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Development of chitosan films containing β-cyclodextrin inclusion complex for controlled release of bioactives
Journal Pre-proof Development of chitosan films containing β-cyclodextrin inclusion complex for controlled release of bioactives I. Zarandona, C. Barba, P. Guerrero, K. de la Caba, J. Maté PII:
S0268-005X(19)32273-8
DOI:
https://doi.org/10.1016/j.foodhyd.2020.105720
Reference:
FOOHYD 105720
To appear in:
Food Hydrocolloids
Received Date: 28 September 2019 Revised Date:
3 January 2020
Accepted Date: 27 January 2020
Please cite this article as: Zarandona, I., Barba, C., Guerrero, P., de la Caba, K., Maté, J., Development of chitosan films containing β-cyclodextrin inclusion complex for controlled release of bioactives, Food Hydrocolloids (2020), doi: https://doi.org/10.1016/j.foodhyd.2020.105720. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. 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. © 2020 Published by Elsevier Ltd.
Author statement I. Zarandona: Investigation, Writing-Original Draft C. Barba: Conceptualization, Investigation, Funding acquisition P. Guerrero: Formal analysis, Supervision, Writing-Review & Editing K. de la Caba: Supervision, Writing-Review & Editing, Funding acquisition J. Maté: Conceptualization, Resources, Writing-Review & Editing,
60
2-phenylethanol Retention efficiency (%)
β-cyclodextrin (β-CD)
40
20
0
-CD
H3C HO
OH
NH2
HO
O HO OH
NH O O
O H2N
-CD
O
O
O
O
-CD
OH
Chitosan films with β-CD:2-phenylethanol inclusion complexes
Development of chitosan films containing β -cyclodextrin inclusion complex for controlled release of bioactives. I. Zarandonaa, C. Barbab, P. Guerreroa*, K. de la Cabaa, J. Matéb a
BIOMAT research group, University of the Basque Country (UPV/EHU), Escuela de
Ingeniería de Gipuzkoa, Plaza de Europa 1, 20018 Donostia-San Sebastián, Spain. b
Department of Agronomy, Biotechnology and Food Science, Public University of
Navarre (UPNa), Campus Arrosadía s/n, Edificio Los Olivos, Pamplona 31006, Spain.
*Corresponding author: Pedro Guerrero e-mail: [email protected] telephone number: +34943018535 1
1
Abstract
2
2-phenyl ethanol is a natural compound, which have many applications due to its nice
3
fragrance, bacteriostatic and antifungal character. However, it is difficult to keep it
4
stable and it is highly volatile. In this work, chitosan films with 2-phenyl ethanol were
5
developed and inclusion complexes with cyclodextrins (CDs) were prepared in order to
6
have a controlled release of 2-phenyl ethanol. β-CD was selected to develop the
7
inclusion complex since it showed higher retention yield (45 %, molar basis) than α- or
8
γ-CDs. Chitosan films incorporated with β-CD:2-phenyl ethanol were homogeneous,
9
transparent and colorless, and showed high mechanical resistance. Furthermore, the
10
release results of the films without the inclusion complex indicated that 2-phenyl
11
ethanol was evaporated during the film preparation, and only an 8 % of the total
12
bioactive was retained in the film, while more than 90 % of 2-phenyl ethanol was
13
retained in the films with the inclusion complex.
14
Keywords: chitosan film; inclusion complex; β-cyclodextrin; 2-phenylethanol; bioactive
15
retention; controlled release.
2
16
1. Introduction
17
The use of active compounds is a strategy to confer functional properties, such as
18
antimicrobial, antioxidant or ultraviolet (UV) light barrier properties, to films. However,
19
many of these compounds, such as vitamins, antioxidants or flavors, are not stable
20
under the preparation, storage and/or use conditions (Hosseini, Nahvi, & Zandi, 2019;
21
Li, Maldonado, Malmr, Rouf, Hua, & Kokini, 2019). Therefore, the use of encapsulation
22
agents for active compounds become necessary to protect the compound from
23
volatilization or possible reactions with external agents, and also to control a sustained
24
release (Reineccius, 2009). Among encapsulation processes, spray-drying, spray-
25
cooling, extrusion or molecular inclusion are employed in industrial processes, but only
26
molecular inclusion occurs at molecular level and, thus, one molecule of the active
27
compound is trapped in the cavity of the host molecule (Reineccius, Reineccius, &
28
Peppard, 2002). The union between the active compound and the host molecule is
29
called inclusion complex. One of these host molecules is cyclodextrin, since the Food
30
and Agriculture Organization (FAO) of the United Nations recognizes it as additive
31
(FAO, 2019).
32
Cyclodextrins (CD) are cyclic oligosaccharides constituted of glucose molecules joined
33
together by α-1,4 bonds (Szente & Szejtli, 1999). CDs are hollow truncated cone
34
structures with an external hydrophilic character and an internal hydrophobic character
35
(Simionato, Domingues, Nerín, & Silva, 2019; Huang, Xu, Ge, & Cheng, 2019).
36
Therefore, it is a suitable molecule to host a variety of bioactives, including those that
37
are non-soluble in water since interactions between cyclodextrins and guest molecules
38
include hydrophobic forces as well as hydrogen bonding (Zhou, Lu, Zhou, & Liu, 2019).
39
Depending on the glucopyranose units conforming the molecule, the most common
40
CDs are α-, β- or γ-CDs, composed of 6, 7 or 8 glucopyranose units, respectively
41
(Prabu & Mohamad, 2020). Due to the variety of guest molecules that can host and
42
their acceptability as food additives, CDs are widely used in food and pharmaceutical 3
43
industries. Regarding food industry, CDs can be employed for different applications,
44
such as food supplement for spaghetti, adding pumpkin oil (Durante et al., 2019), as
45
flavor masking, reducing the high intensity of sourness, bitterness and astringency
46
flavor in lingonberry juice (Kalanne et al., 2019), or as thermal stabilizers (Yoshikiyo et
47
al., 2019). In the pharmaceutical industry, CDs are used to increase drug permeability,
48
solubility and stability and to enhance organoleptic characteristics (Chantasart, &
49
Rakkaew, 2019; Santana, Nadvorny, Passos, Soares, & Soares-Sobrinho, 2019; Yildiz,
50
& Uyar, 2019). Regarding preparation, there are different methods for the inclusion
51
complex preparation, such as freeze-drying, spray drying or coprecipitation (Suzuki et
52
al., 2019).
53
CDs can be used in a variety of matrixes. Morin-β-CD complexes have been
54
incorporated into gelatin to prepare antioxidant films (Yuan et al., 2019). Also
55
antimicrobials, such as citral, have been used to prepare β-CD inclusion complexes to
56
preserve bioactivity during melt extrusion of EVOH films (Chen, Li, Ma, Mcdonald, &
57
Wang, 2019). In order to provide films with both antioxidant and antibacterial
58
properties, essential oils have been encapsulated into β-CD to promote cumulative
59
release from chitosan films for food packaging applications (Adel, Ibrahim, El-Shafei, &
60
Al-Shemy, 2019). In this regard, several works have been reported in relation to the
61
use of chitosan with CD inclusion complexes for controlled release of bioactives such
62
as resveratrol (Zhang, Cao, Ma, Chen, & Li, 2017), carvacrol (Andrade-Del Olmo,
63
Pérez-Álvarez, Hernáez, Ruiz-Rubio, & Vilas-Vilela, 2019), or gallic acid (Munhuweyi,
64
Caleb, Reenen, & Opara, 2018).
65
The goal of this work was to assess the effectiveness of cyclodextrin inclusion
66
complexes as stabilizers and release controllers of 2-phenyl ethanol in chitosan films.
67
2-phenyl ethanol is naturally present in more than one hundred food products (Nijssen,
68
Ingen-Visscher, & van Donders, 2016) and it is used in food industry to enhance
69
flavour and odor. Although it has bacteriostatic and antifungal character, it is very 4
70
volatile and highly susceptible to oxidation, thus, storing and keeping it stable is a
71
troublesome (Yadav, & Lawate, 2011). In order to address this challenge, 2-phenyl
72
ethanol has been microencapsulated with methylcellulose, alginate and carboxymethyl
73
chitosan (Qiu, Tian, Yin, Zhou, & Zhu, 2019). However, to the best of our knowledge,
74
this work assesses the effectiveness of 2-phenyl ethanol trapped into α-, β-, and γ-CDs
75
for the first time. Additionally, chitosan films with β-CD:2-phenyl ethanol were
76
developed and the optical, physicochemical and mechanical properties of the films
77
were characterized. In order to assess if the addition of the inclusion complex alters the
78
properties of the film, neat chitosan and chitosan with 2-phenyl ethanol films were
79
prepared. Furthermore, the release of 2-phenyl ethanol from chitosan films into a fatty
80
food simulant was determined.
