Nanocomposite Films Based on Flaxseed Gum and Cellulose Nanocrystals

Prado, Natália Soares; Silva, Ingrid Souza Vieira da; Silva, Thiago Alves Lopes; Oliveira, Welles Júnior de; Motta, Leila Aparecida de Castro; Pasquini, Daniel; Otaguro, Harumi

doi:10.1590/1980-5373-MR-2018-0134

Abstract

Flaxseed gum (FG)-based films were developed with the addition of glycerol as a plasticizer and glutaraldehyde as a crosslinking agent. HCl was added to improve crosslinking and decrease the hydrophilicity of the matrix. Different cellulose nanocrystal (CN) amounts were used as reinforcements in the optimum FG formulation. The crosslinking process at pH 3.5 led to a lower solubility of FG in water (from 100% to 53%) and an increase in thermal stability (from 160 ºC to 209 ºC). FTIR analysis confirmed a reduction in the -OH band due to crosslinking between the hydroxyl groups of FG. A diffuse diffraction pattern was observed for all FG films. The addition of 4% w/w of CN contributed to reduction of water solubility (from 53% to 20.8%) and absorption (from 21.9% to 6.8%). Finally, an improvement was observed in the tensile mechanical properties in the nanocomposites, showing satisfactory results for the proposed formulations, mainly with 8% w/w of CN added to the matrix. Overall, this study demonstrated that FG/CN nanocomposites are promising materials to be use as a sustainable biopolymer for application as bioplastics.

Keywords:
Flaxseed gum; cellulose nanocrystals; crosslinking; nanocomposite; biopolymer

1. Introduction

Due to the search for and necessity of application of sustainable products, biopolymers appear for proposed use in several innovative fields, such as packaging¹1 Biscarat J, Charmette C, Sanchez J, Pochat-Bohatier C. Development of a new family of food packaging bioplastics from cross-linked gelatin based films. The Canadian Journal of Chemical Engineering. 2015;93(2):176-182.^-²2 Razzaq HAA, Pezzuto M, Santagata G, Silvestre C, Cimmino S, Larsen N, et al. Barley ß-glucan-protein based bioplastic film with enhanced physicochemical properties for packaging. Food Hydrocolloids. 2016;58:276-283., biomedicine³3 Kowalczuk M, Adamus G. Mass spectrometry for the elucidation of the subtle molecular structure of biodegradable polymers and their degradation products. Mass Spectrometry Reviews. 2016;35(1):188-198. and agriculture⁴4 Harmaen AS, Khalina A, Ali HM, Azowa IN. Thermal, Morphological, and Biodegradability Properties of Bioplastic Fertilizer Composites Made of Oil Palm Biomass, Fertilizer, and Poly(hydroxybutyrate-co-valerate). International Journal of Polymer Science. 2016;2016:3230109.^-⁵5 Accinelli C, Abbas HK, Little NS, Kotowicz JK, Mencarelli M, Shier WT. A liquid bioplastic formulation for film coating of agronomic seeds. Crop Protection. 2016;89:123-128.. When evaluating different sources of biomass, flaxseed gum shows potential for these applications. It may be preferentially used as a thickener, stabilizer or emulsifier in food systems⁶6 Chen C, Huang X, Wang L, Li D, Adhikari B. Effect of flaxseed gum on the rheological properties of peanut protein isolate dispersions and gels. LWT. 2016;74:528-533.. In cosmetic and pharmaceutical applications, it has been used as a lubricant and even as artificial mucus⁷7 Fabre JF, Lacroux E, Valentin R, Mouloungui Z. Ultrasonication as a highly efficient method of flaxseed mucilage extraction. Industrial Crops and Products. 2015; 65: 354-360..

Flaxseed-based mucilage is constituted by a major neutral fraction (L-arabinose, D-xylose and D-galactose) and a minor acidic fraction (L-rhamnose, L-fucose, L-galactose, and D-galacturonic acid)⁸8 Warrand J, Michaud P, Picton L, Muller G, Courtois B, Ralainirina R, et al. Structural investigations of the neutral polysaccharide of Linum usitatissimum L. seeds mucilage. International Journal of Biological Macromolecules. 2005;35(3-4):121-125.^-⁹9 Muralikrishna G, Salimath PV, Tharanathan RN. Structural features of an arabinoxylan and a rhamno-galacturonan derived from linseed mucilage. Carbohydrate Research. 1987;161(2):265-271.. The association of these two fractions provides a basis of interesting rheological properties (gel formation) and morphological characteristics, which are important for its final application. Flaxseed gum has also been used to strengthen the starch films, to attain better mechanical performance¹⁰10 Li X, Wang Y, Li D. Effects of Flaxseed Gum Addition and Drying Conditions on Creep-Recovery Properties and Water Vapour Transmission Rate of Starch-Based Films. International Journal of Food Engineering. 2009;5(4):10.. Tee and his collaborators developed an edible film based on flaxseed gum as a sustainable alternative for food coating and packaging¹¹11 Tee YB, Wong J, Tan MC, Talib RA. Development of Edible Film from Flaxseed Mucilage. BioResources. 2016;11(4):10286-10295., and Wang and colleagues evaluated the dynamic-mechanical properties of edible films of flaxseed gum with addition of plasticizer¹²12 Wang Y, Li D, Wang L, Yang L, Özkan N. Dynamic mechanical properties of flaxseed gum based edible films. Carbohydrate Polymers. 2011;86(2):499-504..

It is important to point out that the major commercial interest is often in flaxseed oil, but it is possible to add value to the flaxseed gum and husk. In this way, studies to know better the physical-chemical properties of flaxseed gum and its capacity for film formation become relevant, and justifies the interest in its applications as a bioplastic.

It is well established that natural gums exhibit undesirable properties, such as high hydration rates that restrict their use in specific applications or in high humidity media¹³13 Rana V, Rai P, Tiwary AK, Singh RS, Kennedy JF, Knill CJ. Modified gums: Approaches and applications in drug delivery. Carbohydrate Polymers. 2011;83(3):1031-1047., and inadequate mechanical properties, such as fragility and brittleness.

The insertion of plasticizers and crosslinking agents may avoid or minimize some of these inconveniences, as an expected consequence of altering the properties of such added materials according to the target product.

Plasticizers such as glycerol (GLY), propylene glycol or polyethylene glycol¹⁴14 Dutta PK, Tripathi S, Mehrotra GK, Dutta J. Perspectives for chitosan based antimicrobial films in food applications. Food Chemistry. 2009;114(4):1173-1182. are commonly used to increase film flexibility through reducing hydrogen bonds along the polymer, leading, as a consequence, to a rise intermolecular spacing¹⁵15 Janjarasskul T, Krochta JM. Edible Packaging Materials. Annual Review of Food Science and Technology. 2010;1:415-448. and the molecular mobility of the polymer chains.

Chemical crosslinking produces intermolecular bonds between polymer chains¹⁶16 Hager AS, Vallons KJR, Arendt EK. Influence of Gallic Acid and Tannic Acid on the Mechanical and Barrier Properties of Wheat Gluten Films. Journal of Agricultural and Food Chemistry. 2012;60(24):6157-6163. which increase water resistance, cohesion, stiffness and mechanical strength¹⁷17 Tropini V, Lens JP, Mulder WJ, Silvestre F. Wheat gluten films cross-linked with 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide and N-hydroxysuccinimide. Industrial Crops and Products. 2004;20(3):281-289.. Crosslinking involves the use of crosslinking agents such as genipine, glutaraldehyde (GLA) and formaldehyde¹⁴14 Dutta PK, Tripathi S, Mehrotra GK, Dutta J. Perspectives for chitosan based antimicrobial films in food applications. Food Chemistry. 2009;114(4):1173-1182.. GLA is the most-used crosslinking agent due to its low cost¹⁸18 Khor E. Methods for the treatment of collagenous tissues for bioprostheses. Biomaterials. 1997;18(2):95-105. and its ability to provide a higher water resistance of the obtained material¹⁹19 Liu L, Liu CK, Fishman ML, Hicks KB. Composite films from pectin and fish skin gelatin or soybean flour protein. Journal of Agricultural and Food Chemistry. 2007;55(6):2349-2355..

