Biodegradable sodium alginate and lignosulphonic acid blends: characterization and swelling studies

Reddy, S. Giridhar; Pandit, Akanksha Saxena

doi:10.1590/S0104-14282013005000006

Abstract

In this article, Sodium alginate and Lignosulphonic acid blends were prepared in different weight ratios by solution casting method. Swelling experiments were conducted for Sodium alginate and its blends by adding calcium chloride for various intervals in a pH 7.4 medium. The strength of the films increases after their treatment with CaCl2 at higher intervals forming an alginate network. The SA/LS blend (80/20) is subjected for sorption studies at variable pH 1.2 & 7.4, in order to test the suitability of the blends for controlled drug delivery. Further, experiments were conducted for de-crosslinking using 0.1M HCl. The solvent uptake for the blends decreased with increasing LS content in the blends. Blends were investigated by X-ray diffraction and Fourier Transform Infra-Red spectroscopy in order to study the crystallinity and molecular interactions. XRD confirms the reduction in cluster space in blends leading to lower uptake of solvent.

Sodium alginate; blends; swelling; biomaterials; water soluble polymers; crosslinking

Biodegradable sodium alginate and lignosulphonic acid blends: characterization and swelling studies

S. Giridhar Reddy; Akanksha Saxena Pandit

Bangalore Campus, Amrita Vishwa Vidyapeetham

^{Endereço para correspondência} Endereço para correspondência: Akanksha Saxena Pandit Chemistry Department Amrita School of Engineering Bengaluru Campus Amrita Vishwa Vidyapeetham Carmelram Post, Karnataka, India e-mail: s_akanksha@rediffmail.com; s_akanksha@blr.amrita.edu

ABSTRACT

In this article, Sodium alginate and Lignosulphonic acid blends were prepared in different weight ratios by solution casting method. Swelling experiments were conducted for Sodium alginate and its blends by adding calcium chloride for various intervals in a pH 7.4 medium. The strength of the films increases after their treatment with CaCl₂ at higher intervals forming an alginate network. The SA/LS blend (80/20) is subjected for sorption studies at variable pH 1.2 & 7.4, in order to test the suitability of the blends for controlled drug delivery. Further, experiments were conducted for de-crosslinking using 0.1M HCl. The solvent uptake for the blends decreased with increasing LS content in the blends. Blends were investigated by X-ray diffraction and Fourier Transform Infra-Red spectroscopy in order to study the crystallinity and molecular interactions. XRD confirms the reduction in cluster space in blends leading to lower uptake of solvent.

Keywords: Sodium alginate, blends, swelling, biomaterials, water soluble polymers, crosslinking.

Introduction

Sodium alginate (SA) blends are the biodegradable polymers that are soluble in water and various other aqueous solvents. Their application in various biomedical fields has been a major area of study over the last half century. The sodium alginate hydrogels are largely used due to their high biocompatibility^[1]. Over the past year, a large part of the work in the biomedical field has revolved around applications such as carriers for the modified release of drugs and bioactive macromolecules^[1]. Recently, the application of alginate hydrogels as scaffolding materials has attracted much attention in the areas of tissue engineering^[2]. Alginates are an interesting family of polymers that have been studied for a wide variety of biomedical applications^[2-4]. This interest in the alginates is primarily due to its relative ease with which they can undergo gelation with divalent cations under the very mild conditions suitable for biomacromolecules and living cells^[5,6]. But alginate hydrogels possess a limited mechanical stability under physiological conditions^[5]. For biomedical applications aimed at vivo, the mechanical properties are important because they must possess sufficient mechanical strength and flexibility to withstand compressional forces from the surrounding tissues in vivo without fear of collapse. To improve the mechanical stability of membrane, Sodium alginate (SA) needs to be blended with other polymer such as Lignosulphonic acid (LS). LS is a natural biopolymer obtained as a plant byproduct formed from sulphite cooking of wood and is large tonnage wastes from pulp and paper industry. In this study, we aimed to prepare blends of sodium alginate and sodium salt of lignosulphonic acid from which blends with enhanced stability under physiological conditions can be obtained via ionically cross-linking formation in calcium chloride solution. Sorption experiments are conducted for SA and blends for water uptake. The sorption technique is a good tool for the crystalline characterization of polymer blends^[7,8]. The analysis of the equilibrium sorption by a blend can provide information on polymer - polymer interactions and morphology of the system. Particular attention has been given to the effects of blend ratio and solvent uptake and the correlation of the results with the morphology of the matrices using XRD and FTIR characterization. Finally, SA/LS (80/20) blend is studied for water uptake in variable pH 1.2 and pH 7.4 for possible use in oral delivery of drugs along the Gastro intestinal tract.

