processes

Article

Effects of Spray-Drying Inlet Temperature on the Production of
High-Quality Native Rice Starch

Jamie Boon Jun Tay 1,† , Xinying Chua 2,†, Cailing Ang 3, Gomathy Sandhya Subramanian 4, Sze Yu Tan 4,
Esther Marie Jierong Lin 4, Wen-Ya Wu 4, Kelvin Kim Tha Goh 3,* and Kaiyang Lim 1,*

����������
�������

Citation: Tay, J.B.J.; Chua, X.; Ang,

C.; Subramanian, G.S.; Tan, S.Y.; Lin,

E.M.J.; Wu, W.-Y.; Goh, K.K.T.; Lim, K.

Effects of Spray-Drying Inlet

Temperature on the Production of

High-Quality Native Rice Starch.

Processes 2021, 9, 1557. https://

doi.org/10.3390/pr9091557

Academic Editor: César Ozuna

Received: 22 July 2021

Accepted: 27 August 2021

Published: 31 August 2021

Publisher’s Note: MDPI stays neutral

with regard to jurisdictional claims in

published maps and institutional affil-

iations.

Copyright: © 2021 by the authors.

Licensee MDPI, Basel, Switzerland.

This article is an open access article

distributed under the terms and

conditions of the Creative Commons

Attribution (CC BY) license (https://

creativecommons.org/licenses/by/

4.0/).

1 Chemical Engineering and Food Technology Cluster, Singapore Institute of Technology, 10 Dover Drive,
Singapore 138683, Singapore; jamietay97@gmail.com

2 Nagase Singapore Pte Ltd., 600 North Bridge Road, #11-01 Parkview Square, Singapore 188778, Singapore;
Xinying.chua@nagase.com.sg

3 School of Food and Advanced Technology, Massey University, Private Bag 11222, Palmerston North 4442,
New Zealand; C.Ang@massey.ac.nz

4 Institute of Materials Research and Engineering (IMRE), A*STAR, 2 Fusionopolis Way, Innovis,
Singapore 138634, Singapore; subramaniang@imre.a-star.edu.sg (G.S.S.); tansy@imre.a-star.edu.sg (S.Y.T.);
linem@imre.a-star.edu.sg (E.M.J.L.); wuwy@imre.a-star.edu.sg (W.-Y.W.)

* Correspondence: K.T.Goh@massey.ac.nz (K.K.T.G.); Kaiyang.Lim.John@gmail.com (K.L.)
† Co-first authors, these authors contributed equally to this work.

Abstract: Rice starch is a common functional ingredient used in various food applications. The drying
regime to obtain dry starch powder is an important processing step, which affects the functional
properties of the starch. The application of extreme thermal treatment during the conventional
drying process tends to elicit irreversible changes to the rice starch, resulting in the loss of desired
functionalities. In a previous study, we reported the development of a novel low temperature spray-
drying based process which efficiently dries waxy rice starch, while preserving its physicochemical
properties and functionalities. This study, a follow-up to the previous report, evaluated the effect of
different spray-drying inlet temperatures on the production yield, physicochemical properties, and
functionalities of waxy rice starch. Increasing the inlet temperature from 40 ◦C to 100 ◦C resulted
in an increase in the process yield from 74.83% to 88.66%, respectively. All spray dried waxy rice
starches possessed a low moisture content of less than 15%, and a consistent particle size (median
~6.00 µm). Regardless of the inlet temperatures, the physicochemical functionalities, including
the pasting characteristics and flowability, were similar to that of the native waxy rice starch. The
molecular and A-type crystalline structure of the waxy rice starches were also conserved. An inlet
temperature of 60 ◦C represented the optimum temperature for the spray-drying process, with a
good yield (84.55 ± 1.77%) and a low moisture content (10.74 ± 1.08%), while retaining its native
physicochemical functionalities and maximizing energy efficacy.

Keywords: waxy rice starch; spray drying; physicochemical properties; pasting behavior; particle
size; crystalline structure

1. Introduction

Rice starch is a common food ingredient with beneficial functionalities, including
thickening, stabilizing, and gelling capabilities [1]. Rice starch is used in a wide range of
food applications, including poultry products, confectionery, baked goods, soups, and
sauces [2].

Preparation of rice starch begins with milling of the rice into fine rice flour. The
milled flour then undergoes an alkaline steeping treatment to remove the majority of the
proteins (<1.5%), deriving the rice starch [3]. The rice starch finally undergoes drying in
order to obtain the final starch powder [1]. The choice of drying methodology is crucial in
determining the yield and functionalities of the final rich starch product.

Processes 2021, 9, 1557. https://doi.org/10.3390/pr9091557 https://www.mdpi.com/journal/processes

https://www.mdpi.com/journal/processes
https://www.mdpi.com
https://orcid.org/0000-0002-6124-3685
https://orcid.org/0000-0003-4800-9381
https://doi.org/10.3390/pr9091557
https://doi.org/10.3390/pr9091557
https://creativecommons.org/
https://creativecommons.org/licenses/by/4.0/
https://creativecommons.org/licenses/by/4.0/
https://doi.org/10.3390/pr9091557
https://www.mdpi.com/journal/processes
https://www.mdpi.com/article/10.3390/pr9091557?type=check_update&version=1


Processes 2021, 9, 1557 2 of 16

Commonly-employed drying processes include drum drying [4], oven drying [5] and
flash drying [6]. However, due to exposure to prolonged and high thermal conditions of
these drying processes, the physicochemical properties of the resultant rice starches may be
modified, resulting in a loss of functionalities of the native rice starch [6–8]. Spray drying
represents a possible alternative drying strategy to process rice starch, while retaining
its native physicochemical properties and functionalities [9]. Spray drying is different
from most drying methods in which the starch is first dried to form a dried starch cake
before pulverizing it to powder format. Instead, spray drying first atomizes the starch
suspension into small droplets before drying. Using a dual fluid nozzle, the sample and
air are pushed through a small orifice at high pressure, breaking up the starch suspension
into fine droplets. These droplets then fall through the drying chamber, together with hot
air flowing in a co-current fashion, thoroughly drying the droplets in the process. The
dried starch powder is separated in the subsequent cyclone and retrieved in the collection
chamber [10]. Due to its mechanism, the spray drying process offers various advantages,
including continuous processing, uniform particle quality and lower exposure to thermal
conditions. In a previous study, we demonstrated the feasibility of using a low-temperature
spray-drying process to effectively dry rice starch [11]. Following our previous report, this
study examined the effect of the spray-drying inlet temperature on the resultant waxy rice
starch. This study aimed to provide meaningful insights into the impact of the spray-drying
inlet temperature on the physicochemical properties of the starch, as well as assessing the
optimum inlet temperature for spray drying waxy rice starch. These findings substantiate
the data from our previous study and show the benefits of using the spray dryer as an
effective drying methodology to produce waxy rice starch powder.

2. Materials and Methods
2.1. Materials

The waxy rice flour (Erawan, Cho Heng Rice Vermicelli Factory Co. Ltd., Nakhon
Pathom, Thailand) used for the experiments was procured from a local supermarket (Fair-
price, Singapore). Chemicals and reagents were purchased from Sigma-Aldrich (Singapore),
unless otherwise stated.

2.2. Protein Extraction

Protein extraction of the milled waxy rice flour was carried out using an established
alkaline steeping method [1]. The waxy rice flour was incubated in 0.1% (w/v) sodium
hydroxide (NaOH) with continuous stirring at 500 rpm for 18 h, under atmospheric
conditions (25 ◦C). The rice flour to NaOH ratio was maintained at 1:2 (v/v). The resulting
suspension was centrifuged (5430R, Eppendorf, Hamburg, Germany) at 2000× g for 5 min
(20 ◦C) and the separated protein layer was removed by manual scraping. Subsequently, the
starch was resuspended in deionized water. The pH of the waxy rice starch suspension was
adjusted to pH 6.50, using 1.0 M hydrochloric acid (HCl). The resulting starch suspension
was washed thrice with a copious amount of deionized water in order to remove any
remnant salt. Finally, the starch solution was kept at 4 ◦C overnight (18 h) in preparation
for the subsequent drying processes. The starch solution before drying is assumed to be
the native waxy rice starch and is denoted as “Before Drying” in the rest of the study.

