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Mechanical, thermal, and barrier properties of methylcellulose/cellulose nanocrystals nanocomposites

Abstract

In this work, the effects of incorporating cellulose nanocrystals from soy hulls (WSH30) on the mechanical, thermal, and barrier properties of methylcellulose (MC) nanocomposites were evaluated. MC/WSH30 nanocomposite films with different filler levels (2, 4, 6, 8, and 10%) were prepared by casting. Compared to neat MC film, improvements in the mechanical and barrier properties were observed, while thermal stability was retained. The improved mechanical properties of nanocomposites prepared may be attributed to mechanical percolation of WSH30, formation of a continuous network of WSH30 linked by hydrogen interactions and a close association between filler and matrix.

Cellulose nanocrystals; agro-industrial residue; reinforcement; methylcellulose; nanocomposites


SEÇÃO TÉCNICA

TECHNICAL-SCIENTIFIC SESSION

Mechanical, thermal, and barrier properties of methylcellulose/cellulose nanocrystals nanocomposites

Hudson Alves SilvérioI; Wilson Pires Flauzino NetoI; Ingrid Souza Vieira da SilvaI; Joyce Rover RosaI; Daniel PasquiniI; Rosana Maria Nascimento de AssunçãoII; Hernane da Silva BarudIII; Sidney José Lima RibeiroIII

IInstituto de Química, Universidade Federal de Uberlândia – UFU

IIFaculdade de Ciências Integradas do Pontal, Universidade Federal de Uberlândia – UFU

IIIInstituto de Química de Araraquara, Universidade Estadual Paulista Júlio de Mesquita – UNESP

Corresponding author Corresponding author: Daniel Pasquini, Instituto de Química, Universidade Federal de Uberlândia – UFU, Campus Santa Mônica, Av. João Naves de Ávila, 2121, CEP 38400-902, Uberlândia, MG, Brazil, e-mail: pasquini@iqufu.ufu.br; danielpasquini2005@yahoo.com.br

ABSTRACT

In this work, the effects of incorporating cellulose nanocrystals from soy hulls (WSH30) on the mechanical, thermal, and barrier properties of methylcellulose (MC) nanocomposites were evaluated. MC/WSH30 nanocomposite films with different filler levels (2, 4, 6, 8, and 10%) were prepared by casting. Compared to neat MC film, improvements in the mechanical and barrier properties were observed, while thermal stability was retained. The improved mechanical properties of nanocomposites prepared may be attributed to mechanical percolation of WSH30, formation of a continuous network of WSH30 linked by hydrogen interactions and a close association between filler and matrix.

Keywords: Cellulose nanocrystals, agro-industrial residue, reinforcement, methylcellulose, nanocomposites.

Introduction

Synthetic oil-based polymers are widely used as packaging because of their excellent properties, including high strength, elongation, lightweight, and water resistance. These plastics are convenient, safe, strong, and economical (inexpensive), but not biodegradables[1]. Therefore, several groups have tried to develop packaging from renewable sources that are environmentally friendly, inexpensive, lightweight, possess good thermomechanical properties, and provide a reasonable barrier to the transfer of liquids and gases[2].

The increasing interest in biodegradable materials has motivated industrial and academic research to use biopolymers in applications where synthetic polymers or mineral fillers were traditionally used. As a result, intensive studies have been devoted to cellulose nanocrystals (CN). The main characteristics that stimulate the use of CN as reinforcing agents in polymers include their large specific surface area (estimated at several hundred m2.g–1), high elastic modulus (150 GPa), low density (approximately 1.566 g/cm3), biocompatibility, and biodegradability[3,4].

CN-based nanocomposites generally exhibit significant improvements in thermal, mechanical, and barrier properties when compared to the neat polymer or conventional composites, even at low loading filler levels[5]. These outstanding properties were ascribed to a mechanical percolation, which results mainly from the strong interactions between CN through hydrogen bond forces phenomenon and the very short distances between the fillers (these distances begin to approach molecular dimensions)[6,7].

Due to its low cost, abundance, and availability, vegetable waste biomass can be better utilized, reducing production costs and disposal in the environment. It is clear that the manufacture of new high performance materials from vegetable waste biomass (e.g. soybean hulls) can provide technological, economic, and environmental benefits to the country.