Bao and collaborators reported the most favorable acid media conditions for crosslinking of agar with glutaraldehyde²⁰20 Bao L, Yang W, Mao X, Mou S, Tang S. Agar/collagen membrane as skin dressing for wounds. Biomedical Materials. 2008;3(4):044108.. Crosslinking of polyvinyl alcohol with glutaraldehyde in acidic medium was also proposed by Reis and collaborators²¹21 dos Reis EF, Campos FS, Lage AP, Leite RC, Heneine LG, Vasconcelos WL, et al. Synthesis and characterization of poly (vinyl alcohol) hydrogels and hybrids for rMPB70 protein adsorption. Materials Research. 2006;9(2):185-191..

Cellulose nanocrystals have been applied in several areas including drugs²²22 Döge N, Hönzke S, Schumacher F, Balzus B, Colombo M, Hadam S, et al. Ethyl cellulose nanocarriers and nanocrystals differentially deliver dexamethasone into intact, tape-stripped or sodium lauryl sulfate-exposed ex vivo human skin - assessment by intradermal microdialysis and extraction from the different skin layers. Journal of Controlled Release. 2016;242:25-34., packaging²³23 da Silva ISV, Flauzino Neto WP, Silvério HA, Pasquini D, Andrade MZ, Otaguro H. Mechanical, thermal and barrier properties of pectin/cellulose nanocrystal nanocomposite films and their effect on the storability of strawberries (Fragaria ananassa). Polymers for Advanced Technologies. 2017;28(8):1005-1012., medicine²⁴24 De France KJ, Chan KJW, Cranston ED, Hoare T. Enhanced Mechanical Properties in Cellulose Nanocrystal-Poly(oligoethylene glycol methacrylate) Injectable Nanocomposite Hydrogels through Control of Physical and Chemical Cross-Linking. Biomacromolecules. 2016;17(2):649-660. and the textile industry²⁵25 Chattopadhyay DP, Patel BH. Synthesis, Characterization and Application of Nano Cellulose for Enhanced Performance of Textiles. Journal of Textile Science & Engineering. 2016;6(2):248., aimed primarily at reinforcement. Because it has desirable properties, such as transparency and rigidity, and being an abundant, biodegradable material, it has aroused great commercial interest with competitive advantages over fossil and industrialized materials²⁶26 Kalia S, Sabaa MW, eds. Polysaccharide Based Graft Copolymers. Berlin, Heidelberg: Springer; 2013..

In an attempt to minimize these problems and enable use of FG as a bioplastic, we developed flaxseed gum films with glycerol, glutaraldehyde, and addition of HCl. The film with lower water solubility will be taken as the standard for the nanocomposites development with different levels of cellulose nanocrystals (2, 4 and 8% w/w). The effects of crosslinking on the thermal and morphological properties, as well as changes in chemical structure, were examined by thermal gravimetric analysis (TGA), X-ray diffraction (XRD) and Fourier Transform infrared (FTIR), respectively. Moreover, solubility, water absorption, water contact angle, and mechanical tensile strength of films and nanocomposites were measured. Scanning electron microscopy (SEM) images were also collected. As far as know, there have been no reports in the literature on flaxseed gum/cellulose nanocrystal nanocomposite studies.

2. Experimental

2.1 Materials

Flaxseed golden grains were purchased from a local supermarket (Cereale - Uberlândia, Minas Gerais, Brazil). Other reagents were: phosphorus pentoxide (P₂O₅, 98.5%; Sigma-Aldrich), glycerol (Isofar), glutaraldehyde solution (50 wt % in H₂O; Sigma Aldrich), hydrochloric acid (Vetec), potassium chloride (99-100%; Vetec), Eucalyptus bleached Kraft pulp and sulfuric acid (Vetec).

2.2 Preparation of cellulose nanocrystals

The CNs were isolated from bleached Kraft pulp (KP) of Eucalyptus urograndis (Eucalyptus urophila hybrid and Eucalyptus grandis). The experimental conditions of the CN process were reported by Da Silva and collaborators²³23 da Silva ISV, Flauzino Neto WP, Silvério HA, Pasquini D, Andrade MZ, Otaguro H. Mechanical, thermal and barrier properties of pectin/cellulose nanocrystal nanocomposite films and their effect on the storability of strawberries (Fragaria ananassa). Polymers for Advanced Technologies. 2017;28(8):1005-1012.. The CNs were prepared by hydrolysis at 45 °C for 50 min. For each gram of fiber we used 20 ml of H₂SO₄ 60 wt %.

2.3 Extraction of flaxseed gum

The seeds (240 g) were soaked in distilled water (960 mL) at room temperature (25 ± 1°C) for approximately 18 h. After this time, more distilled water (800 mL) was added and vigorously stirred for 15 min. Finally, two filtrations were performed to separate the gum. The total suspended solids for FG suspension was analyzed by drying and resulted in 0.9% w/w.

2.4 Preparation of flaxseed gum films

Based on preliminary tests, the amounts of glycerol and glutaraldehyde were fixed at 30% w/w and 15% w/w, respectively, using 2.0 g total dry mass of flaxseed gum in the formulation. The criteria used to choose the formulation was based in the flexibility, appearance and uniformity of the obtained films. The pure flaxseed gum (FG) films were prepared using only the gum suspension. The gum suspension and additives were mixed under stirring for 10 min. For the FG_GLY/GLA/HCl formulation the flaxseed gum strain was previously acidified with 1.5 M HCl to pH 3.5. All films were obtained, by a casting method, into petri dishes with dimensions of 150 mm ×15 mm and placed in an oven, Jeio Tech model OF-02, with air circulation at 35 °C for 48 h. Due to preliminary solubility tests, FG_GLY/GLA/HCl formulations was chosen as the control sample to obtain the nanocomposites.

2.5 Preparation of flaxseed gum nanocomposites

As mentioned above in the text, FG_GLY/GLA/HCl formulation was chosen as the control sample to obtain the nanocomposites. For the nanocomposites preparation 2, 4 and 8% w/w of CN was added together with the suspension of gum and additives. The nanocomposites were named FG_{2% CN}, FG_{4% CN} and FG_{8% CN} according to the cellulose nanocrystal content.

2.6 Thermal gravimetric analysis (TGA)

Thermal stability of the films were evaluated using Shimadzu DTG-60H equipment. The analysis conditions were: a nitrogen atmosphere with flow rate of 50 mL min⁻¹, a heating rate of 10 ºC min⁻¹, a temperature range of 25 to 600 ºC, and a sample mass between 5 and 7 mg. The initial temperature of degradation (T_onset) was defined as the intersection of the tangents drawn from the thermogravimetric curves.

2.7 X-ray diffraction (XRD)

X-ray diffractograms for all films, nanocomposites, and cellulose nanocrystals were obtained at room temperature over a 2θ range from 5 to 40 at a scan rate of 4° min⁻¹ using a Shimadzu LabX XRD-6000 operating at a power of 40 kV with a current of 30 mA and CuKα radiation (1.5406 Å).