Experimental

Chemicals

Sodium alginate (MW=300000 gm/mol) and lignosulphonic acid (MW = 50000 gm/mol) were used as obtained from Sigma Aldrich Bangalore India Limited. Calcium chloride and buffer capsules of pH 1.2 and pH 7.4 were used as received from SD Fine Chem Ltd.

Preparation of blends

The aqueous solution of alginate (sodium alginate solution with a concentration of 1 wt. (%) was prepared by stirring preliminary swollen sodium alginate in distilled water for 3 hours) and sodium lignosulphonic acid were mixed in various compositions (100/0, 80/20 & 60/40 by weight). The sample films were cast by pouring the compositions on glass substrates, dried at room temperature for 72 hours, and then dried at 60 °C to constant weight in a vacuum oven^[9]. The dried films of thickness 0.2 mm were obtained and the blends were cut in to circular shape of diameter 1.9 cm as reported in^[10].

Curing SA-LS blends using calcium chloride as crosslinking agent

The blends are cross-linked by dipping in 2% CaCl₂ solution for various intervals and then allowed to dry at 30 °C in a dust free chamber till they attained constant weight. Here it should be noted that mode of drying process affects the stability of blends. The drying of blends at higher temperature may result in surface cracking which can facilitate the surface erosion upon rehydration. This will ultimately affect the swelling/degradation behavior. Experimental conditions were maintained uniform throughout the investigations.

Characterisation

Swelling studies of blends for water uptake

The swelling behavior of the cross-linked films was measured, based on the solvent uptake by the blends in different pH solutions at the room temperature. Further, blends are wiped with tissue paper to remove water on the blends surface. The 'Weight change' was monitored at different time-intervals till the blends showed constant weight. The fractional weight change was transformed to percentage using the following empirical relationship^[11]:

Percentage of Swelling = (Final weight - Initial weight) / Initial weight × 100.

The measurements were made in triplicate and average data was used for calculations.

X-Ray diffraction studies

A Brucker D8 advanced powder X-ray diffractometer was used to study the solid state morphology of SA, LS and SA/LS Blends in powdered form. X-rays of 1.548 Å wavelengths were generated by a Cu Kα source. The angle of diffraction was varied from 5° to 60° to identify the change in the crystal structure and intermolecular distances between the intersegmental chains in blends.

Fourier transform infrared spectroscopy (FT-IR) studies

FT-IR spectra of the blends were measured on a Nicolet impact 400 FT-IR spectrophotometer. The samples were prepared by making KBr pellets containing 3 wt. (%) of materials.

Results and Discussions

Effect of crosslinking on blends

The blends are cured, in order to investigate the effect of Calcium Chloride and alginate content on the swelling behavior of blends. We synthesized three blends of the proportion SA/LS blend (100/0, 80/20, and 60/40). In order to investigate, water uptake behavior of SA/LS blend (80/20) samples were cross linked for 10, 20, 30 and 60 minutes was studied. The swelling studies were conducted using buffer solution (pH 7.4) as penetrate. All swelling behaviors are plotted on the average of three trials. It has been reported, that maximum time required for calcium ions induced crosslinking of alginate is nearly 30 minutes. In order to investigate this aspect the SA/LS blends 80/20 were cured for, 10, 20, 30 and 60 minutes. The swelling results are depicted in Figure 1a. The Figure 1a clearly indicates that blend films exhibits different swelling/degradation behavior. The SA/LS (80/20) blend cured for 10 minutes exhibits maximum swelling nearly 430 ± 10% in one hour and then starts to disintegrate slowly and finally dissolves in 15 hours, whereas swelling decreases at higher intervals of crosslinking ie 320 ± 12% for 20 minutes curing and 220 ± 10% for 30 minutes curing. The swelling decreases drastically for 60 minutes curing ie about 40 ± 10%. The above experimental data reveals one important fact that in the present system, the crosslinking processes is not completed in 30 minutes. Perhaps it requires almost 60 minutes for complete curing. It has been reported that alginate cross-linked at higher intervals provide mechanical strength to the films due to crosslinking of polyguluronate residues in alginates^[12].

