Pasting, thermal, morphological, rheological and structural characteristics of Chenopodium (Chenopodium album) starch

Accepted Manuscript Pasting, thermal, morphological, rheological and structural characteristics of Chenopodium (Chenopodium album) starch Romee Jan, D.C. Saxena, Sukhcharn Singh PII:

S0023-6438(15)30258-9

DOI:

10.1016/j.lwt.2015.10.040

Reference:

YFSTL 5035

To appear in:

LWT - Food Science and Technology

Received Date: 22 June 2015 Revised Date:

13 October 2015

Accepted Date: 17 October 2015

Please cite this article as: Jan, R., Saxena, D.C., Singh, S., Pasting, thermal, morphological, rheological and structural characteristics of Chenopodium (Chenopodium album) starch, LWT - Food Science and Technology (2015), doi: 10.1016/j.lwt.2015.10.040. 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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Pasting, thermal, morphological, rheological and structural characteristics of Chenopodium

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(Chenopodium album) starch.

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Romee Jan*, D. C. Saxena and Sukhcharn Singh

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* Corresponding author

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Academic Affiliation:

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Department of Food Engineering and Technology,

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Sant Longowal Institute of Engineering & Technology

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Longowal, Sangrur, Punjab, INDIA

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Email: [email protected]

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Phone: 91-01672-253705

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Fax: 91-01672-280057

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Pasting, thermal, morphological, rheological and structural characteristics of

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Chenopodium (Chenopodium album) starch.

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Romee Jan*, D. C. Saxena and Sukhcharn Singh

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Abstract

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Chenopodium album is an annual fast-growing underutilized pseudo cereal with high percentage

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of s t a r c h c o n t e n t . The aim of present study was to analyze the isolated starch for

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its physicochemical, morphological, pasting, thermal, rheological and FTIR spectrometric

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characteristics. Amylose content of C. album V1 a n d C. album V2 starches was f o u n d

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16.75g/100g and 19.11g/100g. The starch showed polygonal s h a p e a n d granule size w a s

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f o u n d t o v a r y from 1.021 to 1.033 µm, respectively. P e a k gelatinization temperature

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(Tp) for C. album V1 was found to be 63.20°C while for C. album V2 it was 61.05°C. Peak

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viscosity of the starch varied from 1812 cP for C. album V1 to 4012 cP for C. album V2,

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respectively. Thus C. album starch showed higher paste viscosity and unique viscoelastic

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behavior that might enhance their potential usage in different product formulations. FTIR

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spectrometric analysis revealed almost similar structural components within C. album V1 and C.

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album V2 starches. However, morsel variability was observed with Amaranthus starch.

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Key words: Chenopodium, Amaranth, Starch, Dynamic rheology, physicochemical properties.

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1. Introduction

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Chenopodium album belongs to the family chenopodiaceae with Chenopodium as the

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generic name and grows as an annual wild plant at an altitude of 4,700 meters above sea level.

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The plant is cultivated widely in Europe, North America, Iran and Asia with Western

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Rajasthan, Kulu and Shimla acting as the prominent cultivators of the crop within the India.

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The weedy plant is known as “pigweed” in English while as its popular Hindi name is

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“Bathua”. The plant is relatively inexpensive, commonly available in India during summer

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and winter seasons in the fields of wheat, barley, mustard and gram. The seeds generally go

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to waste due to non availability of processing techniques for the crop. The valuable

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underutilized pseudo-cereals like the Chenopodium are regarded like the true cereals, rich

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in mealy material enabling their elaborative utilization in different types of flour, bread,

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noodles and other starch related products. The starch from Chenopodium can be isolated in

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saponin-free form. The main constituent of grain is the small sized (< 1 µm) starch granule

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with an amylose content of about 11% that creates unique applications in food industries and

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being a major constituent of grains it can confer to structure, texture, consistency and appeal

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to many food systems (Lorenz, 1990).