2.8 Atomic force microscopy (AFM)

Atomic Force microscopy (AFM) was analyzed using the Shimadzu SPM-9600 equipment. A droplet of the aqueous CNCs suspension (1x 10^-4 g mL^-1) was deposited onto a freshly cleaved mica surface and air-dried. AFM images were captured with a scan rate of 1 Hz using Si tips with a curvature radius of less than 10 nm and a spring constant of 42 nm^-1. The dimensions of the nanocrystals were determined using VectorScan software.

2.9 Fourier transform infrared (FTIR) analysis

FTIR experiments were performed to collect spectra of films and nanocomposites using a Shimadzu IRPrestige-21. The sample and KBr were mixed and compacted in a weight ratio of 1:100. The experiments were carried out over the range of 400-4000 cm⁻¹, with a resolution of 4 cm⁻¹ and 32 scans per sample.

2.10 Scanning alectron microscopy (SEM)

The fracture region of samples was analyzed with a TECAN model Vega3 scanning electron microscope. Samples were fractured after immersion in liquid nitrogen, fixed on aluminum supports with carbon tape, and metallized with gold. SEM images were obtained at 3500 x magnification and with an acceleration voltage of 5.0 kV.

2.11 Solubility (S)

Three aliquots of each film formulation and nanocomposite (diameter of 2 cm) were dried in an oven at 105 °C for 2 h. This condition was determined by successive weighing until there was no discernible mass variation. After that, each sample was weighed to determine the initial dry matter (w_b), and then immersed in 30 mL distilled water in a beaker. The beaker was sealed and periodically stirred up to 24 h at 23 ± 2 °C. Finally, the insoluble portion of the sample was removed, oven dried at 105 °C for 24 h and weighed (w_f) to determine the weight of the solubilized dry matter. Water solubility of each film was determined by Eq. (1).

(1)

Solubility (%) = [\frac{w_{i} - w_{f}}{w_{i}}] \times 100

2.12 Water absorption (Wa)

Wa experiments were conducted with three replica of each sample and nanocomposite (2 cm diameter) which were dried in an oven at 105 °C for 2 h. After drying, they were removed from the oven and stored in a desiccator with silica until weighing (w_i). The samples were then transferred into a desiccator containing potassium chloride solution (RH = 85%) prepared according to the standard ASTM E104-02, as described in the work of Babaee and collaborators²⁷27 Babaee M, Jonoobi M, Hamzeh Y, Ashori A. Biodegradability and mechanical properties of reinforced starch nanocomposites using cellulose nanofibers. Carbohydrate Polymers. 2015;132:1-8.. The weight of the samples after water absorption was recorded by periodically withdrawing them from the desiccator at intervals of 0.5, 1, 2, 4 and 8 h. The process was followed up to steady state (w_f), where the value of several consecutive weighings did not demonstrate relevant absorption. The measurements of Wa were carried out using Equation (2).

(2)

Wa (%) = [\frac{w_{i} - w_{f}}{w_{i}}] \times 100

2.13 Contact angle

The water contact angle measurement data were collected in an Attension Theta Lite TL100 Optical Tensiometer operated at room temperature (25 ± 1 °C). Samples of (2 cm × 1 cm) were cut and fixed with double-sided adhesive tape. The sessile drop method was used, based on measuring the contact angle between a water droplet and the surface of the film (sample) with a syringe. The drop image was captured by a camera coupled to the computer and the contact angle calculated by the measurement average for 2 s. Through the stored images, the software determined the contact angle by fitting a mathematical expression to the Young-Laplace shape and calculating the slope of the tangent to the drop at the liquid-solid-vapor interface. This assay was performed in triplicate and values are given as medium values and standard deviation.

2.14 Elemental analysis

The carbon, hydrogen, and nitrogen content of the films were determined with a CE Instruments EA1110-CHN/O elemental analyzer. The protein content (%) of the samples was calculated by multiplying the nitrogen content (%) by 6.25²⁸28 Kaushik P, Dowling K, Adhikari R, Barrow CJ, Adhikari B. Effect of extraction temperature on composition, structure and functional properties of flaxseed gum. Food Chemistry. 2017;215:333-340.^-²⁹29 Razmkhah S, Razavi SMA, Mohammadifar MA, Ale MT, Gavlighi HA. Protein-free cress seed (Lepidium sativum) gum: Physicochemical characterization and rheological properties. Carbohydrate Polymers. 2016;153:14-24..

2.15 Tensile tests

The tensile behavior of films and flaxseed gum nanocomposites was analyzed using an Instron 5982 universal testing machine with 5 kN load cell according to ASTM D 882-02 and as described in the work of Kumar and collaborators³⁰30 Kumar P, Sandeep KP, Alavi S, Truong VD, Gorga RE. Preparation and characterization of bio-nanocomposite films based on soy protein isolate and montmorillonite using melt extrusion. Journal of Food Engineering. 2010;100(3):480-489.. The experiments were performed at room temperature with a crosshead speed of 25 mm min^-1 using rectangular strips (1 cm x 9 cm) samples. The distance between the claws was 5 cm, and the thickness was measured before each run. Before analysis, the samples were conditioned at 25 ± 2 °C and controlled relative humidity (59% RH - sodium bromide solution) for at least 5 days. The thickness of the samples was measured using the micrometer (Zaas precision); the values and standard deviation from five aleatory points into the selected film area are reported in the Table 4. The tensile strength at break (σ), elongation at break (ε) and Young's modulus (E) were determined from these films. Ten samples were assayed for each formulation.

3. Results and Discussion

3.1 Thermal gravimetric analysis (TGA)

The TGA curves shown in Figure 1 for the flaxseed gum films and nanocomposites obtained from neat FG, FG_GLY/GLA and FG_GLY/GLA/HCl, exhibit a slight decrease in mass (~5%) starting below 100 °C, which can be attributed to water evaporation. The T_onset, T_{max degradation} and % residue are presented in Table 1. The other mass losses are related to the degradation of macromolecular chains and additives. It can be seen that the thermal stability (T_onset) decreased from 256 °C for neat FG to 160 °C with crosslinking and plasticizer agent addition (FG_GLY/GLA). The glycerol addition decreases the thermal stability of the flaxseed gum matrix because it acts as a polymer chains separator decreasing the interactions between them. This effect was also reported by Da Silva and collaborators²³23 da Silva ISV, Flauzino Neto WP, Silvério HA, Pasquini D, Andrade MZ, Otaguro H. Mechanical, thermal and barrier properties of pectin/cellulose nanocrystal nanocomposite films and their effect on the storability of strawberries (Fragaria ananassa). Polymers for Advanced Technologies. 2017;28(8):1005-1012. in a pectin matrix. This explains the decrease in T_onset from 256 °C (FG) to 160 °C (FG_GLY/GLA). On the other hand, this effect was minimized in acid medium as can be observed by the increase of 160 °C to 209 °C. Suggesting that glutaraldehyde did not act as a crosslinking agent because crosslinked polymers are expected to exhibit a higher thermal stability than the starting polymer. With the addition of acid, however, the FG_GLY/GLA/HCl film showed higher thermal stability, with a T_onset of 209 °C. Which suggest an increase crosslinking efficiency between the polymeric chains. Finally, higher residue levels were obtained for all samples, which may be related to the presence of minerals in the gum which precipitate as salts. Mazza and collaborators reported the presence of potassium, calcium, phosphorus and magnesium in the extraction of gum³¹31 Mazza G, Biliaderis CG. Functional Properties of Flax Seed Mucilage. Journal of Food Science. 1989;54(5):1302-1305., which corroborates the obtained waste values. The nanocomposites thermal stability (Figure 1 and Table 1) was very close compared to the control film (FG_GLY/GLA/HCl). This indicates that the addition of CN did not alter the thermal stability of the control film.

Figure 1
TGA curves for films made from FG films and nanocomposites.