81
2. Materials and methods
82
2.1. Materials
83
Chitosan (CHI), with a molecular weight of 375 kDa and a deacetylation degree above
84
75 %, was supplied by Sigma-Aldrich, Spain. Acetic acid (1 N) and glycerol (GLY, 99.0
85
% purity), used as solvent and plasticizer, respectively, were supplied by Panreac,
86
Spain. 2-phenyl ethanol and α- and β-cyclodextrins (CAVAMAX® w6 and w7,
87
respectively), used for the development of inclusion complexes, were food grade and
88
supplied by Wacker Chemical, Spain; while γ-cyclodextrins were provided by Roquette,
89
France.
90
2.2. Inclusion complex preparation
91
The inclusion complexes of 2-phenyl ethanol were prepared according to Barba,
92
Eguinoa, & Maté (2015) with some modifications. Firstly, 10 % (w/w) cyclodextrins
93
were hydratated for 10 min; then, 2-phenyl ethanol was added in equimolar ratio and
94
the mixture was mechanically stirred for 24 h. In order to obtain the dry powder, a B-
95
191, Büchi spray-dryer was used at the following conditions: 100 % aspirator capacity, 5
96
inlet temperature of 180 ºC, and pump at 4 mL/min. The powder was collected and
97
stored in vials at -20 ºC.
98
2.3. FTIR analysis of α-, β-, and γ-cyclodextrin complexes
99
Fourier-transform infrared (FTIR) spectroscopy was carried out with a Nicolet Avatar
100
260. Inclusion complexes (α-CD:2-phenyl ethanol, β-CD:2-phenyl ethanol, and γ-CD:2-
101
phenyl ethanol), cyclodextrins (α-CD; β-CD and γ-CD) and 2-phenyl ethanol were
102
milled with anhydrous KBr and the pellet was formed by compression. The spectra
103
were recorded between 4000-800 cm-1 with 32 scans and a resolution of 4 cm-1.
104
2.4. Retention of 2-phenyl ethanol cyclodextrin
105
2-phenyl ethanol was extracted from cyclodextrins by liquid-liquid extraction following
106
the method of Charve & Reineccius (2009) with some modifications. The analysis was
107
carried out one week after the inclusion complex was formed. 0.15 g of the inclusion
108
complex was weighed and added into a centrifuge glass tube and 5 mL hexane and 10
109
mL distilled water were added. The mixture was shaken energetically for 2 min and
110
then, vortexed for 2 min. The samples were put into a bath at 85 ºC and shacked for 30
111
min. The organic phase was gathered into a 50 mL flask. For each sample, three
112
extractions were carried out, adding the organic phase into the 50 mL flask. A fourth
113
extraction was done to confirm that the extraction was completed. From a 1:10
114
solution, 1 µL was injected into a Hewlett-Packard 5890 series II gas chromatography
115
spectrometer (Agilent Technology, Barcelona, Spain), equipped with a flame ionization
116
detector (FID) and a Supra Wax 280 column (1.0 µm x 0.53 mm, 30 m). The gas carrier
117
employed was helium, the injection temperature was 250 ºC, the oven temperature
118
program was started at 40 ºC with a temperature ramp of 5 ºC/min up to 220 ºC (1
119
min), and the detector temperature was set at 300 ºC. In order to avoid the fluctuation
120
of the signal, an internal standard (1-heptanol) was added to the calibration standards
6
121
and samples. The retention of 2-phenyl ethanol was calculated as the ratio of
122
experimental concentration over the theoretical content.
123
2.5. Films preparation
124
Chitosan films were prepared by solution casting. 1 wt % chitosan was dissolved in 1
125
wt % acetic acid solution under stirring for 45 min. Then, 10 wt % 2-phenyl ethanol or
126
10 wt % β-CD:2-phenyl ethanol (based on chitosan) was added and stirring was
127
continued for other 30 min. Finally, 15 wt % glycerol (based on chitosan) was added
128
into some solutions as plasticizer and other 30 min of stirring were needed until total
129
homogenization of the mixture. The solution was casted into Petri dishes and dried at
130
room temperature for 48 h. In total, six compositions were analyzed: control films,
131
named as CHI0GLY and CHI15GLY as a function of glycerol content; chitosan films
132
with 2-phenyl ethanol, named as CHI0GLY2PE and CHI15GLY2PE; and chitosan films
133
with β-CD:2-phenyl ethanol inclusion complex, named as CHI0GLYCD:2PE and
134
CHI15GLYCD:2PE.
135
2.6. Optical properties of films
136
Color and gloss parameters of the films were analyzed. Color measurements were
137
recorded with a CR-400 Minolta Chroma Meter colorimeter (Konica Minolta, Tokyo,
138
Japan). Ten replicates were carried out for each sample. For the determination of color
139
parameters CIELAB scale was used: L* from 0 to 100 (from black to white), a* from –
140
to + (from greenness to redness), and b* from – to + (from blueness to yellowness).
141
The films were laid on a standard white plate with color parameter values of L*= 97.39,
142
a*= 0.03 and b*= 1.77.
143
Multi Gloss 268 Plus (Konica Minolta, Tokyo, Japan) was used for the determination of
144
gloss with an incidence angle of 60º according to ASTM D523 (ASTM, 2018). For each
145
composition, ten samples were assessed at room temperature.
7
146
Light-barrier capacity of films was measured by using a UV-VIS-NIR Shimadzu 3600
147
spectrophotometer (Shimadzu Scientific Instruments, Kyoto, Japan) in the range of
148
200-800 nm.
149
2.7. Physicochemical properties of films
150
A Nicolet Nexus FTIR spectrometer (Thermo Fisher Scientific, Messachusetts, USA)
151
with a Golden Gate ATR sampling accessory was employed for collecting FTIR
152
spectra. The spectra were acquired between 4000 and 800 cm-1 with 32 scans for each
153
sample and a resolution of 4 cm-1.
154
A PANalytic Xpert Pro (PANalytical, Almelo, The Netherlands) X-ray diffraction (XRD)
155
equipment was employed with a diffraction unit at 40 kV and 40 mA. A Cu-Kα source
156
(λ= 1.5418 Å) was employed as radiation source and the data were collected between
157
2º and 34º (step size = 0.026, time per step = 118 s).
158
2.8. Mechanical and barrier properties of films
159
In order to determine the tensile strength (TS), elongation at break (EAB) and Young’s
160
modulus (E), an Instron 5967 electromechanical testing system (Instron,
161
Massachusetts, USA) was used. Samples were cut into dog bone-shaped of 4.75 mm
162
× 22.25 mm and tests were carried out according to ASTM D1708-13 (ASTM 2013). A
163
tensile load cell of 500 N was used and tensile tests were carried out with a crosshead
164
rate of 1 mm/min. Five replicates were tested for each sample.
165
Water vapor permeability (WVP) was tested with a PERME™ W3/0120 chamber
166
(Labthink Instruments Co. Ltd., Shandong, China) in a controlled humidity environment,
167
according to ASTM E96-00 (ASTM, 2000). Film discs were cut with a diameter of 7.40
168
cm and a test area of 33 cm2. The temperature and relative humidity were set up at 38
169
ºC and 90 %, respectively. Water vapor transmission rate (WVTR) was calculated as:
=
· 8
170
where G is the weight change (g), t is the time (s), and A is the film area that was
171
tested (cm2).
172
WVP was calculated by the following equation:
=
∆
·
173
where L is the film thickness (cm) and ∆P is the partial pressure difference of the water
174
vapor across the film (Pa).
175
Three replicates for each sample were reported for the WVP analysis.
176
2.9. Bioactive release
177
Film pieces (1 cm x 2 cm) were submerged into 8 mL of 95 % ethanol solution, used as
178
a fatty food simulant (Liang et al., 2017), for 4 days under continuous stirring (200 rpm)
179
at room temperature. Aliquots were collected at different times (30 min, 1 h, 2 h, 4 h, 8
180
h, 1 d, 2 d, 3 d, and 4 d). The bioactive release was analyzed by using a UV-VIS-NIR
181
Shimadzu 3600 spectrophotometer (Shimadzu Scientific Instrument, Kyoto, Japan). 2-
182
phenyl ethanol concentration was calculated by means of a calibration curve from 0.1
183
to 10.0 µg/ mL at the maximum wavelength absorbance (207 nm). The accumulative
184
release percentage was calculated by the ratio of the release determined by the
185
calibration curve and the theoretical total release.
186
2.10. Statistical analysis
187
In order to determine significant differences among the samples, analysis of variance
188
(ANOVA) was carried out with SPSS software (SPSS Statistics 25.0). For multiple
189
comparisons, Tukey’s multiple range test was used with a statistically significance at
190
the P < 0.05 level.