2.3. Spray Drying

The waxy rice starch dispersion (20% w/w solid content) was spray dried using a
lab-scale spray dryer (B-290, Buchi, Flawil, Switzerland), attached with a dehumidifier
(IDFA3E, SMC Pneumatics, Tokyo, Japan). The inlet temperature varied from 40 ◦C to
100 ◦C, with other process parameters, such as the aspiration rate (100%), feed flowrate
(4 mL/min) and air flow rate (601 L/h, pressure drop of 0.75 bar), maintained constant. In
the subsequent sections, the waxy rice starches that are spray dried at an inlet temperature
at 40 ◦C, 50 ◦C, 60 ◦C, 70 ◦C, 80 ◦C and 100 ◦C are denoted as “SP 40”, “SP 50”, “SP 60”,
“SP 70”, “SP 80” and “SP 100” respectively.



Processes 2021, 9, 1557 3 of 16

2.4. Physicochemical Properties of Waxy Rice Starch

All spray dried waxy rice starch powders were subjected to various characterization
techniques. The techniques used are detailed in the following sections.

2.4.1. Moisture Content Analysis

The moisture contents of the respective starch samples were determined using a
halogen lamp moisture analyzer (Hal. Moisture Analyzer HE53, Mettler Toledo, Columbus,
OH, USA). An amount of 1.50 g of starch powder was weighed on a disposable aluminum
pan and dried at 140 ◦C using the rapid setting. The moisture content was presented in
terms of the percentage of moisture content.

2.4.2. Kjeldahl Method

The protein contents of the respective waxy rice starches were determined using
Kjeldahl method (VAP450, Gerhardt Analytical Systems, Königswinter, Germany). An
amount of 1.0 g of starch powder, along with 12 mL of concentrated sulfuric acid and
2 Kjeltabs, were added into Kjeldahl digestion tubes. The mixture was subsequently
subjected to digestion at 230 ◦C for 15 min, before being cooled to room temperature
(~25 ◦C) in a fume hood. The reaction mixture was subsequently distilled and auto-titrated
with 0.1 M hydrochloric acid (HCl) and 2% boric acid solution. The ammonia content was
evaluated by determining the corresponding amount HCl utilized for the neutralization
process. Based on the ammonia content, a conversion factor of 5.95 was used to calculate
the protein content in the resultant waxy rice starch.

2.4.3. Process Yield

The process yield from the spray-drying process is calculated, based on the following
formula:

processyield =
weightofspraydriedstarch (g) (100−moisture content ofspray dried starch)

100

weightofstarchsuspension (g) (100−moisture content starch suspension)
100

× 100% (1)

2.4.4. Particle Size Analysis

The particle size of the waxy rice starches was measured using a particle size analyzer
(Mastersizer 3000, Malvern Panalytical, Malvern, UK). A starch suspension with a solid
content of 5.0% (w/w) was prepared at room temperature (~25 ◦C) and pipetted into the
laser diffraction particle size analyzer dispersion tank until a final obscuration within the
range of 5–7% was attained. A sonication protocol (30%, 120 s) was implemented in order
to break up loose starchz agglomerates before subjecting the starch dispersion to particle
size analysis. The particle size distribution, surface-weighted diameter (D[3,2]) and particle
size distribution were obtained. All parameters were defined based on Mie Theory with
refractive index set as 1.53.

2.4.5. Density and Flowability Analyses

Bulk densities of the spray-dried waxy rice starches were measured by adding 5.0 g of
the respective starch into a graduated measuring cylinder before the initial volume was
recorded. The tapped density was determined by subjecting the starch in the measuring
cylinder to mechanical tapping for 500 repetitions (Autotap, Quantachrome Instruments,
Gras, Austria). The bulk and tapped densities were derived based on the volume of the
starch before and after tapping. The bulk density and tapped densities were calculated
using the following equations:

Bulk density
( g

cm3

)
=

Weight of starch (g)
Initial volume (cm3)

(2)



Processes 2021, 9, 1557 4 of 16

Tapped density
( g

cm3

)
=

Weight of starch (g)
Tapped volume (cm3)

(3)

The Hausner Ratio (HR) and Carr’s Index were subsequently determined as an
empirical number to indicate the flowability of the starches. HR and Carr’s Index were
determined using the following equations:

Hausner Ratio (HR) =
Tapped density

Bulk density
(4)

Carr’s Index (%) =

(
1− Bulk density

Tapped density

)
× 100% (5)

2.5. Pasting Profiles

Pasting properties of the waxy rice starches were analyzed using a rheometer (MCR
102, Anton Paar GmbH, Gras, Austria), installed with a starch cell (C-ETD160/ST, Anton
Paar GmbH, Gras, Austria) and spindle geometry (ST-24-2D/2V/2V-30, Anton Paar GmbH,
Gras, Austria). An appropriate amount of the respective spray-dried waxy rice starch was
weighed and hydrated in deionized water in order to form a final starch suspension with a
solid content of 5.0% (w/w). The starch solution was pre-stirred at 500 rpm for 30 min at
atmospheric conditions (~25 ◦C) using a benchtop stirring plate (Hei-Connect, Heidolph,
Schwabach, Germany). The starch suspension was subjected to pasting analysis. The
starch was then preheated from 20 ◦C to 50 ◦C at an accelerated heating rate of 4 ◦C/min.
Subsequently, a second controlled heating phase was applied during which the temperature
of the suspension was raised gradually, from 50 ◦C to 95 ◦C at 2 ◦C/min, followed by
holding the temperature at 95 ◦C for 5 min. The starch suspension was then cooled to
50 ◦C at a rate of 6 ◦C/min. Throughout the entire pasting analysis, a constant shearing of
160 rpm was applied to ensure the homogeneity of the suspension. The viscosity of the
starch suspension was recorded throughout the entire pasting process.

2.6. Raman Spectroscopy

A few grams of the sample were placed onto a glass slide before being focused under
the objective lens of a Raman microscope (Alpha 300S, Witec, Ulm, Germany). A 100×
objective lens with NA of 0.90 was utilized for all measurements. A 532 nm Nd: YAG
laser with a power of 7 mW was used as the excitation source. A total of five spectrum
measurements were collected for each sample and these were collated to derive the final
spectrum. Each point spectrum was taken with an integration time of 5 s and accumulated
five times to achieve a better signal-to-noise ratio. Cosmic ray removal on spectra was done
using Witec Project software.

2.7. Starch Crystallinity Analysis

The crystallinity of the waxy rice starches was evaluated qualitatively and quanti-
tatively, using Polarized Light Microscopy, Differential Scanning Calorimetry (DSC) and
X-ray Diffraction (XRD).

2.7.1. Polarized Light Microscopy

A drop of 5.0% (w/w) starch suspension was observed under a polarized light micro-
scope (Eclipse Ci DS-Ri2, Nikon, Tokyo, Japan) with an objective lens magnification set
to 40×. Images of the granules with a birefringence cross were taken for the respective
samples.

2.7.2. Differential Scanning Calorimetry (DSC)

The thermal properties of the waxy rice starch granules were measured using a
differential scanning calorimeter (214 Polyma, Netzsch, Selb, Germany), installed with
Proteus-70 analysis software. The waxy rice starches were rehydrated in deionized water



Processes 2021, 9, 1557 5 of 16

at a ratio of 1:4 (w/v). The starch suspensions were left to stir at 500 rpm for 30 min,
before 20 µL was pipetted into the differential scanning calorimeter pan. The pan was
hermetically sealed with an inverted unpierced lid. It was left to stand for 12 h at an
atmospheric condition of 25 ◦C in order to equilibrate before being subjected to DSC
analysis. For all DSC analysis, a sealed empty aluminum pan was used as a reference.
The pans were heated from 20 ◦C to 110 ◦C at a heating rate of 10 ◦C/min, with enthalpy
(4H, J/g) being measured throughout the entire heating cycle. The spectrum was further
analyzed to determine the properties of the starches, including onset (TO), conclusion
(Tc) and peak gelatinization (TP) temperatures, as well as the derived parameters, such as
degree to crystallization.

2.7.3. X-ray Diffraction (XRD) Analysis

All of the waxy rice starches were left to equilibrate under atmospheric condition for
seven days before the XRD measurements. The respective starch powders were pressed
manually and mounted onto the sample holder. XRD measurements were conducted with
a diffractometer (GADDS, Bruker, Billerica, MA, USA) which was equipped with nickel
filtered Cu-K a radiation (wavelength 1.540598Å) radiation. The samples were scanned
under fixed conditions of 40 kV and 30 mA. The scan range varied between the 3◦ to 85◦

(2θ) with 100 s per frame and three frames per scan. The XRD data were processed and
analyzed using Bruker Eva software.

