The Effect of Processing Parameters and Solid Concentration on the Microstructure and Pore Architecture of Gelatin-Chitosan Scaffolds Produced by Freeze-Drying

Angulo, Daniel Enrique López; Sobral, Paulo José do Amaral

doi:10.1590/1980-5373-MR-2015-0793

Abstract

One of the main components for being successful in tissue engineering is developing a scaffold with an appropriate architecture for allow migration, cell proliferation, and differentiation. A gelatin-chitosan scaffold by vacuum freeze-drying has been developed for tissue engineering applications. The effects of solid concentration and freezing processing on the scaffold morphology and porous size were investigated. As the chitosan content was increased the viscoelastic properties of pigskin gelatin was modified, the maximum G' values were lower than the values for pure gelatin solution, and the thermal transition points also occurred at lower temperatures, as well as a decrease of pore size tendency was observed and the scaffold visibly increased porosity, the structure scaffold was observed with an interconnected and more homogeneous pore matrix. The pore sizes become smaller and pore walls thinner, while interconnectivity increases along with declining pre-freezing temperature. The chitosan-gelatin scaffold will be a promising candidate in tissue engineering.

Keywords
tissue engineering; cell proliferation; interconnected pore matrix

1. Introduction

Tissue engineering is an emerging science enclosing such diverse fields as molecular biology and materials engineering. It attempts to develop biological substitutes for damaging organs and tissues¹1 Teimouri A, Azadi M, Emadi R, Lari J, Chermahini AN. Preparation, characterization, degradation and biocompatibility of different silk fibroin based composite scaffolds prepared by freeze-drying method for tissue engineering application. Polymer Degradation and Stability. 2015;121:18-29.. Porous scaffolds have been extensively utilized in tissue engineering for playing an important role in manipulating cell function and guidance of new tissue formation as well as transporting nutrients and removing wastes²2 Chen G, Ushida T, Tateishi T. Scaffold design for tissue engineering. Macromolecular Bioscience. 2002;2(2):67-77.^,³3 Zmora S, Glicklis R, Cohen S. Tailoring the pore architecture in 3-D alginate scaffolds by controlling the freezing regime during fabrication. Biomaterials. 2002;23(20):4087-4094..

An ideal tissue engineered scaffold must have overall constructions, internal structures, surface properties, mechanical properties, and material properties to meet the requirements of host tissue⁴4 Sengers BG, Taylor M, Please CP, Oreffo ROC. Computational modelling of cell spreading and tissue regeneration in porous scaffolds. Biomaterials. 2007;28(10):1926-1940.^,⁵5 Chen M, Zuo B. Summarization of cartilage scaffolds material for tissue engineer. Modern Silk Science and Technology. 2011;26(3):110-113.. Ideally, the porosity of the scaffolds, mean pore size and the pore structure should be appropriate for cell adhesion, proliferation, migration, differentiation and extracellular matrix regeneration. High porosity (generally greater than 90%) and a large pore size (about 100-200 µm) as well as highly interconnected pore structure are necessary for the transport of cells and metabolites⁶6 Freyman TM, Yannas IV, Gibson LJ. Cellular materials as porous scaffolds for tissue engineering. Progress in Materials Science. 2001;46(3-4):273-282.^,⁷7 Geiger M, Friess W. Collagen sponge implants - applications, characteristics and evaluation: part II. Pharmaceutical Technology Europe. 2002;14(4):58-66.. The materials should be biocompatible without inflammation or toxicity in vivo and processed into 3D structure¹1 Teimouri A, Azadi M, Emadi R, Lari J, Chermahini AN. Preparation, characterization, degradation and biocompatibility of different silk fibroin based composite scaffolds prepared by freeze-drying method for tissue engineering application. Polymer Degradation and Stability. 2015;121:18-29.^,⁸8 Yang S, Leong KF, Du Z, Chua CK. The design of scaffolds for use in tissue engineering. Part I. Traditional factors. Tissue Engineering. 2001;7(6):678-689..

Moreover, an ideal wound dressing scaffold should present several specific properties for the intended application, including capacity to absorb wound exudates, maintenance of the moisture, protection from secondary infection, provision of adequate gaseous exchange, provision of thermal insulation, free from particulate or toxic contaminants, mechanical durability, flexibility, and non toxicity⁹9 Purna et . Collagen based dressings-a review. Burns. 2000;26(1):54-62.^,¹⁰10 Haugh MG, Murphy CM, O'Brien FJ. Novel freeze-drying methods to produce a range of collagen-glycosaminoglycan scaffolds with tailored mean pore sizes. Tissue Engineering: Part C: Methods. 2009;16(5):887-894..

Many polymers and biopolymers have been extensively investigated as potential materials for wound covering scaffold production. The use of natural biopolymers such as chitosan, collagen and gelatin in the construction of wound healing devices is quite attractive, mostly because of their biocompatibility, possibility of various chemical modifications, and relatively low cost of production (in many cases directly from renewable sources)¹¹11 Jayakumar R, Prabaharan M, Sudheesh Kumar PT, Nair SV, Tamura H. Biomaterials based on chitin and chitosan in wound dressing applications. Biotechnology Advances. 2011;29(3):322-337.

