniques (Kalichevsky et al.,
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1992; Paris et al., 2001a and 2001b). Spectral decomposition of C-1 peak of 13C CP/MAS
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NMR spectrum under 1H decoupling revealed five types of α-(1-4) linkages in starch (Paris et
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al., 2001a and 2001b). The glass transition temperatures of amorphous waxy maize starches
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varying in moisture contents have been measured by pulsed (through rigid lattice limit) and
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solid state 13C CP/MAS NMR (Kalichevsky et al., 1992) (supplementary material Fig. 3).
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The water plasticizing effect (10 and 22% water content) generally followed the Couchman-
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Karasz equation, which is commonly used for predicting the glass transition temperatures of
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random copolymers and amorphous mixtures. The comparison between different methods
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[DSC (differential scanning calorimetry) vs NMR] in measuring the starch glass transition is
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discussed in a following section (section 9: correlations between NMR and other analytical
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techniques).
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The degree of branching (DB) of starch has been studied by 1H NMR based on the anomeric
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protons involved in α-(l-4) and α-(l-6) linkages (Gidley, 1985; Nilsson et al., 1996; Dunn &
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Krueger, 1999; Tizzotti et al., 2011; Syahariza et al., 2013). D2O was commonly employed as
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the solvent for the DB quantification (Gidley, 1985). For example, DB of potato amylose and
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maize amylopectin were 1 and 4.77%, respectively (Nilsson et al., 1996). DB of starches
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from 14 rice genotypes ranged from 2.7−3.6% (Syahariza et al., 2013). DB of both intact and
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degraded starches can be measured by 1H NMR (Gidley, 1985). Tizzotti et al. (2011)
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employed dimethyl-d6 sulfoxide with the addition of a small amount of deuterated
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trifluoroacetic acid (TFA) as the starch solvent. This resulted in a well-defined and clear 1H
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NMR spectrum with improved quantification efficiency. DB by NMR analysis showed a
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good correlation with that by a traditional method which is discussed in a following section
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(section 9: correlations between NMR and other analytical techniques).
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3.3.Structure of amylose crystals The physical structure of the amylose crystals was studied by 13C CP/MAS NMR (Horii et al.,
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1987; Paris et al., 1999). A-type and B-type amylose crystals had different patterns of NMR
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spectra (supplementary material Fig. 4). Increasing water content increased the peak
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resolution. The C-1 peak was a triplet for the crystals with A-type polymorph and a doublet
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for the B-type samples. Therefore, the native starch and amylose crystals share similar C-1
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peak pattern of NMR spectrum regarding the polymorphism. Compared with native starch,
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the amylose crystals had NMR spectra with much sharper peaks due to the much increased
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degree of crystallinity (Horii et al., 1987).
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The water mobility in starch has been studied by 17O and 2H NMR (Richardson et al., 1987),
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and 2H and 1H NMR (Li et al., 1998; Baianu et al., 1999). Three types of water were proposed
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for potato starch. The first type was related to the anisotropically bound water. The second
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type was related to the trapped water, and the third one was from the average between free
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and weakly bound water populations (Richardson et al.. 1987; Baianu et al., 1999). Li et al.
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(1998) studied the molecular mobility of “freezable” and “unfreezable” water in waxy maize
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starch by 1H NMR coupled with DSC analysis. Decreasing the temperature decreased the
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proportion of the mobile water. Much of the water (>50% of water present) remained highly
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immobile when the starch was in a glassy, solid, semi-crystalline state. This suggests that the
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glassy state of starch may not be employed to predict the molecular mobility of water in
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relation to food stability (Li et al., 1998).
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3.5.V-type amylose inclusion complexes Amylose can form the V-type inclusion complexes with small guest molecules both in the
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solution and in solid states (Pérez & Bertoft, 2010). Jane et al. (1985) analysed the structure
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of V-type complexes formed in solution by 13C NMR. The downfield shifts induced by
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complexing agents such as iodine were larger for the signals of C-1 and C-4 than those of C-2,
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C-3, and C-6. This suggests the formation of V-type complexes in the solution. The physical
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structure of V-type complexes with different guest molecules and amyloses in solid state has
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been probed mostly by solid state 13C CP/MAS NMR (Table 3) and some NMR spectra are
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shown (supplementary material Fig. 5). Le Bail et al. (2013 & 2015) assigned the peaks of
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different carbons of V-type amylose complexes with specific chemical shifts. The chemical
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shifts of 102.7, 81.4, 74.9, 71.6, 61.3, and 60 ppm were related to C-1, C-4, C-3, C2-C5, and
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C-6, respectively. Gidley & Bociek (1988) linked the chemical shifts of C-1 and C-4 to the
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torsion angles (φ and ψ) of conformation. The chemical shifts of C-1 and C-4 of the amylose
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in both solution and solid states were found to be more susceptible to the induced
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conformational changes as a result of guest molecule inclusion (Jane et al., 1985; Le Bail et
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al., 2005; Gidley & Bociek, 1988). There are differences in the NMR spectra among V6I,
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V6II, V6III, V7, and V8-type amylose complexes due to the differences in the size of helical
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cavity (six-, seven-, and eight-fold helices) and the physical positioning of guest molecules
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(Le Bail et al., 2005; Gidley and Bociek, 1988). For example, the NMR spectra of V6- and
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V7-type inclusion complexes are similar. In comparison, the V8-type complexes with 1-
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naphthol had the downward chemical shifting by 1 ppm for both the C-1 and C-4 peaks
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(Gidley & Bociek, 1988). The un-complexed guest molecules that remained in the samples
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may be detected by NMR. For example, the un-complexed palmitic acids were resolved in
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the complexed palmitic acids was 32.4 ppm (Lebail et al., 2000). The chemical shift (32.4
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C CP/MAS NMR spectrum with the chemical shift of 33.6 ppm, while the chemical shift of
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the fatty acid chains. The structural differences between different types of V-type complexes
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as revealed by 13C CP/MAS NMR can also be reflected by the results from other analytical
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techniques such as DSC and XRD. The NMR method should be employed in combination
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with other techniques (e.g., XRD and DSC) to better understand the nature of V-type
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amylose inclusions complexes.
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Gelatinization and retrogradation are related to starch interactions with water and are
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fundamental for starch applications. Various NMR techniques (13C CP/MAS, time-domain 1H,
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water during these processes (Table 4). The content of double helices in starch granules as
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measured by solid state 13C CP/MAS NMR was positively correlated with the enthalpy
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change of gelatinization (∆H) as measured by DSC (Cooke & Gidley, 1992). Hydration
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properties of potato starch were studied through the CP and SP modes of solid state 13C and
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starch while gelatinization and hydrolysis reduced the immobile fractions of native starch.
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Phosphorus-containing compounds became completely mobile upon gelatinization (Larsen et
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al., 2013). Proton properties were also studied by 1H NMR (Ritota et al., 2008; Rondeau-
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Mouro et al., 2015). Four types of water differing in their mobility were observed in starch-
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water systems during gelatinization (Ritota et al., 2008). Water with the highest mobility was
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related to the bulk of water, while the others were associated with the chemical and diffusive
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exchanges with starch components (Ritota et al., 2008). Rondeau-Mouro et al. (2015)
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employed the time-domain 1H NMR to study the temperature-associated changes of T2
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(spin–spin relaxation time) during starch gelatinization. Two T2 components were due to the
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slow diffusional exchanges between different water layers in starch. The fraction with the
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P MAS NMR (Larsen et al., 2013). As expected, hydration increased the molecular order of
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amylose. Low-resolution NMR measurements (proton NMR) are fast and require no sample
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pre-treatment, while providing useful information of the starch gelatinization process (Ritota
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et al., 2008). Cheetham and Tao (1998a) employed 17O NMR relaxation technique and
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revealed that T2 change was related to the water content and the degree of starch
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gelatinization. Higher contents of amylose and phosphates were related to lower water
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mobility. Upon gelatinization with no/little shearing, the granules are not completely
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dissolved and remain in fragile forms termed the starch ghost (Zhang et al., 2014). The ghost
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structure of gelatinized starch was probed by solid state 13C CP/MAS NMR (Zhang et al.,
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2014). V-type inclusion complexes were found in potato and maize starch ghosts. Upon α-
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amylase hydrolysis, the V-type polymorph became more prominent while a small amount of
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B-type polymorph was recorded in the potato starch ghost. It was suggested that temporary
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entanglements of amylopectin and their size are related to the ghost formation (Zhang et al.,
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2014).
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Starch retrogradation has been studied by 13C CP/MAS and 1H NMR (Gidley, 1989;
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Ambigaipalan et al., 2013; Teo & Seow, 1992; Smits et al., 1998). 13C CP/MAS NMR
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analysis showed that the intensity of C-4 peak decreased during the retrogradation of pulse
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starches, while the content of double helices increased (Ambigaipalan et al., 2013). In
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amylose gel, the B-type polymorph was observed (Gidley, 1989). 1H NMR analysis of the re-
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crystallized starch showed that the rate of decay after radiofrequency pulse was different than
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that of the amorphous starch (Teo & Seow, 1992). This could be due to the water release
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from the hydrated starch chains during re-crystallization. Smits et al. (1998) analysed the
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retrogradation of starch stored below and above the glass transition temperature (Tg). T1
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relaxation time decreased before increasing when the storage temperature was above Tg,
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while it increased before levelling off when the storage temperature was below Tg. In the
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the recrystallization of starch, respectively. In the latter case, the increase was mostly due to
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the decrease in free volume (Smits et al., 1998). Kulik and Haverkamp (1997) employed one-
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and two-dimensional exchange solid-state NMR for the analysis of waxy maize starch
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retrogradation. Slow motions with the correlation time of tens of milliseconds were detected.
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Starch retrogradation occurred over a wide range of correlation times. 5. Enzyme susceptibility and resistant starch
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The structural changes of maize starches varying in amylose content during enzyme
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hydrolysis and processing were followed by solid state 13C CP/MAS NMR spectroscopy
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(Htoon et al., 2009; Shrestha et al., 2012). Hydrolysis by artificial saliva α-amylase had little
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effect on the contents of double and single helices as well as the non-ordered proportion of
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maize starches (Shrestha et al., 2012). Enzyme hydrolysis of the thermally-processed maize
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starches with high amylose contents (>50%) increased the contents of double helices while
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decreasing the proportion of amorphous starch (Htoon et al., 2009). The molecular structure
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of resistant starch after enzyme hydrolysis was characterised by various NMR techniques
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(Colquhoun et al., 1995). Relaxation and solid state 13C CP/MAS NMR tests showed that the
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amylose gel had a double helical (rigid) fraction and a mobile amorphous fraction. Upon
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hydrolysis by porcine pancreatic α-amylase, the mobile fraction was removed and the gel
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became rigid and fully ordered (Colquhoun et al., 1995). The gels of amylomaize V,
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amylomaize VII, and wheat starches after enzyme hydrolysis contained 60−70% of double
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helical structure as revealed by solid state 13C CP/MAS NMR. Structurally-defected B-type
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double helical aggregates were reported in the cooled gels.
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6. Modifications
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6.1.Physical modifications
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C CP/MAS and 1H NMR techniques have been used to probe the structural changes of
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starches upon different physical treatments including high pressure, melt-process and
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ultrasound, and microwave (Table 5). These processes gelatinized starch and increased the
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content of amorphous material in the systems (Deng et al., 2014; Guo et al., 2015; Lima &
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Andrade, 2010; Fan et al., 2013a and 2013b). High pressure had no effect on the chemical
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shifts of carbon resonance peaks, while decreasing the relative crystallinity of starch. Pressure
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treatment up to 600 MPa increased the proportion of the amorphous regions of starch, while
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having no effect on the polymorph type (Deng et al., 2014; Guo et al., 2015). Rapid heating
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in oil bath and microwave heating had similar effects in increasing the content of amorphous
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material and decreasing that of the double helices (Fan et al., 2013a and 2013b). 1H NMR
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analysis showed that rapid conventional heating gave a lower water mobility of starch system
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than did the microwave heating (Fan et al., 2013a and 2013b). Sonicated and melt-processed
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high amylose maize starch had similar spectra, and the ultrasound better de-aggregated the
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starch (Lima and Andrade, 2010).
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6.2.Chemical modifications
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The structural changes of various starches hydrolysed by acid and alkaline solutions were
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followed by 13C CP/MAS NMR (Table 5). The acid treatment reduced the content of
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amorphous starch while increasing that of double helix and degree of crystallinity
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(Atichokudomchai et al., 2004; Cai et al., 2014a). Wang and Copeland (2012) showed that
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the alkali hydrolysis had no effect on the chemical shifts of various carbon peaks of pea
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starch spectrum while broadening the resonance peak of C-2–C-5 sites. The content of double
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helix decreased due to the alkali hydrolysis of the amorphous regions of the granules. Alkali
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treatment had no effect on the NMR spectra of rice starches differing in amylose contents (24
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and 58%) (Cai et al., 2014b).
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The position and level of substitution in starch (e.g., acetylated, phosphorylated,
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hydroxylpropylated, octenyl succinic anhydride (OSA)-modified) have been determined by
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degree of branching of starch (Tizzotti et al., 2011). For the measurement, the starch was
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either intact or in the forms of limit dextrins from enzyme hydrolysis (de Graaf et al., 1995;
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Xu & Seib, 1997; Zhao et al., 2015). For example, Xu and Seib (1997) determined the
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hydroxypropyl (HP) levels of modified maize, wheat, and cassava starches based on the
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intensity of HP methyl signal in comparison with that of the methine and methylene (HCO)
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multiplet. The position of hydroxypropylation was determined from the anomeric proton
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signals of the spectrum of α-limit dextrins (Xu & Seib, 1997). Tizzotti et al. (2011) dissolved
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starch samples in dimethyl-d6 sulfoxide with deuterated trifluoroacetic acid (TFA) addition,
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and analysed the degree of substitution of octenyl succinic anhydride (OSA)-modified
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starches by 1H-NMR. The starch degradation by TFA had no effect on the detection. This
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method gave an improved spectrum resolution and accuracy of quantification (Tizzotti et al.,
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2011). The introduction of new functional groups has been verified by 13C CP/MAS, 13C, and
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OSA-modified soluble maize starch. The modified starch had the extra peaks at 0.8−3.0 ppm
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and a shoulder at 5.56 ppm in the 1H NMR spectrum due to the OSA group. The intensity of
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these peaks increased with the increasing degree of substitution. Changes were also observed
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in the 13C spectrum. C-1 signal of the internal glucosyl units of the modified starch became
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broader. A shoulder peak of C-4 was observed. These suggest that the substitution occurred at
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the O-2 and O-3 positions (Ye et al., 2014). Chauhan et al. (2015) analysed the potato starch
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by both 1H and 13C NMR. Thiolated starch had an additional peak at 2.1 ppm (SH group) and
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another peak between 3 and 4 ppm (–CH2 in the –OC–CH2SH). The extra signals of CH2 at
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3–3.5 ppm and of CH3 at 1.8–2.5 ppm for the S−ethyl groups were noted for the sulphonium
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H NMR (Table 5). The principles of the determination are similar to that of measuring the
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H NMR analysis. For example, Ye et al. (2014) used both 13C and 1H NMR to analyse the
14
ACCEPTED MANUSCRIPT structure. Differences in the 13C NMR spectra were observed (Chauhan et al., 2015). New
323
peaks in the range of 175–180 ppm were noted for the thiolated starch. The new peak at ~50
324
ppm was due to the carbon in the chloroacetyl group. These peaks of both 1H and 13C NMR
325
spectra verified the successful sulfur-functionalization of starch (Chauhan et al., 2015). Solid
326
state 13C CP/MAS NMR has been used to verify the successful modification of starch (Rashid
327
et al., 2012; Wei et al., 2008; Geng et al., 2010). Wei et al. (2008) analysed the cationic maize
328
starch by 13C CP/MAS NMR. Compared with the control, extra peaks at around 31 ppm were
329
due to the fragments of methylene of the long cationic chain, indicating the successful
330
production of cationic starch. Geng et al. (2010) analysed the maize starch laurate by 13C
331
CP/MAS NMR. Carbon resonances of the fatty ester chains (10–35 ppm) and that of the ester
332
group (170–175 ppm) were recorded in the spectrum of modified starch. This suggests the
333
successful esterification of starch with the methyl laurate (Geng et al., 2010).
334
Starch was degraded by oxidation and ozone treatment (Salomonsson et al., 1991; Sandhu et
335
al., 2012). Structure of the degraded products was studied by 1H NMR and/or 13C NMR
336
(Salomonsson et al., 1991; Sandhu et al., 2012). In bromine-oxidised potato starch, the level
337
and position of keto and carboxylic groups were determined (Salomonsson et al., 1991). 1H
338
NMR analysis of ozone-treated wheat starch revealed that the β-glucuronic acid group was at
339
the C-1 position and keto group at the C-2 position (Sandhu et al., 2012).
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6.3.Starch-grafted copolymers
341
Starch-grafted copolymers have many applications such as superabsorbent and thermoplastics.