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Studies on new natural starches are essential for their best use and also to increase the

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utilization of starchy flours. A growing demand for starch from the food industry has created

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the need for new sources of this polysaccharide. The research on separation and

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characterization of starch from Chenopodium album grain is scanty and these grains c a n

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b e e x p l o r e d a s a new source of starch for various food formulations. However keeping

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in view of above, the present study aims to explore the pasting, thermal, morphological,

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rheological and structural properties of the starch extracted from different cultivars of

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Chenopodium album and compared to the starch isolated from other pseudocereal.

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2. Materials and methods

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2.1. Raw Material

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The grains of C. album (V1) are not commonly available in market. Hence, the grains of

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C. album var. IC415477 (V1) were procured from National Bureau of Plant Genetic

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Resources (NBPGR), Shimla, Himachal Pradesh, India. The grains of C. album var. local

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Punjab (V2) and Amaranthus cholai var. local Punjab (V3) was locally procured. The samples

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were analyzed for carbohydrate and protein by standard methods of analysis AOAC (992-23,

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1995).

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2.2. Isolation of starch

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The starch was isolated from different cultivars using the pre-standardized process of

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starch extraction. Grains (100g) were steeped in 100 ml of NaOH (0.25g/100ml) at 4°C for

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24h. The supernatant was decanted, and fresh volume of sodium hydroxide was added to the

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solid part and stirred for another 1h at ambient temperature, double deionized water was used

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during steeping. The steeped grains were ground in a grinder (wet grinding) and the paste

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obtained was mixed with (1:5 ratio) water to form the slurry. The slurry was filtered through

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200, 300 and 400 mesh sieve, respectively. The filtrate was centrifuged at 3830 x g for 10

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min. The process of washing and centrifugation were repeated six times until the white

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starchy layer was obtained. The starch was dried for 6h at 40°C and passed through a mesh of

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100 BSS (149 µm).

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2.3. Physicochemical properties 2.3.1. Color determination 4

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The color values of starches from three varieties was measured using Hunter colorimeter (Model

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I5 Green Macbeth, USA) in terms of lightness (L*). Whiteness index (WI) was calculated

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according to Chin-Lin Hsu, Wenlung Chen, Yih-Ming Weng & Chin-Yin Tseng, (2003) as per the

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following equation:

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 = 100 − (100 − )² + ² + ²

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where: L, a, and b were Hunter L, a, and b values.

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2.3.2. Amylose content

Amylose content of the samples was examined by the method of Morrison & Laignelet,

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(1983). Starch sample of 70mg was mixed with 10 ml of urea and DMSO (Dimethyl Sulfoxide)

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solution in 1:9 ratio and heated for 10 min at 100 °C with continuous stirring. The mixed

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sample was incubated at 100°C for 1 h and then cooled to room temperature. Addition of 0.5

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ml solution of above mixed incubated sample was taken with subsequent addition of 25 ml

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distilled water and 1 ml solution of iodine (I) and potassium iodide (KI). Blank sample was also

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prepared and absorbance was taken at 635nm.

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  (%) = (28.414 × ! " !)- 6.218

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Where blue value (BV) is the absorbance at 635nm of starch and I2/KI solution. 2.3.3. Swelling power and solubility

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The procedure of Bello-Perez, Acevedo, Zamudio-Flores, Mendez-Montealvo, &

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Rodriguez- Ambriz, (2010) with few modifications was used for determination of

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swelling power and solubility of starches. These were determined over a temperature

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range of 55 to 95°C. Starch slurry (2g/100ml, starch dry basis) in centrifuge tubes was

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heated at 55, 65, 75, 85 and 95°C for 30 minutes. The tubes after cooling were centrifuged at

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112 x g for 20 min. (C24, BL; M/s. Remi Laboratory Industries, Mumbai, India). The

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supernatant was carefully decanted in petriplates, evaporated and dried at 105°C for 5 h

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till constant weight is achieved and were weighed to calculate the g/100g Solubility. The

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residue was weighed for swelling power estimation. The experiment was conducted in