12 Busilacchi A, Gigante A, Mattioli-Belmonte M, Manzotti S, Muzzarelli RA. Chitosan stabilizes platelet growth factors and modulates stem cell differentiation toward tissue regeneration. Carbohydrate Polymers. 2013;98(1):665-676.

13 Hoyer B, Bernhardt A, Heinemann S, Stachel I, Meyer M, Gelinsky M. Biomimetically mineralized salmon collagen scaffolds for application in bone tissue engineering. Biomacromolecules. 2012;13(4):1059-1066.

14 Renó CO, Lima BFAS, Sousa E, Bertran CA, Motisuke M. Scaffolds of calcium phosphate cement containing chitosan and gelatin. Materials Research. 2013;16(6):1362-1365.^-¹⁵15 Yang C, Fang C. Microporous nano-hydroxyapatite/collagen/phosphatidylserine scaffolds embedding collagen microparticles for controlled drug delivery in bone tissue engineering. Materials Research. 2015;18(5):1077-1081.. Particularly, gelatin and chitosan are non-toxic, biodegradable, and biocompatible¹⁴14 Renó CO, Lima BFAS, Sousa E, Bertran CA, Motisuke M. Scaffolds of calcium phosphate cement containing chitosan and gelatin. Materials Research. 2013;16(6):1362-1365.. This biopolymer has the capacity to form thermoreversible gel. Gelatin gel formation, at a molecular level, implicate a structural re-arrangement of the protein, involving the change from a messy stage to a more ordered one, formed by triple helix structures. The knowledge of the gel forming suspensions rheological properties by stationary and dynamic tests, is important for the design and processing of freezing gels.

Among several approach to produce biopolymers-based scaffolds, the freeze-drying processing is interesting because do not demand special equipment. With this processing, material pore characteristics such as size, homogeneity and orientation are dependent on ice crystal nucleation and growth, and can be controlled by modulating the freezing process⁹9 Purna et . Collagen based dressings-a review. Burns. 2000;26(1):54-62.

10 Haugh MG, Murphy CM, O'Brien FJ. Novel freeze-drying methods to produce a range of collagen-glycosaminoglycan scaffolds with tailored mean pore sizes. Tissue Engineering: Part C: Methods. 2009;16(5):887-894.^-¹¹11 Jayakumar R, Prabaharan M, Sudheesh Kumar PT, Nair SV, Tamura H. Biomaterials based on chitin and chitosan in wound dressing applications. Biotechnology Advances. 2011;29(3):322-337.. While pore size is largely governed by freezing temperature, pore homogeneity is achieved by controlling freezing rate and providing a uniform contact surface¹⁰10 Haugh MG, Murphy CM, O'Brien FJ. Novel freeze-drying methods to produce a range of collagen-glycosaminoglycan scaffolds with tailored mean pore sizes. Tissue Engineering: Part C: Methods. 2009;16(5):887-894.^,¹¹11 Jayakumar R, Prabaharan M, Sudheesh Kumar PT, Nair SV, Tamura H. Biomaterials based on chitin and chitosan in wound dressing applications. Biotechnology Advances. 2011;29(3):322-337..

In these contexts, aiming to develop a low cost scaffold, we are trying to develop a material based on blends of gelatin and chitosan by freeze-drying processing. We hypothesized that these biopolymers can have opposite charge depending of pH and this will contribute to a better material. Moreover, they can be modified and/or crosslinked by using a reactant as the glutaraldehyde. Thus, the objective of this work was focused on the study of the influence of gelatin:chitosan ratio, and on the effect of two freezing processing on scaffold microstructure (pore size range, average pore size). The effect of gelatin and chitosan concentration on the flow behavior and viscoelastic properties of gel forming suspensions was also studied.

2. Materials and methods

2.1. Materials

A pig skin gelatin type-A was used (bloom 260; molecular weight ~5.2x10⁴ Da; moisture content = 9.98 %), supplied by Gelnex South America (Itá Santa Catarina, Brazil). Chitosan (derived from crab shell with minimum deacetylation degree of 85%, MW: 2x10⁵) was purchased from Sigma (St. Louis, MO, USA). Acetic acid (Sigma) and glycerol (Synth) were all chemical reagents of analytical grade.

2.2. Fabrication of Porous Scaffolds.

Blends of gelatin (GE) and chitosan (CH) were prepared by thorough mixing of gelatin (2%) and chitosan (1%) solutions in 0.05 M acetic acid, with GE:CH ratios of 3:7, 5:5, 7:3, 9:1, under stirring with a magnetic bar, at 50°C, for 2 h., then the glycerol (gly) was added in 0,3%, the pH of solutions was adjusted to 5. The solution blends were then poured into a glass petri dish and then: a) freezing in refrigerator at -27°C (for evaluating the effect of the solid concentration), and b) the glass petri was left 2 hours in liquid nitrogen system chamber -190°C, and then was kept in a refrigerator -27°C until the lyophilization (for evaluating the effect of freezing rate it was utilized two temperatures). After that, these products were submitted to the first freeze-drying at -55°C for 18 h. reaching a sponge-like material (Figure 1).

Figure 1
Diagram of the steps of obtaining scaffolds, left (effect of the solid concentration) and right (effect of freezing rate).