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Table 1
Thermal stability (T_onset and T_{max degradation} ) and residue %.

3.2 X-ray diffraction (XRD)

A diffuse diffraction pattern was observed for all flaxseed gum films and CN (Figure 2). This pattern is characteristic of amorphous polymers³²32 Baltá-Calleja FJ, Vonk CG. X-ray Scattering of Synthetic Polymers. Amsterdam: Elsevier Science; 1989. and has two distinct halos. The van der Waals halo is seen at 2θ values of 18-20°. The low van der Waals halo is at 2θ values of 10-13°. The displacement to higher values of 2θ for both halos may be explained by the complexes structure of flaxseed gum. In the case of the FG_GLY/GLA/HCl film, the X-ray pattern shows a decrease in the low van der Waals intensity halo and a shift to lower values, an indication of a reduction in the two-dimensional order or a larger structural organization. The presence of 2θ peaks at 15°, 22.5° and 34° to CN is attributed the predominance of cellulose type I³³33 Henrique MA, Flauzino Neto WP, Silvério HA, Martins DF, Gurgel LVA, Barud HS, et al. Kinetic study of the thermal decomposition of cellulose nanocrystals with different polymorphs, cellulose I and II, extracted from different sources and using different types of acids. Industrial Crops and Products. 2015;76:128-140.. The peak at 34? of 2θ is preferably found in CN than into nanocomposites, due to the incorporate quantity, but the peak still there masked by the influence of matrix and additives. An increase in the intensity of these peaks with CN content was observed, which carried out an increase degree of crystallinity to the FG films.

Figure 2
XRD patterns for films, nanocomposites and cellulose nanocrystal.

3.3 Atomic force microscopy (AFM)

The AFM images in Figure 3 show isolated cellulose nanocrystals. The CN displays a rod-like shape with an average length of 155 ± 27 nm, an average diameter of 4 ± 1 nm, and an aspect ratio of 37 ± 10.

Figure 3
XRD pattern of CN and (b) atomic force microscopy image of CN.

3.4 Fourier transform infrared analysis (FTIR)

The changes in the chemical structure of the films after addition of the plasticizer and crosslinking agent, as well as CN insertion, were evaluated using FTIR (Figure 4). A broad absorption band at 3357 cm^-1, attributed to hydroxyl groups stretching was observed for all sample curves. An absorption at ~2930 cm^-1 was attributed to the C-H bonds of the CH₂-CH₃ groups of aliphatic chains. The corresponding symmetrical stretching was observed at 2856 cm^-1³⁴34 Burgos-Díaz C, Rubilar M, Morales E, Medina C, Acevedo F, Marqués AM, et al. Naturally occurring protein-polysaccharide complexes from linseed (Linum usitatissimum) as bioemulsifiers. European Journal of Lipid Science and Technology. 2016;118(2):165-174.. The peak at 1620 cm^-1 in the spectrum is characteristic of the C=O stretching vibrations of galacturonic acid and the presence of water. The scissor-type vibrations of the -CH₂ and -OH bonds contribute to signals at 1414 and 1345 cm^-1 , respectively. Symmetric C-O-C stretching vibrations appeared at 1241 cm^-1, while a strong absorbance at 1042 cm^-1 is attributed to asymmetric stretching vibrations of C-O-C bonds³⁵35 Liu J, Shen J, Shim YY, Reaney MJT. Carboxymethyl derivatives of flaxseed (Linum usitatissimum L.) gum: characterisation and solution rheology. International Journal of Food Science & Technology. 2016;51(2):530-541.. Vibration elongation of FG branches produces spectrum absorption lines at 898 and 825 cm^-1³⁵35 Liu J, Shen J, Shim YY, Reaney MJT. Carboxymethyl derivatives of flaxseed (Linum usitatissimum L.) gum: characterisation and solution rheology. International Journal of Food Science & Technology. 2016;51(2):530-541.. The absorption band at 1149 cm^-1 corresponds to the glycoside bond C-O-C³⁶36 Pawlak A, Mucha M. Thermogravimetric and FTIR studies of chitosan blends. Thermochimica Acta. 2003;396(1-2):153-166..

Figure 4
FTIR spectra for all FG films and nanocomposites

A reduction in the -OH band can also be observed for FG_GLY/GLA/HCl and the nanocomposites due to crosslinking between the hydroxyl groups of flaxseed gum polysaccharides. It could be predicted that the modification caused by crosslinking would not be observed by infrared because the bridges formed by glutaraldehyde contain only CH₂-CH₂ bonds and ether bonds (C-O-C), both already existing in the polysaccharide structure. Bao et al. also failed to show changes in the infrared spectrum after crosslinking of agar with glutaraldehyde²⁰20 Bao L, Yang W, Mao X, Mou S, Tang S. Agar/collagen membrane as skin dressing for wounds. Biomedical Materials. 2008;3(4):044108..

In the case of FG nanocomposites (FG_{2% CN}, FG_{4% CN} and FG_{8% CN}), no major differences were observed in the absorption peaks with the addition of CN, because of the similarity of the functional groups in comparison with glycerol and glutaraldehyde.

3.5 Elemental analysis

The presences of protein contaminants may also modify the film morphology. Therefore, the carbon, hydrogen, and nitrogen contents were measured to evaluate protein contaminants in flaxseed gum (Table 2). The protein content was 5.81 % for the FG film. Kaushik and collaborators reported that protein content in the FG samples increased significantly from 4.4% to 15.1% when the extraction temperature was raised from 30 to 90 °C²⁸28 Kaushik P, Dowling K, Adhikari R, Barrow CJ, Adhikari B. Effect of extraction temperature on composition, structure and functional properties of flaxseed gum. Food Chemistry. 2017;215:333-340..

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Table 2
Elemental analysis data of FG films.

3.6 Scanning electron microscopy (SEM)

The cryo-fractured films and nanocomposites observed by SEM are shown in Figures 5 and ⁶6 Chen C, Huang X, Wang L, Li D, Adhikari B. Effect of flaxseed gum on the rheological properties of peanut protein isolate dispersions and gels. LWT. 2016;74:528-533., respectively. The FG film showed a rough and irregular cross-section compared to the FG_GLY/GLA film, which was related to the impurities or residues from the raw material that remained in the film, such as proteins, lipids, and fiber. Although the concentrations of these components are low, they can interact with flaxseed gum and each other, which influences the final film structure.

The addition of glycerol and glutaraldehyde (Figure 5b) allowed greater organization of the matrix, result in a more compact appearance. However, the presence of small domains is still observed which may be related to the small fraction of proteins that had a low dispersion at the pH studied. With the addition of HCl (Figure 5c) the sample had a more homogeneous appearance and a better distribution of these domains. However, the formation of pores was also observed. The addition of acid also resulted in a sticky appearance due to glycerol exudation on the surface. As mentioned above, the function of glycerol is as plasticizer, and with acts on the distance between the polymer chains. With the crosslinking process (pH = 3.5) the glycerol loses space for crosslinks exceeding the surface of the film.Some authors have reported this behavior of plasticizer exudation on the film surface³⁷37 Gao C, Pollet E, Avérous L. Properties of glycerol-plasticized alginate films obtained by thermo-mechanical mixing. Food Hydrocolloids. 2017;63:414-420..

Figure 5
SEM micrographs of fractured region of films. a) FG, b) FG_GLY/GLA and c) FG_GLY/GLA/HCl with a magnification of 3500 x.

For the nanocomposite originating from the addition of CN, the presence of pores was not observed (Figure 6). Nevertheless, the rough appearance observed for the nanocomposites was due to the insertion of the filler, which created tortuous paths in the matrix, showed good aggregation and homogeneity with both components, which can contribute to better mechanical properties. With the increase of CN, a decrease in the glycerol exudation effect was also evidenced.