191
3. Results and discussion
192
3.1. Characterization of α-, β-, and γ-cyclodextrin inclusion complexes 9
193
FTIR spectroscopy was used in order to characterize α-, β-, and γ-cyclodextrin
194
inclusion complexes with 2-phenyl ethanol. As can be seen in Figure 1, the O-H
195
stretching vibration band is observed around 3390 cm-1, indicative of the hydroxyl
196
groups of cyclodextrin (Salih et al., 2020). The C-O-C stretching vibrations are
197
observed at 1158 cm-1, associated to the oligosaccharide structure, and the bands at
198
1080 and 1030 cm-1 correspond to the C-C stretching vibrations of the cyclodextrin ring
199
carbons (Han, Zhang, Shen, Zheng & Zhang, 2019). Additionally, the characteristic
200
band of the α-pyranyl vibration in cyclodextrin appeared at 943 cm−1 and the
201
characteristic band of α-(1,4) glucopyranose in cyclodextrin appeared at 890 cm−1
202
(Yuan, Ye, Gao, Yuan, Lan, Lou, Wang, 2013). As can be seen, there was no chemical
203
interaction between the cyclodextrin and 2-phenyl ethanol. However, some
204
characteristic bands of cyclodextrin were shifted in the inclusion complex spectra. The
205
O-H stretching vibration displaced from 3383 cm-1 for β-cyclodextrin to 3393 cm-1 for
206
the inclusion complex. Furthermore, C-O-C stretching vibration band moved slightly to
207
lower wavenumbers, from 1158 cm-1 for β-cyclodextrin to 1157 cm-1 for the inclusion
208
complex. The shift of these bands suggested physical interactions between
209
cyclodextrins and 2-phenyl ethanol (Xiao, Hou, Kang, Niu, & Kou, 2019).
γ-CD α-CD β-CD
Transmittance (%)
γ-CD:2-PE α-CD:2-PE β-CD:2-PE
890 943 1158
3390
4000
3500
3000
2500
2000
1500
1000
Wavenumber (cm-1)
210 211
Figure 1. FTIR spectra of α-, β-, and γ-cyclodextrin (CD) inclusion complexes. 10
212
3.2. Retention yield of 2-phenyl ethanol
213
The retention yield of 2-phenyl ethanol for α-, β-, and γ-cyclodextrin inclusion
214
complexes was determined. The highest value was observed for β-clyclodextrin
215
inclusion complex (45 %), followed by γ-cyclodextrin (40 %) and finally, α-cyclodextrin
216
(32 %). These relative low retention values can be related to the fact that 2-phenyl
217
ethanol has only one hydroxyl group to get attached to the cyclodextrin and, thus, the
218
interactions could be weaker. Regarding the differences in retention values, those
219
differences can be associated to the cavity size of CDs. While α-cyclodextrin cavity is
220
the smallest (5.7 Å) to host 2-phenyl ethanol, γ-cyclodextrin cavity is too big (9.5 Å)
221
and, therefore, the interactions between the host and the guest were weaker. However,
222
β-cyclodextrin cavity (7.8 Å) was big enough to host 2-phenyl ethanol and small
223
enough to facilitate physical interactions between them (Ciobanu, Mallard, Landy,
224
Brabie, Nistor & Fourmentin, 2013; Decock, Landy, Surpateanu, & Fourmentin, 2008).
225
Taking the above into consideration, chitosan films were prepared with the inclusion
226
complex with the highest retention yield; therefore, β-cyclodextrin:2-phenyl ethanol
227
inclusion complexes were incorporated into chitosan film forming solutions.
228
3.3. Optical properties of films
229
All films were transparent and colorless. Regarding CIELab color parameters (Table 1),
230
all films presented L* values close to 100, indicating high lightness of the films, a*
231
parameter had slightly negative values, while b* parameter showed positive values, as
232
also shown in other works for chitosan films (Pereira, Queiroz de Arruda, & Stefani,
233
2015). Considering the ∆E* value referred to CHI0GLY, the films did not show
234
differences for the naked eye, since ∆E* values were lower than 1 (Uranga et al.,
235
2019). Furthermore, statistical analysis concluded that there were no significant
236
difference among samples for L*, a* and ∆E* parameters, only a slight difference for b*
237
value, which was not relevant. Therefore, the addition of glycerol, 2-phenyl ethanol, or 11
238
the inclusion complex did not affect the film color. Regarding gloss values (Table 1),
239
there was a slight increase (P < 0.05) with the addition of 2-phenyl ethanol or the
240
inclusion complex, but there was no significant (P > 0.05) difference among the films
241
with 2-phenyl ethanol, regardless the presence of CDs. Gloss and surface roughness
242
are inversely correlated; therefore, lower values of gloss are related to rougher
243
surfaces (Luchese, Uranga, Spada, Tessaro, & de la Caba, 2018; Valencia-Sullca et
244
al., 2016). For an incidence angle of 60º, values greater than 70 gloss units (G.U.) are
245
considered glossy surfaces (Villalobos et al. 2005); therefore, the values measured in
246
this work indicated that chitosan film surface was rough.
247
Table 1. Color (L*, a*, b* and ∆E* parameters) and gloss values for chitosan films. Film
L*
a* a
b* a
a
∆E*
Gloss60 (G.U.)
CHI0GLY
96.9 ± 0.5
-0.03 ± 0.06
2.5 ± 0.2
---
14 ± 2a
CHI15GLY
96.6 ± 0.4a
-0.11 ± 0.08a
3.1 ± 0.3b
0.6a
16 ± 1a
CHI0GLY2PE
96.7 ± 0.3a
-0.08 ± 0.09a
2.8 ± 0.2a
0.3a
18 ± 2a,b
CHI15GLY2PE
96.8 ± 0.3a
-0.11 ± 0.07a
2.9 ± 0.2b
0.4a
20 ± 2b
CHI0GLYCD:2PE
96.4 ± 0.3a
-0.10 ± 0.04a
2.9 ± 0.2b
0.6a
20 ± 1b
CHI15GLYCD:2PE
96.4 ± 0.7a
-0.11 ± 0.08a
2.9 ± 0.2b
0.6a
20 ± 1b
248
Two means followed by the same letter in the same parameter are not significantly
249
(P > 0.05) different through the Tukey's multiple range test.
250
Additionally, ultraviolet-visible (UV-vis) spectroscopy was carried out and results are
251
shown in Figure 2. As can be seen, films were transparent since there was no
252
absorption at 600 nm (Uranga et al., 2019). Furthermore, there was no absorption in
253
the visible range from 400 to 800 nm, although chitosan films absorbed UV light,
254
especially below 250 nm, probably due to some chromophores present in chitosan
255
(Leceta, Guerrero, Ibarburu, Dueñas, & de la Caba, 2013). In this regard, UV light
256
barrier properties provide films with value-added properties, which can reduce lipid
257
oxidation in food products and extend food shelf life (Fasihi, Noshirvani, Hashemi,
258
Fazilati, Salavati, & Coma, 2019).
12
Absorbance (a.u.) 200
300
400
500
600
700
800
Wavelength (nm)
259 260
Figure 2. UV-vis light absorption of chitosan films: CHI0GLY, blue line; CHI15GLY, red
261
line; CHI0GLY2PE, green line; CHI15GLY2PE, pink line; CHI0GLYCD:2PE, orange
262
line; and CHI15GLYCD:2PE, black line.
263
3.4. Physicochemical properties of films
264
In order to assess the interactions among the components of the films, FTIR analysis
265
was carried out and the FTIR spectra of chitosan films are shown in Figure 3. The
266
characteristic bands of chitosan appeared at 1630 cm-1 (amide I band), associated to
267
C=O stretching; at 1530 cm-1 (amide II band), related to N-H bending; and at 1310 cm-1
268
(amide III band) assigned to C-N stretching (Mauricio-Sánchez, Salazar, Luna-
269
Bárcenas, & Mendoza-Galván, 2018). Moreover, O-H stretching band and C-O-C
270
absorption band were observed at 3250 cm-1 and around 1080 cm-1, respectively
271
(Branca et al., 2016). No new band was observed between the control spectra and the
272
spectra corresponding to the films with 2-phenyl ethanol, with or without CDs,
273
indicating that no chemical reaction occurred. However, some band displacements
274
were observed when β-CD:2-phenyl ethanol was incorporated into chitosan films; in
275
particular, for O-H and N-H stretching band from 3264 to 3214 cm-1, for amide II band
276
from 1546 to 1538 cm-1, and for amide III band from 1324 to 1332 cm-1. This suggests
13
physical interactions, such as hydrogen bonding or electrostatic interactions among the
278
components of the films (Roy & Rhim, 2020). Additionally, a similar behavior was
279
observed with the addition of glycerol since O-H and N-H stretching band shifted from
280
3214 to 3243 cm-1 and amide II band from 1538 to 1540 cm-1 due to hydrogen bonding
281
with glycerol.
Transmittance (%)
277
Amide III Amide I Amide II
4000
3500
3000
2500
2000
1500
1000
Wavenumber (cm-1)
282 283
Figure 3. FTIR spectra of chitosan films: CHI0GLY, blue line; CHI15GLY, red line;
284
CHI0GLY2PE, green line; CHI15GLY2PE, pink line; CHI0GLYCD:2PE, orange line;
285
and CHI15GLYCD:2PE, black line.