2.8. Statistical Analysis

All of the experiments were conducted in triplicate (unless otherwise stated), with
the mean and standard deviation computed for all measurements. ANOVA was used to
analyze the differences at a 95% confidence interval. The statistical analysis was performed
using Graphpad Prism (Version 8, Graphpad Software, San Diego, CA, USA).

3. Results and Discussion
3.1. Physical Properties of Spray-Dried Waxy Rice Starch

The various physicochemical properties of the respective spray-dried waxy rice
starches were examined.

Table 1 features the process yield and crucial product quality of the spray-dried waxy
rice starches. Changes in the inlet temperature had no significant effect on the protein
content of the resultant waxy rice starch. The protein contents (dry basis) of all of the
spray-dried waxy rice starches were found to be less than 1%, comparable to commercial
rice starches [1]. Similar results were observed in our previous studies, where changes in
drying strategies had no significant impact on the protein content [11]. The results and
published literature showed that the protein content is reliant on the efficacy of the prior
alkaline steeping process that is intended to remove protein, rather than the subsequent
drying process.

Table 1. Product specifications and process yield of spray-dried waxy rice starches. Values denoted
with different alphabets in the same column are significantly different (p < 0.05).

Protein Content (%) Moisture Content (%) Process Yield (%)

SP 40 0.64 ± 0.22 a 13.92 ± 0.32 a 74.83 ± 4.34 a

SP 50 0.79 ± 0.24 a 12.42 ± 1.67 ab 82.42 ± 5.73 a

SP 60 0.66 ± 0.19 a 10.74 ± 1.08 bcd 84.55 ± 1.77 a

SP 70 0.73 ± 0.14 a 9.67 ± 0.53 cef 85.16 ± 0.82 a

SP 80 0.66 ± 0.15 a 9.26 ± 0.40 deg 88.66 ± 6.19 b

SP 100 0.66 ± 0.13 a 7.99 ± 0.30 fg 85.66 ± 1.18 a

Moisture content is another key indicator influencing the quality of spray-dried waxy
rice starch [12]. For the food industry, a low moisture content of less than 15% is often
necessary for dried products in order to deter undesirable microbial growth and ensure



Processes 2021, 9, 1557 6 of 16

product stability [13,14]. During the spray-drying process, the atomized starch dispersion
and hot air flows in the same direction. This co-current spray-drying configuration implies
that when the atomized starch particles come into contact with the heated drying air, this
results in rapid moisture evaporation from the particles [15]. Interestingly, our data showed
effective moisture evaporation from the waxy rice starch, with a final moisture content
of 13.92 ± 0.32%, even at a low inlet temperature of 40 ◦C. As the inlet temperature was
increased, from 40 ◦C to 100 ◦C, the moisture content of the resultant starch decreased
proportionately from 13.92 ± 0.32% to 7.99 ± 0.30%, respectively. Similar findings were
reported in a study by Shi, Li, Wang, Zhou, & Adhikari, where the authors observed a
decrease in starch moisture content, from 9.78% to 8.31%, when the spray-drying inlet air
temperature was increased from 75 ◦C to 175 ◦C [16]. Such phenomenon can be attributed
to a steeper heat gradient associated with a higher inlet temperature, which results in a
higher transfer rate of thermal energy into the starch granules. The higher thermal energy
provides an increased impetus for an enhanced rate of moisture evaporation from the
starch granules, resulting in a lower moisture content of the waxy rice starch powder.

Process yield is a key parameter when considering the feasibility of the spray-drying
process as a drying methodology for the large scale manufacture of dried starch products.
An increase in inlet temperature, from 40 ◦C to 80 ◦C, resulted in a general increase in
the process yield. The increase in the process yield can be attributed to the lowered
moisture content of waxy rice starch that is spray dried at a higher inlet temperature,
which translated to reduced adhesion on the wall of the drying chamber. A lower moisture
content generally reduces the tendency for the deposition of starch particles on the walls of
the drying chamber, lowering process losses and improving the yield. However, a further
increase in the inlet temperature to 100 ◦C resulted in a drop in the process yield. The
use of too high an air inlet temperature may have resulted in gelatinization of the starch
particles which are stuck on the drying chamber wall. This can lead to a higher tendency
for the subsequent spray-dried rice starch particles to stick to the wall, due to the formation
of a sticky gelatinized starch layer on the drying chamber surfaces.

Rice starch is widely known to have the smallest granule size of commercially available
starches, with reported granule sizes ranging from 2 µm to 7 µm [17]. This small granule
size is essential for certain functionalities of rice starch in some food applications. Some
of such applications include sugar coating in confectionery products and replacing fat in
low-fat cream [17]. In order to retain its functionality, it is crucial that the particle size of
the rice starch powder be kept as small as possible; ideally similar to that of the granule
size. In addition, the particle size distribution of the product should also be uniform (less
polydispersed) in order to ensure good consistency. The atomization mechanism of the
spray dryer allows the user to maintain good control over the particle size [18]. Spray-
drying parameters, such as the air inlet temperature, pump rate and air flow rate, bear
great significance in terms of controlling the resultant particle size of spray-dried products.
Manipulation of the inlet temperature does not affect the particle size of the spray-dried
waxy rice starch, with all spray-dried products having very similar particle sizes (between
5.61 ± 0.57 µm to 6.12 ± 0.11 µm) (Figure 1). The average particle size of these spray-
dried waxy rice starches is also similar to that of the native rice starch (5.80 ± 0.01 µm).
Furthermore, all spray-dried products show a good particle size distribution, with a
unimodal distribution curve (Figure 1b). Such results exemplify the importance of the
atomizing process in controlling the particle size of the rice starch and the respective size
distributions. Since inlet temperature shows no direct impact on the atomizing process,
changes to the inlet temperature do not affect the particle size and size distribution of the
waxy rice starch.



Processes 2021, 9, 1557 7 of 16

Processes 2021, 9, x FOR PEER REVIEW 7 of 17 
 

 

size distributions. Since inlet temperature shows no direct impact on the atomizing pro-
cess, changes to the inlet temperature do not affect the particle size and size distribution 
of the waxy rice starch. 

 
Figure 1. Particle size (a) characteristics and (b) distribution of native and spray dried waxy rice starches. Values denoted 
with different alphabets in the same column are significantly different (p < 0.05). 

The bulk and tapped densities of the spray-dried starches were also examined (Table 
2). The Hausner Ratio and Carr’s Index, which provided an indication of the flowability 
of the respective spray-dried waxy rice starch powder, were derived from these parame-
ters. While there exist minute differences in the bulk and tapped density of the respective 
spray-dried waxy rice starch powders, there are no significant differences when analyzed 
using the Hausner Ratio and Carr’s Index. Generally, all spray-dried waxy rice starches 
possessed poor flowability, as reflected in the high Hausner Ratio (HR) and Carr’s Index 
[19]. Similar results were reported for waxy rice starch dried using other methodologies, 
such as oven drying and freeze drying [11]. Rather than being due to the effect of drying 
methods, the poor flow properties could mainly be attributed to the inherently small par-
ticle sizes (5.61 μm to 6.12 μm) of waxy rice starches. Such a small particle size meant that 
these particles have a larger surface area to volume ratio and a higher tendency for contact 
between particles, resulting in increased interparticle adhesion forces [20]. Such cohesive 
forces eventually led to greater resistance in the flowability of the particles [21]. Similar 
findings were also commonly reported for various starch powders and were not limiting 
to waxy rice starches. A study by Arollado, Pellazar, Manalo, Siocson, & Ramirez exhib-
ited high HR of 1.39 to 1.44 for fruit starches. The starches had irregular shapes and small 
particle sizes, which led to the interlocking of particles and limited flowability [22]. A sep-
arate study by Odeniyi, Adepoju, & Jaiyeoba revealed a high HR of 1.65 for acha starch. 
The enhanced cohesive forces between the starch particles was believed to be the main 
cause for the increased resistance to powder flowability [23]. Therefore, to improve the 
flowability of the starch powders, formulation additives, such as flow activators (e.g., col-
loidal silicon dioxide), can be utilized. These flow activators, which are also known as 
glidants, act by reducing the bulk density which, in turn, decreases the cohesion and ad-
hesion of the particles [24]. Similar strategies can be applied to spray-dried waxy rice 
starch in order to enhance its flowability. 