Effect of alginate content

The effect of SA content on swelling behavior of the blends was studied. The results are shown in Figure 1b. The pure sodium alginate (100/0) and SA/LS blends (80/20 and 60/40), cured for 30 minutes using 2% Calcium chloride solution were swelled using buffer solution of pH 7.4 as penetrate. The Figure 1b clearly indicates, that blend films exhibit different swelling/degradation behavior. The Pure SA (100/0) exhibit maximum swelling of 500 ± 12% of water uptake in buffer solution (pH 7.4). However, the swelling decreases in SA/LS blends (80/20 & 60/40). SA/LS blend (80/20) exhibits moderate swelling i.e. 220 ± 12% in one hour and then starts to disintegrate slowly after 2 hours and finally dissolves in 15 hours. On the other hand SA/LS blends (60/40) cured for same time shows a lower water uptake ie nearly 110 ± 10% in 60 minutes and stable up to 48 hours. It has been reported that the blends has relatively more cross linked structure and hence they exhibit lower water uptake due to tight structure in the intermolecular chain; they exhibit minimum swelling^[13].

Swelling behavior in pH 1.2 and pH 7.4

In order to test the suitability of the blends for gastrointestinal drug delivery, the swelling behavior of SA/LS blend in ratio of 80/20, cross linked for 30 minutes using calcium chloride as crosslinking agent was studied. The SA/LS (80/20) blend was subjected for swelling for water uptake in pH 7.4 and pH 1.2. From Figure 2a, it is found that swelling decreases drastically in acidic medium 100 ± 4% in 30 minutes and then do not swell further. This is well expected because alginates do not swell significantly at low pH^[15]. When a dosage is administered orally, goes to the stomach and after residing there for a definite time-period, it passes on to small intestine and then finally to colon. In this way, the polymer loaded with drug has to get exposed to a sharp pH change in the range 1-2 (gastric fluid) to 7-8 (intestinal fluid). Therefore, in order to mimic the transition of proposed SA/LS blend (80/20) from mouth to colon, they should be exposed to the media of varying pH. Relying on the data given by a group of pharmaceutical researchers regarding the transit time of a dosage form along GI tract^[14], we exposed the blend to medium of pH 1.2 for a period of 3 hours and then transferred the same blend in the phosphate buffer of pH 7.4 for rest of the time. The results of swelling measurements have been depicted in Figure 2b. It is clear that the water uptake of the blend was nearly 100 ± 4% in the acidic solution in first 30 minutes and did not swell further. When they were transferred into medium of pH 7.4, there was sudden rise in water uptake. The blend swelled to nearly 400 ± 9% in the next 1 hour and attained equilibrium water uptake of 400 ± 23% in a total duration of 4 hours, then started to disintegrate in next 1 hour. This can be explained as follows: when the blend is placed in the medium of pH 1.2, they exhibit almost minimum swelling (i.e. nearly 100 ± 4% water uptake). However, on transferring them into phosphate buffer medium of pH 7.4, they begin to absorb water at faster rate. This is due to the fact that their stay in the medium of pH 1.2 results in acid - catalyzed hydrolysis of alginates into low molecular alginic acid^[16]. Moreover, in acidic pH, the protonation of carboxylate groups, attached at polyguluronate blocks of alginate results in decrease in ionic crosslinking of the blend. So when this blend is transferred into the phosphate buffer of pH 7.4, the blend begins to take up water. The ion-exchange (although at a slower rate) between Ca⁺² ions of blend and Na+ ions of phosphate buffer also makes the structure loose, thus enhancing the uptake of water. Finally, when the blend attains maximum swelling (which is nearly 400 ± 9%) low molecular weight segments of alginic acid and linear chains of LS become unable to retain the hydrated structure and hence the blend begins to disintegrate. This finally causes total dissolution of the blend.

Effect of treatment with 0.1 M HCl

In order to investigate the effect of acid treatment on the swelling behavior of the blends, the SA/LS blend (80/20) is treated with 0.1 M HCl for definite time periods, i.e. for 10, 20 and 30 minutes and their swelling behavior was studied in the phosphate buffer solution of pH 7.4 at 25 °C. The results as depicted in Figure 2c reveal that the blend treated for 30 minutes with 0.1 M HCl demonstrates highest water uptake of 430 ± 10% in 30 minutes then begin to disintegrate and finally dissolve completely, while the blend treated for 20 minutes, swell to nearly 400 ± 10% in the same time period. The untreated blend exhibited minimum water uptake. The observed findings may be explained as below. The SA/LS (80/20) blend exposed for sufficiently longer time (i.e. 30 minutes) in 0.1 M HCl, the alginate undergoes an appreciable degree of hydrolysis. The degree of crosslinking is also reduced to a greater extent. When this blend is put in solution of pH 7.4, they begin to take up water with subsequent dissolution of alginic acid segments. This result in relatively higher water uptake (430 ± 10% water uptakes in 30 minutes) and then the blend begin to disintegrate and finally dissolve. The untreated blend exhibit minimum water uptake due to highly cross-linked structure and do not show any tendency to disintegrate.