286
In order to determine the structure of the films, XRD analysis was carried out. As can
287
be observed in Figure 4, films without the inclusion complex present two broad peaks,
288
one at 11.7º and another one around 21.3º, characteristic of chitosan (Pang &
289
Zhitomirsky, 2005). These broad peaks indicate the amorphous character of chitosan
290
films. Regarding the films with the inclusion complex, two sharp peaks appeared at 6.2º
291
and 12.3º, characteristic of β-CD (Campos et al., 2019; Menezes et al., 2016). This
292
indicates that CDs maintained certain degree of crystallinity after the incorporation into
293
chitosan matrix. However, the intensity of these peaks was different for the films with
294
and without glycerol, which could be attributed to the change in molecular organization
14
of the cyclodextrin (Campos et al., 2018). Since glycerol is a small molecule, it can
296
penetrate between chitosan chains, decreasing intramolecular interactions among
297
chitosan chains and facilitating the interactions of chitosan with the additives
298
incorporated into the film forming formulation (Zarandona, Puertas, Dueñas, Guerrero,
299
& de la Caba, 2020). As shown by FTIR results, the intermolecular interactions with
300
cyclodextrin molecules occurred by hydrogen bonding, which changed the chitosan film
301
structure due to the heterogeneous nucleation effect between the inclusion complex
302
and chitosan (Li, & Zhen, 2017) and, as a consequence, the film mechanical behavior
303
also changed.
Intensity (a.u.)
295
2
4
6
8
10 12 14 16 18 20 22 24 26 28 30 32 34
2θ (º)
304 305
Figure 4. XRD diffractograms of chitosan films: CHI0GLY, blue line; CHI15GLY, red
306
line; CHI0GLY2PE, green line; CHI15GLY2PE, pink line; CHI0GLYCD:2PE, orange
307
line; and CHI15GLYCD:2PE, black line.
308
3.5. Mechanical and barrier properties
309
In order to assess the effect of structure changes in the mechanical behavior, tensile
310
tests were performed and TS and EAB values were measured and shown in Table 2.
311
As expected, films plasticized with glycerol showed higher EAB values and lower TS
312
and EM values, indicating more flexible and less rigid films due to the increase of free 15
313
volume (Rivero, Damonte, Garcia, & Pinotti, 2016). Regarding the addition of 2-phenyl
314
ethanol to the film forming solution, it was observed that this compound did not
315
significantly (P > 0.05) change TS or EAB values with respect to the corresponding
316
control film, probably due to the 2-phenyl ethanol evaporation during film preparation
317
when CDs were not used; however, an increase of EM values was noticed, indicating a
318
higher rigidity, probably due to the interactions among chitosan and the remaining
319
amount of 2-PE. The most significant change was observed for TS values when the
320
inclusion complex was incorporated into formulations; in particular, TS value
321
significantly (P < 0.05) increased from 34.5 to 48.8 MPa for the chitosan films with the
322
inclusion complex but without glycerol. In accordance, EM values also increased and
323
EAB values decreased. This behavior can be related to the interactions among
324
chitosan and CD, as shown by FTIR analysis, which would lead to a more compact
325
network, increasing resistance and rigidity, but decreasing flexibility (Siripatrawan &
326
Vitchayakitti, 2016; Sun et al., 2014). It is worth noting that TS values above 40 MPa
327
are higher values than those found for commercial packaging films, such as PP or
328
LDPE (Honarvar et al., 2017, Lomate, Dandi, & Mishra, 2018).
329
Table 2. Tensile strength (TS, MPa), elongation at break (EAB, %), Young’s Modulus
330
(EM, MPa) and water vapor permeability (WVP, g·cm-1·s-1·Pa-1) of chitosan films.
Film
TS
EAB
EM
WVP -12
(MPa)
(%)
(MPa)
(10 g·cm-1·s-1·Pa-1)
CHI0GLY
34.5 ± 2.2a
9.2 ± 2.2b
1511 ± 163a,b
1.08 ± 0.04a
CHI15GLY
32.4 ± 3.1a 16.4 ± 3.1a
1374 ± 125a
1.04 ± 0.02a
CHI0GLY2PE
39.5 ± 3.6a
7.8 ± 1.6b
2205 ± 114c
0.89 ± 0.04b
CHI15GLY2PE
33.7 ± 3.4a 12.3 ± 3.4a
1687 ± 72b
0.82 ± 0.01b
CHI0GLYCD:2PE
48.8 ± 3.2b
7.4 ± 2.2b
2639 ± 173d
0.83 ± 0.03b
CHI15GLYCD:2PE 37.5 ± 4.1a
8.1 ± 2.3b
1960 ± 84c
0.85 ± 0.02b
331
Two means followed by the same letter in the same parameter are not significantly
332
(P > 0.05) different through the Tukey's multiple range test.
16
333
Regarding water vapor permeability (WVP), there was no significant difference (P >
334
0.05) between the chitosan films without 2-phenyl ethanol. However, the addition of the
335
active compound significantly (P < 0.05) decreased WVP values, probably due to the
336
interactions with chitosan (Salami, Rezaee, Askari, & EmamDjomeh, 2020), as shown
337
by FTIR, and also due to the increase of crystallinity, as observed by XRD. Although
338
WVP values found in this work are lower than those measured for chitosan films in
339
other works (Priyadarshi, Sauraj, Kumar, Deeba, Kulshreshtha, & Negi, 2018), these
340
values are still higher than those shown by commercial films (Honarvar et al., 2017,
341
Lomate, Dandi, & Mishra, 2018).
342
3.6. Release of 2-phenyl ethanol
343
The release of 2-phenyl ethanol from chitosan films with 2-phenyl ethanol and from
344
chitosan films with β-cyclodextrin:2-phenyl ethanol was carried out in order to compare
345
the delivery trend during the immersion into 95 % ethanol for 4 days (Figure 5).
346
Regarding CHI0GLY2PE films, it is worth noting that some bioactive content was lost
347
before the analysis, probably during film preparation due to the high volatility of the
348
compound and, as a result, a maximum release of 8 % was achieved. However,
349
chitosan films with the inclusion complex retained the bioactive inside β-cyclodextrin
350
after film preparation. An improvement of 2-PE retention through its encapsulation with
351
methylcellulose, alginate sodium and carboxymethyl chitosan has also been observed
352
in other works (Qiu, Tian, Yin, Zhou, & Zhu, 2019). In this work, 2-phenyl ethanol was
353
released after 4 h of immersion into 95 % ethanol. The fast release of 2-phenyl ethanol
354
could be explained due to the weak interactions with β-cyclodextrin, since 2-pheyl
355
ethanol has only one hydroxyl group.
17
100
Release (%)
80
60
40
20
0 0
10
20
30
40
50
60
70
80
90
100
Time (h)
356 357
Figure 5. Bioactive release from chitosan films: CHI0GLY2PE, green line;
358
CHI0GLYCD:2PE, orange line.
359
4. Conclusions
360
This work showed the good capacity of cyclodextrins to form inclusion complex with 2-
361
phenyl ethanol. Specifically, β-cyclodextrin showed the highest retention yield. The
362
films obtained were homogeneous, transparent and colorless. Moreover, the addition of
363
the inclusion complex into chitosan film forming solutions led to chitosan films with
364
improved properties. In particular, tensile strength reached values up to 48 MPa. The
365
tensile strength increase was related to the physical interactions between chitosan and
366
the inclusion complex, which were corroborated by FTIR and XRD analyses, which
367
indicated the crystalline structure of chitosan films with the inclusion complex. Finally,
368
the release of 2-phenyl ethanol into 95 % ethanol was carried out in films with and
369
without β-cyclodextrin. Results suggested that the bioactive was evaporated during film
370
preparation for the films without the inclusion complex. In contrast, the films with the
371
inclusion complex preserved the bioactive inside the inclusion complex. These results
372
indicated that CDs were effective to avoid the loss of bioactive compounds during film
373
preparation. 18
374
Acknowledgments
375
Authors thank the Ministry of Science, Innovation and Universities (RTI2018-097100-B-
376
C22), the University of the Basque Country (GIU18/154), and the Basque Government
377
(Department of Quality and Food Industry) for their financial support. Iratxe Zarandona
378
thanks the Quality and Food Industry Department of the Basque Government for her
379
fellowship (22-2018-00078). Carmen Barba thanks Public University of Navarre for the
380
financial support for young researcher projects (UPNA2018-04-INC). Also thanks are
381
due to the Advanced Research Facilities (SGIker) from the UPV/EHU. Finally, authors
382
would like to thank Roquette and Wacker Chemie AG for providing cyclodextrin
383
samples.
384
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27
Highlights •
Cyclodextrins (CDs) formed inclusion complexes with 2-phenyl ethanol.
•
β-CDs showed higher retention yield than α- or γ-CDs.
•
Films with β-CD:2-phenyl ethanol were homogeneous, transparent and colorless.
•
Tensile strength of chitosan films reached values up to 48 MPa.