Table 2. Flow characteristics of spray dried waxy rice starches. Values denoted with different al-
phabets in the same column are significantly different (p < 0.05). 

 Bulk Density 
(g/cm3) 

Tapped Density 
(g/cm3) 

Hausner Ratio 
(HR) 

Carr’s Index 
(%) 

SP 40 0.33 ± 0.01 h 0.47 ± 0.02 a 1.41 ± 0.02 a 28.96 ± 1.00 a 
SP 50 0.36 ± 0.01 abc 0.51 ± 0.02 abcd 1.40 ± 0.04 a 28.31 ± 2.06 a 
SP 60 0.37 ± 0.00 ade 0.51 ± 0.00 bef 1.39 ± 0.00 a 28.00 ± 0.00 a 

Figure 1. Particle size (a) characteristics and (b) distribution of native and spray dried waxy rice starches. Values denoted
with different alphabets in the same column are significantly different (p < 0.05).

The bulk and tapped densities of the spray-dried starches were also examined (Table 2).
The Hausner Ratio and Carr’s Index, which provided an indication of the flowability of
the respective spray-dried waxy rice starch powder, were derived from these parameters.
While there exist minute differences in the bulk and tapped density of the respective spray-
dried waxy rice starch powders, there are no significant differences when analyzed using
the Hausner Ratio and Carr’s Index. Generally, all spray-dried waxy rice starches possessed
poor flowability, as reflected in the high Hausner Ratio (HR) and Carr’s Index [19]. Similar
results were reported for waxy rice starch dried using other methodologies, such as oven
drying and freeze drying [11]. Rather than being due to the effect of drying methods,
the poor flow properties could mainly be attributed to the inherently small particle sizes
(5.61 µm to 6.12 µm) of waxy rice starches. Such a small particle size meant that these
particles have a larger surface area to volume ratio and a higher tendency for contact
between particles, resulting in increased interparticle adhesion forces [20]. Such cohesive
forces eventually led to greater resistance in the flowability of the particles [21]. Similar
findings were also commonly reported for various starch powders and were not limiting to
waxy rice starches. A study by Arollado, Pellazar, Manalo, Siocson, & Ramirez exhibited
high HR of 1.39 to 1.44 for fruit starches. The starches had irregular shapes and small
particle sizes, which led to the interlocking of particles and limited flowability [22]. A
separate study by Odeniyi, Adepoju, & Jaiyeoba revealed a high HR of 1.65 for acha starch.
The enhanced cohesive forces between the starch particles was believed to be the main
cause for the increased resistance to powder flowability [23]. Therefore, to improve the
flowability of the starch powders, formulation additives, such as flow activators (e.g.,
colloidal silicon dioxide), can be utilized. These flow activators, which are also known
as glidants, act by reducing the bulk density which, in turn, decreases the cohesion and
adhesion of the particles [24]. Similar strategies can be applied to spray-dried waxy rice
starch in order to enhance its flowability.

Table 2. Flow characteristics of spray dried waxy rice starches. Values denoted with different
alphabets in the same column are significantly different (p < 0.05).

Bulk Density
(g/cm3)

Tapped Density
(g/cm3)

Hausner Ratio
(HR)

Carr’s Index
(%)

SP 40 0.33 ± 0.01 h 0.47 ± 0.02 a 1.41 ± 0.02 a 28.96 ± 1.00 a

SP 50 0.36 ± 0.01 abc 0.51 ± 0.02 abcd 1.40 ± 0.04 a 28.31 ± 2.06 a

SP 60 0.37 ± 0.00 ade 0.51 ± 0.00 bef 1.39 ± 0.00 a 28.00 ± 0.00 a

SP 70 0.37 ± 0.01 bdf 0.52 ± 0.02 ceg 1.40 ± 0.02 a 28.69 ± 1.15 a

SP 80 0.38 ± 0.00 cefg 0.53 ± 0.01 dfg 1.38 ± 0.02 a 27.35 ± 1.15 a

SP 100 0.40 ± 0.00 g 0.57 ± 0.01 h 1.42 ± 0.02 a 29.34 ± 1.15 a



Processes 2021, 9, 1557 8 of 16

3.2. Pasting Behaviour

Having a good understanding of the pasting behavior of waxy rice starches is im-
portant, as this is an indicator of the functionalities of starch granules when subjected to
heating in excess water. This is especially the case for dried starches, as they had been
exposed to prior thermal treatment, which could significantly affect the physicochemical
properties and functionalities of the starches. As reported in our previous study, oven-dried
waxy rice starch demonstrated a significantly different pasting profile as compared to the
native rice starches. There were significant increases in the peak, breakdown and final
viscosities as compared to the native rice starch. These differences could be attributed to
minute changes in the starch, which include leaching of amylopectin and the formation of
minute fissure cracks on the granule surface during the process of oven drying [11]. The
findings further supplement the hypothesis that the drying process can have a significant
effect on the resultant starch properties and functionalities. Figure 2 illustrates the pasting
curves of waxy rice starch which were spray dried at different inlet temperatures. Regard-
less of the inlet temperatures, the pasting profiles for all spray-dried waxy rice starches
are similar. The pasting profiles are also identical to that of the native waxy rice starch
(Before Drying). In contrast to other thermal-based drying methods, the results from our
study highlight that the inlet temperature of the spray dryer had no significant effect on the
functionalities of the waxy rice starch obtained. Interestingly, even at an inlet temperature
of 100 ◦C, which is beyond the gelatinization temperature of rice starch (~64 ◦C), there
is no adverse effect on the general pasting behavior of the produced starch. This may be
due to the very short time during which the starch granules were exposed to the high
inlet temperature; a timeframe which did not provide sufficient thermal energy to elicit
any changes to the pasting properties of the starch granules. Table S1 lists the pasting
properties of the respective spray-dried way rice starches. In comparing these against the
native waxy rice starch (Before Drying), there is no significant difference in the respective
pasting parameters. Similar to the pasting curve, even at the highest inlet temperature
of 100 ◦C, the respective pasting parameters remained consistent with that of the native
waxy rice starch and reported results [25]. The results from this study highlight that the
choice of spray-drying inlet temperature does not significantly affect the pasting behavior
of the product. This can be attributed to the rapid drying mechanism of the spray-drying
process, during which exposure to thermal conditions removes only the surface water
without affecting the properties of the starch granules. The residence time of the particles
in the drying chamber typically ranges from 12 to 30 s [26]. This means that exposure to the
thermal conditions is greatly reduced, compared with other drying methods which have a
longer drying time (e.g., oven drying, ~12 h). Moreover, the spray dryer utilizes co-current
product-air flow configuration, which means that the hottest gases are in contact with the
wettest materials and the temperature of the solids decrease as they moves through the
dryer, preventing the potential for overheating [27]. In addition, it is known that waxy
rice starch possesses a semi-crystalline structure, due to the presence of high amylopectin
content (>98%) [28]. It is plausible that due to the extensive branching amylopectin chains,
they are likely to be less mobile within the granules due to steric hindrances as compared
to the amylose. Thus, amylopectin molecules are less likely to re-arrange and form new
associations with one another [25] during the brief spike in temperature. This possibly
explains why, even at a high air inlet temperature of 100 ◦C, gelatinization of the waxy rice
starch (with high amylopectin content) is not observed. This multitude of different factors
work in tandem to avoid undesirable thermal degradation of the spray-dried starches, even
at a high inlet temperature of 100 ◦C.



Processes 2021, 9, 1557 9 of 16Processes 2021, 9, x FOR PEER REVIEW 9 of 17 
 

 

 
Figure 2. Pasting profile of native and spray dried waxy rice starches. 

3.3. Crystalline Structure 
Crystallinity of starch has a direct impact on its hydration and paste-forming prop-

erties [29]. Starch granules possess semi-crystalline structures, which are comprised of 
both crystalline and amorphous regions. Rice starches, in particular, are well-known to 
have densely packed glucose helices, forming a typical A-type crystalline structure [30]. 
In order to preserve the native functionality of the rice starch, it is important to conserve 
the extension and type of crystalline structures in the spray-dried starches. 