Figure 6
SEM micrographs obtained from fractured region of the FG nanocomposites. a) FG_{2% CN}, b) FG_{4% CN} and c) FG_{8% CN} with a magnification of 3500 x.

3.7 Solubility (S)

The water solubility data of the flaxseed gum films and nanocomposites are presented in Table 3. The neat FG and FG_GLY/GLA were completely soluble in water, suggesting in insufficient crosslinking of the polysaccharide chains, but in the presence of acid (FG_GLY/GLA/HCl), the sample showed a significant reduction, from 100% to 53%. The decrease in the solubility in this case is compatible with the crosslinking process, which diminishes the solubility of the material in an aqueous medium.

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Table 3
Interaction data of FG films and nanocomposites with water. Solubility, absorption and contact angle.

The CN insertion contributed to the reduction of solubility for all nanocomposites in comparison with the FG_GLY/GLA/HCl film. According to Slavutsky and Bertuzzi, the reduction in solubility by the insertion of CN is indicative of strong interactions between CN with the matrix. These interactions confer stability and resistance to the composites obtained³⁸38 Slavutsky AM, Bertuzzi MA. Water barrier properties of starch films reinforced with cellulose nanocrystals obtained from sugarcane bagasse. Carbohydrate Polymers. 2014;110:53-61.. However, in the nanocomposite profiles, the higher amount of CN conferred higher solubility. There was a decrease in solubility with the addition of up to 4% w/w of CN. Conversely, the solubility increased with the addition of 8% w/w, probably due to the increase in hydrophilic charge. This indicates that the FG/CN nanocomposite reached its maximum water resistance when 4% w/w of CN was incorporated.

3.8 Water absorption (Wa)

The water absorption values from the films and nanocomposites are presented in Table 3. In general, the films and nanocomposites reached equilibrium after between two and three days. With the addition of glutaraldehyde and glycerol, there was a decrease in the water absorption value from 11.4% to 5.0%. This may be associated with the more compact structure of the FG_GLY/GLA film compared to pure FG (Figure 5).

With HCl addition, the FG_GLY/GLA/HCl film absorbed almost four times more water. This result was not expected as a decrease in solubility generally leads to a decrease in water absorption. Alternatively, water absorption can be influenced by porosity, which allows more water to be absorbed by the film, as suggested by the SEM image of the FG_GLY/GLA/HCl film (Figure 5C).

With the addition of CN there was a considerable reduction in water absorption. Zhang and collaborators evaluated the incorporation of CN into soy protein and attributed low water absorption values to hydrogen bond interactions and physical crosslinking between CN and the matrix³⁹39 Zhang S, Xia C, Dong Y, Yan Y, Li J, Shi SQ, et al. Soy protein isolate-based films reinforced by surface modified cellulose nanocrystal. Industrial Crops and Products. 2016;80:207-213..

3.9 Contact angle

The contact angle measurements are presented in Table 3 for all films and nanocomposites. The FG film showed an anomalous behavior, with a contact angle of 107°, exhibiting great hydrophobic character. This can be explained by the presence of soluble proteins and oil after the extraction of flaxseed gum in water, as reported by Kaushik and collaborators²⁸28 Kaushik P, Dowling K, Adhikari R, Barrow CJ, Adhikari B. Effect of extraction temperature on composition, structure and functional properties of flaxseed gum. Food Chemistry. 2017;215:333-340.. The contact angle of the FG_GLY/GLA/HCl film was lower than the FG_GLY/GLA film, which was not expected due to increased crosslinking, which should result in a higher angle. Alternatively, the film’s sticky appearance and the increase in the contact angle for the FG_{GLY/GLA /HCl} sample justified, since wettability is a parameter directly related to surface interactions. Therefore a high concentration of glycerol favors wettability (lower contact angle) due to the hydrophilicity for both components (water and film surface).

The contact angle of the nanocomposites decreased with the addition of CN up to 8%. This was attributed to the more hydrophilic character of CN compared to flaxseed gum. Reddy and collaborators also reported that the inclusion of CN promotes the contact angle decrease of agar films⁴⁰40 Reddy JP, Rhim JW. Characterization of bionanocomposite films prepared with agar and paper-mulberry pulp nanocellulose. Carbohydrate Polymers. 2014;110:480-488.. However, the FG_{8% CN} nanocomposite showed an increase compared to nanocomposites, which may be justified by the decrease in glycerol exudation when a large amount of CN was added, promoting an increase in contact angle.

3.10 Tensile tests

The tensile results of the films and nanocomposites are displayed in Table 4. In the case of FG_GLY/GLA/HCl, this exhibited the lowest values of ε and σ in comparison with the FG_GLY/GLA film. Glycerol exudation reduces its ability to act as a plasticizer. Furthermore, the increase in film water absorption generates structures with reduced tensile strength at the rupture. Alternatively, the addition of acid (pH = 3.5) induced the formation of structures with higher resistance to water, corresponding to a greater degree of crosslinking. This is in contrast to the formulations in FG_GLY/GLA (no pH correction), which dissolved completely after 24 hours in water.

Thumbnail

Table 4
Tensile strength (σ), elongation at break (ε) and Young's modulus (E) of the FG films and FG/CN nanocomposite films.

The linear behavior of σ and E values with the increase of CN was observed for the nanocomposites, showing a better mechanical performance and filler effect, to values greater than 2% w/w of CN.

In fact, efficient reinforcement was only expected above the critical fraction of the filling phase volume, defined as the percolation threshold, which depends on the proportion of the nanoparticle. This suggests the formation of a rigid continuous network of nanocrystals bound through hydrogen bonds⁴¹41 Flauzino Neto WP, Mariano M, da Silva ISV, Silvério HA, Putaux JL, Otaguro H, et al. Mechanical properties of natural rubber nanocomposites reinforced with high aspect ratio cellulose nanocrystals isolated from soy hulls. Carbohydrate Polymers. 2016;153:143-152.. The filler percolation threshold was calculated from the aspect ratio found by microscopic observations and assuming a density of 1.045 g cm^-3 (measured using a pycnometer) and 1.570 g cm^-3⁴²42 Dufresne A. Interfacial phenomena in nanocomposites based on polysaccharide nanocrystals. Composite Interfaces. 2003;10(4-5):369-387. for FG and cellulose nanocrystals, respectively. The values calculated for CN were up to 2.8% w/w. This is in agreement with tension values for FG _{4% CN} and FG_{8% CN}.

As can be seen, the Young’s modulus for FG_{8% CN} was 13 times higher than for the reference sample FG_GLY/GLA/HCl and FG_{2% CN}. The nanocrystal insertion enlarges the application and processing window of flaxseed gum, which presented low initial values of resistance that limit its use in any manufacture where greater stiffness is required.

4. Conclusions

The present work demonstrated that the crosslinking of FG with GLA at pH 3.5 resulted in different morphologies and properties, playing a fundamental role in the solubility of the films that proved to be more stable in water. However, an increase in water absorption and glycerol exudation effect was observed. Solubility, water absorption and the tensile strength and stiffness of the films were significantly improved with higher amounts of CN (FG_{8% CN}) addition. This was due to the enhancement generated by the strong interaction between CN dispersed into the polymer matrix. The materials described in this study are therefore able to improve the properties of flaxseed gum and may allow for application as bioplastics in food, agricultural and pharmaceutical industries.

5. Acknowledgments

The authors thank CAPES, CNPq, FAPEMIG and Federal University of Uberlândia for financial support.