•
Films with inclusion complex preserved the bioactive inside the inclusion complex.
Conflict of interest Authors declare no conflict of interest
S0268-005X(19)32273-8
DOI:
https://doi.org/10.1016/j.foodhyd.2020.105720
Reference:
FOOHYD 105720
To appear in:
Food Hydrocolloids
Received Date: 28 September 2019 Revised Date:
3 January 2020
Accepted Date: 27 January 2020
Please cite this article as: Zarandona, I., Barba, C., Guerrero, P., de la Caba, K., Maté, J., Development of chitosan films containing β-cyclodextrin inclusion complex for controlled release of bioactives, Food Hydrocolloids (2020), doi: https://doi.org/10.1016/j.foodhyd.2020.105720. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. 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. © 2020 Published by Elsevier Ltd.
Author statement I. Zarandona: Investigation, Writing-Original Draft C. Barba: Conceptualization, Investigation, Funding acquisition P. Guerrero: Formal analysis, Supervision, Writing-Review & Editing K. de la Caba: Supervision, Writing-Review & Editing, Funding acquisition J. Maté: Conceptualization, Resources, Writing-Review & Editing,
60
2-phenylethanol Retention efficiency (%)
β-cyclodextrin (β-CD)
40
20
0
-CD
H3C HO
OH
NH2
HO
O HO OH
NH O O
O H2N
-CD
O
O
O
O
-CD
OH
Chitosan films with β-CD:2-phenylethanol inclusion complexes
Development of chitosan films containing β -cyclodextrin inclusion complex for controlled release of bioactives. I. Zarandonaa, C. Barbab, P. Guerreroa*, K. de la Cabaa, J. Matéb a
BIOMAT research group, University of the Basque Country (UPV/EHU), Escuela de
Ingeniería de Gipuzkoa, Plaza de Europa 1, 20018 Donostia-San Sebastián, Spain. b
Department of Agronomy, Biotechnology and Food Science, Public University of
Navarre (UPNa), Campus Arrosadía s/n, Edificio Los Olivos, Pamplona 31006, Spain.
*Corresponding author: Pedro Guerrero e-mail: [email protected] telephone number: +34943018535 1
1
Abstract
2
2-phenyl ethanol is a natural compound, which have many applications due to its nice
3
fragrance, bacteriostatic and antifungal character. However, it is difficult to keep it
4
stable and it is highly volatile. In this work, chitosan films with 2-phenyl ethanol were
5
developed and inclusion complexes with cyclodextrins (CDs) were prepared in order to
6
have a controlled release of 2-phenyl ethanol. β-CD was selected to develop the
7
inclusion complex since it showed higher retention yield (45 %, molar basis) than α- or
8
γ-CDs. Chitosan films incorporated with β-CD:2-phenyl ethanol were homogeneous,
9
transparent and colorless, and showed high mechanical resistance. Furthermore, the
10
release results of the films without the inclusion complex indicated that 2-phenyl
11
ethanol was evaporated during the film preparation, and only an 8 % of the total
12
bioactive was retained in the film, while more than 90 % of 2-phenyl ethanol was
13
retained in the films with the inclusion complex.
14
Keywords: chitosan film; inclusion complex; β-cyclodextrin; 2-phenylethanol; bioactive
15
retention; controlled release.
2
16
1. Introduction
17
The use of active compounds is a strategy to confer functional properties, such as
18
antimicrobial, antioxidant or ultraviolet (UV) light barrier properties, to films. However,
19
many of these compounds, such as vitamins, antioxidants or flavors, are not stable
20
under the preparation, storage and/or use conditions (Hosseini, Nahvi, & Zandi, 2019;
21
Li, Maldonado, Malmr, Rouf, Hua, & Kokini, 2019). Therefore, the use of encapsulation
22
agents for active compounds become necessary to protect the compound from
23
volatilization or possible reactions with external agents, and also to control a sustained
24
release (Reineccius, 2009). Among encapsulation processes, spray-drying, spray-
25
cooling, extrusion or molecular inclusion are employed in industrial processes, but only
26
molecular inclusion occurs at molecular level and, thus, one molecule of the active
27
compound is trapped in the cavity of the host molecule (Reineccius, Reineccius, &
28
Peppard, 2002). The union between the active compound and the host molecule is
29
called inclusion complex. One of these host molecules is cyclodextrin, since the Food
30
and Agriculture Organization (FAO) of the United Nations recognizes it as additive
31
(FAO, 2019).
32
Cyclodextrins (CD) are cyclic oligosaccharides constituted of glucose molecules joined
33
together by α-1,4 bonds (Szente & Szejtli, 1999). CDs are hollow truncated cone
34
structures with an external hydrophilic character and an internal hydrophobic character
35
(Simionato, Domingues, Nerín, & Silva, 2019; Huang, Xu, Ge, & Cheng, 2019).
36
Therefore, it is a suitable molecule to host a variety of bioactives, including those that
37
are non-soluble in water since interactions between cyclodextrins and guest molecules
38
include hydrophobic forces as well as hydrogen bonding (Zhou, Lu, Zhou, & Liu, 2019).
39
Depending on the glucopyranose units conforming the molecule, the most common
40
CDs are α-, β- or γ-CDs, composed of 6, 7 or 8 glucopyranose units, respectively
41
(Prabu & Mohamad, 2020). Due to the variety of guest molecules that can host and
42
their acceptability as food additives, CDs are widely used in food and pharmaceutical 3
43
industries. Regarding food industry, CDs can be employed for different applications,
44
such as food supplement for spaghetti, adding pumpkin oil (Durante et al., 2019), as
45
flavor masking, reducing the high intensity of sourness, bitterness and astringency
46
flavor in lingonberry juice (Kalanne et al., 2019), or as thermal stabilizers (Yoshikiyo et
47
al., 2019). In the pharmaceutical industry, CDs are used to increase drug permeability,
48
solubility and stability and to enhance organoleptic characteristics (Chantasart, &
49
Rakkaew, 2019; Santana, Nadvorny, Passos, Soares, & Soares-Sobrinho, 2019; Yildiz,
50
& Uyar, 2019). Regarding preparation, there are different methods for the inclusion
51
complex preparation, such as freeze-drying, spray drying or coprecipitation (Suzuki et
52
al., 2019).
53
CDs can be used in a variety of matrixes. Morin-β-CD complexes have been
54
incorporated into gelatin to prepare antioxidant films (Yuan et al., 2019). Also
55
antimicrobials, such as citral, have been used to prepare β-CD inclusion complexes to
56
preserve bioactivity during melt extrusion of EVOH films (Chen, Li, Ma, Mcdonald, &
57
Wang, 2019). In order to provide films with both antioxidant and antibacterial
58
properties, essential oils have been encapsulated into β-CD to promote cumulative
59
release from chitosan films for food packaging applications (Adel, Ibrahim, El-Shafei, &
60
Al-Shemy, 2019). In this regard, several works have been reported in relation to the
61
use of chitosan with CD inclusion complexes for controlled release of bioactives such
62
as resveratrol (Zhang, Cao, Ma, Chen, & Li, 2017), carvacrol (Andrade-Del Olmo,
63
Pérez-Álvarez, Hernáez, Ruiz-Rubio, & Vilas-Vilela, 2019), or gallic acid (Munhuweyi,
64
Caleb, Reenen, & Opara, 2018).
65
The goal of this work was to assess the effectiveness of cyclodextrin inclusion
66
complexes as stabilizers and release controllers of 2-phenyl ethanol in chitosan films.
67
2-phenyl ethanol is naturally present in more than one hundred food products (Nijssen,
68
Ingen-Visscher, & van Donders, 2016) and it is used in food industry to enhance
69
flavour and odor. Although it has bacteriostatic and antifungal character, it is very 4
70
volatile and highly susceptible to oxidation, thus, storing and keeping it stable is a
71
troublesome (Yadav, & Lawate, 2011). In order to address this challenge, 2-phenyl
72
ethanol has been microencapsulated with methylcellulose, alginate and carboxymethyl
73
chitosan (Qiu, Tian, Yin, Zhou, & Zhu, 2019). However, to the best of our knowledge,
74
this work assesses the effectiveness of 2-phenyl ethanol trapped into α-, β-, and γ-CDs
75
for the first time. Additionally, chitosan films with β-CD:2-phenyl ethanol were
76
developed and the optical, physicochemical and mechanical properties of the films
77
were characterized. In order to assess if the addition of the inclusion complex alters the
78
properties of the film, neat chitosan and chitosan with 2-phenyl ethanol films were
79
prepared. Furthermore, the release of 2-phenyl ethanol from chitosan films into a fatty
80
food simulant was determined.