Many polymeric matrices have been reinforced with CN, resulting in nanocomposites that often showed improvements in thermomechanical properties, as is the case for polylactic acid (PLA)[8], polycaprolactone (PCL)[9], carboxymethylcellulose (CMC)[10] and poly(vinyl alcohol) (PVA)[11]. To the best of our knowledge in the literature, there are two studies in which the thermomechanical and barrier properties of the methylcellulose (MC) were improved by the addition of the montmorillonite nanoparticles[12] and cellulose nanofibers[2]. However, there is no record in the literature of reinforcement of MC with CN.

MC, a biodegradable polymer, is a modified type of cellulose that is the most abundant biopolymer in nature. MC is widely used in the pharmaceutical, food, agricultural, construction, paints, ceramics, detergents, adhesives, and cosmetics industries. This biopolymer is water soluble, has excellent film forming properties, and causes no toxic effects on the human body. Films made with this material have low permeability to oxygen and lipids, pose no threat to the environment, and are profitable. However, the limitations of these films include: weak thermo-mechanical properties and water sensitivity, and poor barrier properties[2]. In an attempt to maximize the potential use of MC films, in this study we developed unpublished nanocomposite films of MC reinforced with CN, and evaluated their thermomechanical and barrier properties against light and water vapor. In the present paper, the storage modulus (E'), loss tangent (tan d), water vapor permeability (Pw), light transmittance (Tr), and thermal stability (TS) of the nanocomposites were measured at different filler loading levels.

Experimental

Materials

CN prepared according our previous work[4], phosphorus pentoxide (P2O5, 98.5%; Sigma-Aldrich), and methylcellulose powder (MW = 40.000; GS = 1.75 ± 0.01 determined as described by Vieira et al.[13]; Sigma-Aldrich).

Preparation of cellulose nanocrystals

The CN were isolated from purified soy hulls and characterized in our previous work[4]. The obtained nanocrystals were denominated WSH30. The WSH30 were prepared by hydrolysis at 40 ºC for 30 min using 30 mL of H2SO4 (10.06 M) per gram of fiber.

Preparation of MC/WSH30 nanocomposites

Aqueous 1% (w/v) MC solutions were mixed with aqueous suspension of WSH30 followed by ultrasonic treatment for 15 min. The weight ratios of WSH30 to MC were 2:98 (2%), 4:96 (4%), 6:94 (6%), 8:92 (8%) and 10:90 (10%). MC/WSH30 nanocomposite films and neat MC film were fabricated using a casting method at 35 ºC for 24 h in oven. The final mass of all the films was 0.7 g and their thickness ranged from 0.017 to 0.040 mm.

Characterizations and measurements

Dynamic Mechanical Thermoanalyses (DMTA)

Dynamic mechanical properties of the nanocomposites films and neat MC film were evaluated using a TA Instruments DMA Q800 on rectangular films (ca. 20 × 6.42 × 0.04 mm) in tensile mode with an oscillation frequency of 1 Hz, a static force of 10 mN, an oscillation amplitude of 15.0 mm, and an automatic tension setting of 125%. Measurements were carried out with a heating rate of 3 ºC/min and range of 25-250 ºC.

Water Vapor Permeability (Pw)

Water vapor permeability was measured by Payne's cup technique using P2O5 as a drying agent. To perform the analysis, permeation to water vapor was carried as described in the work of Morelli and Ruvolo Filho[14], in which one can analyze the ability of each sample to permeate by its loss of mass, which was directly proportional to the loss of water flowing through the film in this case. The thicknesses of the films with 0, 2, 4, 6, 8, and 10% load (WSH30) were 3.124, 2.972, 2.591, 2.108, 1.905, and 2.794 mm, respectively. Two replicates of each sample were placed in a controlled environmental chamber with a constant temperature (T) of 20.0 ± 1.0 ºC, pressure of vaporization of water (DPv) of 17.54 mmHg, and 0% relative humidity.

Light Transmittance (Tr)

Light transmittance by the nanocomposite films and neat MC film was measured in a Shimadzu UV-vis spectrometer (model UV-250 1PC) at 25 ºC and correlated based on the film thicknesses using the Lambert-Beer's law. The experiments were carried out in the wavelength range of 200-800 nm with a 0.5 nm spectral bandwidth. The thickness of the films produced ranged from 0.025 to 0.035 mm.