Through the polarized light microscope, it was clearly observed that all spray-dried 
waxy rice starch granules exhibited the characteristic birefringence with a “Maltese Cross” 
(Figure 3). Extensive modifications to the crystalline structure of the granule are often ac-
companied by the loss of its characteristic birefringence. For instance, starch gelatinization 
would result in loss of birefringence due to absorption of water by amorphous regions, 
resulting in destabilization of its crystalline structure [31]. The presence of birefringence 
provides a preliminary indication that the crystalline structures and crystallinity of the 
starches was not affected by the spray-drying process or the varying inlet temperatures. 

Figure 2. Pasting profile of native and spray dried waxy rice starches.

3.3. Crystalline Structure

Crystallinity of starch has a direct impact on its hydration and paste-forming prop-
erties [29]. Starch granules possess semi-crystalline structures, which are comprised of
both crystalline and amorphous regions. Rice starches, in particular, are well-known to
have densely packed glucose helices, forming a typical A-type crystalline structure [30]. In
order to preserve the native functionality of the rice starch, it is important to conserve the
extension and type of crystalline structures in the spray-dried starches.

Through the polarized light microscope, it was clearly observed that all spray-dried
waxy rice starch granules exhibited the characteristic birefringence with a “Maltese Cross”
(Figure 3). Extensive modifications to the crystalline structure of the granule are often ac-
companied by the loss of its characteristic birefringence. For instance, starch gelatinization
would result in loss of birefringence due to absorption of water by amorphous regions,
resulting in destabilization of its crystalline structure [31]. The presence of birefringence
provides a preliminary indication that the crystalline structures and crystallinity of the
starches was not affected by the spray-drying process or the varying inlet temperatures.

While polarized microscopy provides a qualitative estimation of the crystallinity, X-
ray Diffraction (XRD) is a high-resolution tool used to determine any modification in the
crystalline structure of the respective spray-dried starch granules. Waxy rice starch gener-
ally possesses an A-type crystalline structure, formed via the interaction of amylopectin
with short branch-chains and closed branching points [32]. As such, a XRD spectroscopic
analysis of rice starches would often show the characteristic diffraction patterns as defined
by peaks at 15◦, 17◦, 18◦, 23◦ and 26◦ [33].



Processes 2021, 9, 1557 10 of 16Processes 2021, 9, x FOR PEER REVIEW 10 of 17 
 

 

 
Figure 3. Spray dried waxy rice starches observed under polarized light microscope at 40× magnification. 

While polarized microscopy provides a qualitative estimation of the crystallinity, X-
ray Diffraction (XRD) is a high-resolution tool used to determine any modification in the 
crystalline structure of the respective spray-dried starch granules. Waxy rice starch gen-
erally possesses an A-type crystalline structure, formed via the interaction of amylopectin 
with short branch-chains and closed branching points [32]. As such, a XRD spectroscopic 
analysis of rice starches would often show the characteristic diffraction patterns as defined 
by peaks at 15°, 17°, 18°, 23° and 26° [33]. 

Upon exposure to the extensive drying process, changes in the crystalline structure 
of the starch are expected [34]. A report by K. Liu, Hao, Chen, & Gao explored the effects 
of dry heat treatment on waxy potato starch. Changes in the X-ray pattern (from B to B + 
A type) were observed after the starch samples were exposed to heat treatment. Further-
more, it was reported that the peaks at 5.5° and 17.1° had weakened [34]. The change in 
crystalline structure was attributed to the reorientation of the double helices during the 
thermal treatment, which could have led to crystalline disruption. In contrast to other 
drying methods, spray drying does not affect the crystalline structure of the rice starch. In 
comparing the XRD spectroscopic diffraction patterns exhibited by native (Before Drying) 
to the spray dried waxy rice starches, it is evident that the XRD spectrometric fingerprint 
are identical. The five characteristic peaks (15°, 17°, 18°, 23° and 26°) can be clearly distin-
guished in Figure 4. This result further affirms the previous polarized microscopy results. 
The spray-drying process and, more importantly, the variation in inlet temperature did 
not induce any change to the crystalline structure of the granules. Even with a higher inlet 
temperature (100 °C), the A-type crystalline structure of the waxy rice starch was pre-
served in the resultant spray-dried waxy rice powder. 

Figure 3. Spray dried waxy rice starches observed under polarized light microscope at 40×magnification.

Upon exposure to the extensive drying process, changes in the crystalline structure
of the starch are expected [34]. A report by K. Liu, Hao, Chen, & Gao explored the
effects of dry heat treatment on waxy potato starch. Changes in the X-ray pattern (from
B to B + A type) were observed after the starch samples were exposed to heat treatment.
Furthermore, it was reported that the peaks at 5.5◦ and 17.1◦ had weakened [34]. The
change in crystalline structure was attributed to the reorientation of the double helices
during the thermal treatment, which could have led to crystalline disruption. In contrast
to other drying methods, spray drying does not affect the crystalline structure of the rice
starch. In comparing the XRD spectroscopic diffraction patterns exhibited by native (Before
Drying) to the spray dried waxy rice starches, it is evident that the XRD spectrometric
fingerprint are identical. The five characteristic peaks (15◦, 17◦, 18◦, 23◦ and 26◦) can
be clearly distinguished in Figure 4. This result further affirms the previous polarized
microscopy results. The spray-drying process and, more importantly, the variation in inlet
temperature did not induce any change to the crystalline structure of the granules. Even
with a higher inlet temperature (100 ◦C), the A-type crystalline structure of the waxy rice
starch was preserved in the resultant spray-dried waxy rice powder.



Processes 2021, 9, 1557 11 of 16Processes 2021, 9, x FOR PEER REVIEW 11 of 17 
 

 

 
Figure 4. X-ray diffractograms (XRD) of native (Before Drying) and spray dried waxy rice starches. 

Both polarized microscopy and XRD represent excellent qualitative tools to deter-
mine the retention of crystallinity and the crystalline structure type. Differential Scanning 
Calorimetry (DSC) is a quantitative tool used to determine the degree of crystallinity and 
various pasting parameters. Upon prolonged heating, starch generally undergoes gelati-
nization. This is an endothermic process that corresponds to the loss of starch crystallinity 
after being exposed to heat and moisture treatment [35]. As starch granules change from 
a semi-crystalline to amorphous phase, breakage of the crystallites occurs. This is a mo-
lecular disordering transition [17]. However, based on our study (Table 3), there is no 
significant difference in the gelatinization characteristics (TO, TP, TC, TC-TO and △H) be-
tween the native waxy rice starch and the spray-dried waxy rice starches. These results 
also correspond to that of native waxy rice starch. In the experimental findings reported 

Figure 4. X-ray diffractograms (XRD) of native (Before Drying) and spray dried waxy rice starches.

Both polarized microscopy and XRD represent excellent qualitative tools to determine
the retention of crystallinity and the crystalline structure type. Differential Scanning
Calorimetry (DSC) is a quantitative tool used to determine the degree of crystallinity
and various pasting parameters. Upon prolonged heating, starch generally undergoes
gelatinization. This is an endothermic process that corresponds to the loss of starch
crystallinity after being exposed to heat and moisture treatment [35]. As starch granules
change from a semi-crystalline to amorphous phase, breakage of the crystallites occurs.



Processes 2021, 9, 1557 12 of 16

This is a molecular disordering transition [17]. However, based on our study (Table 3), there
is no significant difference in the gelatinization characteristics (TO, TP, TC, TC-TO and4H)
between the native waxy rice starch and the spray-dried waxy rice starches. These results
also correspond to that of native waxy rice starch. In the experimental findings reported by
Y. Qin et al., TO, TP and TC of native waxy rice starch were found to be 59.08 ◦C, 64.21 ◦C
and 72.09 ◦C, respectively [36]. Despite slight deviances, our results generally agree with
that reported in the literature. The slight differences in gelatinization characteristics may
be due to variances in the botanical source of the rice starches [37]. More importantly, TC-O
provides an indication of the degree of crystallinity of the respective waxy rice starches.
Increases in the inlet temperature do not significantly affect the degree of crystallinity.
This, again, is due to the low exposure time to thermal treatment during the spray-drying
process. This result corresponds to the XRD result, in which the calculated area under
the curve for the spray-dried rice starches dried at different inlet temperatures (data not
shown) showed no significant difference. This result is different from that of other drying
methods. Li et al., have explored the impacts of oven drying on waxy rice starch. After
the rice starch samples were oven dried, there was a significant increase (by 9.11%) in
the degree of crystallinity and change in enthalpy. The authors reported that during the
thermal exposure of starches, there were changes to the amorphous regions, which led to
differences in the degree of crystallinity [8].