81
2. Materials and methods
82
2.1. Materials
83
Chitosan (CHI), with a molecular weight of 375 kDa and a deacetylation degree above
84
75 %, was supplied by Sigma-Aldrich, Spain. Acetic acid (1 N) and glycerol (GLY, 99.0
85
% purity), used as solvent and plasticizer, respectively, were supplied by Panreac,
86
Spain. 2-phenyl ethanol and α- and β-cyclodextrins (CAVAMAX® w6 and w7,
87
respectively), used for the development of inclusion complexes, were food grade and
88
supplied by Wacker Chemical, Spain; while γ-cyclodextrins were provided by Roquette,
89
France.
90
2.2. Inclusion complex preparation
91
The inclusion complexes of 2-phenyl ethanol were prepared according to Barba,
92
Eguinoa, & Maté (2015) with some modifications. Firstly, 10 % (w/w) cyclodextrins
93
were hydratated for 10 min; then, 2-phenyl ethanol was added in equimolar ratio and
94
the mixture was mechanically stirred for 24 h. In order to obtain the dry powder, a B-
95
191, Büchi spray-dryer was used at the following conditions: 100 % aspirator capacity, 5
96
inlet temperature of 180 ºC, and pump at 4 mL/min. The powder was collected and
97
stored in vials at -20 ºC.
98
2.3. FTIR analysis of α-, β-, and γ-cyclodextrin complexes
99
Fourier-transform infrared (FTIR) spectroscopy was carried out with a Nicolet Avatar
100
260. Inclusion complexes (α-CD:2-phenyl ethanol, β-CD:2-phenyl ethanol, and γ-CD:2-
101
phenyl ethanol), cyclodextrins (α-CD; β-CD and γ-CD) and 2-phenyl ethanol were
102
milled with anhydrous KBr and the pellet was formed by compression. The spectra
103
were recorded between 4000-800 cm-1 with 32 scans and a resolution of 4 cm-1.
104
2.4. Retention of 2-phenyl ethanol cyclodextrin
105
2-phenyl ethanol was extracted from cyclodextrins by liquid-liquid extraction following
106
the method of Charve & Reineccius (2009) with some modifications. The analysis was
107
carried out one week after the inclusion complex was formed. 0.15 g of the inclusion
108
complex was weighed and added into a centrifuge glass tube and 5 mL hexane and 10
109
mL distilled water were added. The mixture was shaken energetically for 2 min and
110
then, vortexed for 2 min. The samples were put into a bath at 85 ºC and shacked for 30
111
min. The organic phase was gathered into a 50 mL flask. For each sample, three
112
extractions were carried out, adding the organic phase into the 50 mL flask. A fourth
113
extraction was done to confirm that the extraction was completed. From a 1:10
114
solution, 1 µL was injected into a Hewlett-Packard 5890 series II gas chromatography
115
spectrometer (Agilent Technology, Barcelona, Spain), equipped with a flame ionization
116
detector (FID) and a Supra Wax 280 column (1.0 µm x 0.53 mm, 30 m). The gas carrier
117
employed was helium, the injection temperature was 250 ºC, the oven temperature
118
program was started at 40 ºC with a temperature ramp of 5 ºC/min up to 220 ºC (1
119
min), and the detector temperature was set at 300 ºC. In order to avoid the fluctuation
120
of the signal, an internal standard (1-heptanol) was added to the calibration standards
6
121
and samples. The retention of 2-phenyl ethanol was calculated as the ratio of
122
experimental concentration over the theoretical content.
123
2.5. Films preparation
124
Chitosan films were prepared by solution casting. 1 wt % chitosan was dissolved in 1
125
wt % acetic acid solution under stirring for 45 min. Then, 10 wt % 2-phenyl ethanol or
126
10 wt % β-CD:2-phenyl ethanol (based on chitosan) was added and stirring was
127
continued for other 30 min. Finally, 15 wt % glycerol (based on chitosan) was added
128
into some solutions as plasticizer and other 30 min of stirring were needed until total
129
homogenization of the mixture. The solution was casted into Petri dishes and dried at
130
room temperature for 48 h. In total, six compositions were analyzed: control films,
131
named as CHI0GLY and CHI15GLY as a function of glycerol content; chitosan films
132
with 2-phenyl ethanol, named as CHI0GLY2PE and CHI15GLY2PE; and chitosan films
133
with β-CD:2-phenyl ethanol inclusion complex, named as CHI0GLYCD:2PE and
134
CHI15GLYCD:2PE.
135
2.6. Optical properties of films
136
Color and gloss parameters of the films were analyzed. Color measurements were
137
recorded with a CR-400 Minolta Chroma Meter colorimeter (Konica Minolta, Tokyo,
138
Japan). Ten replicates were carried out for each sample. For the determination of color
139
parameters CIELAB scale was used: L* from 0 to 100 (from black to white), a* from –
140
to + (from greenness to redness), and b* from – to + (from blueness to yellowness).
141
The films were laid on a standard white plate with color parameter values of L*= 97.39,
142
a*= 0.03 and b*= 1.77.
143
Multi Gloss 268 Plus (Konica Minolta, Tokyo, Japan) was used for the determination of
144
gloss with an incidence angle of 60º according to ASTM D523 (ASTM, 2018). For each
145
composition, ten samples were assessed at room temperature.
7
146
Light-barrier capacity of films was measured by using a UV-VIS-NIR Shimadzu 3600
147
spectrophotometer (Shimadzu Scientific Instruments, Kyoto, Japan) in the range of
148
200-800 nm.
149
2.7. Physicochemical properties of films
150
A Nicolet Nexus FTIR spectrometer (Thermo Fisher Scientific, Messachusetts, USA)
151
with a Golden Gate ATR sampling accessory was employed for collecting FTIR
152
spectra. The spectra were acquired between 4000 and 800 cm-1 with 32 scans for each
153
sample and a resolution of 4 cm-1.
154
A PANalytic Xpert Pro (PANalytical, Almelo, The Netherlands) X-ray diffraction (XRD)
155
equipment was employed with a diffraction unit at 40 kV and 40 mA. A Cu-Kα source
156
(λ= 1.5418 Å) was employed as radiation source and the data were collected between
157
2º and 34º (step size = 0.026, time per step = 118 s).
158
2.8. Mechanical and barrier properties of films
159
In order to determine the tensile strength (TS), elongation at break (EAB) and Young’s
160
modulus (E), an Instron 5967 electromechanical testing system (Instron,
161
Massachusetts, USA) was used. Samples were cut into dog bone-shaped of 4.75 mm
162
× 22.25 mm and tests were carried out according to ASTM D1708-13 (ASTM 2013). A
163
tensile load cell of 500 N was used and tensile tests were carried out with a crosshead
164
rate of 1 mm/min. Five replicates were tested for each sample.
165
Water vapor permeability (WVP) was tested with a PERME™ W3/0120 chamber
166
(Labthink Instruments Co. Ltd., Shandong, China) in a controlled humidity environment,
167
according to ASTM E96-00 (ASTM, 2000). Film discs were cut with a diameter of 7.40
168
cm and a test area of 33 cm2. The temperature and relative humidity were set up at 38
169
ºC and 90 %, respectively. Water vapor transmission rate (WVTR) was calculated as:
=
· 8
170
where G is the weight change (g), t is the time (s), and A is the film area that was
171
tested (cm2).
172
WVP was calculated by the following equation:
=
∆
·
173
where L is the film thickness (cm) and ∆P is the partial pressure difference of the water
174
vapor across the film (Pa).
175
Three replicates for each sample were reported for the WVP analysis.
176
2.9. Bioactive release
177
Film pieces (1 cm x 2 cm) were submerged into 8 mL of 95 % ethanol solution, used as
178
a fatty food simulant (Liang et al., 2017), for 4 days under continuous stirring (200 rpm)
179
at room temperature. Aliquots were collected at different times (30 min, 1 h, 2 h, 4 h, 8
180
h, 1 d, 2 d, 3 d, and 4 d). The bioactive release was analyzed by using a UV-VIS-NIR
181
Shimadzu 3600 spectrophotometer (Shimadzu Scientific Instrument, Kyoto, Japan). 2-
182
phenyl ethanol concentration was calculated by means of a calibration curve from 0.1
183
to 10.0 µg/ mL at the maximum wavelength absorbance (207 nm). The accumulative
184
release percentage was calculated by the ratio of the release determined by the
185
calibration curve and the theoretical total release.
186
2.10. Statistical analysis
187
In order to determine significant differences among the samples, analysis of variance
188
(ANOVA) was carried out with SPSS software (SPSS Statistics 25.0). For multiple
189
comparisons, Tukey’s multiple range test was used with a statistically significance at
190
the P < 0.05 level.