342
Structures of starch-grafted copolymers were probed by solution 1H and 13C NMR as well as
343
solid state 13C CP/MAS NMR (Table 6). For example, Zou et al. (2012) analysed starch-g-
344
polyacrylamide by solution 13C NMR to reveal the grafting positions and ratios on specific
345
carbons (supplementary material Fig. 6). The peaks at 180–190 ppm were related to the
15
ACCEPTED MANUSCRIPT amide carbonyl, and those at 35–50 ppm corresponded to the hybridised carbon atoms (–
347
(CH2–CH)n) units in the copolymers. A new peak at 61.8 ppm was related to the grafting of
348
C-6 (Zou et al., 2012). The intensity ratio of peaks at 63.5 ppm and 61.8 ppm reflected the
349
ratio of C-6 grafting. Yang et al. (2015) verified the grafting of maleic anhydride (MA) and
350
epoxidized cardanol (epicard) onto maize starch by 1H NMR. A new peak at 13 ppm in the
351
spectrum of the starch graft was related to the carboxyl group and the peaks at 6.1–6.6 ppm
352
were of the double bonds. In contrast, the 1H NMR spectrum of the epicard-grafted starch had
353
no peak at 13 ppm, suggesting the interactions of carboxyl groups with the epoxy groups. The
354
peaks at 6.7–7.2 ppm were due to the benzene groups of the epicard. These structural features
355
obtained from the NMR spectra confirmed the successful production of the copolymers.
356
Zhang et al. (2008) analysed the structure of starch-g-poly(sodium acrylate) by solid state 13C
357
CP/MAS NMR. The spectrum of the copolymer was compared with that of the pure starch
358
and poly(sodium acrylate). The spectra shared a similarity with some differences. An extra
359
shoulder of the spectrum was recorded on the C-6 peak, indicating the OH group of C-6 was
360
involved in the grafting process.
361
Physical mixtures of starch and other polymers were also studied by NMR. 1H NMR
362
relaxometry was used to study the starch and poly(lactic acid) (PLA) blend with the
363
incorporation of montmorillonite clay and silica (nanoparticles) (Brito et al., 2015). Proton
364
spin-lattice relaxation time of the blends was between that of starch and PLA, suggesting the
365
interactions and miscibility. Nanoparticle addition increased the relaxation time, suggesting
366
the occurrence of new interactions and the reduced molecular mobility.
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7. Interactions with other components
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In food systems, multiple ingredients co-exist. The interactions of starch with various non-
369
starch components may greatly impact the quality of food products. Some of the starch
370
interactions with various food ingredients have been examined by both 1H and solid state 13C 16
ACCEPTED MANUSCRIPT CP/MAS NMR (Table 7). For example, the interactions of rice starch with tea polyphenols
372
during starch gelatinization were probed by 1H NMR (Wu et al., 2011). The non-covalent
373
interactions were revealed when compared to the 1H spectra of physical mixtures of starch
374
and polyphenols. The altered coupling constants suggest stronger interactions in the samples
375
during gelatinization. Li et al. (2014) analysed the interactions between amylose and metal
376
ion (Cu2+). Compared with the 1H spectrum of amylose in D2O, the presence of Cu2+
377
broadened the carbon peaks (supplementary material Fig. 7). This suggests the binding of
378
Cu2+ ions by the OH groups of starch (Li et al., 2014). Beeren & Hindsgaul (2013) studied
379
the binding interactions between potato amylopectin and HPTS-C16H33 (an amphiphilic
380
molecule) by 1H NMR. Upon binding, the proton signals shifted downfield due to the
381
formation of the helical structure of amylopectin external chains. Some of the resulting
382
products of starch interactions with other components (e.g., protein) in the solid form have
383
been studied by 13C CP/MAS NMR (Pizzoferrato et al., 1998 and 1999; Hu et al., 2013; Luo
384
et al., 2013). For example, Luo et al. (2013) analysed the structure of enzyme-modified
385
starch-zinc complexes. Compared with the control, the C-6 chemical shift of the complexes
386
moved downfield by 0.96 ppm, while the chemical shifts of the other carbons had no change.
387
This suggests that the interactions were mainly on the OH group of C-6 (Luo et al., 2013). Hu
388
et al. (2013) studied the interactions between rice starch and 1-butanol in an HCl solution. In
389
comparison with the control, an extra peak for C-1 at 100.3 ppm was observed in the sample.
390
This suggests the formation of V-type complexes between amylose and butanol. Therefore, it
391
is possible to better study the nature of both the process and resulting products of starch
392
interactions by NMR techniques.
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8. Starch in food and complex systems
394
The structural changes of starch and water in some food systems (bread and film) have been
395
studied by various NMR techniques (Table 8). Primo-Martín et al. (2007) studied the 17
ACCEPTED MANUSCRIPT structural changes of starch in flour, bread crumb, and bread crust by solid state 13C CP/MAS
397
NMR. The triplet of C-1 peak of the starch in flour was lost in the bread due to baking and
398
gelatinization. The increasing intensity of peaks at 82 and 102 ppm suggests an increasing
399
proportion of amorphous region. An upward displacement of the C-1 peak position in the
400
bread crust and crumb suggests the formation of V-type inclusion complexes. Sivam et al.
401
(2013) used 13C CP/MAS NMR to study the starch properties of bread as affected by pectin
402
and polyphenol addition. Polyphenols and pectins decreased the intensity of C-6 peak by
403
35−40%. The reasons remain to be illustrated by employing simple model systems (e.g.,
404
starch-pectin mixture). Mihhalevski et al. (2012) employed various NMR techniques to study
405
the structure and composition of the starches in wheat and rye sourdough breads. 13C NMR
406
spectra of the wheat and rye starches were similar. The 31P NMR spectra of wheat and rye
407
starches were different due to the difference in lipid composition. 13C CP/MAS NMR
408
analysis revealed the differences in the structures of retrograded starches in the breads. Starch
409
retrogradation can be affected by various factors such as starch structure, composition, and
410
the presence of the non-starch components (Hoover, 1995). Bosmans et al. (2012) employed
411
1
412
material Fig. 8). The proton peaks were assigned according to simple model systems. This
413
analysis helped better understand the role of water with different molecular mobility in bread
414
properties. The structure of starch in extruded films was analysed by 13C CP/MAS NMR
415
(Pushpadass et al., 2009). The extrusion process induced the changes in the NMR spectrum.
416
The C1 peak in the spectrum of starch in the film was a duplet (indicating B-type polymorph),
417
while that of the native starch was a triplet (indicating A-type polymorph). This suggests the
418
occurrence of re-crystallization of the gelatinized starch after the extrusion. The applications
419
of NMR spectroscopy in characterising the pharmaceutical tablets of starch have been
420
reviewed (Thérien-Aubin & Zhu, 2009), and thus is not related in the present review.
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ACCEPTED MANUSCRIPT 421
9. Correlations between NMR and other analytical techniques The results of some specific parameters of starch obtained from the NMR analysis were
423
compared with those measured by other techniques (Table 9). The studied aspects of starch
424
included chemical composition, structures of granules and components (e.g., degree of
425
branching), gelatinization and retrogradation, glass transition temperatures, and degree of
426
substitution in modified starch. Kasemsuwan and Jane (1996) analysed the total phosphorus
427
content of different starches by both 31P NMR and colorimetry-based methods. The results of
428
these two methods agreed well. Dunn and Krueger (1999) analysed the amylose contents by
429
1
430
these two assays agreed well with each other. The degree of branching (DB) of various
431
starches were measured by 1H NMR and high-performance size-exclusion chromatography
432
(HPSEC), and was also reflected by the blue value obtained from starch-iodine interaction
433
(Nilsson et al., 1996; Syahariza et al., 2013). Both 1H NMR and HPSEC methods gave
434
similar DB values which were highly correlated with the blue value of starch. The contents of
435
double helices of starch measured by 13C CP/MAS NMR were compared with the degree of
436
crystallinity of starch measured by XRD (Lopez-Rubio et al., 2008; Witt & Gilbert, 2014;
437
Mutungi et al., 2012). Contents of double helices of different types of starches were
438
positively correlated with the degree of crystallinity from the XRD analysis. Lopez-Rubio et
439
al. (2008) noted that the contents of double helices in starch granules are not equal to that of
440
degree of crystallinity as some of the double helices do not crystallize. This discrepancy was
441
also observed when monitoring the structural changes of crystalline parts of starch during
442
acid hydrolysis by two different methods (i.e., NMR and XRD) (Atichokudomchai et al.,
443
2004) (supplementary material Fig. 9). The degree of crystallinity was also correlated with
444
the data from Fourier transform-Raman spectroscopy and gelatinization parameters
445
(temperatures and ∆H) by DSC. The results were highly correlated with the NMR results
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H NMR and also by the iodine-binding spectrophotometry-based assay. The results from
19
ACCEPTED MANUSCRIPT (Witt & Gilbert, 2014; Mutungi et al., 2012; Cooke and Gidley, 1992). Starch retrogradation
447
reflected by 1H NMR was positively correlated with that by the Instron texture analyser
448
(Seow & Teo, 1996). Retrogradation of pulse starches quantified by 13C CP/MAS NMR was
449
compared with that by FTIR–ATR, XRD, DSC, and the enzyme susceptibility of α-amylase
450
(Ambigaipalan et al., 2013). The extents of retrogradation measured by DSC, XRD, and
451
NMR were similar, and those by NMR, FTIR-ATR, and enzyme susceptibility methods were
452
different. The similarity and discrepancy indicate that different methods may reflect different
453
aspects of the retrogradation. Ambigaipalan et al. (2013) suggested that 13C CP/MAS NMR is
454
sensitive to the conformational changes related with amylopectin crystallization while FTIR
455
more reflects the crystallization and re-association of both amylopectin-amylopectin and
456
amylose–amylopectin chains. Therefore, a comprehensive approach employing different
457
instruments should be used to gain a holistic picture of the starch retrogradation. Kalichevsky
458
et al. (1992) studied the glass transition temperature of amorphous starch by pulsed 1H NMR,
459
DSC, Instron texture analyser, and dynamic mechanical thermal analysis (DMTA). The glass
460
transition temperatures of starch measured by NMR were lower than those by DSC and other
461
techniques by 20−30 oC (supplementary material Fig. 3). The NMR technique probes a lower
462
mobility distance scale and determines proton mobility, while DSC and DMTA relate to a
463
transition with an increased mobility for a large proportion of the starch chains (Kalichevsky
464
et al., 1992). The degree of substitution (acetylation and hydroxypropylation) as well as the
465
degree of grafting of starch copolymers were analysed by NMR techniques. The results from
466
NMR analysis were compared with that of wet chemistry-method (e.g., Johnson and titration
467
methods) (de Graaf et al., 1995; Gurruchaga et al., 1992). NMR-based methods (1H and 13C)
468
agreed well with the traditional wet chemistry methods for the modification analyis, while
469
being time-saving.
470
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10. Conclusions 20
ACCEPTED MANUSCRIPT NMR techniques have been used to probe diverse aspects of starch systems. These techniques
472
include liquid state 1H NMR, 13C NMR, 31P NMR, and 17O NMR and solid state 13C CP/MAS
473
NMR. Various aspects/parameters of starch that have been studied by NMR include chemical
474
composition, degree of molecular order, degree of branching, degree of gelatinization and
475
retrogradation, glass transition temperature, physical structure of V-type amylose inclusion
476
complexes, and extents and position of modification. NMR techniques have also been used to
477
characterise starch interactions with various non-starch food components such as polyphenols,
478
proteins, and minerals. The baking and staling processes of bread have been monitored, and
479
the physical structure of starch in edible films has been followed. The structural information
480
obtained from NMR analysis provides a strong basis for better understanding the
481
physicochemical properties of starch and food systems. The composition and molecular
482
structure of starch obtained from NMR analysis correlate well with the results of other
483
techniques such as XRD and wet chemistry-based methods. Compared with traditional
484
methods for starch characterisation, the NMR approach can be simple, efficient, and time-
485
saving, while the solid state NMR method can be non-destructive. Besides NMR, most of the
486
studies also employed some other techniques to characterise starch systems. NMR-based
487
techniques complement the others for a comprehensive understanding of the structural and
488
physicochemical properties of starch. It should be stressed that some structural parameters of
489
starch are sensitive to the nature of the measurement technique. The knowledge obtained
490
from NMR analysis will be of great importance for a better understanding of the starch
491
functionalities and the role of starch in food and non-food applications.
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492 493
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Table captions
2
Table 1 Chemical composition of starch quantified by NMR spectroscopy
3
Table 2 Structural characterisation of starch studied by NMR spectroscopy
4
Table 3 Structure of V-type inclusion complexes revealed by NMR spectroscopy
5
Table 4 Gelatinization and retrogradation processes monitored by NMR spectroscopy
6
Table 5 Structure of modified starches as studied by NMR spectroscopy
7
Table 6 Structure of starch graft copolymers as studied by NMR spectroscopy
8
Table 7 Interactions of starch with non-starch components as monitored by NMR spectroscopy
9
Table 8 NMR characterization of bread and starch films
SC
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Table 9 Correlations between NMR and other analytical techniques in structural characterization of starch systems
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10
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1
1
ACCEPTED MANUSCRIPT
Table 1
Parameter
Starch
NMR type
Major findings
31
Degree of phosphorylation on the C-3 position was independent of potato variety, while that Muhrbeck and
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11
source Potato
P NMR
SC
Degree of phosphorylation on
on C-6 position varied greatly among different genotypes
Phosphate
Various
31
P NMR
M AN U
the C-3 and C-6
Normal cereal starches contained mostly phospholipids. Tuber and root starches were free of phospholipids. Legume and potato starches mostly contained phosphate monoesters.
phosphate,
Phosphate monoesters of all starches were more on the C-6 than on the C-3 of the glucose
phospholipids
units Various
31
P NMR
Potato starch mostly contained phosphate monoester (0.086%). Wheat starch contained
Tellier, 1991
Lim et al., 1994
Kasemsuwan and
EP
Phosphate
TE D
monoester, inorganic sources
Reference
mostly phospholipids (0.058%), high-amylose (50% amylose content) maize starch mostly Jane, 1996
phosphate,
contained phosphate monoesters (0.0049%) and phospholipids (0.015%). Waxy maize
phospholipids
starch had trace amounts of phosphate monoesters
phosphorylation site Curcuma
Heteronuclear
on glucan chains
1
rhizome
AC C
monoester, inorganic sources
A combination of heteronuclear 1H, 13C and 1H, 13C, 31P NMR spectra efficiently
H, 13C double, determined the phosphorylation sites. Monophosphate esters are on the C-3 and C-6
Schmieder et al., 2013 2
ACCEPTED MANUSCRIPT
H NMR
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1
Phosphatidylcholine was mixed with starch in DMSO. Phospholipid content was
Genkina &
determined by 31P NMR with tributyl phosphate as the standard. This method allows the
Kurkovskaya,
quantification of phospholipids without the regards of sample forms
2013
Branching ratios of starch were obtained from 1H NMR. This ratio was then used for the
Dunn and
determination of amylose content
Krueger, 1999
SC
sources
P NMR
M AN U
Various
31
TE D
Amylose content
Wheat
EP
Phospholipids
H,13C, 31P triple positions of the glucose unit
AC C
1
3
ACCEPTED MANUSCRIPT
12
Table 2 NMR type
Major findings
Molecular order
Solid state 13C CP/MAS
13
NMR
starch for the first time
Solid state 13C CP/MAS
13
NMR
starch for the first time. The spectrum was related to the polymorph type Bociek, 1985
SC
Various sources
C NMR spectrum was interpreted in relation to the crystallinity of
C NMR spectrum was interpreted in relation to the crystallinity of
Reference Marchessault & Taylor, 1985 Gidley &
M AN U
Molecular order
Maize, potato
RI PT
Targeted structure Starch source
of starch
Rice
Solid state 13C CP/MAS
13
NMR
triplet for A-type polymorph starches, and a doublet for B-type starches 1986 The relative degree of crystallinity (37.2−58.9%), relative proportion of Man et al., 2013
NMR
single helices (1−7.9%), double helices (39.6−61.8%), and amorphous
Various sources
AC C
Molecular order
C NMR spectrum was related to the starch polymorph. C-1 peak was a Veregin et al.,
Solid state 13C CP/MAS
EP
Molecular order
Various sources
TE D
Molecular order
(37.2−52.5%) material were quantified. Deficiency of starch branching enzymes I and IIb decreased degree of crystallinity, portion of double helices, and increased the portion of single helices of starch
Solid state 13C CP/MAS
A partial least squares model was produced to rapidly quantify the
Flanagan et al.,
NMR
ordered structure in starch granules from the NMR spectrum
2015 4
ACCEPTED MANUSCRIPT
Waxy maize
temperature
Pulsed NMR, 13C CP/MAS Pulsed NMR and 13C CP/MAS NMR successfully characterised the
Kalichevsky et
NMR
al., 1992
glass transition of amorphous starch with water contents of 10−22%
RI PT
Glass transition
Potato starch, amylose,
13
C CP/MAS NMR, 1H/13C Five types of α(1–4) linkages were found by decompositions of C1
amorphous starch
amylopectin processed
magnetization transfer and resonance spectrum. Distributions of average glycosidic linkages
2001a and
into amorphous and
2D WISE solid state NMR dihedral angles (ϕ, Ψ) were related to the structures resulted from the
2001b
Branching ratio
Various sources
processing 1
Paris et al.,
M AN U
semi-crystalline status
SC
Structure of
H NMR, 13C NMR
Ratios of α(1–4) to α(1–6) linkages of native and degraded starches were Gidley, 1985 determined by 1H NMR and ranged from 17.5 to 26. Glucose and the
1
H NMR
average unit chain length Maize starches varying in 1H NMR
AC C
Branching ratio
amylose content, potato, rice, pea, cassava, wheat Branching ratio
Maize, rice
EP
Branching ratio and Various sources
TE D
reducing residues of larger glucans can be differentiated by 13C NMR
1
H NMR
DB ranged from 1 (potato amylose) to 4.77% (maize amylopectin).