Thermal Gravimetric Analysis (TGA)

Thermal stabilities (TS) of the WSH30 and the nanocomposite films were evaluated using a Shimadzu DTG-60H equipment. The analysis conditions were a nitrogen atmosphere with flow rate of 30 mL.min–1, heating rate of 10 ºC.min–1, temperature range of 25 to 600 ºC, sample mass between 5 and 7 mg, and aluminum pans. The initial temperature of degradation (Tonset) was defined as the intersection of the tangents drawn from the thermogravimetric curve, one before inflection caused by the degradation and the other from 5 mass% degradation after inflection.

Results and Discussion

Preparation of cellulose nanocrystals

In our previous work, the WSH30 were characterized according to their crystallinity index, morphology, and thermal stability. As we reported, WSH30 had a needle-shaped characteristics, crystallinity of 73.5%, initial degradation temperature of ~200 ºC, average length (L) of 122.66 ± 39.40 nm, and a diameter (D) of 2.77 ± 0.67. The results of the morphological investigation using microscopy-based methods (Transmission Electron Microscopy and Atomic Force Microscopy) showed that the aspect ratio (L/D) for WSH30, ranging from about 24 up to 77, with an average value of about 44[4]. This value was greater than 10, which is considered the minimum value for good stress transfer from the matrix to the fibers for any significant reinforcement to occur[5]. Therefore, WSH30 have great potential to be used as reinforcing agents in nanocomposites.

Dynamic Mechanical Thermoanalyses (DMTA)

The Figures 1a and 1b show the evolution of the tensile storage modulus (E') and loss tangent (tan d), measured as a function of temperature, for the neat MC film and MC/WSH30 nanocomposite films with various contents of WSH30. The glass transition temperature (Tg) of the samples was determined as the temperature at the maximum of the tan d peak.


The value of E' is directly related to the ability of a material to withstand mechanical loads recoverable strain. The improvement in E' was found upon CN addition. The E' of the nanocomposites increased modestly between room temperature and Tg. The experimental values of E' at 25 ºC and 220 ºC are shown in Table 1. For example, it increased from 3185.6 MPa at 25 ºC for the neat polymer to 3857.2 MPa for the nanocomposite with 8 wt% WSH30, which corresponded to a 21.1% increase. The relative reinforcement was more significant above Tg (in the rubbery plateau). For example, at 220 ºC, the E' of the nanocomposite containing 8 wt% WSH30 exhibited a modulus of 120.6 MPa, which represents a 119.7% enhancement over that of the neat matrix (54.9 MPa).

The mechanical reinforcement observed for the nanocomposites above Tg was most likely due to percolation. This means that the filler content is high enough for the formation of rigid CN networks, where stress transfer is facilitated by hydrogen-bonding between the CN[15]. This mechanism was shown to be responsible for the reinforcement of several polymeric matrices[16,17]. This hypothesis is supported by calculations obtained using a percolation model according with Siqueira et al.[18]. Taking into account the densities of WSH30 and MC, 1.57 and 1.30 g.cm–3 respectively, and the aspect ratio of the nanoparticles (44), the percolation threshold calculated was 1.91% wt. This shows that percolation occurs in all nanocomposites developed in this study, since the smallest filler loading used was 2% wt.

It is well known that the large specific surface area, high modulus of elasticity, and the aspect ratio of CN play key roles in improving the mechanical properties of polymer/CN composites. Additionally, the hydroxyl groups present in the surface of the CN facilitate hydrogen bond interactions and adhesion between the matrix and filler, which may also lead to improvements in mechanical properties. These characteristics show the ability of CN to significantly reinforce a polymer matrix system at very low filler loadings. For example, the E' of nanocomposite could be increased to about 2200% higher than that of the bulk polymer matrix at only 4 wt% of the CN[15].