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triplicates. Swelling power and solubility was calculated as:
%&ℎ *+% ,  (&)
%&ℎ *  , (+(  %, &)

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%&ℎ * !(&) × 100
%&ℎ *  , (+(  %)

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2.4. Pasting properties

The pasting properties of the starches were evaluated with the Rapid Visco Analyser

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(RVA, Starch Master TM; Model N17133; Newport Scientific Pvt. Ltd., Warriewood,

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Australia). A programmed heating and cooling cycle was used, where the samples were held

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at 50 °C for 1 min, heated to 95°C at 12°C /min, held at 95 °C for 2.5 min, before cooling

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from 95 to 50°C at 12°C /min and holding at 50°C for 2 min. Parameters recorded were

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pasting temperature, peak viscosity, final viscosity (viscosity at 50°C), breakdown

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viscosity (peak trough viscosity) and setback viscosity (final trough viscosity).

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2.5. Thermal properties

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The gelatinization characteristics of the starches were studied using a differential

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scanning calorimeter (DSC-7, PerkinElmer, and Norwalk, CT). Starch (2 mg, dry basis)

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was loaded into aluminum pan and distilled water was added to achieve a starch – water

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suspension containing 70g/100g water. Samples were hermetically sealed and allowed to

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equilibrate for 1 h at room temperature before analysis. The DSC analyzer was calibrated

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using indium and the sample pans were heated at a rate of 10°C/min from 20 to 6

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° 140 C. The t em p eratu re at t h e on s et o f gelatinization (To), at the peak (Tp), at

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conclusion the (Tc) and the enthalpy (∆H) were calculated automatically (Sandhu & Singh,

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2007).

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2.6. Rheological properties

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Dynamic rheology of starches was analyzed wherein temperature sweep oscillatory test

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was performed with Modular Compact Rheometer (MCR102, M/s. Anton Paar, Austria),

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equipped with parallel plate system (50 mm diameter) and PP50-SN32770 (dia.=0.5 mm)

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probe. The gap size was set at 0.5 mm; strain and frequency was set to 0.5% and 1 Hz,

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respectively. About 2 ml of starch suspension (20g/100g) was loaded on the ram of

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Rheometer and the edge of sample was covered with a thin layer of low density silicon

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oil to minimize evaporation losses. The starch sample was subjected to temperature sweep

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test with a temperature ramp from 50 to 90°C at a heating rate of 2°C/min. The dynamic

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rheological properties of starches in terms of storage modulus (G'), loss modulus (G")

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and loss factor (tan δ) were determined as a function of temperature.

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2.7. Morphological properties

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The granule shape as a major morphological characteristic of the sample was analyzed

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at a moisture content of 5-6 g/100g. Scanning electron micrographs (SEMs) were taken

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with a JEOL, Tokyo, Japan, Model No.JSM 6610LV. The Starch samples were mounted

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on aluminum stub using a double backed cellophane tape, coated in auto finer coater,

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JEOLJFC1600, with gold palladium (60:40, g:g). The starch samples were examined at

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magnifications of 5000 and 10000X.

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2.8. X-ray Diffraction Analysis

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The crystallinity of the powdered starch samples was determined using an X-ray

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diffractometer, PAN analytical, Phillips, Holland, Model No. X‟ Pert PRO with the

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following conditions: target

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0.5°/min. Origin Pro software package was used for determining the total area under the

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curve and the area under each prominent peak. The percentage crystallinity was calculated

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using formula below:

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(( !+( , /) × 100 0  (

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Cu-anode X-ray, 30 kV, 40 mA and scanning speed of

2.9. FTIR spectroscopy

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Infrared spectra were recorded using an Agilent Technologies Cary 660 FTIR spectrometer.

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The samples were analyzed by preparing KBr pellets using anhydrous potassium

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bromide. The proportion of sample was taken as 1:15 g/g of KBr and the granular

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mixture were ground vigorously in a pestle mortar until pulverized into fine powder.