Nilsson et al.,
Average unit chain length (CL) ranged from 21 (maize amylopectin) to
1996
100 glucosyl residues (potato amylose) Ratios of α(1–4) to α(1–6) linkages were determined by 1H NMR. Maize Dunn and starches had the ratios ranging from 21.7 to 83.9%
Krueger, 1999
NMR was used to efficiently determine the degree of branching (DB) of Tizzotti et al.,
5
ACCEPTED MANUSCRIPT
2011; Syahariza
from 2.7−3.6%
et al., 2013
RI PT
maize starch as 3.34%. DB of rice starches from 14 genotypes ranged
DB of whole starch molecules is defined as the percentage of α(1–6) glycosidic linkages (branching points) to the total of α-(1–4) and α-(1–6)
14
glycosidic linkages
SC
13
M AN U
15 16
AC C
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17
6
ACCEPTED MANUSCRIPT
Table 3
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18
Targeted feature
Amylose type
Complexing agent
NMR type
Major findings
References
Formation of
Potato
DMSO, KOH, iodine,
13
Soluble V-type inclusion complexes in solution were
Jane et al., 1985
C NMR
α-naphthol, methyl
characterised. Increasing concentration of complexing agents
inclusion complexes in
alcohol, tert-butyl
induced downfield shift of the signals of C-1 and C-4 (larger shift)
solution
alcohol, n-butyl
M AN U
SC
amylose/amylodextrin
and C-2, C-3, and C-6 (smaller shift). The differences in the shifts
alcohol, cyclohexanol
for C-1 and C-4 indicate the differences in the compactness of the helical structure Gidley and
hexanoic acid, tert-butyl CP/MAS
not affected by the type of complexing agents. V8-type complex
Bociek, 1988
complexes
alcohol, n-butanol, 1-
with 1-naphthol had chemical shifts of C-1 and C-4 peaks
NMR spectra of solid V- Synthetic type amylose inclusion complexes, A- and B-
amylose
AC C
naphthol
TE D
amylose
Ethanol
C
NMR
EP
type amylose inclusion
13
NMR spectra of V6 and V7-type complexes are similar, and are
NMR spectra of solid V- Potato, synthetic Sodium palmitate,
downward by 1 ppm (supplementary material Fig. 5)
13
A triplet C-1 peak for the A-type crystalline form and a doublet C- Horii et al.,
CP/MAS
1 peak for B-type crystals were recorded (supplementary material 1987
NMR, 13C
Fig. 4). Spectrum of V-type amylose is rather different from that of
C
7
ACCEPTED MANUSCRIPT
spin-lattice A- and B-type in that the C-4 line is separated from C-2, C-3, and relaxation
C-5 atoms. 13C T1 values of the crystalline components of
RI PT
type amylose crystals
amyloses are shorter than that of cellulose (suggesting more mobility) Stearic, palmitic, oleic,
13
Chemical shift of the mid-chain methylenes had a change by ~2−3 Snape et al.,
type amylose inclusion
linoleic, linolenic, and
CP/MAS
ppm, suggesting the complexation process. The mid-chain
complexes
docosahexaenoic acids, NMR
1998
M AN U
C
SC
NMR spectra of solid V- Potato
methylenes of lipids in the V-type complexes had the same chemical shifts, except for docosahexaenoic acid. Analysis of
glycerol monooleate,
cross-polarisation dynamics showed that the bulky polar groups
TE D
glycerol monopalmitate, lysophosphatidylcholine
situated outside the V-helical segments and was adjacent to the amorphous regions
Menthone, decanal, 1-
13
Differences in NMR spectra were observed among V6I, V6II,
type amylose inclusion
naphthol, 1-butanol
CP/MAS
V6III, and V8-type amylose complexes. Rehydration increased the 2005
NMR
sharpness of carbon resonance peak, and desorption induced the
AC C
complexes
EP
NMR spectra of solid V- Potato
C
Le Bail et al.,
transition from V6II to V6I-type
8
ACCEPTED MANUSCRIPT
amylose, pea
complexes
13
A single resonance peak at 32.4 ppm was assigned to the
Lebail et al.,
CP/MAS
complexed fatty acids. The uncomplexed palmitic acid was also
2000
NMR,
detected in the samples with a chemical shift of 33.6 ppm. T1
deuterium
relaxation tests revealed a difference between the uncomplexed
NMR
and complexed fatty acids (by 1.1−1.2 s). Temperature-dependent
C
RI PT
type amylose inclusion
Palmitic, lauric acids
SC
NMR spectra of solid V- Synthetic
M AN U
deuterium NMR analysis revealed partially disassociated complexes of amylose-palmitic acid and a full complexation for the amylose–lauric acid
Decanoic acid,
type amylose inclusion
bean (Vicia
carvacrol
complexes
faba), pea,
C
Peaks of 102.7, 81.4, 74.9, 71.6, and 61.3 ppm were related to C1, Le Bail et al.,
C4, C3, C2-C5, and C6, respectively, and these were of V6I form. 2013
NMR
High pressure treatment induced the formation of V-type
EP
CP/MAS
complexes at a low temperature (40 oC)
AC C
tapioca
13
TE D
NMR spectra of solid V- Potato, broad
9
ACCEPTED MANUSCRIPT
NMR spectra of solid V- Potato
3-O-palmitoyl
13
Spectrum had peaks with chemical shifts of 102.7, 81.4, 74.9,
Le-Bail et al.,
type amylose inclusion
chlorogenic acid
CP/MAS
71.6, 61.3, and 60 ppm, and they were related to C1, C4, C3, C2-
2015
NMR
C5, and C6 carbons, respectively. Only the grafted part (palmitoyl
complexes
RI PT
C
moiety) was included in the helical cavity, and the formation of the
type amylose inclusion
13
Phosphatidylcholine
C
potato
complexes
In comparison with the physical mixture of phosphatidylcholine
M AN U
NMR spectra of solid V- Debranched
SC
V-type complexes depended on the graft position
CP/MAS
and debranched maize starch, C-4 peak at 86.46 ppm was better
NMR
separated from the combined C-2, C-3, C-5 peak by 1 ppm.
Cheng et al., 2015
EP
result of inclusion complex formation
AC C
19
TE D
Chemical shifts of C1- and C-4 peaks moved up by 1−1.5 ppm as a
10
ACCEPTED MANUSCRIPT
20
Table 4 NMR type
Major findings
Wheat, maize,
13
The enthalpy change of gelatinisation measured by DSC mostly reflects the loss of molecular (double-
Cooke and
cassava, potato
NMR
helical) order which is measured by solid state NMR
Gidley, 1992
Maize starches
17
17
varying in amylose
relaxation
RI PT
Starch source
O NMR
O spin-spin relaxation time (T2) measurements were used to monitor the starch gelatinization as
affected by various factors. The changes in T2 were related to the degree of gelatinization and water
Cheetham and Tao, 1998a
content. Higher contents of amylose and phosphates were related to lower water mobility. KI decreased
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content
M AN U
C CP/MAS
SC
Gelatinization
Reference
the water mobility during gelatinization 1
H NMR
Four water populations were observed in starch-water systems. One of them was related to the bulk of
EP
Rice
water, while the others were related to the chemical and diffusive exchanges of water with starch
Ritota et al., 2008
AC C
components. The solid-to-liquid ratios from single–pulse experiment followed the water uptake of starch during swelling and gelatinisation processes Potato, wheat, maize
13
C and 31P solid CP and SP modes of 13C and 31P solid state MAS NMR were combined to probe the hydration properties Larsen et al.,
state MAS NMR of potato starch in native, gelatinized, and enzyme-modified status. Hydration increased the molecular
2013
11
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order. Gelatinization and enzyme treatments (branching enzyme and/or β-amylase) reduced the immobile
RI PT
fractions of starch. Carbons of the α(1–4) linkages needed high hydration rates for uniform chemical shifts. Immobile phosphorus-containing chains were only found in the suspension of native starch 13
The structure of starch ghosts after gelatinization was probed. V-type amylose helices were present in
Zhang et al.,
NMR
maize and potato starch ghosts before enzyme digestion. After α-amylase hydrolysis, a small amount of
2014
C CP/MAS
SC
Potato, maize
M AN U
B-type polymorph was observed in potato starch ghost, while the V-type structure became more obvious in maize starch ghost
Time-domain 1H Fraction of the shortest T2 relaxation time was related to the nonexchangeable protons in CH of both
Rondeau-Mouro
NMR
et al., 2015
amylopectin and amylose. Two T2 components were due to slow diffusional exchanges between different water layers
Retrogradation
Amylose gel structure was studied. B-type polymorph was observed from the gel of diluted amylose
and 1H NMR
solution. Gel from concentrated amylose solution (10%) contained rigid B-type double helices and more
C CP/MAS
EP
13
Gidley, 1989
AC C
Synthetic, potato
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Wheat
mobile amorphous single chains
12
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Various sources
Pulsed 1H NMR Pulsed 1H NMR was used to monitor the retrogradation of starch. Proton signals from re-crystallized
RI PT
starch had a different rate of decay after radiofrequency pulse as compared with that of the amorphous
Teo and Seow, 1992
starch. NMR-based technique is simple, non-destructive, and has little requirement of sample size
Slow motions with correlation time of tens of milliseconds were detected by stimulated echo and two-
dimensional
dimensional exchange NMR. Retrogradation occurs over a wide range of correlation times
SC
One- and two-
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Waxy maize
exchange Solid state NMR Potato
13
C CP/MAS
Kulik and Haverkamp, 1997
The retrogradation of starch was monitored below and above the glass transition temperature (Tg). Below Smits et al.,
TE D
NMR, 1H NMR Tg, the relaxation time of 1H NMR increased due to the decreasing free volume before reaching a plateau. 1998 Above Tg, water absorption decreased the relaxation time before an increase due to recrystallization. 13C
13
The retrogradation of starches from various pulses (faba bean, black bean, pinto bean). Intensity of C-4
NMR
peak decreased during retrogradation, while the content of double helices increased
C CP/MAS
AC C
Pulse starches
EP
CP/MAS NMR was not an efficient technique for retrogradation detection Ambigaipalan et al., 2013
13
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Table 5
Modification
Starch
NMR type
Rice, lotus
13
seed
NMR
Uses
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21
Physical
C CP/MAS The structural changes of rice starch as affected by high pressure treatment were followed by 13C Deng et al., 2014;
SC
High pressure
References
CP/MAS NMR. 600 MPa increased the proportion of amorphous material of starch, and had no
Guo et al., 2015
M AN U
effect on the polymorph type. High pressure had no effect on the chemical shifts of various carbon peaks, while decreasing the relative crystallinity High-amylose 1H NMR
Starch was melt-processed (100 oC, 40 rpm, 8 min) and ultrasonicated (750 W, 20 kHz) in the
and ultrasound
maize starch
presence of glycerol. 1H NMR spectra of sonicated and melt-processed samples were similar. 1H Andrade, 2010
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Melt-processing
Lima and
NMR analysis indicated the de-aggregating of starch induced by ultrasound 13
C CP/MAS Microwave heating increased the proportion of amorphous material and decreased that of both
Fan et al., 2013a
EP
Rice
NMR, 1H
single and double helices. The effect of rapid heating in oil bath was similar to that of microwave and 2013b
NMR
heating. Water mobility of starch-water system was also monitored by 1H NMR. Water mobility
AC C
Microwave
of samples subjected to rapid conventional heating was lower and that of microwave heating was higher Chemical 14
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Lotus
13
rhizome,
NMR
C CP/MAS Acid hydrolysis increased the double helix content and decreased the amorphous portion of starch. Atichokudomchai The relative crystallinity increased sharply during the initial hydrolysis before levelling off
RI PT
Acid hydrolysis
cassava 13
C CP/MAS Alkali hydrolysis had no effect on chemical shifts, broadened the resonance peak of C-2–C-5
NMR Alkali hydrolysis
Rice
sites, and decreased the content of double helices from 35 to 30%
SC
Pea
13
NMR
and 58%)
1
Molar substitution of modified starches was quantified by 1H NMR
hydroxypropylated Hydroxypropylated Maize, wheat, 1H NMR
Copeland, 2012
de Graaf et al., 1995
of α-limit dextrins
cassava Hydroxypropylated Sweet potato
Wang and
Both the level and position of hydroxypropylation of starch were determined by 1H NMR analysis Xu and Seib, 1997
EP
H NMR
31
P, 1H NMR Molar substitution was quantified by 1H NMR, and hydroxypropylation mostly occurred at O-2
AC C
Potato
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Substitution Acetylated,
al., 2014a;
C CP/MAS Alkali hydrolysis had no effect on NMR spectra of rice starches varying in amylose contents (24 Cai et al., 2014b
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Alkali hydrolysis
et al., 2004; Cai et
Zhao et al., 2015
(61%), followed by O-6 (21%) and O-3 (17%) Phosphorylation
Canna edulis
31
P NMR
Starch phosphate monoesters had chemical shifts of 4.076 and 4.564 ppm. Phosphorylation
Zhang and Wang,
occurred at C-2 or C-3, and C-6 positions of starch
2009
15
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Laurate
Maize
Solid state 13C 13C NMR analysis verified the esterification of starch with methyl laurate
Geng et al., 2010
Laurate
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NMR High-amylose 1H NMR
Four extra peaks with chemical shifts of 1, 1.2, 1.4, 2.25 ppm were observed in the NMR
maize
spectrum of starch laurate. The peak intensity of these peaks increased with the increasing degree
Maize
modified Starch sulfide
13
C CP/MAS A carboxyl group with chemical shift at 168 ppm in the NMR spectrum confirmed the formation Rashid et al., 2012
NMR Potato
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C=O–O–SiO2Na
SC
of substitution
Lu et al., 2013
of C=O–O–SiO2Na moieties in starch
13
C, 1H NMR In 1H NMR spectrum, thiolated starch has additional peaks at 2.1 ppm (SH group) and between 3 Chauhan et al., 2015
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and 4 ppm (–CH2 in the –OC–CH2SH group). In 13C NMR spectrum, thiolated starch has new signals between 175–180 ppm. Intense peaks round 30 ppm were noted for CH2 and 17 ppm for
Acylated
Octenyl succinic
1
Degrees of substitution of various acylated starches (phthalate, cinnamate, benzoate, and
Thakore et al.,
nanoparticles
palmiate) were measured by 1H NMR
2013
High amylose 1H NMR
Starch acetate, propionate, and butyrate were produced. Acylation reduced the molecular mobility Lim et al., 2015
maize
of starch (reduced T2). Drying and storage further reduced the molecular mobility
Starch
Maize
1
H NMR
H NMR
AC C
Acylated
EP
CH3 from di-ethylamine
Rapid determination of degree of substitution and degree of branching of the modified starch was Tizzotti et al.,
16
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developed by dissolving starch in dimethyl-d6 sulfoxide with deuterated trifluoroacetic acid
modified
addition
OSA
Rice
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anhydride (OSA)-
13
C, 1H NMR 1H and 13C NMR analysis confirmed the formation of octenyl succinic esters. The esterification
2011
Zhang et al., 2013
occurred at 2-OH, 3-OH, and 6-OH of glucosyl residue with 2-OH being the main substitution
Sugary maize
13
C, 1H NMR Soluble starch from sugary maize was modified by OSA. The modified starch showed additional Ye et al., 2014
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OSA
SC
position
peaks at 0.8−3.0 ppm and a shoulder at 5.56 ppm in 1H NMR spectrum. Modified starch had increased ratio of α(1,6) linkages. OSA modification broadened C-1 peak. A shoulder of C-4 peak
Cross-linking
Sweet potato
31
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at 78.1 ppm was observed. The substitution occurred at the O-2 position P, 1H NMR The position and level of phosphorus in cross-linked starch were determined by NMR.