The fact that the samples containing 10 wt% of WSH30 showed a slightly lower modulus than the sample containing 8 wt% may be explained by the aggregation of CN at higher concentrations. It was reported that for MC nanocomposite films reinforced with 10 wt% of montmorillonite nanoparticles[12] at 30 ºC (below the Tg), the E' value increased by 37.5% when compared to the neat matrix of MC. This increase was slightly higher than for MC/WSH30 nanocomposite containing 8 wt% of filler (21.1% increase). However, at 220 ºC (above the Tg), the E' value increased by about 72% for the nanocomposite film with 10 wt% of montmorilonite when compared to the neat matrix. This enhancement was smaller than the increase observed in our work at 220 ºC (119.7% for nanocomposite film with 8 wt% of WSH30).

For all the samples a modest increase of the storage modulus with temperature is observed in rubbery plateau region. However, for nanocomposites containing high nanofiller loading (8 and 10 wt%) the modulus becomes roughly constant over a wide temperature region in rubbery plateau. While in the case of unfilled MC and low filler content nanocomposites (2, 4 and 6 wt%), the increase of the rubbery modulus is known to depend on the degree of crystallinity of the material[19].

The tan d is the mechanical loss factor, which is responsible for the damping properties of the material. This damping is associated with the phase equilibrium between the elastic and viscous phases in the material. The magnitude and area of the tan d peak decreases upon filler addition (Figure 1b). This was associated with the concomitant decrease in the E' drop, and this was responsible for the damping properties[20]. This behavior indicates that the filler (WSH30) partially supports the tension applied on the composite, allowing only one part of this tension might deform the filler/matrix interface. In addition, the incorporation of fillers in the polymeric matrix lead to increased rigidity or restricted mobility of the polymer chains in the region of filler/matrix interface that can be attributed to molecular interactions between these components. Therefore, the relative peak height or area under of tan d peak are proportional to the volume of the constrained polymer chains and change systematically with amorphous content[19].

In the experimental conditions used, DMTA revealed that the Tg of the materials was not significantly influenced by the incorporation of the cellulose filler. As shown in Table 1, the transition regions from a glassy state to rubbery state was approximately 203 ºC, with a range less than 1 ºC, for all samples. The Tg values were similar to previous values reported in the literature for the same polymer[12].

The favorable interactions between the polymer matrix and cellulosic filler are confirmed by the relatively high reinforcing effect provided by the latter. Given the surface chemistry of the CN, we speculate that hydrogen bond interactions between the hydroxyl groups on the surface of the CN with the polar sites of the methylcellulose matrix play a role.

Water Vapor Permeability (Pw)

The Pw values of the nanocomposites with different contents of WSH30 are shown in Table 1.

The growth and metabolism of microorganisms require the presence of water in an available form. The most commonly used measurement to express the availability of water in food is water activity (aw). To reduce aw in food, one can increase the concentration of solutes in the aqueous phase of the food, either by removing water or by adding solutes. A small reduction in aw is often sufficient to have an effect in preserving food[11]. Given the necessity of reducing aw in food packaged in polymeric films, it is very important to evaluate water transport through films produced for this use.

The results obtained for all nanocomposites showed good reduction in Pw when compared to the neat MC film. It was observed that the Pw was progressively reduced with increasing content of WSH30 up to 8%. This is an indication that the nanoparticles were well dispersed and adhered in the polymeric MC matrix. The nanocomposite films with 2, 4, 6, 8, and 10% filler showed decreases in Pw by 7.57, 17.29, 30.27, 36.32, and 13.02%, respectively. However, for us, the Pw at the 10% level was smaller due to agglomeration of WSH30, which occurred to a sufficient extent to provide channels or areas where the membrane permits greater Pw.

The reduction of Pw in the nanocomposite MC/WSH30 films can be explained by the physical barrier to the passage of water provided by CN, i.e. the water must walk along the surface of CN, but fails to pass through, thus leading to a slower diffusion processes and, hence, to a lower permeability[5]. The barrier properties are enhanced if the filler is less permeable and has a good dispersion into the matrix[21]. In the present study, the high crystallinity and the strong interactions between of the hydroxyls groups of the CN, as well as the interactions of the WSH30 with the MC-based films components (mainly cellulose), may have enhanced water vapor barrier properties of the film[22,23].

The reductions in Pw observed for the nanocomposite films in this study were comparable to others reports. Khan et al. obtained 26% reduction in Pw with 1% cellulose nanofibers (CNF) in MC films when compared to the neat MC membrane[2]. Sánchez-García et al. obtained a largest reduction (71%) in Pw with 3% α-cellulose microfibers (CNW) in Carrageenan films when compared to the neat Carrageenan film[24].