Table 3. DSC thermogram of native and spray dried waxy rice starches. TO, TP, TC, TC-TO and4H
represents onset, peak, conclusion, difference between conclusion and onset temperature and change
in enthalpy. Values denoted with different alphabets in the same column are significantly different
(p < 0.05).

TO (◦C) TP (◦C) TC (◦C) TC-TO (◦C) 4H (J/g)

Native 59.00 ± 0.00 a 68.50 ± 0.57 a 76.70 ± 0.57 a 17.70 ± 0.57 a 2.12 ± 0.10 a

SP 40 57.90 ± 2.72 a 66.03 ± 1.42 a 75.97 ± 0.84 a 18.07 ± 3.16 a 1.42 ± 0.69 a

SP 50 57.87 ± 1.27 a 65.33 ± 0.45 a 74.90 ± 0.85 a 17.03 ± 1.88 a 0.99 ± 1.07 a

SP 60 58.23 ± 1.36 a 67.07 ± 2.29 a 75.90 ± 0.78 a 17.67 ± 1.16 a 1.47 ± 0.84 a

SP 70 58.07 ± 1.60 a 66.20 ± 1.23 a 75.10 ± 1.10 a 17.03 ± 2.70 a 1.53 ± 0.53 a

SP 80 58.50 ± 1.32 a 65.97 ± 0.81 a 76.13 ± 0.65 a 17.63 ± 1.88 a 1.80 ± 0.45 a

SP 100 57.97 ± 2.12 a 66.07 ± 1.17 a 75.67 ± 1.04 a 17.70 ± 2.21 a 1.45 ± 0.12 a

All in all, on a macroscopic level, changes in the inlet temperature do not affect the
crystallization and pasting functionalities of the spray-dried waxy rice starches. As such,
the spray-dried waxy rice starch still retains the properties of its native state, preserving
the desired functionalities, including pasting profile, gelatinization characteristics and
crystalline structure.

3.4. Molecular Changes

While there are no changes in the macroscopic system, heat treatment may lead to the
occurrence of minor molecular changes in the waxy rice starches. Such molecular changes
might also lead to deviation of physicochemical properties of the resultant starches.

In a published report by Kamal et al., the authors explored the effect of heat treatment
on sago starch [14]. The starch samples were oven dried for a duration between 8 h to
24 h. The results revealed that the crystalline and amorphous index decreased as the
duration of heat treatment increased. The authors have suggested that these findings could
be due to rearrangements of the molecular order during the heat treatment process [14].
In addition, molecular changes could also be in the form of existing bonds breaking
and/or new covalent bonds forming. To detect such microscopic modifications, the Raman
spectroscopy is often utilized to evaluate the molecular structure of the granules. The
vibrational characteristics of the granules are represented by the Raman peak position,
intensity and spectra range [38]. A study by Qin et al., revealed the effects of maleic
anhydride on the molecular changes of corn starch. The modification of corn starch



Processes 2021, 9, 1557 13 of 16

resulted in the modification of several discrete Raman peaks in the spectrum. In particular,
a new peak was observed at 1839 cm−1 due to C=O stretching in the maleic anhydride [39].
Another study by Volant et al., on acetylated waxy maize starch demonstrated a new peak at
1740 cm−1, which was attributed to the deformation of the C=O bond. In addition, there was
disappearance of a peak at 480 cm−1. These modifications in the Ramen fingerprint indicate
the occurrence of modification on the molecular level after the acetylation process [40].

Figure 5 illustrates the Raman spectrum for spray-dried rice starch processed at differ-
ent inlet temperatures (Figure 5). The spectroscopic fingerprints of the spray dried waxy
rice starches were identical to that of native waxy rice starch (Before Drying), indicating no
drastic changes to existing molecular structures and biochemical bonding. An in-depth
analysis of the respective Raman peak intensities highlighted that the incremental increase
of the spray-drying inlet temperature, from 40 ◦C to 100 ◦C, did not significantly impose
any changes to the molecular structure (e.g., formation of new bonds) within waxy rice
starch granules. Even at the high spray-drying temperature of 100 ◦C, undesired reactions
were not exhibited in the Raman spectra. The previous results from the DSC and pasting
profile supplement the Ramen result, as any molecular changes due to spray drying will
also present some deviation in the respective parameters. As aforementioned, this could be
attributed to the short contact time with the heated air, thus avoiding undesirable thermal
degradation to the waxy rice starch granules.

3.5. Optimized Spray Drying Temperature for Production

Based on the results, varying the spray-drying inlet temperature bears no effect on
the physicochemical properties of the resultant waxy rice starch. However, an increase in
the inlet temperatures has a significant impact on the process yield and product quality.
On these fronts, it is ideal for the process to have an optimum moisture content (typically
below 15%) and a high process yield. At the same time, the inlet temperature should also
be kept low to minimize energy usage. Considering these factors, the inlet temperature for
spray drying of waxy rice starch is recommended to be 60 ◦C. At temperatures below 60 ◦C
(i.e., 40 ◦C and 50 ◦C), the moisture of the product is significantly higher (at approximately
13%), which is quite close to the standard set for dried products. This is coupled with a
lower process yield. As such, decreasing the temperature further than 60 ◦C is not ideal,
although the energy consumption is lower. At higher inlet temperatures of 70 ◦C and 80 ◦C,
the drop in moisture content is rather minor. On the contrary, the energy requirements
for these temperatures are much higher, especially when we are considering large-scale
production. An inlet temperature of 60 ◦C represents the most optimum inlet temperature.
At this temperature, the drying process can potentially achieve a good product yield of
84.55 ± 1.77%, with low moisture content of 10.74 ± 1.08%. This process yield of the spray-
drying process is also expected to be enhanced with upscaling of the process from lab-scale
to industry-scale [16]. A report by Georgia et al. highlighted that upscaling the spray
drying from pilot-scale to production-scale saw the process yield increase from 65.0% to
73.15%. At the recommended spray drying condition, the resultant product quality is also
good, and the particle size of the resultant waxy rice starch is well-controlled with a median
of 5.99 ± 0.07 µm with unimodal size distribution. Pasting behavior and crystallinity
were also well preserved. In addition, spray drying at 60 ◦C, means that the processing
temperature is kept below the gelatinization onset temperature of the waxy rice starch,
thus minimizing the possibility of undesired modification to the rice starch [25]. This will
help to preserve the functionalities of the native waxy rice starch. On top of that, the energy
consumption for the spray drying process at 60 ◦C is much lower, compared to drying at
100 ◦C (data not shown), making the drying process more economical and environmentally
sustainable.



Processes 2021, 9, 1557 14 of 16Processes 2021, 9, x FOR PEER REVIEW 14 of 17 
 

 

 
Figure 5. Raman spectra of native (Before Drying) and spray dried waxy rice starches. 

3.5. Optimized Spray Drying Temperature for Production 
Based on the results, varying the spray-drying inlet temperature bears no effect on 

the physicochemical properties of the resultant waxy rice starch. However, an increase in 
the inlet temperatures has a significant impact on the process yield and product quality. 
On these fronts, it is ideal for the process to have an optimum moisture content (typically 
below 15%) and a high process yield. At the same time, the inlet temperature should also 
be kept low to minimize energy usage. Considering these factors, the inlet temperature 
for spray drying of waxy rice starch is recommended to be 60 °C. At temperatures below 
60 °C (i.e., 40 °C and 50 °C), the moisture of the product is significantly higher (at approx-
imately 13%), which is quite close to the standard set for dried products. This is coupled 
with a lower process yield. As such, decreasing the temperature further than 60 °C is not 
ideal, although the energy consumption is lower. At higher inlet temperatures of 70 °C 
and 80 °C, the drop in moisture content is rather minor. On the contrary, the energy re-
quirements for these temperatures are much higher, especially when we are considering 

Figure 5. Raman spectra of native (Before Drying) and spray dried waxy rice starches.