Zhao et al., 2015
EP
Monostarch monophosphate and distarch monophosphate (molar ratio of ~1:1) were produced from the reaction with sodium trimetaphosphate. Phosphorylation of monostarch monophosphate
Cationization
Maize
13
AC C
occurred at O-3 and O-6 positions. There is 1 cross-link per 2900 glucosyl residues C CP/MAS NMR spectra of three cationic starch derivatives (cationic groups varying in chain length) were
NMR
Wei et al., 2008
similar. Additional peaks near 31 ppm were related to the methylene of the cationic group, confirming the formation of starch ethers
17
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Oxidised starch
Potato
13
C, 1H NMR Positions and contents of the keto and carboxylic groups were determined in oxidised starch. Ring Salomonsson et
Ozone treatment
Wheat
1
H NMR
1
al., 1991
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cleavage occurred between C-2 and C-3 H NMR analysis showed that a keto group formed at C-2 position, and β-glucuronic acid was
formed at C-1 position
2012
AC C
EP
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SC
22
Sandhu et al.,
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23
Starch
Table 6
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24
Graft group
NMR
Use
Various types
Solution 13C NMR
Confirmation of the grafting and measurement of the degree of grafting
Maize
Sodium acrylate
13
C CP/MAS NMR
1
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Maize
SC
type
Reference
Gurruchaga et al., 1992
H relaxation times and solid state 13C CP/MAS NMR spectrum were used to study Zhang et al., 2008
the compatibility of the grafted group and starch as well as the blends of sodium
Maize
Acrylamide
Solution 13C NMR
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acrylate and starch
Graft position and grafted segment length were determined by 13C NMR. Grafting Zou et al., 2012
EP
of acrylamide group mostly occurred at C-6 (supplementary material Fig. 6).
Maize
Lactic acid
13
AC C
Increasing amylose content of starch increased the length of grafted segment C NMR, heteronuclear NMR analysis confirmed the formation of starch-g-lactic acid copolymer
multiple bond coherence
Hu and Tang, 2015
(HMBC)
19
ACCEPTED MANUSCRIPT
Maize
Maleic anhydride,
1
H NMR
1
H NMR analysis confirmed the formation of starch copolymers
1
H and 13C NMR
1
H and 13C NMR analysis confirmed the formation of amylopectin-g-
Yang et al., 2015
n.a.
Acrylamide-co-Nmethylacrylamide
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epoxidized cardanol
poly(acrylamide-co-N-methylacrylamide)
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26 27
32 33
EP
31
AC C
30
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28 29
2015
SC
25
Sasmal et al.,
34 20
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35
Table 7 Reference
Glycerol and
1
H NMR
Native starch granules as affected by glycerol and water were studied by relaxation NMR. The
Cioica et al.,
water
relaxation
presence of glycerol and water increased the molecular mobility of the starch. T2 of starch with
2013
SC
Maize
RI PT
Starch source Other component NMR technique Major observations
water and glycerol had four dynamic components, while that of starch without glycerol had three. T1
Potato and
Protein
Solid state 13C
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distributions were related to the degree of crystallinity of starch Impact of Maillard reactions between starch and amino acid (lysine) on starch structure was
CP/MAS NMR followed by solid state 13C CP/MAS NMR. Intensity of the C1 resonance peak decreased with
chestnut
TE D
increasing lysine concentration. The Maillard reaction due to roasting induced the formation of V-
Pizzoferrato et al., 1998 and 1999
type complexes and reduced the proportion of B-type polymorph in starch zinc
Solid state 13C
Starch modified by α-amylase and glucoamylase was reacted with zinc. The chemical shift of C-6
Luo et al.,
EP
Cassava
AC C
CP/MAS NMR peak of the complexes moved downfield by 0.96 ppm, while that of the other peaks had little change, 2013 as compared with the control. The results suggest that the zinc mostly interacted with OH group of
C-6 of the glucose units
Potato amylose
Metal ion
1
H NMR
The interactions between amylose and Cu2+ broadened the peaks of 1H NMR spectrum of amylose
Li et al.,
(supplementary material Fig. 7). The ratio of signal areas of protons H(2–6) to H(1) decreased upon 2014 21
ACCEPTED MANUSCRIPT
Cu2+ addition. This suggests the binding of Cu2+ with OH groups of amylose
HPTS-C16H33
After 1-butanol-HCl hydrolysis of starch, an additional peak at 100.3 ppm was detected for C1,
NMR
indicating the formation of V-type amylose inclusion complexes
2013
1
Upon binding to amylopectin, the amphiphile of HPTS-C16H33 unfolds, and proton signals of 1H
Beeren &
NMR spectrum shifted downfield
Hindsgaul,
C CP/MAS
H NMR
amylopectin
Rice
Tea polyphenols
1
H NMR
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Potato
13
SC
1-butanol
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rice
Hu et al.,
2013
Starch and tea polyphenols were mixed and gelatinized. Compared with physical mixtures of
Wu et al.,
gelatinized starch and tea polyphenols, the chemical shifts of protons of 1H NMR spectrum of the
2011
TE D
sample were identical. The coupling constants were different, suggesting stronger interactions in the sample than the physical mixture 1
H NMR
Compared with individual component, 1H NMR spectrum of the propofol-hydroxyethyl starch
Silva et al.,
EP
Hydroxyethyl Propofol
complexes had broadened peak at 8.00 ppm and downfield shifts of proton signals of glucose units. 2014
starch
36 37
Table 8
AC C
This suggests the occurrence of the interactions between the hydroxyethyl starch and propofol
22
ACCEPTED MANUSCRIPT
Targeted property
NMR technique Major observations
Bread
Crystallinity of
13
Compared with the spectrum of starch in flour, that of the starch in bread crumb showed a narrowing of Primo-Martín
starch in bread
NMR
the C-1 peak, an upward chemical shift to 102.1 ppm, and the loss of the triplet characteristics. Bread
C CP/MAS
crumb and crust
Reference
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Product
et al., 2007
crust had a similar trend with a peak at 102.3 ppm for rusk rolls and one at 101.9 ppm for crispy rolls.
SC
This indicated the formation of V-type complexes. Increase in peak intensity at 82 and 102 ppm
extent that that of the crust Bread
Water mobility
1
H NMR
The proton mobility of bread crumb and crust was analysed by 1H NMR relaxometry. The assignment
Bosmans et
of proton peaks was made by using starch-water and gluten-water model systems (supplementary
al., 2012
TE D
relaxometry
M AN U
indicated the increasing amounts of amorphous material. Starch of bread crumb gelatinized to a larger
material Fig. 8). This analysis may help better understand the physical changes of bread during
Starch structure and 13C CP/MAS, composition
C, 1H, 31P
Structural changes of starch in rye sourdough and wheat breads during staling were compared by NMR Mihhalevski
13
techniques. 13C NMR spectra of rye and wheat starches are similar. 31P NMR analysis showed that
NMR
phospholipid fraction differed in these two starches. 13C CP/MAS NMR analysis showed that the
AC C
Bread
EP
production and storage
et al., 2012
retrograded rye starch had different polymorph composition than the wheat starch Bread
Starch structure
13
C CP/MAS
Addition of polyphenols and pectins on starch properties in bread was probed by 13C CP/MAS NMR.
Sivam et al.,
23
ACCEPTED MANUSCRIPT
NMR
Polyphenols and pectins decreased the intensity of C-6 peak by 35−40%. V-type complexes and
2013
13
13
NMR
with that of the physical mixture. Difference in C1 peak was observed. C1 peak of extruded films was a al., 2009
C CP/MAS NMR spectrum of extruded maize starch films with glycerol and water was compared
Pushpadass et
SC
duplet, suggesting the existence of B-type polymorph, while that of the physical mixture had A-type
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polymorph
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C CP/MAS
EP
Starch structure
AC C
Film
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amorphous starch existed in the bread
24
ACCEPTED MANUSCRIPT
38
Table 9
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39
Targeted feature
NMR type
Other techniques
Major findings
Various types
Total phosphorus
31
Traditional
Total phosphorus contents of starch measured by 31P NMR agreed with
colorimetric
the results obtained from colorimetric chemical method
content
chemical method Various types
Amylose content
1
H NMR
Iodine-binding
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P NMR
SC
Starch sample
The amylose contents obtained from 1H NMR were comparable to those
spectrophotometry measured by iodine-binding spectrophotometry-based assay
Rice starch
Degree of branching 1H NMR
8 starches from Crystalline region
13
C
& Jane, 1996
Dunn and Krueger, 1999
The unit chain length of starch measured by 1H NMR agreed well with
Nilsson et al.,
value
that by HPSEC. The degree of branching of starch was positively
1996
EP
and unit chain length
Kasemsuwan
HPSEC and blue
AC C
Various sources Degree of branching 1H NMR
TE D
assay
Reference
HPSEC
XRD
correlated with blue value Both methods gave similar DB values (2.7−3.6%) for 14 rice varieties
Syahariza et al., 2013
Contents of double helices are not equal to the degree of crystallinity
Lopez-Rubio et
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ACCEPTED MANUSCRIPT
obtained from XRD analysis, though the results of these two methods are al., 2008
NMR
highly correlated
11 waxy starches Crystalline region
13
from various sources (native
C
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CP/MAS
XRD, DSC
Contents of double helices of both native and annealed starches are
Witt & Gilbert,
CP/MAS
positively correlated with the degree of crystallinity (XRD) and
2014
NMR
gelatinization parameters (DSC)
SC
various sources
Degree of
13
Fourier transform- Samples varying in the degree of crystallinity were produced from
crystallinity
CP/MAS
Raman
debranched cassava starch subjected to hydrothermal processing. Degree 2012
NMR
spectroscopy,
of molecular order by NMR was positively correlated with that derived
C
XRD 13
C
maize, wheat,
CP/MAS
potato, tapioca
NMR
Maize starch, bread, rice cup
Retrogradation
Pulsed 1H NMR
XRD, DSC
EP
Gelatinization
Mutungi et al.,
from XRD and Fourier transform-Raman spectroscopy
AC C
Maize, waxy
TE D
Cassava
M AN U
and annealed)
Molecular (double-helical) order of native starches was higher than
Cooke and
degree of crystallinity measured by XRD. Molecular order is positively
Gidley, 1992
correlated with ∆H (enthalpy change) of gelatinization
Instron texture
The results of starch retrogradation obtained from two methods had a high Seow and Teo,
analyser
and positive correlation
1996
cake
26
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Retrogradation
13
FTIR–ATR, XRD, DSC, XRD, and NMR similarly reflected the extent of retrogradation of
Ambigaipalan
CP/MAS
DSC, enzyme
pulse starches, while NMR, FTIR-ATR, and enzyme susceptibility
et al., 2013
susceptibility (α-
methods had a different pattern
C
RI PT
Pulse starches
amylase)
Cassava
Pulsed H
DSC, Instron
The glass transition temperatures measured by NMR were lower than
temperature
NMR
texture analyser,
those by DSC and other techniques by 20−30 oC (supplementary material al., 1992
DMTA
Fig. 3)
XRD
During initial stage of acid hydrolysis, double helix content from NMR
Atichokudomc
analysis was higher than the degree of crystallinity by XRD analysis.
hai et al., 2004
Degree of
13
C
Kalichevsky et
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crystallinity of acid- CP/MAS hydrolysed starch
SC
Glass transition
M AN U
Waxy maize
NMR
These two values became similar at later stages of hydrolysis
Degree of
1
H NMR
Degree of grafting of copolymers
Degrees of substitution for acetylated and hydroxypropylated starches
spectrophotometry measured by NMR agreed well with those measured from traditional
substitution
Maize
Traditional
13
C NMR
AC C
Potato
EP
(supplementary material Fig. 9) de Graaf et al., 1995
-based method a
methods. 1H-NMR-based method required much less time
Hydrolytic
Degree of grafting of starch measured by a hydrolytic method agreed well Gurruchaga et
Method
with that of the NMR method
al., 1992
27
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HPSEC, High-performance size-exclusion chromatography; XRD, wide-angle X-ray diffraction; DSC, differential scanning calorimetry; FTIR–
41
ATR, Fourier transform infrared spectroscopy-attenuated total reflectance; a, Johnson method and a titration-based method
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40
42
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SC
43
28
ACCEPTED MANUSCRIPT Applications of NMR spectroscopy in starch research are summarized
•
NMR spectroscopy probes structural basis of physical behaviours of starch systems
•
Various types of NMR techniques reveal different aspects of starch structures
•
Results of NMR spectroscopy correlate well with those of other analytical methods
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SC
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•
S0268-005X(16)30555-0
DOI:
10.1016/j.foodhyd.2016.10.015
Reference:
FOOHYD 3633
To appear in:
Food Hydrocolloids
Received Date: 26 June 2016 Revised Date:
4 October 2016
Accepted Date: 7 October 2016
Please cite this article as: Zhu, F., NMR spectroscopy of starch systems, Food Hydrocolloids (2016), doi: 10.1016/j.foodhyd.2016.10.015. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
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ACCEPTED MANUSCRIPT 1 2
3
NMR spectroscopy of starch systems
5
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4
Fan Zhu*
SC
6
School of Chemical Sciences, University of Auckland, Private Bag 92019, Auckland, New
8
Zealand
9
* Correspondence, e-mail: [email protected]
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Running title: starch NMR
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Abstract
16
NMR spectroscopy is used to study the structure and composition of diverse food materials
17
including starch, which is utilised in food and other industries. NMR spectroscopy has been
18
used to investigate the properties of various starch systems. These include chemical
19
composition, physical and chemical structures, gelatinization, retrogradation, enzyme
20
hydrolysis, and modifications of starches from diverse botanical origins. The interactions of
21
starch with other food components in complex systems have also been studied by NMR
22
spectroscopy. Both solid and liquid state NMR techniques have been used, including 1H
23
NMR, 13C NMR, 31P NMR, and 17O NMR. These techniques can be non-destructive, and
24
provide novel insights into the structure of starch systems. NMR spectroscopy is
25
complementary to other analytical techniques such as X-ray diffraction and calorimetry for
26
the characterization of simple and complex starch systems.
27
Keywords: NMR spectroscopy; starch; structure; property; modification; interaction
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1. Introduction NMR (nuclear magnetic resonance) spectroscopy has been widely used for the analysis of
30
food materials such as dairy products, fats and oils, and wine and beverages (Spyros & Dais,
31
2012). The first use of NMR in food science was in the 1950s when the moisture of foods
32
was measured by low resolution NMR. The applications of NMR for food characterisation
33
have become widespread in the 1980s. NMR spectroscopy is a major analytical tool of food
34
science in recent years (Spyros & Dais, 2012; Marcone et al., 2013). This is due to the
35
development of user-friendly instrumentation, the need of effective analytical methods for
36
quality control and food authentication, and the increasing demand from food industry to
37
innovate the processes and products (Spyros & Dais, 2012; Marcone et al., 2013).
38
NMR phenomena have the origins within the nucleus of certain atom types such as C and P.
39
The individual atoms have a net “nuclear” spin. The effects can be noted in a magnetic field,
40
involving the energy exchange between two levels at least (resonance) (Gidley, 2014). For
41
one sample, different nuclei, such as 1H, 13C, 31P, can be chosen to study different aspects of
42
the samples and to extract the relevant information under the natural/industrial conditions
43
(Laws et al., 2002; Spyros & Dais, 2012). Some NMR experiments need no separation of
44
diverse food components, and require relatively a small amount of efforts for sample pre-
45
treatment and preparation as compared with traditional methods (Spyros & Dais, 2012). The
46
food samples can be lipid, semi-solid, and solid. The obtained complex NMR spectra can be
47
further treated with multivariate statistical analysis to gain additional structural information
48
of food systems (Flanagan et al., 2015).
49
Starch is a major component of our diet. It is also an important industrial ingredient for
50
various food and non-food applications. The two types of starch molecules are the amylose
51
(linear and smaller) and the amylopectin (branched and larger). Starch molecules are simply
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53
& Bertoft, 2010). The molecules are naturally assembled in the form of semi-crystalline
54
granules with sizes ranging from ~1 to 100 µm (Pérez & Bertoft, 2010). Understanding the
55
structural changes of starch during various processing (e.g., retrogradation and modification)
56
would be critical for better uses of starch in various scenarios. Different methods have been
57
used for starch structural characterisation. An advantage of NMR over other techniques such
58
as wide-angle X-ray diffraction (XRD) (an abbreviation list of instruments used is presented
59
in supplementary Table 1) is that the other components such as lipids, polyphenols, and
60
protein do not interfere with the starch spectra (Flanagan et al., 2015).
61
Numerous publications have well documented the background and principles of NMR
62
spectroscopy (Laws et al., 2002; Spyros & Dais, 2012; Gidley, 2014). The theoretical
63
principles of starch NMR has also been detailed (Gidley, 2014). The basics of starch structure
64
and functional properties have been systematically reviewed in detail (BeMiller & Whistler,
65
2009; Pérez & Bertoft, 2010). Therefore, the basics of NMR spectroscopy and starch are not
66
covered in the review. This review focuses on the applications of NMR-based techniques for
67
structural characterization of various starch systems. These include the chemical composition,
68
molecular order, interactions, gelatinization, retrogradation, and modifications. Due to the
69
large amount of literature published, representative references have been selected to cover
70
specific topics.