X-Ray diffraction studies

X-ray diffraction studies provide information on the nature of the compound as well as on the spacing between the clusters of the polymer chains. On blending, the polymer chains are in close compaction with one another and thus a reduction in the cluster space may be encountered. The X-ray diffractograms of pure SA, LS and SA/LS blend membranes, shown in Figure 3. Figures 3a, d are diffractograms of pure SA and LS has sharp peaks, and 3b, c has no sharp peaks indicating the amorphous nature of the blend membranes^[13]. The XRD spectra of the SA/LS: 80/20 (Figure 3b) exhibits a broad peak at 2θ = 43° and 49° which may be due to the intermolecular interaction between SA and LS. The SA/LS (60/40) & SA/LS (80/20) blend membranes appears to be more amorphous than pure samples of SA and LS, whereas among blends the SA/LS (60/40) appears to more amorphous than SA/LS(80/20). The increase in amorphous nature in blends leads to shrinkage in cell size or inter-segmental spacing occurring due to blending which would improve the selective permeation of the membrane.

Fourier transform infrared spectroscopy (FT-IR) studies

Fourier transform infrared (FT-IR) spectroscopy of blend films was carried out in order to detect any peak shift that could be attributed to weak interactions or structural changes between the two polymers. The FT-IR spectra of the interpolymer complexes show spectral features similar to those for the homopolymer^[17]. Figure 4 shows the FT-IR spectra of the pure samples and blends in the wavelength ranges of 4000-2500 and 1600-1400 cm^{- 1}.The characteristic band of LS was observed at 1600 cm^{- 1} due to the aromatic structure. On the other hand, the bands of LS appeared at 3500 cm^{- 1} for the hydroxyl groups. The spectrum of the SA/LS blend films was characterized by the presence of the absorption bands typical of the pure components, with the intensity roughly proportional to the blending ratio. The characteristic bands of SA appeared at 1611 and 3500 cm^{- 1} were observed in all spectra of the blends. The spectra 1(Figure 4a) and 4 (Figure 4d) are attributed to single components SA and LS and they do not have much of noise, since the samples are in powder form. But the spectra 2 (Figure 4b) and 3 (Figure 4c) possess more of noise and these are attributed to mixture of two components. Importantly, it can be observed that there is no appearance of new peaks when two components blended. This indicates that, blending might have taken place without any reaction between the two components leading to no structural change.

Conclusion

Blend films of LS and SA could be easily obtained by solution blending and casting onto the glass plate. The transport behavior of SA, SA/LS blends has been examined for water uptake in phosphate buffer of pH (7.4) as probe molecules at the room temperature. The strength of the blends and pure SA can be achieved by using calcium chloride as crosslinking agent for selective permeation. The solvent sorption decreases significantly with increase in LS content in SA. The decrease in solvent sorption, point towards the decrease in intermolecular spacing. The examination of influence of Calcium chloride at higher intervals shows more resistance to water uptake. The SA/LS blend (80/20) is subjected for the media of varying pH (1.2 & 7.4), demonstrates 400 ± 9% water uptake in 4 hours and demonstrates suitability to the possible usage for controlled drug delivery. Finally, swellings are conducted after acid treatment (0.1M HCl) and observed that swellings are altered drastically, due to de-crosslinking. The XRD analysis confirms the decrease in crystalline regions in SA/LS blends. FT-IR analysis of SA and LS reveals that blending has taken place without any structural changes.

Enviado: 06/03/12

Reenviado: 18/06/12

Aceito: 20/06/12

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13. Subba Reddy, A.; Kalyani, S. & Siva Kumar, N. - Polym. Bul., 61, p.779(2008).
14. Krishnaiah, V. S. R.; Satyanarayan, S.; Rama Prasad, Y. V. & Narsimharao, S. - J. Control. Release., 55, p.245(1998). http://dx.doi.org/10.1016/S0168-3659(98)00057-1
15. Mumper, U. J.; Hoffman, A. S.; Puollakkainer, P. A.; Bouchard, L. S. & Gombotz, W. R. - J. Control. Release., 30, p.241(1994). http://dx.doi.org/10.1016/0168-3659(94)90030-2
16. Gombotz, W. R. & Wee, S. F. - Adv. Drug Deliv. Rev., 31, p.267(1998). http://dx.doi.org/10.1016/S0169-409X(97)00124-5
17. Tuncer Aykara, C.; Serkan Demircia, A. & Mehmet, A. - Polymer, 46, p.10750 (2005).