To crosslinking the GE:CH, the obtained sponge was placed inside desiccators containing glutaraldehyde (10%) in 200 ml ethanol (90%) during 2 h. Then, the sponge was immersed in NaOH solution (1%) and washed with distilled water twice, and treated with a NaBH₄ (5% w/v) solution to block residual aldehyde groups. After that, the scaffolds were conveniently washed with distilled water and re-submitted to freezing, followed by the second freeze-drying for 18 h. The best composition was selected for further characterization; the effect of freezing rate.

2.3. Rheological measurements

The scaffolds forming solutions were analyzed to determine it rheological and visco-elastic properties. Rheological tests were carried out in a rheometer (AR2000 Advanced Rheometer; TA Instruments, New Castle, DE, USA) using a cone and plate sensor geometry (cone angle 4°, 60 mm diameter). This equipment controlled the temperature with a peltier system. The results were analyzed using the software Rheology Advantage Data Analysis V.5.3.1 (TA Instruments).

2.3.1. Dynamic tests

For the dynamic tests, the extent of the linear viscoelastic region was determined by performing a strain (0-20%) sweep in gel forming solutions both as a gel (5°C) and as a sol (30°C), in all cases at 1 Hz of frequency. Thus, according to the results of these tests, the strain value used for all following dynamic tests was fixed at 4%, within the linear viscoelastic domain. The viscoelastic parameters determined in these trials were the storage or elastic modulus (G') and the loss or viscous modulus (G'')¹⁶16 Moraes ICF, Carvalho RA, Bittante AMQB, Solorza-Feria J, Sobral PJA. Film forming solutions based on gelatin and poly(vinyl alcohol) blends: Thermal and rheological characterizations. Journal of Food Engineering. 2009;95(4):588-596..

2.3.2. Temperature sweep tests

Early, the scaffold forming solutions were heated up to 50°C without a predestined heating rate program, starting the tests when that measurement temperature was attained¹⁶16 Moraes ICF, Carvalho RA, Bittante AMQB, Solorza-Feria J, Sobral PJA. Film forming solutions based on gelatin and poly(vinyl alcohol) blends: Thermal and rheological characterizations. Journal of Food Engineering. 2009;95(4):588-596.. The measures were separated in two parts, first, the sample was cooled down from 50 to 5°C, remaining at this latter temperature for 5 min., and second heating up the sample to 50°C, at heating rate of 2°C/min. G' and G'' values as a function of temperature were used to establish the following parameters: gelling (T_sol-gel) and melting (T_gel-sol) temperatures, calculated as the temperature where G' changed drastically as an inflexion point; and the viscoelastic moduli (G' and G'') of the gel, calculated at 5°C¹⁷17 Gómez-Guillén MC, Ihl M, Bifani V, Silva A, Montero P. Edible films made from tuna-fish gelatin with antioxidant extracts of two different murta ecotypes leaves (Ugni molinae Turcz). Food Hydrocolloids. 2007;21(7):1133-1143..

2.4. Scanning Electron Microscopy

The surface morphology, structural integrity and interconnectivity of the pores in the scaffold were observed using Scanning Electron Microscopy (Hitachi TM 3000, Japan) at a magnification of 100x. The sample was placed on double sided carbon tape in a vacuum chamber prior to measurement. The surface of the samples was scanned at 15 kV, without previous treatment¹⁸18 Jorge MFC, Alexandre EMC, Flaker CHC, Bittante AMQB, Sobral PJA. Biodegradable Films Based on Gelatin and Montmorillonite Produced by Spreading. International Journal of Polymer Science. 2015, ID 806791, 9p.. The pore sizes of the scaffolds were measured using image visualization software (Image J 1.45s, NIH Image, USA). The values were expressed as the mean ± standard error.

2.5. Statistical analysis

Statistical analysis and interpretation of all results was done by using GraphPad Prism version 6.00 for Windows (GraphPad Software, San Diego, California, USA). One way ANOVA with Bonferroni posttest was performed, to obtain the variance between and within all treatments. P-values less than 0.05 denoted statistical significance.

3. Results and discussions

3.1. Scanning temperature in dynamic rheological tests.

Rheology provides information about the polymer flow properties, including the changes in the behaviour of the polymer when it subjected to a stress with variation in temperature. The storage and loss modulus in case of viscoelastic solids is the measure of stored energy, which represents their elastic portion, and the energy dissipated in the form of heat, representing the viscous portion, respectively¹⁹19 Meyers MA, Chawla KK. Mechanical behavior of materials. New York: Cambridge University Press; 1999. 882p..