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2. Chemical composition
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Chemical compositional parameters, including the contents of amylose and phosphorus-
74
containing compounds in starch, have been measured by different NMR techniques (Table 1).
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Compared with the traditional methods for compositional analysis, NMR-based methods can
4
ACCEPTED MANUSCRIPT be more efficient and time-saving (Tabata & Hizukuri, 1971). The anomeric protons
77
involving in the α-(1,4) and α-(1,6) linkages give rise to different signals in the 1H NMR
78
spectra. Based on this principle, Dunn and Krueger (1999) analysed the amylose contents of
79
starches from various botanical sources using 1H NMR. The results of amylose contents
80
(ranging from 12−76%) agreed well with those measured by the iodine affinity-
81
spectrophotometry-based method. 31P NMR has been used to characterize the nature and
82
composition of phosphorus-containing compounds in starch (Muhrbeck & Tellier, 1991; Lim
83
et al., 1994; Genkina & Kurkovskaya, 2013; Kasemsuwan & Jane, 1996). DMSO was used to
84
increase the solubility of starch α-dextrins for better quantification. Phosphate monoester,
85
inorganic phosphate, and phospholipids of starch in DMSO solution were resolved and
86
quantified (Kasemsuwan & Jane, 1996). The position and degree of phosphorylation on
87
starch chains can be determined (Muhrbeck & Tellier, 1991). The normal cereal starches
88
mostly possess phospholipids. The legume and potato starches mostly contain phosphate
89
monoesters. And the tuber and root starches are free of phospholipids. Phosphate monoesters
90
of all starches were mostly found on the C-6 than on the C-3 of the glucose unit (Lim et al.,
91
1994). Phosphorylation on the C-3 position was independent of potato variety, while that on
92
the C-6 position was found variety-dependent (Muhrbeck & Tellier, 1991). Schmieder et al.
93
(2013) employed a combination of heteronuclear 1H, 13C double, 1H, 13C, 31P triple NMR
94
techniques, and successfully determined the phosphorylation sites of both the starch and
95
glycogen in heterogeneous samples. A full assignment of the resonances of carbohydrates
96
was archived by analysing a set of reference compounds.
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3. Structural characterization
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3.1. Impact of hydration extent
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101
1986; Cheetham & Tao, 1998b; Paris et al., 1999) (supplementary material Fig. 1). The
102
increasing moisture content of starch increased the peak sharpness to various degrees,
103
depending on the polymorph type and starch composition (Paris et al., 1999; Cheetham &
104
Tao, 1998b) (supplementary material Fig. 1). The increasing peak resolution was attributed to
105
the increased mobility of the amorphous regions in the starch granules. The masking effects
106
of resonances from the amorphous region are lost (Morgan et al., 1995). Therefore, the
107
moisture content of the systems should be calibrated for the correct estimation of starch
108
structure.
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Solid state 13C CP/MAS NMR has been used to quantify the molecular order of granular
111
starch (Flanagan et al., 2015; Man et al., 2013) (Table 2). Each carbon of the glycosyl unit in
112
starch is assigned for specific peak in the spectrum (supplementary material Fig. 2). 13C
113
CP/MAS NMR spectra of A-type starches differs from those of B-type starches in some
114
detail. The peak of C-1 with chemical shift of ~100 ppm is a triplet for A-type starches, and a
115
doublet for B-type starches (Veregin et al., 1986). This difference is readily attributed to the
116
specific arrangement of the crystals in the granules (Gidley & Bociek, 1985). The spectrum
117
of the native starch was compared with that of the amorphous starch. The contents of the
118
double and single helices as well as the amorphous material in the granules can be quantified,
119
and the degree of crystallinity can be calculated (supplementary material Fig. 2) (Gidley &
120
Bociek, 1985; Flanagan et al., 2015). For example, Man et al. (2013) quantified the molecular
121
order of starches from rice mutants deficient in SBE I (SBE represents starch branching
122
enzyme) and SBE IIb genes. The mutation decreased the degree of crystallinity, the
123
proportion of double helix, while increasing the proportion of single helix. Therefore, the
124
solid state 13C CP/MAS NMR technique can readily provide information on the physical
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126
partial least squares model to rapidly quantify the amount of ordered double helices directly
127
from the 13C CP/MAS NMR spectrum of starch. This approach removes the procedures of
128
curve fitting and does not need any amorphous standard, while giving accurate results.
129
Amorphous starch has been characterised by various NMR techniques (Kalichevsky et al.,
130
1992; Paris et al., 2001a and 2001b). Spectral decomposition of C-1 peak of 13C CP/MAS
131
NMR spectrum under 1H decoupling revealed five types of α-(1-4) linkages in starch (Paris et
132
al., 2001a and 2001b). The glass transition temperatures of amorphous waxy maize starches
133
varying in moisture contents have been measured by pulsed (through rigid lattice limit) and
134
solid state 13C CP/MAS NMR (Kalichevsky et al., 1992) (supplementary material Fig. 3).
135
The water plasticizing effect (10 and 22% water content) generally followed the Couchman-
136
Karasz equation, which is commonly used for predicting the glass transition temperatures of
137
random copolymers and amorphous mixtures. The comparison between different methods
138
[DSC (differential scanning calorimetry) vs NMR] in measuring the starch glass transition is
139
discussed in a following section (section 9: correlations between NMR and other analytical
140
techniques).
141
The degree of branching (DB) of starch has been studied by 1H NMR based on the anomeric
142
protons involved in α-(l-4) and α-(l-6) linkages (Gidley, 1985; Nilsson et al., 1996; Dunn &
143
Krueger, 1999; Tizzotti et al., 2011; Syahariza et al., 2013). D2O was commonly employed as
144
the solvent for the DB quantification (Gidley, 1985). For example, DB of potato amylose and
145
maize amylopectin were 1 and 4.77%, respectively (Nilsson et al., 1996). DB of starches
146
from 14 rice genotypes ranged from 2.7−3.6% (Syahariza et al., 2013). DB of both intact and
147
degraded starches can be measured by 1H NMR (Gidley, 1985). Tizzotti et al. (2011)
148
employed dimethyl-d6 sulfoxide with the addition of a small amount of deuterated
149
trifluoroacetic acid (TFA) as the starch solvent. This resulted in a well-defined and clear 1H
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NMR spectrum with improved quantification efficiency. DB by NMR analysis showed a
151
good correlation with that by a traditional method which is discussed in a following section
152
(section 9: correlations between NMR and other analytical techniques).
153
3.3.Structure of amylose crystals The physical structure of the amylose crystals was studied by 13C CP/MAS NMR (Horii et al.,
155
1987; Paris et al., 1999). A-type and B-type amylose crystals had different patterns of NMR
156
spectra (supplementary material Fig. 4). Increasing water content increased the peak
157
resolution. The C-1 peak was a triplet for the crystals with A-type polymorph and a doublet
158
for the B-type samples. Therefore, the native starch and amylose crystals share similar C-1
159
peak pattern of NMR spectrum regarding the polymorphism. Compared with native starch,
160
the amylose crystals had NMR spectra with much sharper peaks due to the much increased
161
degree of crystallinity (Horii et al., 1987).
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The water mobility in starch has been studied by 17O and 2H NMR (Richardson et al., 1987),
164
and 2H and 1H NMR (Li et al., 1998; Baianu et al., 1999). Three types of water were proposed
165
for potato starch. The first type was related to the anisotropically bound water. The second
166
type was related to the trapped water, and the third one was from the average between free
167
and weakly bound water populations (Richardson et al.. 1987; Baianu et al., 1999). Li et al.
168
(1998) studied the molecular mobility of “freezable” and “unfreezable” water in waxy maize
169
starch by 1H NMR coupled with DSC analysis. Decreasing the temperature decreased the
170
proportion of the mobile water. Much of the water (>50% of water present) remained highly
171
immobile when the starch was in a glassy, solid, semi-crystalline state. This suggests that the
172
glassy state of starch may not be employed to predict the molecular mobility of water in
173
relation to food stability (Li et al., 1998).
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3.5.V-type amylose inclusion complexes Amylose can form the V-type inclusion complexes with small guest molecules both in the
176
solution and in solid states (Pérez & Bertoft, 2010). Jane et al. (1985) analysed the structure
177
of V-type complexes formed in solution by 13C NMR. The downfield shifts induced by
178
complexing agents such as iodine were larger for the signals of C-1 and C-4 than those of C-2,
179
C-3, and C-6. This suggests the formation of V-type complexes in the solution. The physical
180
structure of V-type complexes with different guest molecules and amyloses in solid state has
181
been probed mostly by solid state 13C CP/MAS NMR (Table 3) and some NMR spectra are
182
shown (supplementary material Fig. 5). Le Bail et al. (2013 & 2015) assigned the peaks of
183
different carbons of V-type amylose complexes with specific chemical shifts. The chemical
184
shifts of 102.7, 81.4, 74.9, 71.6, 61.3, and 60 ppm were related to C-1, C-4, C-3, C2-C5, and
185
C-6, respectively. Gidley & Bociek (1988) linked the chemical shifts of C-1 and C-4 to the
186
torsion angles (φ and ψ) of conformation. The chemical shifts of C-1 and C-4 of the amylose
187
in both solution and solid states were found to be more susceptible to the induced
188
conformational changes as a result of guest molecule inclusion (Jane et al., 1985; Le Bail et
189
al., 2005; Gidley & Bociek, 1988). There are differences in the NMR spectra among V6I,
190
V6II, V6III, V7, and V8-type amylose complexes due to the differences in the size of helical
191
cavity (six-, seven-, and eight-fold helices) and the physical positioning of guest molecules
192
(Le Bail et al., 2005; Gidley and Bociek, 1988). For example, the NMR spectra of V6- and
193
V7-type inclusion complexes are similar. In comparison, the V8-type complexes with 1-
194
naphthol had the downward chemical shifting by 1 ppm for both the C-1 and C-4 peaks
195
(Gidley & Bociek, 1988). The un-complexed guest molecules that remained in the samples
196
may be detected by NMR. For example, the un-complexed palmitic acids were resolved in
197
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the complexed palmitic acids was 32.4 ppm (Lebail et al., 2000). The chemical shift (32.4
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C CP/MAS NMR spectrum with the chemical shift of 33.6 ppm, while the chemical shift of
9
ACCEPTED MANUSCRIPT ppm) of the complexes indicated the existence of both trans and gauche conformations for
200
the fatty acid chains. The structural differences between different types of V-type complexes
201
as revealed by 13C CP/MAS NMR can also be reflected by the results from other analytical
202
techniques such as DSC and XRD. The NMR method should be employed in combination
203
with other techniques (e.g., XRD and DSC) to better understand the nature of V-type
204
amylose inclusions complexes.
205
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4. Gelatinization and retrogradation
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Gelatinization and retrogradation are related to starch interactions with water and are
207
fundamental for starch applications. Various NMR techniques (13C CP/MAS, time-domain 1H,
208
17
209
water during these processes (Table 4). The content of double helices in starch granules as
210
measured by solid state 13C CP/MAS NMR was positively correlated with the enthalpy
211
change of gelatinization (∆H) as measured by DSC (Cooke & Gidley, 1992). Hydration
212
properties of potato starch were studied through the CP and SP modes of solid state 13C and
213
31
214
starch while gelatinization and hydrolysis reduced the immobile fractions of native starch.
215
Phosphorus-containing compounds became completely mobile upon gelatinization (Larsen et
216
al., 2013). Proton properties were also studied by 1H NMR (Ritota et al., 2008; Rondeau-
217
Mouro et al., 2015). Four types of water differing in their mobility were observed in starch-
218
water systems during gelatinization (Ritota et al., 2008). Water with the highest mobility was
219
related to the bulk of water, while the others were associated with the chemical and diffusive
220
exchanges with starch components (Ritota et al., 2008). Rondeau-Mouro et al. (2015)
221
employed the time-domain 1H NMR to study the temperature-associated changes of T2
222
(spin–spin relaxation time) during starch gelatinization. Two T2 components were due to the
223
slow diffusional exchanges between different water layers in starch. The fraction with the
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P MAS NMR (Larsen et al., 2013). As expected, hydration increased the molecular order of
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225
amylose. Low-resolution NMR measurements (proton NMR) are fast and require no sample
226
pre-treatment, while providing useful information of the starch gelatinization process (Ritota
227
et al., 2008). Cheetham and Tao (1998a) employed 17O NMR relaxation technique and
228
revealed that T2 change was related to the water content and the degree of starch
229
gelatinization. Higher contents of amylose and phosphates were related to lower water
230
mobility. Upon gelatinization with no/little shearing, the granules are not completely
231
dissolved and remain in fragile forms termed the starch ghost (Zhang et al., 2014). The ghost
232
structure of gelatinized starch was probed by solid state 13C CP/MAS NMR (Zhang et al.,
233
2014). V-type inclusion complexes were found in potato and maize starch ghosts. Upon α-
234
amylase hydrolysis, the V-type polymorph became more prominent while a small amount of
235
B-type polymorph was recorded in the potato starch ghost. It was suggested that temporary
236
entanglements of amylopectin and their size are related to the ghost formation (Zhang et al.,
237
2014).
238
Starch retrogradation has been studied by 13C CP/MAS and 1H NMR (Gidley, 1989;
239
Ambigaipalan et al., 2013; Teo & Seow, 1992; Smits et al., 1998). 13C CP/MAS NMR
240
analysis showed that the intensity of C-4 peak decreased during the retrogradation of pulse
241
starches, while the content of double helices increased (Ambigaipalan et al., 2013). In
242
amylose gel, the B-type polymorph was observed (Gidley, 1989). 1H NMR analysis of the re-
243
crystallized starch showed that the rate of decay after radiofrequency pulse was different than
244
that of the amorphous starch (Teo & Seow, 1992). This could be due to the water release
245
from the hydrated starch chains during re-crystallization. Smits et al. (1998) analysed the
246
retrogradation of starch stored below and above the glass transition temperature (Tg). T1
247
relaxation time decreased before increasing when the storage temperature was above Tg,
248
while it increased before levelling off when the storage temperature was below Tg. In the
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250
the recrystallization of starch, respectively. In the latter case, the increase was mostly due to
251
the decrease in free volume (Smits et al., 1998). Kulik and Haverkamp (1997) employed one-
252
and two-dimensional exchange solid-state NMR for the analysis of waxy maize starch
253
retrogradation. Slow motions with the correlation time of tens of milliseconds were detected.
254
Starch retrogradation occurred over a wide range of correlation times. 5. Enzyme susceptibility and resistant starch
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The structural changes of maize starches varying in amylose content during enzyme
257
hydrolysis and processing were followed by solid state 13C CP/MAS NMR spectroscopy
258
(Htoon et al., 2009; Shrestha et al., 2012). Hydrolysis by artificial saliva α-amylase had little
259
effect on the contents of double and single helices as well as the non-ordered proportion of
260
maize starches (Shrestha et al., 2012). Enzyme hydrolysis of the thermally-processed maize
261
starches with high amylose contents (>50%) increased the contents of double helices while
262
decreasing the proportion of amorphous starch (Htoon et al., 2009). The molecular structure
263
of resistant starch after enzyme hydrolysis was characterised by various NMR techniques
264
(Colquhoun et al., 1995). Relaxation and solid state 13C CP/MAS NMR tests showed that the
265
amylose gel had a double helical (rigid) fraction and a mobile amorphous fraction. Upon
266
hydrolysis by porcine pancreatic α-amylase, the mobile fraction was removed and the gel
267
became rigid and fully ordered (Colquhoun et al., 1995). The gels of amylomaize V,
268
amylomaize VII, and wheat starches after enzyme hydrolysis contained 60−70% of double
269
helical structure as revealed by solid state 13C CP/MAS NMR. Structurally-defected B-type
270
double helical aggregates were reported in the cooled gels.
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6. Modifications
272
6.1.Physical modifications
12
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C CP/MAS and 1H NMR techniques have been used to probe the structural changes of
274
starches upon different physical treatments including high pressure, melt-process and
275
ultrasound, and microwave (Table 5). These processes gelatinized starch and increased the
276
content of amorphous material in the systems (Deng et al., 2014; Guo et al., 2015; Lima &
277
Andrade, 2010; Fan et al., 2013a and 2013b). High pressure had no effect on the chemical
278
shifts of carbon resonance peaks, while decreasing the relative crystallinity of starch. Pressure
279
treatment up to 600 MPa increased the proportion of the amorphous regions of starch, while
280
having no effect on the polymorph type (Deng et al., 2014; Guo et al., 2015). Rapid heating
281
in oil bath and microwave heating had similar effects in increasing the content of amorphous
282
material and decreasing that of the double helices (Fan et al., 2013a and 2013b). 1H NMR
283
analysis showed that rapid conventional heating gave a lower water mobility of starch system
284
than did the microwave heating (Fan et al., 2013a and 2013b). Sonicated and melt-processed
285
high amylose maize starch had similar spectra, and the ultrasound better de-aggregated the
286
starch (Lima and Andrade, 2010).