4. Conclusions

Low temperature spray drying was proposed as an alternative method for drying
rice starch in a previous study [11]. This study evaluated the effect of different spray-
drying inlet temperatures (40 ◦C to 100 ◦C) on various aspects, such as the physicochemical
properties and functionalities of waxy rice starch. While bearing a significant effect on
process parameters, varying the air inlet temperatures has no significant impact on the
physicochemical properties and functionalities of the resultant spray-dried waxy rice starch.
An air inlet temperature of 60 ◦C is shown to be optimal, producing homogeneous na-
tive waxy rice starch with low moisture content (10.74 ± 1.08%) and good process yield
(84.55 ± 1.77%), while retaining the native physicochemical functionalities (e.g., pasting
characteristics) of rice starch. The current study bears importance to potential manufactur-



Processes 2021, 9, 1557 15 of 16

ers who are considering the use of spray drying for starch manufacturing. Compared to
current drying strategies for starch, which generally operate at temperatures at 130 ◦C and
above, the proposed optimized spray-drying process offers various advantages in terms of
better energy savings, improved thermal efficiency, lower costs and higher productivity.
Beyond the production capabilities and costs, operating at lower temperatures also will
translate to enhanced safety for the production process and workers.

Supplementary Materials: The following are available online at https://www.mdpi.com/article/10
.3390/pr9091557/s1, Table S1: Pasting characteristics of native and spray dried waxy rice starches.

Author Contributions: Conceptualization, K.L., K.K.T.G., J.B.J.T. and X.C.; methodology, K.L.,
K.K.T.G., J.B.J.T. and X.C.; validation, K.L., K.K.T.G., J.B.J.T. and X.C.; formal analysis, K.L., K.K.T.G.,
J.B.J.T., X.C., C.A., G.S.S., S.Y.T., E.M.J.L. and W.-Y.W.; investigation, K.L., K.K.T.G., J.B.J.T., X.C., C.A.,
G.S.S., S.Y.T., E.M.J.L. and W.-Y.W.; data curation, K.L., K.K.T.G. and C.A.; writing—original draft
preparation, J.B.J.T. and X.C.; writing—review and editing, K.L., K.K.T.G. and C.A.; visualization,
K.L., K.K.T.G. and C.A.; supervision, K.L. and K.K.T.G.; project administration, J.B.J.T., X.C. and K.L.
All authors have read and agreed to the published version of the manuscript.

Funding: This work was supported by Science and Engineering Research Count, Pharos Advanced
Surfaces Program [grant number 1523700106].

Institutional Review Board Statement: Not applicable.

Informed Consent Statement: Not applicable.

Data Availability Statement: Data is contained within the article or supplementary material.

Conflicts of Interest: The authors declare no conflict of interest.

References
1. Palacios-Fonseca, A.J.; Castro-Rosas, J.; Gómez-Aldapa, C.A.; Tovar-Benítez, T.; Millán-Malo, B.M.; Del Real, A.; Rodríguez-García,

M.E. Effect of the alkaline and acid treatments on the physicochemical properties of corn starch. CyTA-J. Food 2013, 11, 67–74.
[CrossRef]

2. Šárka, E.; Dvořáček, V. New processing and applications of waxy starch (a review). J. Food Eng. 2017, 206, 77–87. [CrossRef]
3. Oh, S.M.; Shin, M. Physicochemical properties and molecular structures of Korean waxy rice starches. Food Sci. Biotechnol. 2015,

24, 791–798. [CrossRef]
4. Luh, B.S. Rice: Volume I. Production; Springer Science & Business Media: Berlin/Heidelberg, Germany, 2013; ISBN 1489937544.
5. Miano, A.C.; Rojas, M.L.; Augusto, P.E.D. Other Mass Transfer Unit Operations Enhanced by Ultrasound. In Ultrasound: Advances

for Food Processing and Preservation; Elsevier: Amsterdam, The Netherlands, 2017; pp. 369–389.
6. Chapuis, A.; Precoppe, M.; Méot, J.-M.; Sriroth, K.; Tran, T. Pneumatic drying of cassava starch: Numerical analysis and guidelines

for the design of efficient small-scale dryers. Dry. Technol. 2017, 35, 393–408. [CrossRef]
7. Supprung, P.; Noomhorm, A. Optimization of drum drying parameters for low amylose rice (KDML105) starch and flour. Dry.

Technol. 2003, 21, 1781–1795. [CrossRef]
8. Li, Y.; Zhang, H.; Shoemaker, C.F.; Xu, Z.; Zhu, S.; Zhong, F. Effect of dry heat treatment with xanthan on waxy rice starch.

Carbohydr. Polym. 2013, 92, 1647–1652. [CrossRef]
9. Santos, D.; Franco, C.M.L.; Mischan, M.M.; Leonel, M. Improvement in spray-drying technology for preparation of pregelatinized

cassava starch. Food Sci. Technol. 2019, 39, 939–946. [CrossRef]
10. Keshani, S.; Daud, W.R.W.; Nourouzi, M.M.; Namvar, F.; Ghasemi, M. Spray drying: An overview on wall deposition, process

and modeling. J. Food Eng. 2015, 146, 152–162. [CrossRef]
11. Tay, J.B.J.; Chua, X.; Ang, C.; Goh, K.K.T.; Subramanian, G.S.; Tan, S.Y.; Lin, E.M.J.; Wu, W.-Y.; Lim, K. Continuous low-temperature

spray drying approach for efficient production of high quality native rice starch. Dry. Technol. 2021, 1–16. [CrossRef]
12. Zambrano, M.V.; Dutta, B.; Mercer, D.G.; MacLean, H.L.; Touchie, M.F. Assessment of moisture content measurement methods

of dried food products in small-scale operations in developing countries: A review. Trends Food Sci. Technol. 2019, 88, 484–496.
[CrossRef]

13. Opaliński, I.; Chutkowski, M.; Hassanpour, A. Rheology of moist food powders as affected by moisture content. Powder Technol.
2016, 294, 315–322. [CrossRef]

14. Kamal, M.M.; Baini, R.; Mohamaddan, S.; Selaman, O.S.; Zauzi, N.A.; Rahman, M.R.; Rahman, N.A.; Chong, K.H.; Atan, M.F.;
Samat, N.A.S.A. Effect of temperature to the properties of sago starch. In Proceedings of the IOP Conference Series: Materials
Science and Engineering, Miri, Malaysia, 1–3 December 2016; IOP Publishing: Bristol, UK, 2017; Volume 206, p. 12039.

https://www.mdpi.com/article/10.3390/pr9091557/s1
https://www.mdpi.com/article/10.3390/pr9091557/s1
http://doi.org/10.1080/19476337.2012.761651
http://doi.org/10.1016/j.jfoodeng.2017.03.006
http://doi.org/10.1007/s10068-015-0103-2
http://doi.org/10.1080/07373937.2016.1177537
http://doi.org/10.1081/DRT-120025508
http://doi.org/10.1016/j.carbpol.2012.11.002
http://doi.org/10.1590/fst.10418
http://doi.org/10.1016/j.jfoodeng.2014.09.004
http://doi.org/10.1080/07373937.2021.1874967
http://doi.org/10.1016/j.tifs.2019.04.006
http://doi.org/10.1016/j.powtec.2016.02.049


Processes 2021, 9, 1557 16 of 16

15. Dos Santos, T.P.R.; Franco, C.M.L.; Demiate, I.M.; Li, X.-H.; Garcia, E.L.; Jane, J.; Leonel, M. Spray-drying and extrusion processes:
Effects on morphology and physicochemical characteristics of starches isolated from Peruvian carrot and cassava. Int. J. Biol.
Macromol. 2018, 118, 1346–1353. [CrossRef] [PubMed]

16. Shi, A.; Li, D.; Wang, L.; Zhou, Y.; Adhikari, B. Spray drying of starch submicron particles prepared by high pressure homogeniza-
tion and mini-emulsion cross-linking. J. Food Eng. 2012, 113, 399–407. [CrossRef]

17. Wani, A.A.; Singh, P.; Shah, M.A.; Schweiggert-Weisz, U.; Gul, K.; Wani, I.A. Rice starch diversity: Effects on structural,
morphological, thermal, and physicochemical properties—A review. Compr. Rev. Food Sci. Food Saf. 2012, 11, 417–436. [CrossRef]

18. Magee, J.S.; Mitchell, M.M. Fluid Catalytic Cracking: Science and Technology; Elsevier: Amsterdam, The Netherlands, 1993; ISBN
0080887686.