Endereço para correspondência:

Akanksha Saxena Pandit

Chemistry Department

Amrita School of Engineering

Bengaluru Campus Amrita Vishwa Vidyapeetham

Carmelram Post, Karnataka, India

e-mail:

s_akanksha@rediffmail.com;

s_akanksha@blr.amrita.edu

Publication Dates

Publication in this collection
01 Feb 2013
Date of issue
2013

History

Received
06 Mar 2012
Accepted
20 June 2012
Reviewed
18 June 2012

This work is licensed under a Creative Commons Attribution 4.0 International License.

[1] 1. Kim, S. W. & Bae Okano, T. - Pharm. Res., 9, p.283 (1992). PMid:1614957. http://dx.doi.org/10.1023/A:1015887213431

[2] 2. Gutowska, A. & Jeong Jasionowski, B. - Anat. Rec., 263, p.342(2001). PMid:11500810. http://dx.doi.org/10.1002/ar.1115

[3] 3. Sakai, S.; Masuhara, H.; Yamada, Y.; Ono, T. & Ijima, H. J. - Biosci. Bioeng., 100, p.127(2005). PMid:16233864. http://dx.doi.org/10.1263/jbb.100.127

[4] 4. Zimmermann, H.; Zimmermann, D. & Reuss, R. - J. Mater. Sci. Mater. Med., 16, p.491(2005). PMid:15928863. http://dx.doi.org/10.1007/s10856-005-0523-2

[5] 5. Smidsrod, O. & Skjak-Braek, G. - Biotechnology, 8, p.71(1990).

[6] 6. Lee, K. Y & Mooney, D. J. - Chem. Rev., 101, p.1869 (2001). PMid:11710233. http://dx.doi.org/10.1021/cr000108x

[7] 7. Kwei, T. K.; Nishi, T. & Roberts, R. F. - Macromolecules, 7, p.667(1974). http://dx.doi.org/10.1021/ma60041a023

[8] 8. Johnson, T. & Thomas, S. - Polym. Plast. Tech. Eng., 39, p.363 (2000). http://dx.doi.org/10.1081/PPT-100100035

[9] 9. Travinskaya, T. V. & Savelyev, Y. V. - Eur. Polym. J., 42, p.388(2006). http://dx.doi.org/10.1016/j.eurpolymj.2005.07.017

[10] 10. Sujith, A.; Unnikrishnan, G. & Thomas, S. - J. Appl. Polym. Sci., 90, p.2691 (2003). http://dx.doi.org/10.1002/app.12923

[11] 11. Oh Jin, K.; Seung-Taek, O. H. & Sang-Do, L. - Fibers Polym., 8, p.347 (2007).

[12] 12. Aslani, P. & Kennedy, R. A. - J. Control. Release., 42, p.75(1996). http://dx.doi.org/10.1016/0168-3659(96)01369-7

[13] 13. Subba Reddy, A.; Kalyani, S. & Siva Kumar, N. - Polym. Bul., 61, p.779(2008).

[14] 14. Krishnaiah, V. S. R.; Satyanarayan, S.; Rama Prasad, Y. V. & Narsimharao, S. - J. Control. Release., 55, p.245(1998). http://dx.doi.org/10.1016/S0168-3659(98)00057-1

[15] 15. Mumper, U. J.; Hoffman, A. S.; Puollakkainer, P. A.; Bouchard, L. S. & Gombotz, W. R. - J. Control. Release., 30, p.241(1994). http://dx.doi.org/10.1016/0168-3659(94)90030-2

[16] 16. Gombotz, W. R. & Wee, S. F. - Adv. Drug Deliv. Rev., 31, p.267(1998). http://dx.doi.org/10.1016/S0169-409X(97)00124-5

[17] 17. Tuncer Aykara, C.; Serkan Demircia, A. & Mehmet, A. - Polymer, 46, p.10750 (2005).

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Biodegradable sodium alginate and lignosulphonic acid blends: characterization and swelling studies

Abstract

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History