6. References

¹
Biscarat J, Charmette C, Sanchez J, Pochat-Bohatier C. Development of a new family of food packaging bioplastics from cross-linked gelatin based films. The Canadian Journal of Chemical Engineering 2015;93(2):176-182.
²
Razzaq HAA, Pezzuto M, Santagata G, Silvestre C, Cimmino S, Larsen N, et al. Barley ß-glucan-protein based bioplastic film with enhanced physicochemical properties for packaging. Food Hydrocolloids 2016;58:276-283.
³
Kowalczuk M, Adamus G. Mass spectrometry for the elucidation of the subtle molecular structure of biodegradable polymers and their degradation products. Mass Spectrometry Reviews 2016;35(1):188-198.
⁴
Harmaen AS, Khalina A, Ali HM, Azowa IN. Thermal, Morphological, and Biodegradability Properties of Bioplastic Fertilizer Composites Made of Oil Palm Biomass, Fertilizer, and Poly(hydroxybutyrate-co-valerate). International Journal of Polymer Science 2016;2016:3230109.
⁵
Accinelli C, Abbas HK, Little NS, Kotowicz JK, Mencarelli M, Shier WT. A liquid bioplastic formulation for film coating of agronomic seeds. Crop Protection 2016;89:123-128.
⁶
Chen C, Huang X, Wang L, Li D, Adhikari B. Effect of flaxseed gum on the rheological properties of peanut protein isolate dispersions and gels. LWT 2016;74:528-533.
⁷
Fabre JF, Lacroux E, Valentin R, Mouloungui Z. Ultrasonication as a highly efficient method of flaxseed mucilage extraction. Industrial Crops and Products 2015; 65: 354-360.
⁸
Warrand J, Michaud P, Picton L, Muller G, Courtois B, Ralainirina R, et al. Structural investigations of the neutral polysaccharide of Linum usitatissimum L. seeds mucilage. International Journal of Biological Macromolecules 2005;35(3-4):121-125.
⁹
Muralikrishna G, Salimath PV, Tharanathan RN. Structural features of an arabinoxylan and a rhamno-galacturonan derived from linseed mucilage. Carbohydrate Research. 1987;161(2):265-271.
¹⁰
Li X, Wang Y, Li D. Effects of Flaxseed Gum Addition and Drying Conditions on Creep-Recovery Properties and Water Vapour Transmission Rate of Starch-Based Films. International Journal of Food Engineering 2009;5(4):10.
¹¹
Tee YB, Wong J, Tan MC, Talib RA. Development of Edible Film from Flaxseed Mucilage. BioResources 2016;11(4):10286-10295.
¹²
Wang Y, Li D, Wang L, Yang L, Özkan N. Dynamic mechanical properties of flaxseed gum based edible films. Carbohydrate Polymers 2011;86(2):499-504.
¹³
Rana V, Rai P, Tiwary AK, Singh RS, Kennedy JF, Knill CJ. Modified gums: Approaches and applications in drug delivery. Carbohydrate Polymers 2011;83(3):1031-1047.
¹⁴
Dutta PK, Tripathi S, Mehrotra GK, Dutta J. Perspectives for chitosan based antimicrobial films in food applications. Food Chemistry 2009;114(4):1173-1182.
¹⁵
Janjarasskul T, Krochta JM. Edible Packaging Materials. Annual Review of Food Science and Technology 2010;1:415-448.
¹⁶
Hager AS, Vallons KJR, Arendt EK. Influence of Gallic Acid and Tannic Acid on the Mechanical and Barrier Properties of Wheat Gluten Films. Journal of Agricultural and Food Chemistry. 2012;60(24):6157-6163.
¹⁷
Tropini V, Lens JP, Mulder WJ, Silvestre F. Wheat gluten films cross-linked with 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide and N-hydroxysuccinimide. Industrial Crops and Products 2004;20(3):281-289.
¹⁸
Khor E. Methods for the treatment of collagenous tissues for bioprostheses. Biomaterials 1997;18(2):95-105.
¹⁹
Liu L, Liu CK, Fishman ML, Hicks KB. Composite films from pectin and fish skin gelatin or soybean flour protein. Journal of Agricultural and Food Chemistry 2007;55(6):2349-2355.
²⁰
Bao L, Yang W, Mao X, Mou S, Tang S. Agar/collagen membrane as skin dressing for wounds. Biomedical Materials 2008;3(4):044108.
²¹
dos Reis EF, Campos FS, Lage AP, Leite RC, Heneine LG, Vasconcelos WL, et al. Synthesis and characterization of poly (vinyl alcohol) hydrogels and hybrids for rMPB70 protein adsorption. Materials Research 2006;9(2):185-191.
²²
Döge N, Hönzke S, Schumacher F, Balzus B, Colombo M, Hadam S, et al. Ethyl cellulose nanocarriers and nanocrystals differentially deliver dexamethasone into intact, tape-stripped or sodium lauryl sulfate-exposed ex vivo human skin - assessment by intradermal microdialysis and extraction from the different skin layers. Journal of Controlled Release. 2016;242:25-34.
²³
da Silva ISV, Flauzino Neto WP, Silvério HA, Pasquini D, Andrade MZ, Otaguro H. Mechanical, thermal and barrier properties of pectin/cellulose nanocrystal nanocomposite films and their effect on the storability of strawberries (Fragaria ananassa). Polymers for Advanced Technologies. 2017;28(8):1005-1012.
²⁴
De France KJ, Chan KJW, Cranston ED, Hoare T. Enhanced Mechanical Properties in Cellulose Nanocrystal-Poly(oligoethylene glycol methacrylate) Injectable Nanocomposite Hydrogels through Control of Physical and Chemical Cross-Linking. Biomacromolecules 2016;17(2):649-660.
²⁵
Chattopadhyay DP, Patel BH. Synthesis, Characterization and Application of Nano Cellulose for Enhanced Performance of Textiles. Journal of Textile Science & Engineering. 2016;6(2):248.
²⁶
Kalia S, Sabaa MW, eds. Polysaccharide Based Graft Copolymers. Berlin, Heidelberg: Springer; 2013.
²⁷
Babaee M, Jonoobi M, Hamzeh Y, Ashori A. Biodegradability and mechanical properties of reinforced starch nanocomposites using cellulose nanofibers. Carbohydrate Polymers. 2015;132:1-8.
²⁸
Kaushik P, Dowling K, Adhikari R, Barrow CJ, Adhikari B. Effect of extraction temperature on composition, structure and functional properties of flaxseed gum. Food Chemistry 2017;215:333-340.
²⁹
Razmkhah S, Razavi SMA, Mohammadifar MA, Ale MT, Gavlighi HA. Protein-free cress seed (Lepidium sativum) gum: Physicochemical characterization and rheological properties. Carbohydrate Polymers. 2016;153:14-24.
³⁰
Kumar P, Sandeep KP, Alavi S, Truong VD, Gorga RE. Preparation and characterization of bio-nanocomposite films based on soy protein isolate and montmorillonite using melt extrusion. Journal of Food Engineering 2010;100(3):480-489.
³¹
Mazza G, Biliaderis CG. Functional Properties of Flax Seed Mucilage. Journal of Food Science 1989;54(5):1302-1305.
³²
Baltá-Calleja FJ, Vonk CG. X-ray Scattering of Synthetic Polymers. Amsterdam: Elsevier Science; 1989.
³³
Henrique MA, Flauzino Neto WP, Silvério HA, Martins DF, Gurgel LVA, Barud HS, et al. Kinetic study of the thermal decomposition of cellulose nanocrystals with different polymorphs, cellulose I and II, extracted from different sources and using different types of acids. Industrial Crops and Products 2015;76:128-140.
³⁴
Burgos-Díaz C, Rubilar M, Morales E, Medina C, Acevedo F, Marqués AM, et al. Naturally occurring protein-polysaccharide complexes from linseed (Linum usitatissimum) as bioemulsifiers. European Journal of Lipid Science and Technology 2016;118(2):165-174.
³⁵
Liu J, Shen J, Shim YY, Reaney MJT. Carboxymethyl derivatives of flaxseed (Linum usitatissimum L.) gum: characterisation and solution rheology. International Journal of Food Science & Technology. 2016;51(2):530-541.
³⁶
Pawlak A, Mucha M. Thermogravimetric and FTIR studies of chitosan blends. Thermochimica Acta 2003;396(1-2):153-166.
³⁷
Gao C, Pollet E, Avérous L. Properties of glycerol-plasticized alginate films obtained by thermo-mechanical mixing. Food Hydrocolloids. 2017;63:414-420.
³⁸
Slavutsky AM, Bertuzzi MA. Water barrier properties of starch films reinforced with cellulose nanocrystals obtained from sugarcane bagasse. Carbohydrate Polymers 2014;110:53-61.
³⁹
Zhang S, Xia C, Dong Y, Yan Y, Li J, Shi SQ, et al. Soy protein isolate-based films reinforced by surface modified cellulose nanocrystal. Industrial Crops and Products 2016;80:207-213.
⁴⁰
Reddy JP, Rhim JW. Characterization of bionanocomposite films prepared with agar and paper-mulberry pulp nanocellulose. Carbohydrate Polymers 2014;110:480-488.
⁴¹
Flauzino Neto WP, Mariano M, da Silva ISV, Silvério HA, Putaux JL, Otaguro H, et al. Mechanical properties of natural rubber nanocomposites reinforced with high aspect ratio cellulose nanocrystals isolated from soy hulls. Carbohydrate Polymers 2016;153:143-152.
⁴²
Dufresne A. Interfacial phenomena in nanocomposites based on polysaccharide nanocrystals. Composite Interfaces 2003;10(4-5):369-387.