19. Reddy, R.S.; Ramachandra, C.T.; Hiregoudar, S.; Nidoni, U.; Ram, J.; Kammar, M. Influence of processing conditions on functional
and reconstitution properties of milk powder made from Osmanabadi goat milk by spray drying. Small Rumin. Res. 2014, 119,
130–137. [CrossRef]

20. Xu, G.; Lu, P.; Li, M.; Liang, C.; Xu, P.; Liu, D.; Chen, X. Investigation on characterization of powder flowability using different
testing methods. Exp. Therm. Fluid Sci. 2018, 92, 390–401. [CrossRef]

21. Yang, J.; Sliva, A.; Banerjee, A.; Dave, R.N.; Pfeffer, R. Dry particle coating for improving the flowability of cohesive powders.
Powder Technol. 2005, 158, 21–33. [CrossRef]

22. Arollado, E.C.; Pellazar, J.M.M.; Manalo, R.A.M.; Siocson, M.P.F.; Ramirez, R.-L.F. Comparison of the Physicochemical and
Pharmacopeial Properties of starches Obtained from Artocarpus odoratissimus Blanco, Nephelium lappaceum l., and Mangifera
indica l. seeds with Corn starch. Acta Med. Philipp. 2018, 52, 360. [CrossRef]

23. Odeniyi, M.A.; Adepoju, A.O.; Jaiyeoba, K.T. Native and modified Digitaria exilis starch nanoparticles as a carrier system for the
controlled release of naproxen. Starch-Stärke 2019, 71, 1900067. [CrossRef]

24. Jain, G.; Khar, R.K.; Ahmad, F.J. Theory and Practice of Physical Pharmacy-E-Book; Elsevier Health Sciences: Amsterdam, The
Netherlands, 2013; ISBN 8131232654.

25. Ie, P.S. Gelatinization and Molecular Properties of Organic and Conventional Rice and Spelt Starches; Ohio State University: Columbus,
OH, USA, 2011.

26. Todaro, C.M.; Vogel, H.C. Fermentation and Biochemical Engineering Handbook; William Andrew: Norwish, NY, USA, 2014; ISBN
1455730467.

27. Santos, D.; Maurício, A.C.; Sencadas, V.; Santos, J.D.; Fernandes, M.H.; Gomes, P.S. Spray drying: An overview. In Pignatello, R.
(Comp.). Biomaterials-Physics and Chemistry-New Edition; InTechOpen Limited: London, UK, 2018; pp. 9–35.

28. Wang, Y.; Wang, L. Structures of four waxy rice starches in relation to thermal, pasting, and textural properties. Cereal Chem. 2002,
79, 252–256. [CrossRef]

29. Dome, K.; Podgorbunskikh, E.; Bychkov, A.; Lomovsky, O. Changes in the Crystallinity Degree of Starch Having Different Types
of Crystal Structure after Mechanical Pretreatment. Polymers 2020, 12, 641. [CrossRef]

30. Martens, B.M.J.; Gerrits, W.J.J.; Bruininx, E.M.A.M.; Schols, H.A. Amylopectin structure and crystallinity explains variation in
digestion kinetics of starches across botanic sources in an in vitro pig model. J. Anim. Sci. Biotechnol. 2018, 9, 1–13. [CrossRef]

31. Cai, C.; Wei, C. In situ observation of crystallinity disruption patterns during starch gelatinization. Carbohydr. Polym. 2013, 92,
469–478. [CrossRef] [PubMed]

32. Pan, T.; Lin, L.; Wang, J.; Liu, Q.; Wei, C. Long branch-chains of amylopectin with B-type crystallinity in rice seed with inhibition
of starch branching enzyme I and IIb resist in situ degradation and inhibit plant growth during seedling development. BMC
Plant Biol. 2018, 18, 9. [CrossRef] [PubMed]

33. Lian, X.; Cheng, K.; Wang, D.; Zhu, W.; Wang, X. Analysis of crystals of retrograded starch with sharp X-ray diffraction peaks
made by recrystallization of amylose and amylopectin. Int. J. Food Prop. 2017, 20, S3224–S3236. [CrossRef]

34. Liu, K.; Hao, Y.; Chen, Y.; Gao, Q. Effects of dry heat treatment on the structure and physicochemical properties of waxy potato
starch. Int. J. Biol. Macromol. 2019, 132, 1044–1050. [CrossRef] [PubMed]

35. Kadam, S.U.; Tiwari, B.K.; O’Donnell, C.P. Improved thermal processing for food texture modification. Modifying Food Texture
2015, 115–131. [CrossRef]

36. Qin, Y.; Liu, C.; Jiang, S.; Cao, J.; Xiong, L.; Sun, Q. Functional properties of glutinous rice flour by dry-heat treatment. PLoS ONE
2016, 11, e0160371. [CrossRef]

37. Cornejo-Ramírez, Y.I.; Martínez-Cruz, O.; Del Toro-Sánchez, C.L.; Wong-Corral, F.J.; Borboa-Flores, J.; Cinco-Moroyoqui, F.J. The
structural characteristics of starches and their functional properties. CyTA-J. Food 2018, 16, 1003–1017. [CrossRef]

38. Liu, Y.; Xu, Y.; Yan, Y.; Hu, D.; Yang, L.; Shen, R. Application of Raman spectroscopy in structure analysis and crystallinity
calculation of corn starch. Starch-Stärke 2015, 67, 612–619. [CrossRef]

39. Qin, J.; Kim, M.S.; Chao, K.; Bellato, L.; Schmidt, W.F.; Cho, B.-K.; Huang, M. Inspection of maleic anhydride in starch powder
using line-scan hyperspectral Raman chemical imaging technique. Int. J. Agric. Biol. Eng. 2018, 11, 120–125. [CrossRef]

40. Volant, C.; Gilet, A.; Beddiaf, F.; Collinet-Fressancourt, M.; Falourd, X.; Descamps, N.; Wiatz, V.; Bricout, H.; Tilloy, S.; Monflier, E.
Multiscale structure of starches grafted with hydrophobic groups: A new analytical strategy. Molecules 2020, 25, 2827. [CrossRef]
[PubMed]

http://doi.org/10.1016/j.ijbiomac.2018.06.070
http://www.ncbi.nlm.nih.gov/pubmed/29909032
http://doi.org/10.1016/j.jfoodeng.2012.06.017
http://doi.org/10.1111/j.1541-4337.2012.00193.x
http://doi.org/10.1016/j.smallrumres.2014.01.013
http://doi.org/10.1016/j.expthermflusci.2017.11.008
http://doi.org/10.1016/j.powtec.2005.04.032
http://doi.org/10.47895/amp.v52i4.376
http://doi.org/10.1002/star.201900067
http://doi.org/10.1094/CCHEM.2002.79.2.252
http://doi.org/10.3390/polym12030641
http://doi.org/10.1186/s40104-018-0303-8
http://doi.org/10.1016/j.carbpol.2012.09.073
http://www.ncbi.nlm.nih.gov/pubmed/23218322
http://doi.org/10.1186/s12870-017-1219-8
http://www.ncbi.nlm.nih.gov/pubmed/29310584
http://doi.org/10.1080/10942912.2017.1362433
http://doi.org/10.1016/j.ijbiomac.2019.03.146
http://www.ncbi.nlm.nih.gov/pubmed/30910679
http://doi.org/10.1016/B978-1-78242-333-1.00006-1
http://doi.org/10.1371/journal.pone.0160371
http://doi.org/10.1080/19476337.2018.1518343
http://doi.org/10.1002/star.201400246
http://doi.org/10.25165/j.ijabe.20181106.4339
http://doi.org/10.3390/molecules25122827
http://www.ncbi.nlm.nih.gov/pubmed/32570969

	Introduction 
	Materials and Methods 
	Materials 
	Protein Extraction 
	Spray Drying 
	Physicochemical Properties of Waxy Rice Starch 
	Moisture Content Analysis 
	Kjeldahl Method 
	Process Yield 
	Particle Size Analysis 
	Density and Flowability Analyses 

	Pasting Profiles 
	Raman Spectroscopy 
	Starch Crystallinity Analysis 
	Polarized Light Microscopy 
	Differential Scanning Calorimetry (DSC) 
	X-ray Diffraction (XRD) Analysis 

	Statistical Analysis 

	Results and Discussion 
	Physical Properties of Spray-Dried Waxy Rice Starch 
	Pasting Behaviour 
	Crystalline Structure 
	Molecular Changes 
	Optimized Spray Drying Temperature for Production 

	Conclusions 
	References