191
3. Results and discussion
192
3.1. Characterization of α-, β-, and γ-cyclodextrin inclusion complexes 9
193
FTIR spectroscopy was used in order to characterize α-, β-, and γ-cyclodextrin
194
inclusion complexes with 2-phenyl ethanol. As can be seen in Figure 1, the O-H
195
stretching vibration band is observed around 3390 cm-1, indicative of the hydroxyl
196
groups of cyclodextrin (Salih et al., 2020). The C-O-C stretching vibrations are
197
observed at 1158 cm-1, associated to the oligosaccharide structure, and the bands at
198
1080 and 1030 cm-1 correspond to the C-C stretching vibrations of the cyclodextrin ring
199
carbons (Han, Zhang, Shen, Zheng & Zhang, 2019). Additionally, the characteristic
200
band of the α-pyranyl vibration in cyclodextrin appeared at 943 cm−1 and the
201
characteristic band of α-(1,4) glucopyranose in cyclodextrin appeared at 890 cm−1
202
(Yuan, Ye, Gao, Yuan, Lan, Lou, Wang, 2013). As can be seen, there was no chemical
203
interaction between the cyclodextrin and 2-phenyl ethanol. However, some
204
characteristic bands of cyclodextrin were shifted in the inclusion complex spectra. The
205
O-H stretching vibration displaced from 3383 cm-1 for β-cyclodextrin to 3393 cm-1 for
206
the inclusion complex. Furthermore, C-O-C stretching vibration band moved slightly to
207
lower wavenumbers, from 1158 cm-1 for β-cyclodextrin to 1157 cm-1 for the inclusion
208
complex. The shift of these bands suggested physical interactions between
209
cyclodextrins and 2-phenyl ethanol (Xiao, Hou, Kang, Niu, & Kou, 2019).
γ-CD α-CD β-CD
Transmittance (%)
γ-CD:2-PE α-CD:2-PE β-CD:2-PE
890 943 1158
3390
4000
3500
3000
2500
2000
1500
1000
Wavenumber (cm-1)
210 211
Figure 1. FTIR spectra of α-, β-, and γ-cyclodextrin (CD) inclusion complexes. 10
212
3.2. Retention yield of 2-phenyl ethanol
213
The retention yield of 2-phenyl ethanol for α-, β-, and γ-cyclodextrin inclusion
214
complexes was determined. The highest value was observed for β-clyclodextrin
215
inclusion complex (45 %), followed by γ-cyclodextrin (40 %) and finally, α-cyclodextrin
216
(32 %). These relative low retention values can be related to the fact that 2-phenyl
217
ethanol has only one hydroxyl group to get attached to the cyclodextrin and, thus, the
218
interactions could be weaker. Regarding the differences in retention values, those
219
differences can be associated to the cavity size of CDs. While α-cyclodextrin cavity is
220
the smallest (5.7 Å) to host 2-phenyl ethanol, γ-cyclodextrin cavity is too big (9.5 Å)
221
and, therefore, the interactions between the host and the guest were weaker. However,
222
β-cyclodextrin cavity (7.8 Å) was big enough to host 2-phenyl ethanol and small
223
enough to facilitate physical interactions between them (Ciobanu, Mallard, Landy,
224
Brabie, Nistor & Fourmentin, 2013; Decock, Landy, Surpateanu, & Fourmentin, 2008).
225
Taking the above into consideration, chitosan films were prepared with the inclusion
226
complex with the highest retention yield; therefore, β-cyclodextrin:2-phenyl ethanol
227
inclusion complexes were incorporated into chitosan film forming solutions.
228
3.3. Optical properties of films
229
All films were transparent and colorless. Regarding CIELab color parameters (Table 1),
230
all films presented L* values close to 100, indicating high lightness of the films, a*
231
parameter had slightly negative values, while b* parameter showed positive values, as
232
also shown in other works for chitosan films (Pereira, Queiroz de Arruda, & Stefani,
233
2015). Considering the ∆E* value referred to CHI0GLY, the films did not show
234
differences for the naked eye, since ∆E* values were lower than 1 (Uranga et al.,
235
2019). Furthermore, statistical analysis concluded that there were no significant
236
difference among samples for L*, a* and ∆E* parameters, only a slight difference for b*
237
value, which was not relevant. Therefore, the addition of glycerol, 2-phenyl ethanol, or 11
238
the inclusion complex did not affect the film color. Regarding gloss values (Table 1),
239
there was a slight increase (P < 0.05) with the addition of 2-phenyl ethanol or the
240
inclusion complex, but there was no significant (P > 0.05) difference among the films
241
with 2-phenyl ethanol, regardless the presence of CDs. Gloss and surface roughness
242
are inversely correlated; therefore, lower values of gloss are related to rougher
243
surfaces (Luchese, Uranga, Spada, Tessaro, & de la Caba, 2018; Valencia-Sullca et
244
al., 2016). For an incidence angle of 60º, values greater than 70 gloss units (G.U.) are
245
considered glossy surfaces (Villalobos et al. 2005); therefore, the values measured in
246
this work indicated that chitosan film surface was rough.
247
Table 1. Color (L*, a*, b* and ∆E* parameters) and gloss values for chitosan films. Film
L*
a* a
b* a
a
∆E*
Gloss60 (G.U.)
CHI0GLY
96.9 ± 0.5
-0.03 ± 0.06
2.5 ± 0.2
---
14 ± 2a
CHI15GLY
96.6 ± 0.4a
-0.11 ± 0.08a
3.1 ± 0.3b
0.6a
16 ± 1a
CHI0GLY2PE
96.7 ± 0.3a
-0.08 ± 0.09a
2.8 ± 0.2a
0.3a
18 ± 2a,b
CHI15GLY2PE
96.8 ± 0.3a
-0.11 ± 0.07a
2.9 ± 0.2b
0.4a
20 ± 2b
CHI0GLYCD:2PE
96.4 ± 0.3a
-0.10 ± 0.04a
2.9 ± 0.2b
0.6a
20 ± 1b
CHI15GLYCD:2PE
96.4 ± 0.7a
-0.11 ± 0.08a
2.9 ± 0.2b
0.6a
20 ± 1b
248
Two means followed by the same letter in the same parameter are not significantly
249
(P > 0.05) different through the Tukey's multiple range test.
250
Additionally, ultraviolet-visible (UV-vis) spectroscopy was carried out and results are
251
shown in Figure 2. As can be seen, films were transparent since there was no
252
absorption at 600 nm (Uranga et al., 2019). Furthermore, there was no absorption in
253
the visible range from 400 to 800 nm, although chitosan films absorbed UV light,
254
especially below 250 nm, probably due to some chromophores present in chitosan
255
(Leceta, Guerrero, Ibarburu, Dueñas, & de la Caba, 2013). In this regard, UV light
256
barrier properties provide films with value-added properties, which can reduce lipid
257
oxidation in food products and extend food shelf life (Fasihi, Noshirvani, Hashemi,
258
Fazilati, Salavati, & Coma, 2019).
12
Absorbance (a.u.) 200
300
400
500
600
700
800
Wavelength (nm)
259 260
Figure 2. UV-vis light absorption of chitosan films: CHI0GLY, blue line; CHI15GLY, red
261
line; CHI0GLY2PE, green line; CHI15GLY2PE, pink line; CHI0GLYCD:2PE, orange
262
line; and CHI15GLYCD:2PE, black line.
263
3.4. Physicochemical properties of films
264
In order to assess the interactions among the components of the films, FTIR analysis
265
was carried out and the FTIR spectra of chitosan films are shown in Figure 3. The
266
characteristic bands of chitosan appeared at 1630 cm-1 (amide I band), associated to
267
C=O stretching; at 1530 cm-1 (amide II band), related to N-H bending; and at 1310 cm-1
268
(amide III band) assigned to C-N stretching (Mauricio-Sánchez, Salazar, Luna-
269
Bárcenas, & Mendoza-Galván, 2018). Moreover, O-H stretching band and C-O-C
270
absorption band were observed at 3250 cm-1 and around 1080 cm-1, respectively
271
(Branca et al., 2016). No new band was observed between the control spectra and the
272
spectra corresponding to the films with 2-phenyl ethanol, with or without CDs,
273
indicating that no chemical reaction occurred. However, some band displacements
274
were observed when β-CD:2-phenyl ethanol was incorporated into chitosan films; in
275
particular, for O-H and N-H stretching band from 3264 to 3214 cm-1, for amide II band
276
from 1546 to 1538 cm-1, and for amide III band from 1324 to 1332 cm-1. This suggests
13
physical interactions, such as hydrogen bonding or electrostatic interactions among the
278
components of the films (Roy & Rhim, 2020). Additionally, a similar behavior was
279
observed with the addition of glycerol since O-H and N-H stretching band shifted from
280
3214 to 3243 cm-1 and amide II band from 1538 to 1540 cm-1 due to hydrogen bonding
281
with glycerol.
Transmittance (%)
277
Amide III Amide I Amide II
4000
3500
3000
2500
2000
1500
1000
Wavenumber (cm-1)
282 283
Figure 3. FTIR spectra of chitosan films: CHI0GLY, blue line; CHI15GLY, red line;
284
CHI0GLY2PE, green line; CHI15GLY2PE, pink line; CHI0GLYCD:2PE, orange line;
285
and CHI15GLYCD:2PE, black line.