The preliminary tests allowed to determine the conditions of tests inside the linear viscoelastic domain: frequency = 1 Hz, and strain amplitude = 0-20%. Thus, scanning temperature in dynamic rheological tests was carried out (Figure 2), allowing the determination of both moduli (G'and G''), which had higher values at low than at higher temperatures. Between these two domains, an inflexion was observed in both moduli. These behaviors are typical of physical gels presenting a sol-gel (T_sol-gel) and a gel-sol (T_gel-sol) transition. The result shown, when the systems showed a gel character, it was also observed that the stiffness (elastic character) increased with gelatin concentration in the blend. Similar profiles have been observed by several authors in gelatin based systems¹⁷17 Gómez-Guillén MC, Ihl M, Bifani V, Silva A, Montero P. Edible films made from tuna-fish gelatin with antioxidant extracts of two different murta ecotypes leaves (Ugni molinae Turcz). Food Hydrocolloids. 2007;21(7):1133-1143.^,²⁰20 Van den Bulcke AI, Bogdanov B, De Rooze N, Schacht EH, Cornelissen M, Berghmans H. Structural and rheological properties of methacrylamide modified gelatin hydrogels. Biomacromolecules. 2000;1(1):31-38.^,²¹21 Cho SM, Gu YS, Kim SB. Extracting optimization and physical properties of yellowfin tuna (Thunnus albacares) skin gelatin compared to mammalian gelatins. Food Hydrocolloids. 2005;19(2):221-229.. When the chitosan concentration was increased, the viscoelastic properties of pig gelatin was modified, the maximum G' values were lower than the values for pure gelatin solution, and the thermal transition points also occurred at lower temperatures. A decrease in percentage renaturation of food grade gelatin by incorporation of chitosan has been previously reported²²22 Arvanitoyannis IS. Formation and properties of collagen and gelatin films and coatings. In: Gennadios A, ed. Protein-based Films and Coatings. Boca Raton: CRC Press; 2002. p.275-304..

Figure 2
Storage (G') and loss (G'') moduli of scaffold based on blends of gelatin and chitosan as a function of temperature. (A and C) cooling; (B and D) heating, both at 2°C/min.

The temperatures of the sol-gel and gel-sol transitions, fitted as the temperature where the peak of the curve of the first derivative of G' occurred, were affected by the chitosan concentration. The increase in the chitosan concentration in the blend, as it was noted above, caused an intense reduction (46.4%) in the T_sol-gel, which decreased from around 15.3°C to 8.2°C, whereas the T_gel-sol decreased (24.3%) from around 28.8°C to about 21.8°C (Table 1). These phenomena may well be related with the processes involved in the coil-helix/helix-coil transition. The gelatin triple helix formation (coil-helix transition) is a slow process, which continues almost indefinitely, while the dissociation (helix-coil transition) of the triple helix is an equilibrium process linked with the transition temperature²³23 Fitzsimons SM, Mulvihill DM, Morris ER. Segregative interactions between gelatin and polymerized whey protein. Food Hydrocolloids. 2008;22(3):485-492.. Therefore, this is indicative of a pronounced loss of the gelatin's ability to refold into triple-helix chains in the presence of chitosan. Adding chitosan at the higher proportion led to a substantial increase in the viscous modulus (G'') during cooling.

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Table 1
Transition temperatures T_sol–gel and T_gel–sol of gel forming solutions based on different rate of gelatin and chitosan.

It is interesting to analyze the isoelectric point of the gelatin in terms of molecular interactions with chitosan. The gelatin used in this study is type-A, therefore the isoelectric point should be around pH 8-9, further solutions were adjusted to pH 5, therefore gelatin below its isoelectric point it is positively charged. Also, chitosan is a cationic polysaccharide, where the interactions between gelatin and chitosan are produced by both electrostatic and hydrogen bonding²⁴24 Taravel MN, Domard A. Collagen and its interaction with chitosan. II. Influence of the physicochemical characteristics of collagen. Biomaterials. 1995;16(11):865-871.. The latter occur extensively between the -COOH, -NH2, and -OH groups on the amino acids in the gelatin and the -OH and -NH₂ groups on the chitosan, and are particularly notable at low temperatures. The chitosan structure is formed by units of glucosamine and N-acetyl D-glucosamine linked by β-(1→4) where the deacetylation degree is the percentage of amino groups that remaining free in the chitosan molecule, in fact, a high amount of options is presented to generate electrostatic interactions with pig gelatin which is more polar. Due to the acidic pH of the suspensions, these amine residues of chitosan are protonated (NH₃⁺) and could form electrostatic interactions preferably with acid residues of gelatin (COO- from Glutamine and Aspartic acid), they will also form bridges with polar residues above. However, the amount of formed interactions will depend on the degree of exposure of residues of the protein to interact with the chitosan and that will be determined by the degree of unfolding of the protein, as well as by the relative abundance of acid residues in protein versus polar residues and the stoichiometry of the interaction.

3.2. Effect of biopolymers ratios on morphology

The average thickness of GE:CH scaffold was between 1.4-1.7 mm (Table 2). As pig gelatin being a macromolecules and forms cross-linkage with chitosan molecules through hydrogen bonding and electrostatic interaction, the highest proportion of gelatin it had increased the thickness of scaffold. The porous microstructure of the scaffolds has a remarkable influence on the cell intrusion, proliferation and function, when tissue engineering uses are envisioned¹⁴14 Renó CO, Lima BFAS, Sousa E, Bertran CA, Motisuke M. Scaffolds of calcium phosphate cement containing chitosan and gelatin. Materials Research. 2013;16(6):1362-1365.. Because of that, this structure must be well controlled. Then, the GE:CH ratio was evaluated and optimized through the their intrinsic microstructure and porous size observation. It can be observed in Figure 3 that the chitosan have an important effect on material microstructure allowing the formation of sponge type structure.

