key: cord-0987145-co2sq91s authors: Wegrzynowska-Drzymalska, Katarzyna; Grebicka, Patrycja; Mlynarczyk, Dariusz T.; Chelminiak-Dudkiewicz, Dorota; Kaczmarek, Halina; Goslinski, Tomasz; Ziegler-Borowska, Marta title: Crosslinking of Chitosan with Dialdehyde Chitosan as a New Approach for Biomedical Applications date: 2020-08-03 journal: Materials (Basel) DOI: 10.3390/ma13153413 sha: 1b037eb8d4d293d55e9950cf9a225141f320b788 doc_id: 987145 cord_uid: co2sq91s Materials based on natural high molecular compounds are particularly interesting for biomedical applications. It is known that the cross-linking agent used for preparation of biomacromolecule-based materials is as important as used biopolymer. Therefore, natural cross-linkers containing reactive carbonyl groups are of great interest especially for modifying properties of natural polysaccharides. One of the most popular cross-linking agents is glutaraldehyde. Nevertheless, the unreacted particles can be released from the cross-linked material and cause cytotoxic effects. This can be eliminated when using a cross-linker based e.g., on polysaccharides. This article describes quick and efficient synthesis of dialdehyde chitosan (DACS) and its application for the preparation of chitosan films. Materials obtained with different amount of DACS were fully characterized in terms of structure and surface morphology. Thermal and mechanical properties as well as hydrophilic character were also examined. The results obtained were compared with the materials obtained by cross-linking chitosan with low molecular weight glutaraldehyde and high molecular weight cross-linking agent based on polysaccharide–dialdehyde starch. Toxicity of all obtained materials was tested using the Microtox(®) test. It has been shown that due to better mechanical, thermal and surface properties as well as lower toxicity, dialdehyde chitosan is a very promising crosslinking agent. Recently, a growing interest in low-toxic materials derived from natural sources or waste has been observed in many fields of material science and applications. Attempts are being made to obtain completely new materials or to modify already known components to improve their properties. In recent years, interest in polysaccharides and materials based on these biopolymers has increased significantly [1, 2] . Apart from biocompatibility and biodegradability, polysaccharides are susceptible to chemical modification, which allows their structure and properties to be tailored into the form required for their further use [3, 4] . This approach can be seen in many fields of science and, in particular, in the design and synthesis of materials for medicine, pharmacy, and biological applications [5] [6] [7] . Chitosan, a polysaccharide derived from the partial deacetylation of chitin, is a cationic linear biopolymer [8, 9] . It has been widely considered as one of the safest biomaterials for various biomedical applications [10] [11] [12] . Chitosan-based materials have been studied so far as drug delivery systems [13, 14] , Given the above information, the primary purpose of this work was to obtain chitosan films cross-linked with dialdehyde chitosan, determination of their characteristics, and comparison with materials cross-linked with dialdehyde starch and a small molecule cross-linking agent, which is the commonly used glutaraldehyde. In order to perform the detailed characterization of all received materials, commonly available methods were applied, e.g., scanning electron microscopy (SEM), attenuated total reflection Fourier-transform infrared (ATR-FTIR) spectroscopy, and atomic force microscopy (AFM). Also, the mechanical properties of the obtained films were determined, including their hydrophilic nature using contact angle measurement. The acute toxicity of the prepared chitosan films was preliminarily studied using the Microtox® test. Given the above information, the primary purpose of this work was to obtain chitosan films cross-linked with dialdehyde chitosan, determination of their characteristics, and comparison with materials cross-linked with dialdehyde starch and a small molecule cross-linking agent, which is the commonly used glutaraldehyde. In order to perform the detailed characterization of all received materials, commonly available methods were applied, e.g., scanning electron microscopy (SEM), attenuated total reflection Fourier-transform infrared (ATR-FTIR) spectroscopy, and atomic force microscopy (AFM). Also, the mechanical properties of the obtained films were determined, including their hydrophilic nature using contact angle measurement. The acute toxicity of the prepared chitosan films was preliminarily studied using the Microtox ® test. Chitosan (low molecular weight: MW = 50 kDa, deacetylation degree = 75-85 %, CAS Number 9012- 76-4,) , corn starch, sodium periodate, glutaraldehyde, diiodomethane (pure for analysis), glycerol were obtained from Sigma-Aldrich (St. Louis, MO, USA) and used without further purification. Acetic acid, sodium hydroxide, concentrated hydrochloric acid (35%), acetone, and phosphate buffer saline (PBS, pH = 7.4) were purchased from Avantor Performance Materials, (Gliwice, Poland). All solutions were prepared with deionized water. The