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Small quantity of this powder was carefully put into pellet-forming mould, pressed under

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hydraulic pressure and then used for obtaining I R s p e c t r u m . The IR region measured was

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between 4000 cm-1 and 400 cm-1 representing the average of 64 scans. All spectra’s were

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recorded at room temperature under ambient conditions

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2.10. Statistical evaluation

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All the analysis were determined in triplicates and Statistical analysis was performed using

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Statistica-log software package version 7 (M/s.

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significant differences were obtained by a one-way analysis of variance (ANOVA)

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followed by Duncan’s multiple range test (DMRT) at significance level of P<0.05.

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3. Results and discussion

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StatSoft Inc., OK, USA).

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The carbohydrate content of C. album V1 and C. album V2 was found 51.18 and 53.65

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g/100g, while protein content of C. album V1 and C. album V2 was 13.83 and 13.12

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g/100g, respectively.

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3.1. Starch yield, purity and color value

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The starch yield, purity and color values of C. album V1, C. album V2, and A. cholai V3

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starches are s h o w n i n T a b l e 1 .Significant variation (p<0.05) in yield of starches was

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observed among C. album V1, C. album V2 and A. cholai V3, respectively. This variation in

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observed yield may be due to the varietal difference among the sources used for

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extraction. Purity of starches was observed in the range of 99.12 to 99.65 g/100g. However,

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significant differences were not observed in the purity of C. album V1 and C. album V2

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starch. While significantly highest purity was noted in A. cholai V3 starch. This might be

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due to the compositional changes (protein, fat and fiber content) of the starches. The L*

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value of extracted starches varied significantly (p≤0.05) from 95.95 to 96.83. While as the

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whiteness of the starches ranged from 94.14 to 94.61, respectively. Lowest L*

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value was observed for C. album V1 starch and the highest value was observed for A.

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cholai V3. H o w e v e r higher w h i t e n e s s w a s o b s e r v e d for A. cholai V3 starch

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a n d l o w e r w h i t e n e s s w a s n o t i c e d f o r C. album V1 starch. The observed

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values of lightness were found greater than 90, which gives a satisfactory whiteness for

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starch purity as reported previously by Boudries et al., (2009).

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3.2. Physico-chemical properties of starch

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3.2.1. Amylose content

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Amylose content of C. album starches differ significantly (p ≤ 0.05) with higher mean value

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of 19.11 g/100g in C. album V2 followed by 16.75 g/100g in C. album V1 (Table 1).

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Amylose content affects the functional and physicochemical properties of starch, including

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its pasting, gelatinization, retrogradation and swelling characteristics ( Svegmark,

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Hel m ers s o n , Nilsson, Andersson, & Svensson, 2002). Also the factors such as botanical

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sources, climatic conditions, harvest time and different types of soil during cultivation

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affects the variability in amylose and amylopectin ratio within the same specie (Noda et al.,

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2004).

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3.2.2. Swelling power and solubility

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Swelling power of the C. album V2 starch ranged from 1.5 to 1.48 g/g, where as solubility

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varied from 6.66 to 60.0 g/100g within the temperature range of 55 to 95°C, as shown in

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Figure 1(a) and (b). While in case of C. album V1 and A. cholai V3, the swelling power was

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found to be 1.63 to 1.85 g/g and 2.85 to 8.41g/g, whereas the solubility values ranged from

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5.0 to 50 g/100g and 4 to 36 g/100g, respectively. The trend showed by the curves related to

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swelling power and solubility of starches was found similar upon increase in the

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temperature. C. album V1 and C. album V2 starches showed similar increasing trend in

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early hours of heating that changed towards the decreasing trend thereafter in late periods

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of the study. Starch aqueous suspension when heated above gelatinization temperature

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results in the distraction of starch crystalline structure and exposure of water molecules to

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hydroxyl groups of amylose and amylopectin through hydrogen bonding, resulting in

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swelling of starch molecules, and increased solubility due to leaching of some soluble

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starch into liquid. A strongly bonded micellar structure of the starch granule may render it

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relatively defiant to swelling, also Sasaki, Yasui, Matsuki, & Satake, (2003) suggested

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that amylose reinforced the internal network within the granule that restricts the swelling

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and the waxy starch swell to a greater extent than normal amylose starch. Contrarily to it A.