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Table 2
Effect of GE:CH ratio on the porous size and porous size range of the scaffolds.

Figure 3
Superficial SEM Images of scaffolds obtained with different GE:CH ratios: 9:1 (A), 7:3 (B), 5:5 (C) and 3:7 (D).

Then, scaffold fabricated with higher proportion of gelatin (GE:CH= 9:1, Figure 3a) have irregular pore structure without a well visible porous networking structure. The pore walls were thicker with very few holes in the pore walls, which may indicate that the interconnectivity of the scaffolds could be poor. This effect could difficult fluid exchange and growing of native tissue. Similar structure was observed for GE:CH= 7:3 (Figure 3b) ratio material. As the chitosan content was increased, a more homogeneous structure can be observed, with some tendency for lower porous size formation. Moreover, these scaffolds visibly presented increased porosity, and with matrix with an interconnected and more homogeneous pore structure (GE:CH=5:5, Figure 3c; GE:CH=3:7, Figure 3d). Very thin walls can be observed for equal proportion of biopolymers, but with less homogeneous porous size distribution (GE:CH= 5:5, Figure 3c). This increasing in homogeneity of porous size allow more hollow space, meaning that more fluid and liquid component could be introduced to the scaffolds.

The porous size was calculated after image treatments allowing calculation of data presented at Table 2, where it can be observed that, in overall, the pore size varied between 132 and 393 µm, for all formulations. The smallest and the largest (P < 0.05) average pore size was 179 µm, for scaffolds produced with GE:CH= 3:7 ratio, and 203 µm, for GE:CH= 7:3, respectively (Table 2). These results suggested that the proportion of GE and CH was directly related to the pore size.

Previous research²⁵25 Doillon CJ, Whyne CF, Brandwein S, Silver FH. Collagen-based wound dressings: Control of the pore structure and morphology. Journal of Biomedical Materials Research. 1986;20(8):1219-1228. reported that the mean pore size of collagen based scaffolds was affected by the viscosity of the material solution. Increasing the chitosan content raises the viscosity of the polymeric solution, reducing the density of the complex solution and leads to an increased porosity²⁶26 O'Brien FJ, Harley BA, Yannas IV, Gibson L. Influence of freezing rate on pore structure in freeze-dried collagen-GAG scaffolds. Biomaterials. 2004;25(6):1077-1086. after freeze-drying. The viscosity of the solution is large (>2%) , which is unfavorable to the water and the molecular chains moving in the solution. Therefore, the number of ice nuclei in the solution with high concentration is smaller and more difficult to grow larger than that of the low concentration one²⁶26 O'Brien FJ, Harley BA, Yannas IV, Gibson L. Influence of freezing rate on pore structure in freeze-dried collagen-GAG scaffolds. Biomaterials. 2004;25(6):1077-1086.. So, the pore size is inversely proportional to the concentration of the scaffolds²⁷27 Alizadeha M, Abbasi F, Khoshfetrat AB, Ghaleh H. Microstructure and characteristic properties of gelatin/chitosan scaffold prepared by a combined freeze-drying/leaching method. Materials Science & Engineering: C. 2013;33(7):3958-3967.. All scaffolds obtained in this work were freeze-dried at the same time and under the same conditions; thus, the difference in the pore structure is associated only with the GE:CH ratios.

Thus, considering these quali-quantitative results of SEM, it could be concluded that GE:CH 5:5 formulation were with good pore size and porosity, which indicated that the sponge scaffold meet the basic requirements as tissue engineering material. However, the structure scaffold can even be improved by altering the conditions of freezing before freeze-drying; the effect of freezing rate is an important factor to be evaluated in terms of its interconnected porous structure.

3.3. Effect of freezing processing on morphology

In these essays, the materials were produced by freeze-drying after freezing at -190ºC (by quenching in liquid nitrogen). Then, these scaffolds were cryofractured for analysis of internal microstructure beside the surface structure. The results of these analyses are presented at Figure 4. These results indicated that freezing processing had an evident effect on the pore size and distribution in these scaffolds, due to the difference in the growth velocity of ice crystals formed during freezing of materials. Scaffolds prepared by quenching samples in liquid nitrogen (-190°C, Figure 4 c,d) exhibited smaller pores with a uniform distribution and with pore walls thinner, whereas the scaffolds frozen at higher temperatures (-27°C, Figure 4 a,b) exhibited a poor porous microstructure with heterogeneous and big size pores. These results agree with those reported by²⁸28 Mao JS, Zhao LG, Yin YJ, Yao KD. Structure and properties of bilayer chitosan-gelatin scaffolds. Biomaterials. 2003;24(6):1067-1074.. After ice crystals sublimation during freeze-drying, the scaffold structure contains pores that correspond to the size and shape of the ice crystals²⁹29 Hu L, Wang CA, Huang Y, Sun C, Lu S, Hu Z. Control of pore channel size during freeze casting of porous YSZ ceramics with unidirectionally aligned channels using different freezing temperatures. Journal of the European Ceramic Society. 2010;30(16):3389-3396..

Figure 4
Surface (left) and cross-section (right) images of scaffolds frozen at -27°C (a, b) and -190°C (c,d) measured by SEM.