Light Transmittance (Tr)

The results of the spectroscopy in the ultraviolet-visible (UV-VIS) region (200-800 nm) of the neat MC film and MC/WSH30 nanocomposites with 2, 4, 6, 8, and 10% filler mass are shown in Figure 2. The films exhibited optical transmittances (Tr) very close and excellent in the spectrum of visible light (400-750 nm), which is an indication of good interfacial interation and compatibility of nanocomposites and the polymer matrix. The nanometric characteristics of WSH30, with their ultrathin diameter of 2.77 nm and average length of 122.66 nm, combined with a surface area of high hydrophilicity, substantially improved the intermolecular interactions through hydrogen bonding at the interfaces of the WSH30 and MC matrix[25,26]. However, it could not be determined whether there was uniform dispersion of the reinforcing material, since no specific technique was performed to determine this.


In the range of 300-450 nm, we noted that there was a slight tendency of Tr to decrease (92.89-82.56%) with increasing load (0-10% by mass) in the polymer matrix. However, no difference was greater than 10% of the Tr of the nanocomposites when compared to the Tr values of the neat MC film, thereby demonstrating good Tr of the nanocomposites in this range of wavelengths. Still, considering wavelengths in the 300–450 nm range, the Tr values for the nanocomposite with 6% of WSH30 were close to those of the nanocomposite with a 10% load. This probably occurred because the Tr experiment was a punctual test, and the region analyzed for the nanocomposite film MC/6%WSH30 could have been contaminated with some minimal amount of an impurity or there could be some small agglomeration of WSH30 in the nanocomposite occurring. In the final track of the spectrum (450-800 nm), the trend mentioned above is virtually nonexistent because all Tr were above 95%. It is known that beyond the refractive index, which is inherent to each material, the porosity of the film surface also causes light scattering, so the excellent Tr of the films is at least one indication that they were minimally porous[25,26].

The nanocomposites produced in this work exhibited Tr values in the visible region larger than other similar systems, such as the nanocomposite prepared by Ayuk and his collaborators [10 wt% microcrystalline cellulose nanocrystals (NCCMC) in cellulose acetate butyrate], which exhibited Tr values 50% and 65% at wavelengths of 600 nm and 800 nm, respectively[27]. The Tr values of the MC/WSH30 films were also higher than the nanocomposite produced by Tang and Liu[26] (8.4 wt% CNF from carpet dispersed PVA), which had Tr values less than 90% at 600 nm.

Thermal Gravimetric Analysis (TGA)

The thermal degradation of the neat MC and MC/WSH30 nanocomposites as a function of WSH30 content is presented in Figure 3. A slight decrease in weight (~1-5 wt%) of MC and MC nanocomposites started below 120 ºC. The possible causes for the initial weight loss are probably due to moisture and the high water-retention capacity of MC[12].


The main weight decrease of the neat MC and its nanocomposites occurred in the temperature range of 270-380 ºC, and was due to structure degradation of MC. Knowing that the decomposition of MC generally starts around 290 ºC, it is very important to note that the CN added to the MC matrix did not adversely affect its thermal stability (TS), in order to not hinder the processing of the nanocomposites in an industrial process, for example[28].

The initial temperatures of degradation (Tonset) of WSH30 was around 200 ºC[4], while the Tonset of the nanocomposite films ranged from 260 ºC to 276 ºC and the Tonset of the neat MC film was approximately 270 ºC. The thermogravimetric analysis indicated retained the thermal stability of the nanocomposites. We can assume that WSH30 did not affect the Tonset of MC films produced since the WSH30 are not only embedded in the polymer matrix, but also very involved for this matrix.

Beyond 500 ºC, thermograms were consistent for the appearance of carbonized residue in the curves of the nanocomposites. This was due to the sulfate groups on the surfaces of the WSH30, which act as flame retardants[28]. The carbonized residues from the nanocomposite films were 0.4-6.1% by weight.

The TS results obtained in this work are very important because it is not necessary any adjustment or modification of the processing of nanocomposites produced by further processing of MC.