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cholai V3 showed a significantly different behavior whose starch granules continued to

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swell with further increase in temperature as shown in Figure 1(a) & (b). It might be due to

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the presence of low amylose content in A. cholai V3 starch, as reported by Tester &

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Morrison, (1990) that amylose dominates the solubility of starch whereas amylopectin

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mainly influences the starch swelling power. Thus the ratio of amylose and amylopectin in

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the starch granule and the way in which they are arranged inside the granule affect the

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swelling and solubility of the starch.

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3.2.3. Pasting properties

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Pasting properties provide imminent information about the cooking behavior of starches

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during heating and cooling cycles. Viscosity of starches was found to increase with an

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increase in temperature with the C. album V2 exhibiting significantly higher peak viscosity

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(PV) (4012cP) in comparison to C. album V1 and A. cholai V3 starches. Peak viscosity is

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regarded as the maximum viscosity attained by the sample and tendency of starch

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granules to swell freely before physical breakdown.

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increase in temperature may be accredited to the removal of water from the exuded

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amylose of granules as they swell (Ghiasi, Marston & Hoseney, 1982). Pasting temperature

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is the minimum temperature required to cook the starch. C. album V2 starch showed a lower

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pasting temperature of 76.65°C than C. album V1 and A. cholai V3 starches. The high

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pasting temperature of starch indicates the higher resistance of starch granules towards the

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swelling. The break down viscosity (BD) and set back viscosity values (SV) of starch

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paste varied significantly (p ≤ 0.05) with respective mean values of 331cP and 1190cP for

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C.album V2 starch which was found to be higher than A. cholai V3 and lower than C.

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album V1 starch.

The increase in viscosity with

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Breakdown viscosity, measure of resistance of starch paste to heat and shear, indicates the

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stability of the paste and Setback reflects the degree of retrogradation that is

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expected to correlate positively with the amylose content of starch (Abdel-Aal, Hucl,

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Chibbar, Han, & Demeke, 2002). Final viscosity indicates a gelling tendency that gives an

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insight of stability to cooled-cooked starch paste under low shear. C. album V2 showed a

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higher final viscosity (FV) of 4871 cP followed by C. album V1 and A. cholai V3 as shown

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in Table 2. The viscosity of C. album V2 and C. album V1 continued to ascend quite sharply

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on cooling as compared to A. cholai V3 which may be attributed to the higher amylose

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content and water binding capacity of these starches.

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3.2.4. Thermal properties

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Thermal transition temperatures (To, Tp, Tc) along with enthalpy of gelatinization (∆H gel)

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and gelatinization temperature range (TR = Tc-To) are presented in Table 2. C. album

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V2 starch showed significantly (p ≤ 0.05) lower To, Tc and ∆H gel values of 41.75, 63.87°

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C and 12.81 J/g, respectively, in contrary to the higher range observed in C. album V1

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and A. cholai V3 starch. The lower gelatinization temperatures of starch indicated lesser

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energy usage requirement to instigate starch gelatinization and vice versa. Fredriksson,

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Silverio, Anderson, Eliasson, & Aman, (1998) reported starch crystallinity increases with

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amylopectin content and for this reason; higher amylopectin content containing starches

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(i.e. lower amylose content) would be expected to have higher onset, peak, and

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conclusion temperatures. Furthermore starches from various botanical sources diverge in

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compositions that reveal different transition temperatures and gelatinization enthalpies

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(Singh, Singh, Kaur, Sodhi, & Gill, 2003). The values of thermal transitions are in close

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conformity with the annotations of thermal values observed by Steffolani, Leon, & Perez,

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(2013).