Analysis of the images of surface structure allowed calculation of the average pores size: 119.2±38.1 µm, for material frozen at -190°C, and 196.8±36.9, for the specimen frozen at -27°C. Both pore size ranges are within the ideally expected for the transport of cells and metabolites in this kind of material⁶6 Freyman TM, Yannas IV, Gibson LJ. Cellular materials as porous scaffolds for tissue engineering. Progress in Materials Science. 2001;46(3-4):273-282.^,⁷7 Geiger M, Friess W. Collagen sponge implants - applications, characteristics and evaluation: part II. Pharmaceutical Technology Europe. 2002;14(4):58-66., however, the cross-sectional image shows a much more homogeneous structure and arranged in layers to the material obtained after freezing at lower temperature.

It is important to consider how variations in pore architecture affect cell-material interactions. Experimental studies have led to the determination of a characteristic interaction parameter, by careful analysis, it can be shown that two matrices with identical chemistries but differing pore diameters have vastly different abilities to provide for cellular attachment. For example, scaffolds containing pores of 300 mm have a much lower internal surface area than matrices with pore diameters of less than 50 mm and, as such, bind a much lower number of cells in the matrix. Because of the low cellular infiltration, tissue formation in these constructs is slow and in certain cases inhibited due to lack of interactions between cells³⁰30 Yannas IV. Facts and theories of induced organ regeneration. In: Yannas IV, ed. Regenerative Medicine I: Theories, Models and Methods. Berlin: Springer; 2005. p.1-38.. In general, research supports that pores larger than 10 mm (the average cell diameter) will permit cell infiltration³¹31 Agrawal CM, Ray BR. Biodegradable polymeric scaffolds for musculoskeletal tissue engineering. Journal of Biomedical Materials Research. 2001;55(2):141-150.. In terms of successful histogenesis, both pore size and the degree of porosity are tissue and scaffold specific. For example, in vivo osteogenesis occurs in biomaterials of high porosity (>70%) with average pore sizes >300 mm³²32 Karageorgiou V, Kaplan D. Porosity of 3D biomaterial scaffolds and osteogenesis. Biomaterials. 2005;26(27):5474-91.. However, in skin regeneration, successful scaffolds need only to exhibit pore sizes of 20-125 mm³⁰30 Yannas IV. Facts and theories of induced organ regeneration. In: Yannas IV, ed. Regenerative Medicine I: Theories, Models and Methods. Berlin: Springer; 2005. p.1-38.. Therefore, in this study the proposed material according to its porosity and average pore diameter, could be a good candidate for use in tissue regeneration as skin and cartilage.

4. Conclusions

The increase in the chitosan concentration in the blend caused an intense reduction in the T_sol-gel, and T_gel-sol this is indicative of a marked loss of the gelatin's ability to refold into triple-helix chains in the presence of chitosan. Morphology of the pigskin gelatin and chitosan scaffolds prepared by freeze-drying technique and different solid proportion and freezing rate was investigated. The incorporation of chitosan improved the pore structure and size uniformity in superficial area of the scaffolds. The pore sizes becomes smaller and pore walls thinner, while an improved of interconnectivity was observed with declining pre-freezing temperature. It has the porous structure, surface morphology, could be favorable to penetrate nutrients, export metabolic substances and leave new spaces for cells to fill in and produce new intercellular matrix. Finally, the study underscores gelatin-chitosan composite as a potential and promissory scaffold material for skin regeneration.

5. Acknowledgments

The authors would like to thank at the Brazilian National Council for Scientific and Technological Development (CNPq) and TWAS, the academy of sciences for the developing world, for the research grants (190232/2014-5 CNPq/ TWAS-FR: 3240279900). And to the Food´s Laboratory of Sao Paulo University.