287
6.2.Chemical modifications
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The structural changes of various starches hydrolysed by acid and alkaline solutions were
289
followed by 13C CP/MAS NMR (Table 5). The acid treatment reduced the content of
290
amorphous starch while increasing that of double helix and degree of crystallinity
291
(Atichokudomchai et al., 2004; Cai et al., 2014a). Wang and Copeland (2012) showed that
292
the alkali hydrolysis had no effect on the chemical shifts of various carbon peaks of pea
293
starch spectrum while broadening the resonance peak of C-2–C-5 sites. The content of double
294
helix decreased due to the alkali hydrolysis of the amorphous regions of the granules. Alkali
295
treatment had no effect on the NMR spectra of rice starches differing in amylose contents (24
296
and 58%) (Cai et al., 2014b).
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The position and level of substitution in starch (e.g., acetylated, phosphorylated,
298
hydroxylpropylated, octenyl succinic anhydride (OSA)-modified) have been determined by
299
1
300
degree of branching of starch (Tizzotti et al., 2011). For the measurement, the starch was
301
either intact or in the forms of limit dextrins from enzyme hydrolysis (de Graaf et al., 1995;
302
Xu & Seib, 1997; Zhao et al., 2015). For example, Xu and Seib (1997) determined the
303
hydroxypropyl (HP) levels of modified maize, wheat, and cassava starches based on the
304
intensity of HP methyl signal in comparison with that of the methine and methylene (HCO)
305
multiplet. The position of hydroxypropylation was determined from the anomeric proton
306
signals of the spectrum of α-limit dextrins (Xu & Seib, 1997). Tizzotti et al. (2011) dissolved
307
starch samples in dimethyl-d6 sulfoxide with deuterated trifluoroacetic acid (TFA) addition,
308
and analysed the degree of substitution of octenyl succinic anhydride (OSA)-modified
309
starches by 1H-NMR. The starch degradation by TFA had no effect on the detection. This
310
method gave an improved spectrum resolution and accuracy of quantification (Tizzotti et al.,
311
2011). The introduction of new functional groups has been verified by 13C CP/MAS, 13C, and
312
1
313
OSA-modified soluble maize starch. The modified starch had the extra peaks at 0.8−3.0 ppm
314
and a shoulder at 5.56 ppm in the 1H NMR spectrum due to the OSA group. The intensity of
315
these peaks increased with the increasing degree of substitution. Changes were also observed
316
in the 13C spectrum. C-1 signal of the internal glucosyl units of the modified starch became
317
broader. A shoulder peak of C-4 was observed. These suggest that the substitution occurred at
318
the O-2 and O-3 positions (Ye et al., 2014). Chauhan et al. (2015) analysed the potato starch
319
by both 1H and 13C NMR. Thiolated starch had an additional peak at 2.1 ppm (SH group) and
320
another peak between 3 and 4 ppm (–CH2 in the –OC–CH2SH). The extra signals of CH2 at
321
3–3.5 ppm and of CH3 at 1.8–2.5 ppm for the S−ethyl groups were noted for the sulphonium
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H NMR (Table 5). The principles of the determination are similar to that of measuring the
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14
ACCEPTED MANUSCRIPT structure. Differences in the 13C NMR spectra were observed (Chauhan et al., 2015). New
323
peaks in the range of 175–180 ppm were noted for the thiolated starch. The new peak at ~50
324
ppm was due to the carbon in the chloroacetyl group. These peaks of both 1H and 13C NMR
325
spectra verified the successful sulfur-functionalization of starch (Chauhan et al., 2015). Solid
326
state 13C CP/MAS NMR has been used to verify the successful modification of starch (Rashid
327
et al., 2012; Wei et al., 2008; Geng et al., 2010). Wei et al. (2008) analysed the cationic maize
328
starch by 13C CP/MAS NMR. Compared with the control, extra peaks at around 31 ppm were
329
due to the fragments of methylene of the long cationic chain, indicating the successful
330
production of cationic starch. Geng et al. (2010) analysed the maize starch laurate by 13C
331
CP/MAS NMR. Carbon resonances of the fatty ester chains (10–35 ppm) and that of the ester
332
group (170–175 ppm) were recorded in the spectrum of modified starch. This suggests the
333
successful esterification of starch with the methyl laurate (Geng et al., 2010).
334
Starch was degraded by oxidation and ozone treatment (Salomonsson et al., 1991; Sandhu et
335
al., 2012). Structure of the degraded products was studied by 1H NMR and/or 13C NMR
336
(Salomonsson et al., 1991; Sandhu et al., 2012). In bromine-oxidised potato starch, the level
337
and position of keto and carboxylic groups were determined (Salomonsson et al., 1991). 1H
338
NMR analysis of ozone-treated wheat starch revealed that the β-glucuronic acid group was at
339
the C-1 position and keto group at the C-2 position (Sandhu et al., 2012).
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6.3.Starch-grafted copolymers
341
Starch-grafted copolymers have many applications such as superabsorbent and thermoplastics.
342
Structures of starch-grafted copolymers were probed by solution 1H and 13C NMR as well as
343
solid state 13C CP/MAS NMR (Table 6). For example, Zou et al. (2012) analysed starch-g-
344
polyacrylamide by solution 13C NMR to reveal the grafting positions and ratios on specific
345
carbons (supplementary material Fig. 6). The peaks at 180–190 ppm were related to the
15
ACCEPTED MANUSCRIPT amide carbonyl, and those at 35–50 ppm corresponded to the hybridised carbon atoms (–
347
(CH2–CH)n) units in the copolymers. A new peak at 61.8 ppm was related to the grafting of
348
C-6 (Zou et al., 2012). The intensity ratio of peaks at 63.5 ppm and 61.8 ppm reflected the
349
ratio of C-6 grafting. Yang et al. (2015) verified the grafting of maleic anhydride (MA) and
350
epoxidized cardanol (epicard) onto maize starch by 1H NMR. A new peak at 13 ppm in the
351
spectrum of the starch graft was related to the carboxyl group and the peaks at 6.1–6.6 ppm
352
were of the double bonds. In contrast, the 1H NMR spectrum of the epicard-grafted starch had
353
no peak at 13 ppm, suggesting the interactions of carboxyl groups with the epoxy groups. The
354
peaks at 6.7–7.2 ppm were due to the benzene groups of the epicard. These structural features
355
obtained from the NMR spectra confirmed the successful production of the copolymers.
356
Zhang et al. (2008) analysed the structure of starch-g-poly(sodium acrylate) by solid state 13C
357
CP/MAS NMR. The spectrum of the copolymer was compared with that of the pure starch
358
and poly(sodium acrylate). The spectra shared a similarity with some differences. An extra
359
shoulder of the spectrum was recorded on the C-6 peak, indicating the OH group of C-6 was
360
involved in the grafting process.
361
Physical mixtures of starch and other polymers were also studied by NMR. 1H NMR
362
relaxometry was used to study the starch and poly(lactic acid) (PLA) blend with the
363
incorporation of montmorillonite clay and silica (nanoparticles) (Brito et al., 2015). Proton
364
spin-lattice relaxation time of the blends was between that of starch and PLA, suggesting the
365
interactions and miscibility. Nanoparticle addition increased the relaxation time, suggesting
366
the occurrence of new interactions and the reduced molecular mobility.
367
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7. Interactions with other components
368
In food systems, multiple ingredients co-exist. The interactions of starch with various non-
369
starch components may greatly impact the quality of food products. Some of the starch
370
interactions with various food ingredients have been examined by both 1H and solid state 13C 16
ACCEPTED MANUSCRIPT CP/MAS NMR (Table 7). For example, the interactions of rice starch with tea polyphenols
372
during starch gelatinization were probed by 1H NMR (Wu et al., 2011). The non-covalent
373
interactions were revealed when compared to the 1H spectra of physical mixtures of starch
374
and polyphenols. The altered coupling constants suggest stronger interactions in the samples
375
during gelatinization. Li et al. (2014) analysed the interactions between amylose and metal
376
ion (Cu2+). Compared with the 1H spectrum of amylose in D2O, the presence of Cu2+
377
broadened the carbon peaks (supplementary material Fig. 7). This suggests the binding of
378
Cu2+ ions by the OH groups of starch (Li et al., 2014). Beeren & Hindsgaul (2013) studied
379
the binding interactions between potato amylopectin and HPTS-C16H33 (an amphiphilic
380
molecule) by 1H NMR. Upon binding, the proton signals shifted downfield due to the
381
formation of the helical structure of amylopectin external chains. Some of the resulting
382
products of starch interactions with other components (e.g., protein) in the solid form have
383
been studied by 13C CP/MAS NMR (Pizzoferrato et al., 1998 and 1999; Hu et al., 2013; Luo
384
et al., 2013). For example, Luo et al. (2013) analysed the structure of enzyme-modified
385
starch-zinc complexes. Compared with the control, the C-6 chemical shift of the complexes
386
moved downfield by 0.96 ppm, while the chemical shifts of the other carbons had no change.
387
This suggests that the interactions were mainly on the OH group of C-6 (Luo et al., 2013). Hu
388
et al. (2013) studied the interactions between rice starch and 1-butanol in an HCl solution. In
389
comparison with the control, an extra peak for C-1 at 100.3 ppm was observed in the sample.
390
This suggests the formation of V-type complexes between amylose and butanol. Therefore, it
391
is possible to better study the nature of both the process and resulting products of starch
392
interactions by NMR techniques.
393
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8. Starch in food and complex systems
394
The structural changes of starch and water in some food systems (bread and film) have been
395
studied by various NMR techniques (Table 8). Primo-Martín et al. (2007) studied the 17
ACCEPTED MANUSCRIPT structural changes of starch in flour, bread crumb, and bread crust by solid state 13C CP/MAS
397
NMR. The triplet of C-1 peak of the starch in flour was lost in the bread due to baking and
398
gelatinization. The increasing intensity of peaks at 82 and 102 ppm suggests an increasing
399
proportion of amorphous region. An upward displacement of the C-1 peak position in the
400
bread crust and crumb suggests the formation of V-type inclusion complexes. Sivam et al.
401
(2013) used 13C CP/MAS NMR to study the starch properties of bread as affected by pectin
402
and polyphenol addition. Polyphenols and pectins decreased the intensity of C-6 peak by
403
35−40%. The reasons remain to be illustrated by employing simple model systems (e.g.,
404
starch-pectin mixture). Mihhalevski et al. (2012) employed various NMR techniques to study
405
the structure and composition of the starches in wheat and rye sourdough breads. 13C NMR
406
spectra of the wheat and rye starches were similar. The 31P NMR spectra of wheat and rye
407
starches were different due to the difference in lipid composition. 13C CP/MAS NMR
408
analysis revealed the differences in the structures of retrograded starches in the breads. Starch
409
retrogradation can be affected by various factors such as starch structure, composition, and
410
the presence of the non-starch components (Hoover, 1995). Bosmans et al. (2012) employed
411
1
412
material Fig. 8). The proton peaks were assigned according to simple model systems. This
413
analysis helped better understand the role of water with different molecular mobility in bread
414
properties. The structure of starch in extruded films was analysed by 13C CP/MAS NMR
415
(Pushpadass et al., 2009). The extrusion process induced the changes in the NMR spectrum.
416
The C1 peak in the spectrum of starch in the film was a duplet (indicating B-type polymorph),
417
while that of the native starch was a triplet (indicating A-type polymorph). This suggests the
418
occurrence of re-crystallization of the gelatinized starch after the extrusion. The applications
419
of NMR spectroscopy in characterising the pharmaceutical tablets of starch have been
420
reviewed (Thérien-Aubin & Zhu, 2009), and thus is not related in the present review.
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ACCEPTED MANUSCRIPT 421
9. Correlations between NMR and other analytical techniques The results of some specific parameters of starch obtained from the NMR analysis were
423
compared with those measured by other techniques (Table 9). The studied aspects of starch
424
included chemical composition, structures of granules and components (e.g., degree of
425
branching), gelatinization and retrogradation, glass transition temperatures, and degree of
426
substitution in modified starch. Kasemsuwan and Jane (1996) analysed the total phosphorus
427
content of different starches by both 31P NMR and colorimetry-based methods. The results of
428
these two methods agreed well. Dunn and Krueger (1999) analysed the amylose contents by
429
1
430
these two assays agreed well with each other. The degree of branching (DB) of various
431
starches were measured by 1H NMR and high-performance size-exclusion chromatography
432
(HPSEC), and was also reflected by the blue value obtained from starch-iodine interaction
433
(Nilsson et al., 1996; Syahariza et al., 2013). Both 1H NMR and HPSEC methods gave
434
similar DB values which were highly correlated with the blue value of starch. The contents of
435
double helices of starch measured by 13C CP/MAS NMR were compared with the degree of
436
crystallinity of starch measured by XRD (Lopez-Rubio et al., 2008; Witt & Gilbert, 2014;
437
Mutungi et al., 2012). Contents of double helices of different types of starches were
438
positively correlated with the degree of crystallinity from the XRD analysis. Lopez-Rubio et
439
al. (2008) noted that the contents of double helices in starch granules are not equal to that of
440
degree of crystallinity as some of the double helices do not crystallize. This discrepancy was
441
also observed when monitoring the structural changes of crystalline parts of starch during
442
acid hydrolysis by two different methods (i.e., NMR and XRD) (Atichokudomchai et al.,
443
2004) (supplementary material Fig. 9). The degree of crystallinity was also correlated with
444
the data from Fourier transform-Raman spectroscopy and gelatinization parameters
445
(temperatures and ∆H) by DSC. The results were highly correlated with the NMR results
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H NMR and also by the iodine-binding spectrophotometry-based assay. The results from
19
ACCEPTED MANUSCRIPT (Witt & Gilbert, 2014; Mutungi et al., 2012; Cooke and Gidley, 1992). Starch retrogradation
447
reflected by 1H NMR was positively correlated with that by the Instron texture analyser
448
(Seow & Teo, 1996). Retrogradation of pulse starches quantified by 13C CP/MAS NMR was
449
compared with that by FTIR–ATR, XRD, DSC, and the enzyme susceptibility of α-amylase
450
(Ambigaipalan et al., 2013). The extents of retrogradation measured by DSC, XRD, and
451
NMR were similar, and those by NMR, FTIR-ATR, and enzyme susceptibility methods were
452
different. The similarity and discrepancy indicate that different methods may reflect different
453
aspects of the retrogradation. Ambigaipalan et al. (2013) suggested that 13C CP/MAS NMR is
454
sensitive to the conformational changes related with amylopectin crystallization while FTIR
455
more reflects the crystallization and re-association of both amylopectin-amylopectin and
456
amylose–amylopectin chains. Therefore, a comprehensive approach employing different
457
instruments should be used to gain a holistic picture of the starch retrogradation. Kalichevsky
458
et al. (1992) studied the glass transition temperature of amorphous starch by pulsed 1H NMR,
459
DSC, Instron texture analyser, and dynamic mechanical thermal analysis (DMTA). The glass
460
transition temperatures of starch measured by NMR were lower than those by DSC and other
461
techniques by 20−30 oC (supplementary material Fig. 3). The NMR technique probes a lower
462
mobility distance scale and determines proton mobility, while DSC and DMTA relate to a
463
transition with an increased mobility for a large proportion of the starch chains (Kalichevsky
464
et al., 1992). The degree of substitution (acetylation and hydroxypropylation) as well as the
465
degree of grafting of starch copolymers were analysed by NMR techniques. The results from
466
NMR analysis were compared with that of wet chemistry-method (e.g., Johnson and titration
467
methods) (de Graaf et al., 1995; Gurruchaga et al., 1992). NMR-based methods (1H and 13C)
468
agreed well with the traditional wet chemistry methods for the modification analyis, while
469
being time-saving.
470
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10. Conclusions 20
ACCEPTED MANUSCRIPT NMR techniques have been used to probe diverse aspects of starch systems. These techniques
472
include liquid state 1H NMR, 13C NMR, 31P NMR, and 17O NMR and solid state 13C CP/MAS
473
NMR. Various aspects/parameters of starch that have been studied by NMR include chemical
474
composition, degree of molecular order, degree of branching, degree of gelatinization and
475
retrogradation, glass transition temperature, physical structure of V-type amylose inclusion
476
complexes, and extents and position of modification. NMR techniques have also been used to
477
characterise starch interactions with various non-starch food components such as polyphenols,
478
proteins, and minerals. The baking and staling processes of bread have been monitored, and
479
the physical structure of starch in edible films has been followed. The structural information
480
obtained from NMR analysis provides a strong basis for better understanding the
481
physicochemical properties of starch and food systems. The composition and molecular
482
structure of starch obtained from NMR analysis correlate well with the results of other
483
techniques such as XRD and wet chemistry-based methods. Compared with traditional
484
methods for starch characterisation, the NMR approach can be simple, efficient, and time-
485
saving, while the solid state NMR method can be non-destructive. Besides NMR, most of the
486
studies also employed some other techniques to characterise starch systems. NMR-based
487
techniques complement the others for a comprehensive understanding of the structural and
488
physicochemical properties of starch. It should be stressed that some structural parameters of
489
starch are sensitive to the nature of the measurement technique. The knowledge obtained
490
from NMR analysis will be of great importance for a better understanding of the starch
491
functionalities and the role of starch in food and non-food applications.