Publication Dates

Publication in this collection
22 Oct 2018
Date of issue
2018

History

Received
21 Feb 2018
Reviewed
31 July 2018
Accepted
30 Aug 2018

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ¹
Biscarat J, Charmette C, Sanchez J, Pochat-Bohatier C. Development of a new family of food packaging bioplastics from cross-linked gelatin based films. The Canadian Journal of Chemical Engineering 2015;93(2):176-182.

[2] ²
Razzaq HAA, Pezzuto M, Santagata G, Silvestre C, Cimmino S, Larsen N, et al. Barley ß-glucan-protein based bioplastic film with enhanced physicochemical properties for packaging. Food Hydrocolloids 2016;58:276-283.

[3] ³
Kowalczuk M, Adamus G. Mass spectrometry for the elucidation of the subtle molecular structure of biodegradable polymers and their degradation products. Mass Spectrometry Reviews 2016;35(1):188-198.

[4] ⁴
Harmaen AS, Khalina A, Ali HM, Azowa IN. Thermal, Morphological, and Biodegradability Properties of Bioplastic Fertilizer Composites Made of Oil Palm Biomass, Fertilizer, and Poly(hydroxybutyrate-co-valerate). International Journal of Polymer Science 2016;2016:3230109.

[5] ⁵
Accinelli C, Abbas HK, Little NS, Kotowicz JK, Mencarelli M, Shier WT. A liquid bioplastic formulation for film coating of agronomic seeds. Crop Protection 2016;89:123-128.

[6] ⁶
Chen C, Huang X, Wang L, Li D, Adhikari B. Effect of flaxseed gum on the rheological properties of peanut protein isolate dispersions and gels. LWT 2016;74:528-533.

[7] ⁷
Fabre JF, Lacroux E, Valentin R, Mouloungui Z. Ultrasonication as a highly efficient method of flaxseed mucilage extraction. Industrial Crops and Products 2015; 65: 354-360.

[8] ⁸
Warrand J, Michaud P, Picton L, Muller G, Courtois B, Ralainirina R, et al. Structural investigations of the neutral polysaccharide of Linum usitatissimum L. seeds mucilage. International Journal of Biological Macromolecules 2005;35(3-4):121-125.

[9] ⁹
Muralikrishna G, Salimath PV, Tharanathan RN. Structural features of an arabinoxylan and a rhamno-galacturonan derived from linseed mucilage. Carbohydrate Research. 1987;161(2):265-271.

[10] ¹⁰
Li X, Wang Y, Li D. Effects of Flaxseed Gum Addition and Drying Conditions on Creep-Recovery Properties and Water Vapour Transmission Rate of Starch-Based Films. International Journal of Food Engineering 2009;5(4):10.

[11] ¹¹
Tee YB, Wong J, Tan MC, Talib RA. Development of Edible Film from Flaxseed Mucilage. BioResources 2016;11(4):10286-10295.

[12] ¹²
Wang Y, Li D, Wang L, Yang L, Özkan N. Dynamic mechanical properties of flaxseed gum based edible films. Carbohydrate Polymers 2011;86(2):499-504.

[13] ¹³
Rana V, Rai P, Tiwary AK, Singh RS, Kennedy JF, Knill CJ. Modified gums: Approaches and applications in drug delivery. Carbohydrate Polymers 2011;83(3):1031-1047.

[14] ¹⁴
Dutta PK, Tripathi S, Mehrotra GK, Dutta J. Perspectives for chitosan based antimicrobial films in food applications. Food Chemistry 2009;114(4):1173-1182.

[15] ¹⁵
Janjarasskul T, Krochta JM. Edible Packaging Materials. Annual Review of Food Science and Technology 2010;1:415-448.

[16] ¹⁶
Hager AS, Vallons KJR, Arendt EK. Influence of Gallic Acid and Tannic Acid on the Mechanical and Barrier Properties of Wheat Gluten Films. Journal of Agricultural and Food Chemistry. 2012;60(24):6157-6163.

[17] ¹⁷
Tropini V, Lens JP, Mulder WJ, Silvestre F. Wheat gluten films cross-linked with 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide and N-hydroxysuccinimide. Industrial Crops and Products 2004;20(3):281-289.

[18] ¹⁸
Khor E. Methods for the treatment of collagenous tissues for bioprostheses. Biomaterials 1997;18(2):95-105.

[19] ¹⁹
Liu L, Liu CK, Fishman ML, Hicks KB. Composite films from pectin and fish skin gelatin or soybean flour protein. Journal of Agricultural and Food Chemistry 2007;55(6):2349-2355.

[20] ²⁰
Bao L, Yang W, Mao X, Mou S, Tang S. Agar/collagen membrane as skin dressing for wounds. Biomedical Materials 2008;3(4):044108.

[21] ²¹
dos Reis EF, Campos FS, Lage AP, Leite RC, Heneine LG, Vasconcelos WL, et al. Synthesis and characterization of poly (vinyl alcohol) hydrogels and hybrids for rMPB70 protein adsorption. Materials Research 2006;9(2):185-191.

[22] ²²
Döge N, Hönzke S, Schumacher F, Balzus B, Colombo M, Hadam S, et al. Ethyl cellulose nanocarriers and nanocrystals differentially deliver dexamethasone into intact, tape-stripped or sodium lauryl sulfate-exposed ex vivo human skin - assessment by intradermal microdialysis and extraction from the different skin layers. Journal of Controlled Release. 2016;242:25-34.

[23] ²³
da Silva ISV, Flauzino Neto WP, Silvério HA, Pasquini D, Andrade MZ, Otaguro H. Mechanical, thermal and barrier properties of pectin/cellulose nanocrystal nanocomposite films and their effect on the storability of strawberries (Fragaria ananassa). Polymers for Advanced Technologies. 2017;28(8):1005-1012.