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3.2.5. Morphological characteristics

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The scanning electron micrograph of the starches has revealed that the starch granules

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are polygonal and angular in shape. Morphological examination of the starches showed the

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varying size of starch granules with average granule size of 1.021 µm and 1.033 µm found

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in C. album V2 and C. album V1, respectively. Microscopic observations (Figure. 2, A-

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C) of the starch samples reveal the established organization of starch granules in form of

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clusters, which may be due to the aggregation of starch granules natively in the starchy

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perisperm. The size and shapes of the observed granules are in close agreement with

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Villarreal, Ribotta, & Iturriaga, (2013).

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3.2.6. X-ray diffraction analysis

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The X-ray diffraction pattern of starches is shown in Figure 3. C. album V2 starch displayed

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“A”type diffraction pattern with peak intensities observed at 15.23, 17.13, 18.19 and 23.32°

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that are comparable with the findings of Manek et al., (2005) on cereal starches. C. album

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V1 and A. cholai V3 starches showed similar diffractograms as that of C . album V2

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starch. X-ray diffractometry has been used to reveal the presence and characteristics of the

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crystalline structure of the starch granules. The percentage starch crystallinity of C. album V2

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was found to be 29.58%, while as C. album V1 and A. cholai V3 starches showed an average

287

value of 37.47 and 33.88 %, respectively. The starch crystallinity varies with crystal size

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and amount of crystalline region, whereas the amylose chain is responsible for the

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amorphous region and orientation of double helices within the crystalline domain with

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degree of interaction involving double helices (Singh, McCarthy, & Singh, 2006).

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3.2.7. FTIR Spectroscopy

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Interpretation of the infrared (IR) absorption bands is achieved in the light of earlier

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investigation (Yadav, Mahadevamma, Tharanathan, & Ramteke, 2007). The IR spectra

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of starch samples exhibited bands that originate mainly from the vibrational modes of

295

amylose and amylopectin. Infra red spectral patterns of C. album V1 and C. album V2

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starches were found consistent to each other although spectra of A. cholai V3 starch

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powder was found to be up shifted in comparison to C. album V1 and C. album V2

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starches shown in Figure 4. The stretching frequency at about 3200 cm-1 to 3400 cm-

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were assigned to the O-H group for both C. album V1 and C. album V2 starches, while as

the hydroxyl peak for A. cholai V3 was found up shifted at 3552.166 cm-1due to the less

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significant hydrogen bonding.

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Similarly the peaks at 2931.329 cm-1 and 2886.590 are due to the symmetric stretching of

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C-H group and bands appearing at 2 3 6 1 . 1 6 3 c m - 1 are ascribed to the bending vibrational

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modes of glycosidic linkage. The absorption band at 1637.913 cm-1 in C .album V1 and C.

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album V2 is attributed to the O-H related vibration that indicate the inter and intra-

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molecular hydrogen bonding between the amorphous region of starch and water

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molecules. The above mentioned band appeared sharply at about 1652.052 cm -1 in case

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of A. cholai V3 which again confirms the absence of hydrogen bonding (O-H) in its starch.

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Besides this the A. cholai V3 starch showed a broad band of C=N and C=C asymmetric

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stretching due to presence of glycosidic linkage skeleton in the region of 1200-900 cm-1.

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The broad bands in the region of 800 cm -1 to 400 cm-1are bending vibrational modes of the

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glucose pyranose ring.