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492 493
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Physical characterisation of high amylose maize starch and acylated high amylose maize
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Lima, F. F., & Andrade, C. T. (2010). Effect of melt-processing and ultrasonic treatment on
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28
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Table captions
2
Table 1 Chemical composition of starch quantified by NMR spectroscopy
3
Table 2 Structural characterisation of starch studied by NMR spectroscopy
4
Table 3 Structure of V-type inclusion complexes revealed by NMR spectroscopy
5
Table 4 Gelatinization and retrogradation processes monitored by NMR spectroscopy
6
Table 5 Structure of modified starches as studied by NMR spectroscopy
7
Table 6 Structure of starch graft copolymers as studied by NMR spectroscopy
8
Table 7 Interactions of starch with non-starch components as monitored by NMR spectroscopy
9
Table 8 NMR characterization of bread and starch films
SC
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Table 9 Correlations between NMR and other analytical techniques in structural characterization of starch systems
AC C
10
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1
1
ACCEPTED MANUSCRIPT
Table 1
Parameter
Starch
NMR type
Major findings
31
Degree of phosphorylation on the C-3 position was independent of potato variety, while that Muhrbeck and
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11
source Potato
P NMR
SC
Degree of phosphorylation on
on C-6 position varied greatly among different genotypes
Phosphate
Various
31
P NMR
M AN U
the C-3 and C-6
Normal cereal starches contained mostly phospholipids. Tuber and root starches were free of phospholipids. Legume and potato starches mostly contained phosphate monoesters.
phosphate,
Phosphate monoesters of all starches were more on the C-6 than on the C-3 of the glucose
phospholipids
units Various
31
P NMR
Potato starch mostly contained phosphate monoester (0.086%). Wheat starch contained
Tellier, 1991
Lim et al., 1994
Kasemsuwan and
EP
Phosphate
TE D
monoester, inorganic sources
Reference
mostly phospholipids (0.058%), high-amylose (50% amylose content) maize starch mostly Jane, 1996
phosphate,
contained phosphate monoesters (0.0049%) and phospholipids (0.015%). Waxy maize
phospholipids
starch had trace amounts of phosphate monoesters
phosphorylation site Curcuma
Heteronuclear
on glucan chains
1
rhizome
AC C
monoester, inorganic sources
A combination of heteronuclear 1H, 13C and 1H, 13C, 31P NMR spectra efficiently
H, 13C double, determined the phosphorylation sites. Monophosphate esters are on the C-3 and C-6
Schmieder et al., 2013 2
ACCEPTED MANUSCRIPT
H NMR
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1
Phosphatidylcholine was mixed with starch in DMSO. Phospholipid content was
Genkina &
determined by 31P NMR with tributyl phosphate as the standard. This method allows the
Kurkovskaya,
quantification of phospholipids without the regards of sample forms
2013
Branching ratios of starch were obtained from 1H NMR. This ratio was then used for the
Dunn and
determination of amylose content
Krueger, 1999
SC
sources
P NMR
M AN U
Various
31
TE D
Amylose content
Wheat
EP
Phospholipids
H,13C, 31P triple positions of the glucose unit
AC C
1
3
ACCEPTED MANUSCRIPT
12
Table 2 NMR type
Major findings
Molecular order
Solid state 13C CP/MAS
13
NMR
starch for the first time
Solid state 13C CP/MAS
13
NMR
starch for the first time. The spectrum was related to the polymorph type Bociek, 1985
SC
Various sources
C NMR spectrum was interpreted in relation to the crystallinity of
C NMR spectrum was interpreted in relation to the crystallinity of
Reference Marchessault & Taylor, 1985 Gidley &
M AN U
Molecular order
Maize, potato
RI PT
Targeted structure Starch source
of starch
Rice
Solid state 13C CP/MAS
13
NMR
triplet for A-type polymorph starches, and a doublet for B-type starches 1986 The relative degree of crystallinity (37.2−58.9%), relative proportion of Man et al., 2013
NMR
single helices (1−7.9%), double helices (39.6−61.8%), and amorphous
Various sources
AC C
Molecular order
C NMR spectrum was related to the starch polymorph. C-1 peak was a Veregin et al.,
Solid state 13C CP/MAS
EP
Molecular order
Various sources
TE D
Molecular order
(37.2−52.5%) material were quantified. Deficiency of starch branching enzymes I and IIb decreased degree of crystallinity, portion of double helices, and increased the portion of single helices of starch
Solid state 13C CP/MAS
A partial least squares model was produced to rapidly quantify the
Flanagan et al.,
NMR
ordered structure in starch granules from the NMR spectrum
2015 4
ACCEPTED MANUSCRIPT
Waxy maize
temperature
Pulsed NMR, 13C CP/MAS Pulsed NMR and 13C CP/MAS NMR successfully characterised the
Kalichevsky et
NMR
al., 1992
glass transition of amorphous starch with water contents of 10−22%
RI PT
Glass transition
Potato starch, amylose,
13
C CP/MAS NMR, 1H/13C Five types of α(1–4) linkages were found by decompositions of C1
amorphous starch
amylopectin processed
magnetization transfer and resonance spectrum. Distributions of average glycosidic linkages
2001a and
into amorphous and
2D WISE solid state NMR dihedral angles (ϕ, Ψ) were related to the structures resulted from the
2001b
Branching ratio
Various sources
processing 1
Paris et al.,
M AN U
semi-crystalline status
SC
Structure of
H NMR, 13C NMR
Ratios of α(1–4) to α(1–6) linkages of native and degraded starches were Gidley, 1985 determined by 1H NMR and ranged from 17.5 to 26. Glucose and the
1
H NMR
average unit chain length Maize starches varying in 1H NMR
AC C
Branching ratio
amylose content, potato, rice, pea, cassava, wheat Branching ratio
Maize, rice
EP
Branching ratio and Various sources
TE D
reducing residues of larger glucans can be differentiated by 13C NMR
1
H NMR
DB ranged from 1 (potato amylose) to 4.77% (maize amylopectin).
Nilsson et al.,
Average unit chain length (CL) ranged from 21 (maize amylopectin) to
1996
100 glucosyl residues (potato amylose) Ratios of α(1–4) to α(1–6) linkages were determined by 1H NMR. Maize Dunn and starches had the ratios ranging from 21.7 to 83.9%
Krueger, 1999
NMR was used to efficiently determine the degree of branching (DB) of Tizzotti et al.,
5
ACCEPTED MANUSCRIPT
2011; Syahariza
from 2.7−3.6%
et al., 2013
RI PT
maize starch as 3.34%. DB of rice starches from 14 genotypes ranged
DB of whole starch molecules is defined as the percentage of α(1–6) glycosidic linkages (branching points) to the total of α-(1–4) and α-(1–6)
14
glycosidic linkages
SC
13
M AN U
15 16
AC C
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17
6
ACCEPTED MANUSCRIPT
Table 3
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18
Targeted feature
Amylose type
Complexing agent
NMR type
Major findings
References
Formation of
Potato
DMSO, KOH, iodine,
13
Soluble V-type inclusion complexes in solution were
Jane et al., 1985
C NMR
α-naphthol, methyl
characterised. Increasing concentration of complexing agents
inclusion complexes in
alcohol, tert-butyl
induced downfield shift of the signals of C-1 and C-4 (larger shift)
solution
alcohol, n-butyl
M AN U
SC
amylose/amylodextrin
and C-2, C-3, and C-6 (smaller shift). The differences in the shifts
alcohol, cyclohexanol
for C-1 and C-4 indicate the differences in the compactness of the helical structure Gidley and
hexanoic acid, tert-butyl CP/MAS
not affected by the type of complexing agents. V8-type complex
Bociek, 1988
complexes
alcohol, n-butanol, 1-
with 1-naphthol had chemical shifts of C-1 and C-4 peaks
NMR spectra of solid V- Synthetic type amylose inclusion complexes, A- and B-
amylose
AC C
naphthol
TE D
amylose
Ethanol
C
NMR
EP
type amylose inclusion
13
NMR spectra of V6 and V7-type complexes are similar, and are
NMR spectra of solid V- Potato, synthetic Sodium palmitate,
downward by 1 ppm (supplementary material Fig. 5)
13
A triplet C-1 peak for the A-type crystalline form and a doublet C- Horii et al.,
CP/MAS
1 peak for B-type crystals were recorded (supplementary material 1987
NMR, 13C
Fig. 4). Spectrum of V-type amylose is rather different from that of
C
7
ACCEPTED MANUSCRIPT
spin-lattice A- and B-type in that the C-4 line is separated from C-2, C-3, and relaxation
C-5 atoms. 13C T1 values of the crystalline components of
RI PT
type amylose crystals
amyloses are shorter than that of cellulose (suggesting more mobility) Stearic, palmitic, oleic,
13
Chemical shift of the mid-chain methylenes had a change by ~2−3 Snape et al.,
type amylose inclusion
linoleic, linolenic, and
CP/MAS
ppm, suggesting the complexation process. The mid-chain
complexes
docosahexaenoic acids, NMR
1998
M AN U
C
SC
NMR spectra of solid V- Potato
methylenes of lipids in the V-type complexes had the same chemical shifts, except for docosahexaenoic acid. Analysis of
glycerol monooleate,
cross-polarisation dynamics showed that the bulky polar groups
TE D
glycerol monopalmitate, lysophosphatidylcholine
situated outside the V-helical segments and was adjacent to the amorphous regions
Menthone, decanal, 1-
13
Differences in NMR spectra were observed among V6I, V6II,
type amylose inclusion
naphthol, 1-butanol
CP/MAS
V6III, and V8-type amylose complexes. Rehydration increased the 2005
NMR
sharpness of carbon resonance peak, and desorption induced the
AC C
complexes
EP
NMR spectra of solid V- Potato
C
Le Bail et al.,
transition from V6II to V6I-type
8
ACCEPTED MANUSCRIPT
amylose, pea
complexes
13
A single resonance peak at 32.4 ppm was assigned to the
Lebail et al.,
CP/MAS
complexed fatty acids. The uncomplexed palmitic acid was also
2000
NMR,
detected in the samples with a chemical shift of 33.6 ppm. T1
deuterium
relaxation tests revealed a difference between the uncomplexed
NMR
and complexed fatty acids (by 1.1−1.2 s). Temperature-dependent
C
RI PT
type amylose inclusion
Palmitic, lauric acids
SC
NMR spectra of solid V- Synthetic
M AN U
deuterium NMR analysis revealed partially disassociated complexes of amylose-palmitic acid and a full complexation for the amylose–lauric acid
Decanoic acid,
type amylose inclusion
bean (Vicia
carvacrol
complexes
faba), pea,
C
Peaks of 102.7, 81.4, 74.9, 71.6, and 61.3 ppm were related to C1, Le Bail et al.,
C4, C3, C2-C5, and C6, respectively, and these were of V6I form. 2013
NMR
High pressure treatment induced the formation of V-type
EP
CP/MAS
complexes at a low temperature (40 oC)
AC C
tapioca
13
TE D
NMR spectra of solid V- Potato, broad
9
ACCEPTED MANUSCRIPT
NMR spectra of solid V- Potato
3-O-palmitoyl
13
Spectrum had peaks with chemical shifts of 102.7, 81.4, 74.9,
Le-Bail et al.,
type amylose inclusion
chlorogenic acid
CP/MAS
71.6, 61.3, and 60 ppm, and they were related to C1, C4, C3, C2-
2015
NMR
C5, and C6 carbons, respectively. Only the grafted part (palmitoyl
complexes
RI PT
C
moiety) was included in the helical cavity, and the formation of the
type amylose inclusion
13
Phosphatidylcholine
C
potato
complexes
In comparison with the physical mixture of phosphatidylcholine
M AN U
NMR spectra of solid V- Debranched
SC
V-type complexes depended on the graft position
CP/MAS
and debranched maize starch, C-4 peak at 86.46 ppm was better
NMR
separated from the combined C-2, C-3, C-5 peak by 1 ppm.
Cheng et al., 2015
EP
result of inclusion complex formation
AC C
19
TE D
Chemical shifts of C1- and C-4 peaks moved up by 1−1.5 ppm as a
10
ACCEPTED MANUSCRIPT
20
Table 4 NMR type
Major findings
Wheat, maize,
13
The enthalpy change of gelatinisation measured by DSC mostly reflects the loss of molecular (double-
Cooke and
cassava, potato
NMR
helical) order which is measured by solid state NMR
Gidley, 1992
Maize starches
17
17
varying in amylose
relaxation
RI PT
Starch source
O NMR
O spin-spin relaxation time (T2) measurements were used to monitor the starch gelatinization as
affected by various factors. The changes in T2 were related to the degree of gelatinization and water
Cheetham and Tao, 1998a
content. Higher contents of amylose and phosphates were related to lower water mobility. KI decreased
TE D
content
M AN U
C CP/MAS
SC
Gelatinization
Reference
the water mobility during gelatinization 1
H NMR
Four water populations were observed in starch-water systems. One of them was related to the bulk of
EP
Rice
water, while the others were related to the chemical and diffusive exchanges of water with starch
Ritota et al., 2008
AC C
components. The solid-to-liquid ratios from single–pulse experiment followed the water uptake of starch during swelling and gelatinisation processes Potato, wheat, maize
13
C and 31P solid CP and SP modes of 13C and 31P solid state MAS NMR were combined to probe the hydration properties Larsen et al.,
state MAS NMR of potato starch in native, gelatinized, and enzyme-modified status. Hydration increased the molecular
2013
11
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order. Gelatinization and enzyme treatments (branching enzyme and/or β-amylase) reduced the immobile
RI PT
fractions of starch. Carbons of the α(1–4) linkages needed high hydration rates for uniform chemical shifts. Immobile phosphorus-containing chains were only found in the suspension of native starch 13
The structure of starch ghosts after gelatinization was probed. V-type amylose helices were present in
Zhang et al.,
NMR
maize and potato starch ghosts before enzyme digestion. After α-amylase hydrolysis, a small amount of
2014
C CP/MAS
SC
Potato, maize
M AN U
B-type polymorph was observed in potato starch ghost, while the V-type structure became more obvious in maize starch ghost
Time-domain 1H Fraction of the shortest T2 relaxation time was related to the nonexchangeable protons in CH of both
Rondeau-Mouro
NMR
et al., 2015
amylopectin and amylose. Two T2 components were due to slow diffusional exchanges between different water layers
Retrogradation
Amylose gel structure was studied. B-type polymorph was observed from the gel of diluted amylose
and 1H NMR
solution. Gel from concentrated amylose solution (10%) contained rigid B-type double helices and more
C CP/MAS
EP
13
Gidley, 1989
AC C
Synthetic, potato
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Wheat
mobile amorphous single chains
12
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Various sources
Pulsed 1H NMR Pulsed 1H NMR was used to monitor the retrogradation of starch. Proton signals from re-crystallized
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starch had a different rate of decay after radiofrequency pulse as compared with that of the amorphous
Teo and Seow, 1992
starch. NMR-based technique is simple, non-destructive, and has little requirement of sample size
Slow motions with correlation time of tens of milliseconds were detected by stimulated echo and two-
dimensional
dimensional exchange NMR. Retrogradation occurs over a wide range of correlation times
SC
One- and two-
M AN U
Waxy maize
exchange Solid state NMR Potato
13
C CP/MAS
Kulik and Haverkamp, 1997
The retrogradation of starch was monitored below and above the glass transition temperature (Tg). Below Smits et al.,
TE D
NMR, 1H NMR Tg, the relaxation time of 1H NMR increased due to the decreasing free volume before reaching a plateau. 1998 Above Tg, water absorption decreased the relaxation time before an increase due to recrystallization. 13C
13
The retrogradation of starches from various pulses (faba bean, black bean, pinto bean). Intensity of C-4
NMR
peak decreased during retrogradation, while the content of double helices increased
C CP/MAS
AC C
Pulse starches
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CP/MAS NMR was not an efficient technique for retrogradation detection Ambigaipalan et al., 2013
13
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Table 5
Modification
Starch
NMR type
Rice, lotus
13
seed
NMR
Uses
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21
Physical
C CP/MAS The structural changes of rice starch as affected by high pressure treatment were followed by 13C Deng et al., 2014;
SC
High pressure
References
CP/MAS NMR. 600 MPa increased the proportion of amorphous material of starch, and had no
Guo et al., 2015
M AN U
effect on the polymorph type. High pressure had no effect on the chemical shifts of various carbon peaks, while decreasing the relative crystallinity High-amylose 1H NMR
Starch was melt-processed (100 oC, 40 rpm, 8 min) and ultrasonicated (750 W, 20 kHz) in the
and ultrasound
maize starch
presence of glycerol. 1H NMR spectra of sonicated and melt-processed samples were similar. 1H Andrade, 2010
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Melt-processing
Lima and
NMR analysis indicated the de-aggregating of starch induced by ultrasound 13
C CP/MAS Microwave heating increased the proportion of amorphous material and decreased that of both
Fan et al., 2013a
EP
Rice
NMR, 1H
single and double helices. The effect of rapid heating in oil bath was similar to that of microwave and 2013b
NMR
heating. Water mobility of starch-water system was also monitored by 1H NMR. Water mobility
AC C
Microwave
of samples subjected to rapid conventional heating was lower and that of microwave heating was higher Chemical 14
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Lotus
13
rhizome,
NMR
C CP/MAS Acid hydrolysis increased the double helix content and decreased the amorphous portion of starch. Atichokudomchai The relative crystallinity increased sharply during the initial hydrolysis before levelling off
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Acid hydrolysis
cassava 13
C CP/MAS Alkali hydrolysis had no effect on chemical shifts, broadened the resonance peak of C-2–C-5
NMR Alkali hydrolysis
Rice
sites, and decreased the content of double helices from 35 to 30%
SC
Pea
13
NMR
and 58%)
1
Molar substitution of modified starches was quantified by 1H NMR
hydroxypropylated Hydroxypropylated Maize, wheat, 1H NMR
Copeland, 2012
de Graaf et al., 1995
of α-limit dextrins
cassava Hydroxypropylated Sweet potato
Wang and
Both the level and position of hydroxypropylation of starch were determined by 1H NMR analysis Xu and Seib, 1997
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H NMR
31
P, 1H NMR Molar substitution was quantified by 1H NMR, and hydroxypropylation mostly occurred at O-2
AC C
Potato
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Substitution Acetylated,
al., 2014a;
C CP/MAS Alkali hydrolysis had no effect on NMR spectra of rice starches varying in amylose contents (24 Cai et al., 2014b
M AN U
Alkali hydrolysis
et al., 2004; Cai et
Zhao et al., 2015
(61%), followed by O-6 (21%) and O-3 (17%) Phosphorylation
Canna edulis
31
P NMR
Starch phosphate monoesters had chemical shifts of 4.076 and 4.564 ppm. Phosphorylation
Zhang and Wang,
occurred at C-2 or C-3, and C-6 positions of starch
2009
15
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Laurate
Maize
Solid state 13C 13C NMR analysis verified the esterification of starch with methyl laurate
Geng et al., 2010
Laurate
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NMR High-amylose 1H NMR
Four extra peaks with chemical shifts of 1, 1.2, 1.4, 2.25 ppm were observed in the NMR
maize
spectrum of starch laurate. The peak intensity of these peaks increased with the increasing degree
Maize
modified Starch sulfide
13
C CP/MAS A carboxyl group with chemical shift at 168 ppm in the NMR spectrum confirmed the formation Rashid et al., 2012
NMR Potato
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C=O–O–SiO2Na
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of substitution
Lu et al., 2013
of C=O–O–SiO2Na moieties in starch
13
C, 1H NMR In 1H NMR spectrum, thiolated starch has additional peaks at 2.1 ppm (SH group) and between 3 Chauhan et al., 2015
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and 4 ppm (–CH2 in the –OC–CH2SH group). In 13C NMR spectrum, thiolated starch has new signals between 175–180 ppm. Intense peaks round 30 ppm were noted for CH2 and 17 ppm for
Acylated
Octenyl succinic
1
Degrees of substitution of various acylated starches (phthalate, cinnamate, benzoate, and
Thakore et al.,
nanoparticles
palmiate) were measured by 1H NMR
2013
High amylose 1H NMR
Starch acetate, propionate, and butyrate were produced. Acylation reduced the molecular mobility Lim et al., 2015
maize
of starch (reduced T2). Drying and storage further reduced the molecular mobility
Starch
Maize
1
H NMR
H NMR
AC C
Acylated
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CH3 from di-ethylamine
Rapid determination of degree of substitution and degree of branching of the modified starch was Tizzotti et al.,
16
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developed by dissolving starch in dimethyl-d6 sulfoxide with deuterated trifluoroacetic acid
modified
addition
OSA
Rice
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anhydride (OSA)-
13
C, 1H NMR 1H and 13C NMR analysis confirmed the formation of octenyl succinic esters. The esterification
2011
Zhang et al., 2013
occurred at 2-OH, 3-OH, and 6-OH of glucosyl residue with 2-OH being the main substitution
Sugary maize
13
C, 1H NMR Soluble starch from sugary maize was modified by OSA. The modified starch showed additional Ye et al., 2014
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OSA
SC
position
peaks at 0.8−3.0 ppm and a shoulder at 5.56 ppm in 1H NMR spectrum. Modified starch had increased ratio of α(1,6) linkages. OSA modification broadened C-1 peak. A shoulder of C-4 peak
Cross-linking
Sweet potato
31
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at 78.1 ppm was observed. The substitution occurred at the O-2 position P, 1H NMR The position and level of phosphorus in cross-linked starch were determined by NMR.