[24] ²⁴
De France KJ, Chan KJW, Cranston ED, Hoare T. Enhanced Mechanical Properties in Cellulose Nanocrystal-Poly(oligoethylene glycol methacrylate) Injectable Nanocomposite Hydrogels through Control of Physical and Chemical Cross-Linking. Biomacromolecules 2016;17(2):649-660.

[25] ²⁵
Chattopadhyay DP, Patel BH. Synthesis, Characterization and Application of Nano Cellulose for Enhanced Performance of Textiles. Journal of Textile Science & Engineering. 2016;6(2):248.

[26] ²⁶
Kalia S, Sabaa MW, eds. Polysaccharide Based Graft Copolymers. Berlin, Heidelberg: Springer; 2013.

[27] ²⁷
Babaee M, Jonoobi M, Hamzeh Y, Ashori A. Biodegradability and mechanical properties of reinforced starch nanocomposites using cellulose nanofibers. Carbohydrate Polymers. 2015;132:1-8.

[28] ²⁸
Kaushik P, Dowling K, Adhikari R, Barrow CJ, Adhikari B. Effect of extraction temperature on composition, structure and functional properties of flaxseed gum. Food Chemistry 2017;215:333-340.

[29] ²⁹
Razmkhah S, Razavi SMA, Mohammadifar MA, Ale MT, Gavlighi HA. Protein-free cress seed (Lepidium sativum) gum: Physicochemical characterization and rheological properties. Carbohydrate Polymers. 2016;153:14-24.

[30] ³⁰
Kumar P, Sandeep KP, Alavi S, Truong VD, Gorga RE. Preparation and characterization of bio-nanocomposite films based on soy protein isolate and montmorillonite using melt extrusion. Journal of Food Engineering 2010;100(3):480-489.

[31] ³¹
Mazza G, Biliaderis CG. Functional Properties of Flax Seed Mucilage. Journal of Food Science 1989;54(5):1302-1305.

[32] ³²
Baltá-Calleja FJ, Vonk CG. X-ray Scattering of Synthetic Polymers. Amsterdam: Elsevier Science; 1989.

[33] ³³
Henrique MA, Flauzino Neto WP, Silvério HA, Martins DF, Gurgel LVA, Barud HS, et al. Kinetic study of the thermal decomposition of cellulose nanocrystals with different polymorphs, cellulose I and II, extracted from different sources and using different types of acids. Industrial Crops and Products 2015;76:128-140.

[34] ³⁴
Burgos-Díaz C, Rubilar M, Morales E, Medina C, Acevedo F, Marqués AM, et al. Naturally occurring protein-polysaccharide complexes from linseed (Linum usitatissimum) as bioemulsifiers. European Journal of Lipid Science and Technology 2016;118(2):165-174.

[35] ³⁵
Liu J, Shen J, Shim YY, Reaney MJT. Carboxymethyl derivatives of flaxseed (Linum usitatissimum L.) gum: characterisation and solution rheology. International Journal of Food Science & Technology. 2016;51(2):530-541.

[36] ³⁶
Pawlak A, Mucha M. Thermogravimetric and FTIR studies of chitosan blends. Thermochimica Acta 2003;396(1-2):153-166.

[37] ³⁷
Gao C, Pollet E, Avérous L. Properties of glycerol-plasticized alginate films obtained by thermo-mechanical mixing. Food Hydrocolloids. 2017;63:414-420.

[38] ³⁸
Slavutsky AM, Bertuzzi MA. Water barrier properties of starch films reinforced with cellulose nanocrystals obtained from sugarcane bagasse. Carbohydrate Polymers 2014;110:53-61.

[39] ³⁹
Zhang S, Xia C, Dong Y, Yan Y, Li J, Shi SQ, et al. Soy protein isolate-based films reinforced by surface modified cellulose nanocrystal. Industrial Crops and Products 2016;80:207-213.

[40] ⁴⁰
Reddy JP, Rhim JW. Characterization of bionanocomposite films prepared with agar and paper-mulberry pulp nanocellulose. Carbohydrate Polymers 2014;110:480-488.

[41] ⁴¹
Flauzino Neto WP, Mariano M, da Silva ISV, Silvério HA, Putaux JL, Otaguro H, et al. Mechanical properties of natural rubber nanocomposites reinforced with high aspect ratio cellulose nanocrystals isolated from soy hulls. Carbohydrate Polymers 2016;153:143-152.

[42] ⁴²
Dufresne A. Interfacial phenomena in nanocomposites based on polysaccharide nanocrystals. Composite Interfaces 2003;10(4-5):369-387.

Samples	T_onset (°C)	T_{max degradation} (°C)	% residue
FG	256	260	16
FG_GLY/GLA	160	253	16
FG_GLY/GLA/HCl	209	235	20
FG_{2% CN}	204	249	19
FG_{4% CN}	196	254	11
FG_{8% CN}	203	250	14

Samples	%C	%H	%N	%O	% Protein
FG	41.99	6.72	0.93	50.36	5.81
FG_GLY/GLA	41.39	7.78	0.75	50.08	4.69
FG_GLY/GLA/HCl	42.38	7.47	0.46	49.69	2.87

Samples	S (%)	Wa (%)	Contact Angle (°)
FG	100	11.4 ± 0.4	107.0 ± 0.8
FG_GLY/GLA	100	5.0 ± 0.3	80.0 ± 0.6
FG_GLY/GLA/HCl	53 ± 1	21.9 ± 0.2	70.0 ± 0.6
FG_{2% CN}	27 ± 1	7.1 ± 0.2	50 ± 1
FG_{4% CN}	20.8 ± 0.4	6.8 ± 0.1	53.0 ± 0.7
FG_{8% CN}	42.82 ± 0.04	8.84 ± 0.02	65.0 ± 0.3

Samples	Thickness (mm)	σ (MPa)	ε (%)	E (MPa)
FG_GLY/GLA	0.044 ± 0.004	5.6 ± 0.4	58 ± 1	30 ± 2
FG_GLY/GLA/HCl	0.059 ± 0.002	2.1 ± 0.4	47 ± 2	6 ± 1
FG_{2% CN}	0.067 ± 0.002	3.9 ± 0.7	87 ± 2	5.7 ± 0.9
FG_{4% CN}	0.076 ± 0.001	5 ± 2	40.1 ± 0.7	45.1 ± 0.2
FG_{8% CN}	0.099 ± 0.005	6 ± 2	48 ± 4	79 ± 14

Brasil

Brasil

Nanocomposite Films Based on Flaxseed Gum and Cellulose Nanocrystals

Abstract

1. Introduction

2. Experimental

2.1 Materials

2.2 Preparation of cellulose nanocrystals

2.3 Extraction of flaxseed gum

2.4 Preparation of flaxseed gum films

2.5 Preparation of flaxseed gum nanocomposites

2.6 Thermal gravimetric analysis (TGA)

2.7 X-ray diffraction (XRD)

2.8 Atomic force microscopy (AFM)

2.9 Fourier transform infrared (FTIR) analysis

2.10 Scanning alectron microscopy (SEM)

2.11 Solubility (S)

2.12 Water absorption (Wa)

2.13 Contact angle

2.14 Elemental analysis

2.15 Tensile tests

3. Results and Discussion

3.1 Thermal gravimetric analysis (TGA)

3.2 X-ray diffraction (XRD)

3.3 Atomic force microscopy (AFM)

3.4 Fourier transform infrared analysis (FTIR)

3.5 Elemental analysis

3.6 Scanning electron microscopy (SEM)

3.7 Solubility (S)

3.8 Water absorption (Wa)

3.9 Contact angle

3.10 Tensile tests

4. Conclusions

5. Acknowledgments

6. References

Publication Dates

History