6. References

¹
Teimouri A, Azadi M, Emadi R, Lari J, Chermahini AN. Preparation, characterization, degradation and biocompatibility of different silk fibroin based composite scaffolds prepared by freeze-drying method for tissue engineering application. Polymer Degradation and Stability 2015;121:18-29.
²
Chen G, Ushida T, Tateishi T. Scaffold design for tissue engineering. Macromolecular Bioscience 2002;2(2):67-77.
³
Zmora S, Glicklis R, Cohen S. Tailoring the pore architecture in 3-D alginate scaffolds by controlling the freezing regime during fabrication. Biomaterials 2002;23(20):4087-4094.
⁴
Sengers BG, Taylor M, Please CP, Oreffo ROC. Computational modelling of cell spreading and tissue regeneration in porous scaffolds. Biomaterials 2007;28(10):1926-1940.
⁵
Chen M, Zuo B. Summarization of cartilage scaffolds material for tissue engineer. Modern Silk Science and Technology 2011;26(3):110-113.
⁶
Freyman TM, Yannas IV, Gibson LJ. Cellular materials as porous scaffolds for tissue engineering. Progress in Materials Science 2001;46(3-4):273-282.
⁷
Geiger M, Friess W. Collagen sponge implants - applications, characteristics and evaluation: part II. Pharmaceutical Technology Europe 2002;14(4):58-66.
⁸
Yang S, Leong KF, Du Z, Chua CK. The design of scaffolds for use in tissue engineering. Part I. Traditional factors. Tissue Engineering 2001;7(6):678-689.
⁹
Purna et . Collagen based dressings-a review. Burns 2000;26(1):54-62.
¹⁰
Haugh MG, Murphy CM, O'Brien FJ. Novel freeze-drying methods to produce a range of collagen-glycosaminoglycan scaffolds with tailored mean pore sizes. Tissue Engineering: Part C: Methods. 2009;16(5):887-894.
¹¹
Jayakumar R, Prabaharan M, Sudheesh Kumar PT, Nair SV, Tamura H. Biomaterials based on chitin and chitosan in wound dressing applications. Biotechnology Advances 2011;29(3):322-337.
¹²
Busilacchi A, Gigante A, Mattioli-Belmonte M, Manzotti S, Muzzarelli RA. Chitosan stabilizes platelet growth factors and modulates stem cell differentiation toward tissue regeneration. Carbohydrate Polymers. 2013;98(1):665-676.
¹³
Hoyer B, Bernhardt A, Heinemann S, Stachel I, Meyer M, Gelinsky M. Biomimetically mineralized salmon collagen scaffolds for application in bone tissue engineering. Biomacromolecules 2012;13(4):1059-1066.
¹⁴
Renó CO, Lima BFAS, Sousa E, Bertran CA, Motisuke M. Scaffolds of calcium phosphate cement containing chitosan and gelatin. Materials Research 2013;16(6):1362-1365.
¹⁵
Yang C, Fang C. Microporous nano-hydroxyapatite/collagen/phosphatidylserine scaffolds embedding collagen microparticles for controlled drug delivery in bone tissue engineering. Materials Research 2015;18(5):1077-1081.
¹⁶
Moraes ICF, Carvalho RA, Bittante AMQB, Solorza-Feria J, Sobral PJA. Film forming solutions based on gelatin and poly(vinyl alcohol) blends: Thermal and rheological characterizations. Journal of Food Engineering 2009;95(4):588-596.
¹⁷
Gómez-Guillén MC, Ihl M, Bifani V, Silva A, Montero P. Edible films made from tuna-fish gelatin with antioxidant extracts of two different murta ecotypes leaves (Ugni molinae Turcz). Food Hydrocolloids. 2007;21(7):1133-1143.
¹⁸
Jorge MFC, Alexandre EMC, Flaker CHC, Bittante AMQB, Sobral PJA. Biodegradable Films Based on Gelatin and Montmorillonite Produced by Spreading. International Journal of Polymer Science 2015, ID 806791, 9p.
¹⁹
Meyers MA, Chawla KK. Mechanical behavior of materials New York: Cambridge University Press; 1999. 882p.
²⁰
Van den Bulcke AI, Bogdanov B, De Rooze N, Schacht EH, Cornelissen M, Berghmans H. Structural and rheological properties of methacrylamide modified gelatin hydrogels. Biomacromolecules 2000;1(1):31-38.
²¹
Cho SM, Gu YS, Kim SB. Extracting optimization and physical properties of yellowfin tuna (Thunnus albacares) skin gelatin compared to mammalian gelatins. Food Hydrocolloids 2005;19(2):221-229.
²²
Arvanitoyannis IS. Formation and properties of collagen and gelatin films and coatings. In: Gennadios A, ed. Protein-based Films and Coatings Boca Raton: CRC Press; 2002. p.275-304.
²³
Fitzsimons SM, Mulvihill DM, Morris ER. Segregative interactions between gelatin and polymerized whey protein. Food Hydrocolloids 2008;22(3):485-492.
²⁴
Taravel MN, Domard A. Collagen and its interaction with chitosan. II. Influence of the physicochemical characteristics of collagen. Biomaterials 1995;16(11):865-871.
²⁵
Doillon CJ, Whyne CF, Brandwein S, Silver FH. Collagen-based wound dressings: Control of the pore structure and morphology. Journal of Biomedical Materials Research 1986;20(8):1219-1228.
²⁶
O'Brien FJ, Harley BA, Yannas IV, Gibson L. Influence of freezing rate on pore structure in freeze-dried collagen-GAG scaffolds. Biomaterials 2004;25(6):1077-1086.
²⁷
Alizadeha M, Abbasi F, Khoshfetrat AB, Ghaleh H. Microstructure and characteristic properties of gelatin/chitosan scaffold prepared by a combined freeze-drying/leaching method. Materials Science & Engineering: C 2013;33(7):3958-3967.
²⁸
Mao JS, Zhao LG, Yin YJ, Yao KD. Structure and properties of bilayer chitosan-gelatin scaffolds. Biomaterials 2003;24(6):1067-1074.
²⁹
Hu L, Wang CA, Huang Y, Sun C, Lu S, Hu Z. Control of pore channel size during freeze casting of porous YSZ ceramics with unidirectionally aligned channels using different freezing temperatures. Journal of the European Ceramic Society 2010;30(16):3389-3396.
³⁰
Yannas IV. Facts and theories of induced organ regeneration. In: Yannas IV, ed. Regenerative Medicine I: Theories, Models and Methods Berlin: Springer; 2005. p.1-38.
³¹
Agrawal CM, Ray BR. Biodegradable polymeric scaffolds for musculoskeletal tissue engineering. Journal of Biomedical Materials Research 2001;55(2):141-150.
³²
Karageorgiou V, Kaplan D. Porosity of 3D biomaterial scaffolds and osteogenesis. Biomaterials 2005;26(27):5474-91.