Zhao et al., 2015
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Monostarch monophosphate and distarch monophosphate (molar ratio of ~1:1) were produced from the reaction with sodium trimetaphosphate. Phosphorylation of monostarch monophosphate
Cationization
Maize
13
AC C
occurred at O-3 and O-6 positions. There is 1 cross-link per 2900 glucosyl residues C CP/MAS NMR spectra of three cationic starch derivatives (cationic groups varying in chain length) were
NMR
Wei et al., 2008
similar. Additional peaks near 31 ppm were related to the methylene of the cationic group, confirming the formation of starch ethers
17
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Oxidised starch
Potato
13
C, 1H NMR Positions and contents of the keto and carboxylic groups were determined in oxidised starch. Ring Salomonsson et
Ozone treatment
Wheat
1
H NMR
1
al., 1991
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cleavage occurred between C-2 and C-3 H NMR analysis showed that a keto group formed at C-2 position, and β-glucuronic acid was
formed at C-1 position
2012
AC C
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M AN U
SC
22
Sandhu et al.,
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23
Starch
Table 6
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24
Graft group
NMR
Use
Various types
Solution 13C NMR
Confirmation of the grafting and measurement of the degree of grafting
Maize
Sodium acrylate
13
C CP/MAS NMR
1
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Maize
SC
type
Reference
Gurruchaga et al., 1992
H relaxation times and solid state 13C CP/MAS NMR spectrum were used to study Zhang et al., 2008
the compatibility of the grafted group and starch as well as the blends of sodium
Maize
Acrylamide
Solution 13C NMR
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acrylate and starch
Graft position and grafted segment length were determined by 13C NMR. Grafting Zou et al., 2012
EP
of acrylamide group mostly occurred at C-6 (supplementary material Fig. 6).
Maize
Lactic acid
13
AC C
Increasing amylose content of starch increased the length of grafted segment C NMR, heteronuclear NMR analysis confirmed the formation of starch-g-lactic acid copolymer
multiple bond coherence
Hu and Tang, 2015
(HMBC)
19
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Maize
Maleic anhydride,
1
H NMR
1
H NMR analysis confirmed the formation of starch copolymers
1
H and 13C NMR
1
H and 13C NMR analysis confirmed the formation of amylopectin-g-
Yang et al., 2015
n.a.
Acrylamide-co-Nmethylacrylamide
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epoxidized cardanol
poly(acrylamide-co-N-methylacrylamide)
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26 27
32 33
EP
31
AC C
30
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28 29
2015
SC
25
Sasmal et al.,
34 20
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35
Table 7 Reference
Glycerol and
1
H NMR
Native starch granules as affected by glycerol and water were studied by relaxation NMR. The
Cioica et al.,
water
relaxation
presence of glycerol and water increased the molecular mobility of the starch. T2 of starch with
2013
SC
Maize
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Starch source Other component NMR technique Major observations
water and glycerol had four dynamic components, while that of starch without glycerol had three. T1
Potato and
Protein
Solid state 13C
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distributions were related to the degree of crystallinity of starch Impact of Maillard reactions between starch and amino acid (lysine) on starch structure was
CP/MAS NMR followed by solid state 13C CP/MAS NMR. Intensity of the C1 resonance peak decreased with
chestnut
TE D
increasing lysine concentration. The Maillard reaction due to roasting induced the formation of V-
Pizzoferrato et al., 1998 and 1999
type complexes and reduced the proportion of B-type polymorph in starch zinc
Solid state 13C
Starch modified by α-amylase and glucoamylase was reacted with zinc. The chemical shift of C-6
Luo et al.,
EP
Cassava
AC C
CP/MAS NMR peak of the complexes moved downfield by 0.96 ppm, while that of the other peaks had little change, 2013 as compared with the control. The results suggest that the zinc mostly interacted with OH group of
C-6 of the glucose units
Potato amylose
Metal ion
1
H NMR
The interactions between amylose and Cu2+ broadened the peaks of 1H NMR spectrum of amylose
Li et al.,
(supplementary material Fig. 7). The ratio of signal areas of protons H(2–6) to H(1) decreased upon 2014 21
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Cu2+ addition. This suggests the binding of Cu2+ with OH groups of amylose
HPTS-C16H33
After 1-butanol-HCl hydrolysis of starch, an additional peak at 100.3 ppm was detected for C1,
NMR
indicating the formation of V-type amylose inclusion complexes
2013
1
Upon binding to amylopectin, the amphiphile of HPTS-C16H33 unfolds, and proton signals of 1H
Beeren &
NMR spectrum shifted downfield
Hindsgaul,
C CP/MAS
H NMR
amylopectin
Rice
Tea polyphenols
1
H NMR
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Potato
13
SC
1-butanol
M AN U
rice
Hu et al.,
2013
Starch and tea polyphenols were mixed and gelatinized. Compared with physical mixtures of
Wu et al.,
gelatinized starch and tea polyphenols, the chemical shifts of protons of 1H NMR spectrum of the
2011
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sample were identical. The coupling constants were different, suggesting stronger interactions in the sample than the physical mixture 1
H NMR
Compared with individual component, 1H NMR spectrum of the propofol-hydroxyethyl starch
Silva et al.,
EP
Hydroxyethyl Propofol
complexes had broadened peak at 8.00 ppm and downfield shifts of proton signals of glucose units. 2014
starch
36 37
Table 8
AC C
This suggests the occurrence of the interactions between the hydroxyethyl starch and propofol
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Targeted property
NMR technique Major observations
Bread
Crystallinity of
13
Compared with the spectrum of starch in flour, that of the starch in bread crumb showed a narrowing of Primo-Martín
starch in bread
NMR
the C-1 peak, an upward chemical shift to 102.1 ppm, and the loss of the triplet characteristics. Bread
C CP/MAS
crumb and crust
Reference
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Product
et al., 2007
crust had a similar trend with a peak at 102.3 ppm for rusk rolls and one at 101.9 ppm for crispy rolls.
SC
This indicated the formation of V-type complexes. Increase in peak intensity at 82 and 102 ppm
extent that that of the crust Bread
Water mobility
1
H NMR
The proton mobility of bread crumb and crust was analysed by 1H NMR relaxometry. The assignment
Bosmans et
of proton peaks was made by using starch-water and gluten-water model systems (supplementary
al., 2012
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relaxometry
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indicated the increasing amounts of amorphous material. Starch of bread crumb gelatinized to a larger
material Fig. 8). This analysis may help better understand the physical changes of bread during
Starch structure and 13C CP/MAS, composition
C, 1H, 31P
Structural changes of starch in rye sourdough and wheat breads during staling were compared by NMR Mihhalevski
13
techniques. 13C NMR spectra of rye and wheat starches are similar. 31P NMR analysis showed that
NMR
phospholipid fraction differed in these two starches. 13C CP/MAS NMR analysis showed that the
AC C
Bread
EP
production and storage
et al., 2012
retrograded rye starch had different polymorph composition than the wheat starch Bread
Starch structure
13
C CP/MAS
Addition of polyphenols and pectins on starch properties in bread was probed by 13C CP/MAS NMR.
Sivam et al.,
23
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NMR
Polyphenols and pectins decreased the intensity of C-6 peak by 35−40%. V-type complexes and
2013
13
13
NMR
with that of the physical mixture. Difference in C1 peak was observed. C1 peak of extruded films was a al., 2009
C CP/MAS NMR spectrum of extruded maize starch films with glycerol and water was compared
Pushpadass et
SC
duplet, suggesting the existence of B-type polymorph, while that of the physical mixture had A-type
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polymorph
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C CP/MAS
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Starch structure
AC C
Film
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amorphous starch existed in the bread
24
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38
Table 9
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39
Targeted feature
NMR type
Other techniques
Major findings
Various types
Total phosphorus
31
Traditional
Total phosphorus contents of starch measured by 31P NMR agreed with
colorimetric
the results obtained from colorimetric chemical method
content
chemical method Various types
Amylose content
1
H NMR
Iodine-binding
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P NMR
SC
Starch sample
The amylose contents obtained from 1H NMR were comparable to those
spectrophotometry measured by iodine-binding spectrophotometry-based assay
Rice starch
Degree of branching 1H NMR
8 starches from Crystalline region
13
C
& Jane, 1996
Dunn and Krueger, 1999
The unit chain length of starch measured by 1H NMR agreed well with
Nilsson et al.,
value
that by HPSEC. The degree of branching of starch was positively
1996
EP
and unit chain length
Kasemsuwan
HPSEC and blue
AC C
Various sources Degree of branching 1H NMR
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assay
Reference
HPSEC
XRD
correlated with blue value Both methods gave similar DB values (2.7−3.6%) for 14 rice varieties
Syahariza et al., 2013
Contents of double helices are not equal to the degree of crystallinity
Lopez-Rubio et
25
ACCEPTED MANUSCRIPT
obtained from XRD analysis, though the results of these two methods are al., 2008
NMR
highly correlated
11 waxy starches Crystalline region
13
from various sources (native
C
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CP/MAS
XRD, DSC
Contents of double helices of both native and annealed starches are
Witt & Gilbert,
CP/MAS
positively correlated with the degree of crystallinity (XRD) and
2014
NMR
gelatinization parameters (DSC)
SC
various sources
Degree of
13
Fourier transform- Samples varying in the degree of crystallinity were produced from
crystallinity
CP/MAS
Raman
debranched cassava starch subjected to hydrothermal processing. Degree 2012
NMR
spectroscopy,
of molecular order by NMR was positively correlated with that derived
C
XRD 13
C
maize, wheat,
CP/MAS
potato, tapioca
NMR
Maize starch, bread, rice cup
Retrogradation
Pulsed 1H NMR
XRD, DSC
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Gelatinization
Mutungi et al.,
from XRD and Fourier transform-Raman spectroscopy
AC C
Maize, waxy
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Cassava
M AN U
and annealed)
Molecular (double-helical) order of native starches was higher than
Cooke and
degree of crystallinity measured by XRD. Molecular order is positively
Gidley, 1992
correlated with ∆H (enthalpy change) of gelatinization
Instron texture
The results of starch retrogradation obtained from two methods had a high Seow and Teo,
analyser
and positive correlation
1996
cake
26
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Retrogradation
13
FTIR–ATR, XRD, DSC, XRD, and NMR similarly reflected the extent of retrogradation of
Ambigaipalan
CP/MAS
DSC, enzyme
pulse starches, while NMR, FTIR-ATR, and enzyme susceptibility
et al., 2013
susceptibility (α-
methods had a different pattern
C
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Pulse starches
amylase)
Cassava
Pulsed H
DSC, Instron
The glass transition temperatures measured by NMR were lower than
temperature
NMR
texture analyser,
those by DSC and other techniques by 20−30 oC (supplementary material al., 1992
DMTA
Fig. 3)
XRD
During initial stage of acid hydrolysis, double helix content from NMR
Atichokudomc
analysis was higher than the degree of crystallinity by XRD analysis.
hai et al., 2004
Degree of
13
C
Kalichevsky et
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crystallinity of acid- CP/MAS hydrolysed starch
SC
Glass transition
M AN U
Waxy maize
NMR
These two values became similar at later stages of hydrolysis
Degree of
1
H NMR
Degree of grafting of copolymers
Degrees of substitution for acetylated and hydroxypropylated starches
spectrophotometry measured by NMR agreed well with those measured from traditional
substitution
Maize
Traditional
13
C NMR
AC C
Potato
EP
(supplementary material Fig. 9) de Graaf et al., 1995
-based method a
methods. 1H-NMR-based method required much less time
Hydrolytic
Degree of grafting of starch measured by a hydrolytic method agreed well Gurruchaga et
Method
with that of the NMR method
al., 1992
27
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HPSEC, High-performance size-exclusion chromatography; XRD, wide-angle X-ray diffraction; DSC, differential scanning calorimetry; FTIR–
41
ATR, Fourier transform infrared spectroscopy-attenuated total reflectance; a, Johnson method and a titration-based method
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40
42
AC C
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SC
43
28
ACCEPTED MANUSCRIPT Applications of NMR spectroscopy in starch research are summarized
•
NMR spectroscopy probes structural basis of physical behaviours of starch systems
•
Various types of NMR techniques reveal different aspects of starch structures
•
Results of NMR spectroscopy correlate well with those of other analytical methods
AC C
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SC
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•