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3.2.8. Rheological properties

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The rheological properties of starches during heating are shown in Table 3. Storage modulus

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(G') and loss modulus (G") of C. album V1 and C. album V2 starch suspensions increased

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steeply to maxima and still tend to increase further with incessant heating indicating

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their granule resistance to deformation, whereas the parameters for A. cholai V3

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increased initially upon heating reaching a maximum and thereafter decreasing upon

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continuous heating. This reduction in G' and G'' values of A. cholai V3 may be due to the

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disintegration of starch granules leading to the melting of remaining crystallites and

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increasing the molecular mobility. The temperature (TG'max) of C. album V2 starch at

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which the storage modulus (G') loss modulus (G") reached the highest value was found to

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be 87.3°C which was found to be higher than A. cholai V3 but lower than the C. album V1

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starch (Table 3). This increase in both storage and loss moduli before T G'max is due to

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swelling of starch granules and leaching of amylose chains, contributing to the formation of a

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composite network of solvated materials supporting partially disintegrated starch granules

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(Arocas, Sanz & Fiszman, 2009; Hsu, Lu, & Huang, 2000). The G' value of 41,500 Pa, G''

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value of 7590 Pa was observed with a damping factor (Tan δ Peak) of 0.182 in C. album V2

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starch suspension. The variation in G', G'' and tan δ during heating cycle may be due to the

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difference in starch granule structure and its amylose content (Svegmark & Hermansson,

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1993). The results are in close proximity with the study of Kong, Kasapis, Bao, & Corke,

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(2012) on amaranth

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4. Conclusion

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The carbohydrate content of C. album varieties V1 and V2 was found to be 51.18 and

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53.65g/100g, respectively. The starch obtained was found 47.30 and 37.59g/100g being

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higher than A. cholai V3 with higher purity values of 99.12 and 99.20 g/100g,

starch

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respectively. Chenopodium starches showed lower swelling

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diameter, pasting temperature and gelatinization temperature, whereas higher values were

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noticed for amylose content, pasting viscosity and solubility when compared to A. cholai

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V3 starch. A typical A-type X-ray diffraction pattern with crystallinity of 29.58%, 37.47 %

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was found for C. album V1 and V2 starches. The C. album starches showed higher Peak

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G' and G" than A. cholai V3. The analysis of various properties of C. album starches will

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provide valuable information associated with the functional properties of starch, as desirable

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functional properties can be used in various food industries due to its impending

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applications for the development of various products viz., in high viscous foods, as a good

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gelling agent, in dessert and other food formulations and could replace chemically modified

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starches that are currently being used in a number of products. Moreover due to small

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granule size, starches may find wide applications in edible biodegradable films, as fat

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substitutes (due to smooth creamy structure), as a binder with orally active ingredients. The

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above all interesting and unique rheological

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beneficially exploited in the formulation of specialty food products.

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TABLE 1. PROXIMATE COMPOSITION AND FUNCTIONAL PROPERTIES OF CHENOPODIUM ALBUM RAW AND GERMINATED FLOUR Raw C.album flour 9.43b ±0.15 3.25a ±0.03 13.12b ±0.07 6.50a ±0.30 13.09b ±0.04 54.61a ±0.09 14.10b ±0.07

Germinated C.album flour 10.39a ±0.10 2.50b ±0.04 15.45a ±0.05 4.13b ±0.04 16.87a ±0.10 50.66b ±0.06 18.20a ±0.11

241b ±3.51 35.50b ±0.13 41.44a ±0.29

565a ±8.00 38.61a ±0.14 31.75b ±0.20

BD (g/ml) True density(g/ml) Porosity (g/100g) WAI (g/g) WSI (g/100 g) OAC (g/100 g)

0.59a ±0.06 1.30a ±0.10 54.70b ± 4.12 2.29b ±0.15

0.52a ± 0.06 1.36a ±0.10 61.80a ±2.68 3.55a ±0.18 9.60a ±0.70 2.81a ±0.11

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Parameter Moisture (g/100 g) Ash (g/100 g) Protein (g/100 g) Fat (g/100 g) Crude Fibre (g/100 g) Carbohydrate (g/100 g) DPPH radical scavenging activity (g/100 g) Total phenolics (mg/100g) Total dietary fibre (g/100 g) Total starch Functional properties

4.80b ±0.20

2.35b ±0.2

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TABLE 2. PASTING PROPERTIES OF CHENOPODIUM ALBUM FLOUR.