Conclusions

The WSH30 provided a significant improvement (119.7%) in the E' of the nanocomposites when only 8% of the filler had been incorporated into the MC. The reduction in Pw up to 36.32% when 8% loading was used, indicates that the WSH30 were well dispersed and adherent on the polymeric MC matrix. The reduction in permeability to water flow through the nanocomposite films provided by WSH30 CN is a very important factor since these nanofillers reinforce the MC films and enhance their use in environments containing some moisture while still reducing water activity, which prevents, or at least slows, the growth of bacteria. These factors make such films reasonable alternatives that can expand the applications of commercial MC films for food packaging.

The effects of improving the mechanical and barrier properties of the films developed in this study suggests that there was the formation of a strong network of interactions that occur when the process allows for good dispersion and adhesion of the nanoparticles to the matrix, thus allowing more effective in forming strengths hydrogen bonds between the WSH30 and between nanoparticles and matrix.

The nanocomposites produced were quite translucent, showing Tr values in the visible range (400-750 nm) very close to those of the neat MC film. The thermogravimetric analysis indicated that TS was retained for the nanocomposites that we produced.

From the results shown in this study, it is clear that CN obtained from WSH30 have a great potential for use as reinforcing agents in nanocomposites. In this work, high-performance bionanocomposites for diverse applications were produced by adding CN to MC and then compared to the neat MC films.

Acknowledgements

Authors thanks CAPES, CNPq, FAPEMIG for financial support.