Publication Dates

Publication in this collection
04 July 2016
Date of issue
Jul-Aug 2016

History

Received
28 Dec 2015
Reviewed
18 Apr 2016
Accepted
05 June 2016

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.

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Yang C, Fang C. Microporous nano-hydroxyapatite/collagen/phosphatidylserine scaffolds embedding collagen microparticles for controlled drug delivery in bone tissue engineering. Materials Research 2015;18(5):1077-1081.

[16] ¹⁶
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[17] ¹⁷
Gómez-Guillén MC, Ihl M, Bifani V, Silva A, Montero P. Edible films made from tuna-fish gelatin with antioxidant extracts of two different murta ecotypes leaves (Ugni molinae Turcz). Food Hydrocolloids. 2007;21(7):1133-1143.

[18] ¹⁸
Jorge MFC, Alexandre EMC, Flaker CHC, Bittante AMQB, Sobral PJA. Biodegradable Films Based on Gelatin and Montmorillonite Produced by Spreading. International Journal of Polymer Science 2015, ID 806791, 9p.

[19] ¹⁹
Meyers MA, Chawla KK. Mechanical behavior of materials New York: Cambridge University Press; 1999. 882p.

[20] ²⁰
Van den Bulcke AI, Bogdanov B, De Rooze N, Schacht EH, Cornelissen M, Berghmans H. Structural and rheological properties of methacrylamide modified gelatin hydrogels. Biomacromolecules 2000;1(1):31-38.

[21] ²¹
Cho SM, Gu YS, Kim SB. Extracting optimization and physical properties of yellowfin tuna (Thunnus albacares) skin gelatin compared to mammalian gelatins. Food Hydrocolloids 2005;19(2):221-229.

[22] ²²
Arvanitoyannis IS. Formation and properties of collagen and gelatin films and coatings. In: Gennadios A, ed. Protein-based Films and Coatings Boca Raton: CRC Press; 2002. p.275-304.

[23] ²³
Fitzsimons SM, Mulvihill DM, Morris ER. Segregative interactions between gelatin and polymerized whey protein. Food Hydrocolloids 2008;22(3):485-492.

[24] ²⁴
Taravel MN, Domard A. Collagen and its interaction with chitosan. II. Influence of the physicochemical characteristics of collagen. Biomaterials 1995;16(11):865-871.

[25] ²⁵
Doillon CJ, Whyne CF, Brandwein S, Silver FH. Collagen-based wound dressings: Control of the pore structure and morphology. Journal of Biomedical Materials Research 1986;20(8):1219-1228.

[26] ²⁶
O'Brien FJ, Harley BA, Yannas IV, Gibson L. Influence of freezing rate on pore structure in freeze-dried collagen-GAG scaffolds. Biomaterials 2004;25(6):1077-1086.

[27] ²⁷
Alizadeha M, Abbasi F, Khoshfetrat AB, Ghaleh H. Microstructure and characteristic properties of gelatin/chitosan scaffold prepared by a combined freeze-drying/leaching method. Materials Science & Engineering: C 2013;33(7):3958-3967.

[28] ²⁸
Mao JS, Zhao LG, Yin YJ, Yao KD. Structure and properties of bilayer chitosan-gelatin scaffolds. Biomaterials 2003;24(6):1067-1074.

[29] ²⁹
Hu L, Wang CA, Huang Y, Sun C, Lu S, Hu Z. Control of pore channel size during freeze casting of porous YSZ ceramics with unidirectionally aligned channels using different freezing temperatures. Journal of the European Ceramic Society 2010;30(16):3389-3396.

[30] ³⁰
Yannas IV. Facts and theories of induced organ regeneration. In: Yannas IV, ed. Regenerative Medicine I: Theories, Models and Methods Berlin: Springer; 2005. p.1-38.

[31] ³¹
Agrawal CM, Ray BR. Biodegradable polymeric scaffolds for musculoskeletal tissue engineering. Journal of Biomedical Materials Research 2001;55(2):141-150.

[32] ³²
Karageorgiou V, Kaplan D. Porosity of 3D biomaterial scaffolds and osteogenesis. Biomaterials 2005;26(27):5474-91.

GE-CH ratio	T_sol-gel (°C)	T_gel-sol (°C)
10:0	15.3_a ± 0.07	28.8^a ± 0.14
9:1	11.9_b ± 0.04	28.3^a ± 0.09
7:3	9.1_c ± 0.01	25.8^b ± 0.14
5:5	8.8_d ± 0.06	25.4^b ± 0.14
3:7	8.2_e ± 0.06	21.8^c ± 0.21

GE-CH	Pore size (μm)	Pore size range (μm)	Scaffolds Thickness (mm)
3:7	178.5^a ± 69.1	132-311	1.46^a ± 0.03
5:5	198.3^ab ± 47.9	162-296	1.40^a ± 0.02
7:3	202.8^b ± 64.1	163-338	1.70^b ± 0.04
9:1	192.5^ab ± 49.8	160-393	1.66^b ± 0.03

Brasil