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Parameter Raw C.album flour Germinated C.album flour a Peak viscosity (cP) 925 ±15.01 863b ±25.50 Trough viscosity (cP) 887a ±12.05 645b ±7.54 a Breakdown (cP) 32 ±1.04 21b ±1.82 a Final viscosity (cP) 1412 ±21.50 1351b ±16.00 Setback (cP) 510a ±18.00 451b ±17.52 ° a Pasting temperature ( C) 86.45 ±2.41 84.83a ±0.58 Mean values in the same row which is not followed by the same letter are significantly different (p < 0.05). Mean ± standard deviation (n=3).

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TABLE 3. PHYSICAL, TEXTURAL PROPERTIES AND LIGHTNESS VALUES OF COOKIES Parameter *Wheat flour cookies Raw C. album flour Germinated C. (control) cookies album flour cookies b b Weight (g) 12.80 ±0.05 13.04 ±0.36 14.43a ±0.49 b b Thickness (mm) 7.03 ±0.07 7.49 ±0.50 8.21a ±0.33 Diameter (mm) 50.72b ±0.06 54.37a ±0.52 54.76a ±0.89 a a Spread ratio 7.21 ±0.03 7.25 ±0.65 6.66a ±0.84 Hardness (N) 92.25a ±5.98 49.30b ±6.55 44.43b ±13.07 a c L* value 65.20 ±2.22 42.00 ±1.10 36.60b±1.04 *Chauhan et al., 2015 Mean values in the same row which is not followed by the same letter are significantly different (p < 0.05). Mean ± standard deviation (n=3).

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TABLE 4. ANTIOXIDANT ACTIVITY, TOTAL PHENOLICS AND TOTAL DIETARY FIBRE OF COOKIES. Parameter *Wheat flour cookies Raw C. album flour Germinated C. (control) cookies album flour cookies c b DPPH radical 16.42 ±0.17 19.44 ±0.52 23.97a ±0.35 scavenging activity (g/100 g)/(TAC) Total phenolic NA 323b±3.44 671a± 5.60 Content(TPC) (mg/100g) Total dietary fibre 10.70c ±0.11 35.85b ±0.87 38.77a ±1.39 (g/100 g) *Chauhan et al., 2015 Mean values in the same row which is not followed by the same letter are significantly different (p < 0.05). Mean ± standard deviation (n = 3).

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TABLE 5. SENSORY ANALYSIS OF COOKIES. *Wheat flour cookies Raw C. album flour Germinated C. (control) cookies album flour cookies a a Color & appearance 7.25 ±0.50 6.50 ±0.75 6.75a ±0.22 a a Aroma 7.00 ±0.60 7.25 ±0.50 7.75a ±0.36 Taste 7.00a ±0.40 7.00a ±0.25 7.75a ±0.11 a b Mouth feel 7.50 ±0.77 6.75 ±0.25 7.25ab ±0.22 Texture 6.50b ±0.75 7.00ab ±0.38 7.50a ±0.12 ab b Overall acceptability 6.75 ±0.50 6.50 ±0.75 7.75a ±0.20 *Chauhan et al., 2015 Mean values in the same row which is not followed by the same letter are significantly different (p < 0.05). Mean ± standard deviation (n=3).

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Figure 2. SEM micrographs of starches: (A1, A2) top two images representing C. album (V2) at magnification level of 5000 x and 10000 x. the middle two micrographs (B1, B2) belong to C. album (V1) at 5000 x and 10000 x, while the last two micrographs (C1, C2) are from A. cholai (V3) at 5000 x and 10000 x.

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Figure 4. FTIR spectrometric analysis of starch acquired from C .album (V1), C .album (V2) and A. cholai (V3).

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Highlights

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Smaller starch granule with higher paste viscosity and solubility was observed. Lower gelatinization temperature of starch with high degree of crystallinity. Unique viscoelastic behaviour and FTIR analysis of the starch were observed. The obtained starch can be a used as a replacement for chemically modified starches May find application in development of newer product formulations.

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