Received: Feb. 20, 2014

Accepted: July 10, 2014

  • 1. Simi, C. K. & Abraham, T. E. - Colloid Polym. Sci., 288, p.297 (2010). http://dx.doi.org/10.1007/s00396-009-2151-8
  • 2. Khan, R. A.; Salmieri, S.; Dussault, D.; Uribe-Calderon, J.; Kamal, M. R.; Safrany, A. & Lacroix, M. - J. Agric. Food Chem., 58, p.7878 (2010). http://dx.doi.org/10.1021/jf1006853 PMid:20545366
  • 3. Dufresne, A. - Compos. Interfaces., 10, p.369 (2003). http://dx.doi.org/10.1163/156855403771953641
  • 4. Flauzino Neto, W. P.; Silvério, H. A.; Dantas, N. O. & Pasquini, D. - Ind. Crops Prod., 42, p.480 (2013). http://dx.doi.org/10.1016/j.indcrop.2012.06.041
  • 5. Azeredo, H. M. C.; Mattoso, L. H. C.; Wood, D.; Williams, T. G.; Avena-Bustillos, R. J. & McHugh, T. H. - J. Food Sci., 74, p.N31 (2009). http://dx.doi.org/10.1111/j.1750-3841.2009.01186.x PMid:19646052
  • 6. Favier, V.; Canova, G. R.; Cavaillé, J. Y.; Chanzy, H.; Dufresne, A. & Gauthier, G. - Polym. Adv. Technol., 6, p.351 (1995a). http://dx.doi.org/10.1002/pat.1995.220060514
  • 7. Favier, V.; Chanzy, H. & Cavaillé, J. Y. - Macromolecules., 28, p.6365 (1995b). http://dx.doi.org/10.1021/ma00122a053
  • 8. Lin, N.; Chen, G. J.; Huang, J.; Dufresne, A. & Chang, P. R. - J. Appl. Polym. Sci., 113, p.3417 (2009). http://dx.doi.org/10.1002/app.30308
  • 9. Siqueira, G.; Bras, J. & Dufresne, A. - Biomacromolecules., 10, p.425 (2009). http://dx.doi.org/10.1021/bm801193d PMid:19113881
  • 10. Flauzino Neto, W. P.; Silvério, H. A.; Vieira, J. G.; Alves, H. C. S.; Pasquini, D.; Assunção, R. M. N. & Dantas, N. O. - Macromol. Symp., 319, p.93 (2012). http://dx.doi.org/10.1002/masy.201100194
  • 11. Silvério, H. A.; Flauzino Neto, W. P. & Pasquini, D. - J. Nanomater., 2013, p.1 (2013). http://dx.doi.org/10.1155/2013/289641
  • 12. Rimdusit, S.; Jingjid, S.; Damrongsakkul, S.; Tiptipakorn, S. & Takeichi, T. - Carbohydr. Polym., 72, p.444 (2008). http://dx.doi.org/10.1016/j.carbpol.2007.09.007
  • 13. Vieira, R. G. P.; Rodrigues Filho, G.; Assunção, R. M. N.; Meireles, C. S.; Vieira, J. G. & Oliveira, G. S. - Carbohydr. Polym., 67, p.182 (2007). http://dx.doi.org/10.1016/j.carbpol.2006.05.007
  • 14. Morelli, F. C. & Ruvolo Filho, A. - Polímeros., 20, p.121 (2010). http://dx.doi.org/10.1590/S0104-14282010005000014
  • 15. Tang, L. & Weder, C. - Appl. Mater. & Inter., 2, p.1073 (2010). http://dx.doi.org/10.1021/am900830h
  • 16. Capadona, J. R.; Shanmuganathan, K.; Tyler, D. J.; Rowan, S. J. & Weder, C. - Science., 319, p.1370 (2008). http://dx.doi.org/10.1126/science.1153307 PMid:18323449
  • 17. Azizi Samir, M. A.; Alloin, F. & Dufresne, A. - Biomacromolecules., 6, p.612 (2005). http://dx.doi.org/10.1021/bm0493685 PMid:15762621
  • 18. Siqueira, G.; Bras, J. & Dufresne, A. - Polymers., 2, p.728 (2010). http://dx.doi.org/10.3390/polym2040728
  • 19. Bindu, P. & Thomas, S. - J. Phys. Chem. B., 117, p.12632 (2013). http://dx.doi.org/10.1021/jp4039489 PMid:24090199
  • 20. Pasquini, D.; Teixeira, E. M.; Curvelo, A. A. S.; Belgacem, M. N. & Dufresne, A. - Ind. Crops Prod., 32, p.486 (2010). http://dx.doi.org/10.1016/j.indcrop.2010.06.022
  • 21. Lagaron, J. M.; Catalá, R. & Gavara, R. - J. Mater. Sci. Technol., 20, p.1 (2004). http://dx.doi.org/10.1179/026708304225010442
  • 22. Azeredo, H. M.; Mattoso, L. H.; Avena-Bustillos, R. J. A.; Filho, G. C.; Munford, M. L.; Wood, D. & Mchugh, T. H. - J. Food Sci., 75, p.N1 (2010). http://dx.doi.org/10.1111/j.1750-3841.2009.01386.x
  • 23. Paralikar, S. A.; Simonsen, J. & Lombardi, J. - J. Membr. Sci., 320, p.248 (2008). http://dx.doi.org/10.1016/j.memsci.2008.04.009
  • 24. Sánchez-García, M. D.; Hilliou, L. & Lagarón, J. M. - J. Agric. Food Chem., 58, p.12847 (2010). http://dx.doi.org/10.1021/jf102764e PMid:21073192
  • 25. Moon, R. J.; Martini, A.; Nairn, J.; Simonsen, J. & Youngblood, J. - Chem. Soc. Rev., 40, p.3941 (2011). http://dx.doi.org/10.1039/c0cs00108b PMid:21566801
  • 26. Tang, C. & Liu, H. - Compos., Part A Appl. Sci. Manuf., 39, p.1638 (2008). http://dx.doi.org/10.1016/j.compositesa.2008.07.005
  • 27. Etang Ayuk, J.; Mathew, A. P. & Oksman, K. - J. Appl. Polym. Sci., 114, p.2723 (2009). http://dx.doi.org/10.1002/app.30583
  • 28. Roman, M. & Winter, W. T. - Biomacromolecules., 5, p.1671 (2004). http://dx.doi.org/10.1021/bm034519+ PMid:15360274
  • Corresponding author:

    Daniel Pasquini,
    Instituto de Química, Universidade Federal de Uberlândia – UFU,
    Campus Santa Mônica, Av. João Naves de Ávila, 2121,
    CEP 38400-902, Uberlândia, MG, Brazil,
    e-mail:
  • Publication Dates

    • Publication in this collection
      19 Jan 2015
    • Date of issue
      Dec 2014

    History

    • Accepted
      10 July 2014
    • Received
      20 Feb 2014
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