286
In order to determine the structure of the films, XRD analysis was carried out. As can
287
be observed in Figure 4, films without the inclusion complex present two broad peaks,
288
one at 11.7º and another one around 21.3º, characteristic of chitosan (Pang &
289
Zhitomirsky, 2005). These broad peaks indicate the amorphous character of chitosan
290
films. Regarding the films with the inclusion complex, two sharp peaks appeared at 6.2º
291
and 12.3º, characteristic of β-CD (Campos et al., 2019; Menezes et al., 2016). This
292
indicates that CDs maintained certain degree of crystallinity after the incorporation into
293
chitosan matrix. However, the intensity of these peaks was different for the films with
294
and without glycerol, which could be attributed to the change in molecular organization
14
of the cyclodextrin (Campos et al., 2018). Since glycerol is a small molecule, it can
296
penetrate between chitosan chains, decreasing intramolecular interactions among
297
chitosan chains and facilitating the interactions of chitosan with the additives
298
incorporated into the film forming formulation (Zarandona, Puertas, Dueñas, Guerrero,
299
& de la Caba, 2020). As shown by FTIR results, the intermolecular interactions with
300
cyclodextrin molecules occurred by hydrogen bonding, which changed the chitosan film
301
structure due to the heterogeneous nucleation effect between the inclusion complex
302
and chitosan (Li, & Zhen, 2017) and, as a consequence, the film mechanical behavior
303
also changed.
Intensity (a.u.)
295
2
4
6
8
10 12 14 16 18 20 22 24 26 28 30 32 34
2θ (º)
304 305
Figure 4. XRD diffractograms of chitosan films: CHI0GLY, blue line; CHI15GLY, red
306
line; CHI0GLY2PE, green line; CHI15GLY2PE, pink line; CHI0GLYCD:2PE, orange
307
line; and CHI15GLYCD:2PE, black line.
308
3.5. Mechanical and barrier properties
309
In order to assess the effect of structure changes in the mechanical behavior, tensile
310
tests were performed and TS and EAB values were measured and shown in Table 2.
311
As expected, films plasticized with glycerol showed higher EAB values and lower TS
312
and EM values, indicating more flexible and less rigid films due to the increase of free 15
313
volume (Rivero, Damonte, Garcia, & Pinotti, 2016). Regarding the addition of 2-phenyl
314
ethanol to the film forming solution, it was observed that this compound did not
315
significantly (P > 0.05) change TS or EAB values with respect to the corresponding
316
control film, probably due to the 2-phenyl ethanol evaporation during film preparation
317
when CDs were not used; however, an increase of EM values was noticed, indicating a
318
higher rigidity, probably due to the interactions among chitosan and the remaining
319
amount of 2-PE. The most significant change was observed for TS values when the
320
inclusion complex was incorporated into formulations; in particular, TS value
321
significantly (P < 0.05) increased from 34.5 to 48.8 MPa for the chitosan films with the
322
inclusion complex but without glycerol. In accordance, EM values also increased and
323
EAB values decreased. This behavior can be related to the interactions among
324
chitosan and CD, as shown by FTIR analysis, which would lead to a more compact
325
network, increasing resistance and rigidity, but decreasing flexibility (Siripatrawan &
326
Vitchayakitti, 2016; Sun et al., 2014). It is worth noting that TS values above 40 MPa
327
are higher values than those found for commercial packaging films, such as PP or
328
LDPE (Honarvar et al., 2017, Lomate, Dandi, & Mishra, 2018).
329
Table 2. Tensile strength (TS, MPa), elongation at break (EAB, %), Young’s Modulus
330
(EM, MPa) and water vapor permeability (WVP, g·cm-1·s-1·Pa-1) of chitosan films.
Film
TS
EAB
EM
WVP -12
(MPa)
(%)
(MPa)
(10 g·cm-1·s-1·Pa-1)
CHI0GLY
34.5 ± 2.2a
9.2 ± 2.2b
1511 ± 163a,b
1.08 ± 0.04a
CHI15GLY
32.4 ± 3.1a 16.4 ± 3.1a
1374 ± 125a
1.04 ± 0.02a
CHI0GLY2PE
39.5 ± 3.6a
7.8 ± 1.6b
2205 ± 114c
0.89 ± 0.04b
CHI15GLY2PE
33.7 ± 3.4a 12.3 ± 3.4a
1687 ± 72b
0.82 ± 0.01b
CHI0GLYCD:2PE
48.8 ± 3.2b
7.4 ± 2.2b
2639 ± 173d
0.83 ± 0.03b
CHI15GLYCD:2PE 37.5 ± 4.1a
8.1 ± 2.3b
1960 ± 84c
0.85 ± 0.02b
331
Two means followed by the same letter in the same parameter are not significantly
332
(P > 0.05) different through the Tukey's multiple range test.
16
333
Regarding water vapor permeability (WVP), there was no significant difference (P >
334
0.05) between the chitosan films without 2-phenyl ethanol. However, the addition of the
335
active compound significantly (P < 0.05) decreased WVP values, probably due to the
336
interactions with chitosan (Salami, Rezaee, Askari, & EmamDjomeh, 2020), as shown
337
by FTIR, and also due to the increase of crystallinity, as observed by XRD. Although
338
WVP values found in this work are lower than those measured for chitosan films in
339
other works (Priyadarshi, Sauraj, Kumar, Deeba, Kulshreshtha, & Negi, 2018), these
340
values are still higher than those shown by commercial films (Honarvar et al., 2017,
341
Lomate, Dandi, & Mishra, 2018).
342
3.6. Release of 2-phenyl ethanol
343
The release of 2-phenyl ethanol from chitosan films with 2-phenyl ethanol and from
344
chitosan films with β-cyclodextrin:2-phenyl ethanol was carried out in order to compare
345
the delivery trend during the immersion into 95 % ethanol for 4 days (Figure 5).
346
Regarding CHI0GLY2PE films, it is worth noting that some bioactive content was lost
347
before the analysis, probably during film preparation due to the high volatility of the
348
compound and, as a result, a maximum release of 8 % was achieved. However,
349
chitosan films with the inclusion complex retained the bioactive inside β-cyclodextrin
350
after film preparation. An improvement of 2-PE retention through its encapsulation with
351
methylcellulose, alginate sodium and carboxymethyl chitosan has also been observed
352
in other works (Qiu, Tian, Yin, Zhou, & Zhu, 2019). In this work, 2-phenyl ethanol was
353
released after 4 h of immersion into 95 % ethanol. The fast release of 2-phenyl ethanol
354
could be explained due to the weak interactions with β-cyclodextrin, since 2-pheyl
355
ethanol has only one hydroxyl group.
17
100
Release (%)
80
60
40
20
0 0
10
20
30
40
50
60
70
80
90
100
Time (h)
356 357
Figure 5. Bioactive release from chitosan films: CHI0GLY2PE, green line;
358
CHI0GLYCD:2PE, orange line.
359
4. Conclusions
360
This work showed the good capacity of cyclodextrins to form inclusion complex with 2-
361
phenyl ethanol. Specifically, β-cyclodextrin showed the highest retention yield. The
362
films obtained were homogeneous, transparent and colorless. Moreover, the addition of
363
the inclusion complex into chitosan film forming solutions led to chitosan films with
364
improved properties. In particular, tensile strength reached values up to 48 MPa. The
365
tensile strength increase was related to the physical interactions between chitosan and
366
the inclusion complex, which were corroborated by FTIR and XRD analyses, which
367
indicated the crystalline structure of chitosan films with the inclusion complex. Finally,
368
the release of 2-phenyl ethanol into 95 % ethanol was carried out in films with and
369
without β-cyclodextrin. Results suggested that the bioactive was evaporated during film
370
preparation for the films without the inclusion complex. In contrast, the films with the
371
inclusion complex preserved the bioactive inside the inclusion complex. These results
372
indicated that CDs were effective to avoid the loss of bioactive compounds during film
373
preparation. 18
374
Acknowledgments
375
Authors thank the Ministry of Science, Innovation and Universities (RTI2018-097100-B-
376
C22), the University of the Basque Country (GIU18/154), and the Basque Government
377
(Department of Quality and Food Industry) for their financial support. Iratxe Zarandona
378
thanks the Quality and Food Industry Department of the Basque Government for her
379
fellowship (22-2018-00078). Carmen Barba thanks Public University of Navarre for the
380
financial support for young researcher projects (UPNA2018-04-INC). Also thanks are
381
due to the Advanced Research Facilities (SGIker) from the UPV/EHU. Finally, authors
382
would like to thank Roquette and Wacker Chemie AG for providing cyclodextrin
383
samples.
384
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27
Highlights •
Cyclodextrins (CDs) formed inclusion complexes with 2-phenyl ethanol.
•
β-CDs showed higher retention yield than α- or γ-CDs.
•
Films with β-CD:2-phenyl ethanol were homogeneous, transparent and colorless.
•
Tensile strength of chitosan films reached values up to 48 MPa.
•
Films with inclusion complex preserved the bioactive inside the inclusion complex.
Conflict of interest Authors declare no conflict of interest