synthesis and characterization of dialdehyde starch was described in detail in our previous work [48] . Briefly, corn starch (1.5 g) was dissolved in deionized water (30 mL) . Periodate aqueous solutions of varying concentration (weight ratio of oxidant/corn starch = 0.5, 0.7, 0.9, 1.0, and 1.1) were prepared and then added to the starch suspension under magnetic stirring. The mixture was heated to 40 • C, and stirring was continued in the dark for 3 h. After cooling to room temperature, the appropriate quantity of acetone was poured into the reaction mixture solution to precipitate the product. The white precipitate was collected, washed with deionized water, and dried at room temperature for 24 h. The dialdehyde starch obtained was used as a cross-linking agent for chitosan films. Chitosan (1.0 g) was dissolved in acetic acid solution (C = 1% m/m, 100 mL) and mechanically stirred at room temperature for 2 h. Different amounts of sodium periodate were dissolved in deionized water (weight ratio of oxidant/chitosan = 0.5, 0.7, 0.9, and 1.0) and added to the chitosan solution under magnetic stirring. The mixture was heated to 40 • C, and stirring was continued in the dark for 3 h. After cooling to room temperature, the appropriate quantity of acetone was added. The white precipitate was isolated by filtration and washed three times with deionized water. Finally, DACS was dried at room temperature for 24 h. Chitosan (0.5 g) was dissolved in acetic acid (C = 1% m/m, 50 mL). Then, the 5%, 10%, or 15% (weight percent based on the dry weight of the polysaccharide) of the appropriate cross-linking agent (dialdehyde starch, dialdehyde chitosan, or glutaraldehyde) was added. The blends were mixed for 2 h with magnetic stirring and were poured onto the leveled glass plates to allow the solvent to evaporate. The number of aldehyde groups by acid-base titration of the modified chitosan solutions was determined [49] . The content of the chitosan units containing the dialdehyde groups was calculated from the Equation (1): where: C 1 (mol/L) and V 1 (dm 3 ) are the concentration and volume of NaOH solution, C 2 (mol/L) and V 2 (dm 3 and distilled water (15 mL) were added. Then phenolphthalein solution was added, and the sample was titrated with NaOH solution (0.25 M). The procedure was performed in triplicate for each sample. The ATR-FTIR spectra of chitosan, dialdehyde chitosan, and chitosan cross-linked films were obtained using the Spectrum Two TM spectrophotometer (Perkin Elmer, Waltham, MA, USA) equipped with an ATR accessory with an incorporated diamond crystal. Spectra were recorded from 4000 to 400 cm −1 with the resolution of 4 cm −1 and 32-scans at room temperature. The morphology for CS, DACS, films, and cross-sections of films were observed with the use of the 1430 VP model scanning electron microscope manufactured by LEO Electron Microscopy Ltd, Cambridge, England. The films were first immersed in liquid nitrogen to fracture and to obtain clear cross-sections. All samples for which the surfaces and cross-sections were tested were covered with gold. The contact angle of two liquids, glycerol, and diiodomethane, on the surface of chitosan, dialdehyde chitosan and cross-linked films was measured at constant temperature (24 • C) using a goniometer equipped with the system of drop-shape analysis (DSA produced by KRÜSS GmbH, Hamburg, Germany). Each θ is an average of at least 5 measurements. The surface free energy was calculated by the Owens-Wendt method [50] . Thermogravimetric analysis of chitosan, dialdehyde chitosan, and cross-linked films was performed on a SDT 2960 Simultaneous DSC-TGA thermogravimetric analyzer (TA Instruments, New Castle, DE, USA). The measurements were performed at a 10 • C/min heating rate in the range from 20 • C to 600 • C in the atmosphere of nitrogen. The mechanical properties of films were studied using EZ-Test E2-LX Shimadzu texture analyzer (Shimadzu, Kyoto, Japan). Five samples of each type were cut and tested. The films were placed in the measuring holders and subjected to stretching at the speed of 20 mm/min. The tensile strength and Young's modulus (E) of each film were measured. Morphological appearance of obtained films was evaluated by the atomic force microscopy (AFM) technique, with MultiMode Nanoscope IIIa Veeco Metrology Inc., Santa Barbara, CA, USA. Roughness parameters such as the root mean square (R q ), arithmetic mean (R a ), and R max were calculated for 5 µm × 5 µm scanned area using NanoScope Analysis software, version-1.40, Bruker, Billerica, MA, USA. The swelling ability (SA) was measured by the conventional gravimetric method [51] . The dry sample was weighed and placed in 0.05 M PBS (pH 7.4) at room temperature. After the appropriate incubation time, the films were removed from PBS, placed on absorbent paper, and the wet material was weighted. The value was an average of three measurements. The swelling ability was assessed according to the following Equation (2): where W s and W d denote the weights of swollen and dry samples, respectively. Toxicity of prepared materials was evaluated by applying the materials to Microtox ® acute toxicity test, the 81.9% Screening Test, which was performed using Microtox ® M500 equipment (Modern Water, Cambridge, UK) with a slight modification [52, 53] . To evaluate the toxicities of the films precooled diluent (supplied by the producer) was added to the cuvettes containing Aliivibrio fischeri bacteria suspension, which was followed immediately by immersing of the film fragment. The decrease of cell viability was measured with Microtox ® M500 and Microtox Omni software (version-4.2, Modern Water, Londyn, UK) based on the cell bioluminescence at 490 nm [54] . The method of oxidation of chitosan to its dialdehyde derivative was described and discussed in the literature [44] . Usual methods of chitosan oxidation with sodium periodate yield a 49% content of aldehyde groups after a 48 h reaction. Only Keshk et al. reported that the reaction of chitosan with potassium periodate within 48 h led to the oxidized polysaccharide with 58.8% content of aldehyde groups [45] . In this work, we decided to elaborate our previously reported method for the oxidation of starch for dialdehyde chitosan synthesis [4, 48] . In this method, reaction time was only 3 h. After determining the number of aldehyde groups in the sugar unit for dialdehyde chitosan, the ratio of reagents 1:1 was chosen ( Table 1 ). As shown in Table 1 these conditions allowed obtaining chitosan with the highest content of aldehyde groups-58%. The applied method compared to previous work describing DACS synthesis by Keshl et al. leads to oxidized chitosan with the same oxidation degree after a 16-fold reduction of reaction time [45] . The scheme for the synthesis of dialdehyde chitosan is presented in Figure 2 . It should be pointed out that the reaction procedure and the work up are not demanding, as the dialdehyde product is precipitating from the reaction mixture after the addition of acetone. The adapted reaction is a one-step oxidation with sodium periodate as an oxidation agent. The mechanism for periodate oxidation of chitosan was already reported by Keshk et al. (Figure 3 ) [45] . It factors in the ammonia formed during the reaction, which was detected and quantified. As a result of this reaction, dialdehyde chitosan is obtained in the form of a light beige amorphous powder, which is soluble in water. The adapted reaction is a one-step oxidation with sodium periodate as an oxidation agent. The mechanism for periodate oxidation of chitosan was already reported by Keshk et al. (Figure 3 ) [45] . It factors in the ammonia formed during the reaction, which was detected and quantified. As a result of this reaction, dialdehyde chitosan is obtained in the form of a light beige amorphous powder, which is soluble in water. The adapted reaction is a one-step oxidation with sodium periodate as an oxidation agent. The mechanism for periodate oxidation of chitosan was already reported by Keshk et al. (Figure 3 ) [45] . It factors in the ammonia formed during the reaction, which was detected and quantified. As a result of this reaction, dialdehyde chitosan is obtained in the form of a light beige amorphous powder, which is soluble in water. In order to define the structure, morphology and thermal stability of prepared dialdehyde chitosan, standard techniques were applied: infrared spectroscopy, microscopic analysis, contact angle measurements, thermal analysis, and X-ray diffraction (XRD). In the spectrum of unmodified chitosan, the characteristic absorption bands at 3355, 3289 cm −1 (attributed to O-H and N-H stretching vibrations), 2869 cm −1 (CH stretching), 1651cm −1 (C=O stretching of amide I), 1550 cm −1 (N-H bending of amide II), 1151 cm −1 (C-O-C stretching), and 1062, 1027 cm −1 (C-O stretching) were observed (Figure 4a ). The obtained spectrum is consistent with the literature data [55, 56] . After oxidation, a new band at 1722 cm −1 representing the carbonyl stretching vibrations appeared ( Figure 4b ). Additionally, a newly formed sharp band at 1630 cm −1 derived from carbonyl group confirmed oxidation of chitosan. The changes in the shape and intensity of the hydroxyl band (3355 cm −1 ) can be explained by the opening of cyclic structure and oxidation of chitosan saccharide units. Moreover, the intensity of absorption bands in DACS, attributed to pyranose rings, decrease significantly. Considerable changes were also observed in the vibration range of the C-O-C groups (1300-1400 cm −1 ), which proves the effective modification of glucoside rings caused by their opening and oxidation in positions C2 and C3. Materials 2020, 13, x FOR PEER REVIEW 7 of 28 In order to define the structure, morphology and thermal stability of prepared dialdehyde chitosan, standard techniques were applied: infrared spectroscopy, microscopic analysis, contact angle measurements, thermal analysis, and X-ray diffraction (XRD). In the spectrum of unmodified chitosan, the characteristic absorption bands at 3355, 3289 cm −1 (attributed to O-H and N-H stretching vibrations), 2869 cm −1 (CH stretching), 1651cm −1 (C=O stretching of amide I), 1550 cm −1 (N-H bending of amide II), 1151 cm −1 (C-O-C stretching), and 1062, 1027 cm −1 (C-O stretching) were observed (Figure 4a ). The obtained spectrum is consistent with the literature data [55, 56] . After oxidation, a new band at 1722 cm −1 representing the carbonyl stretching vibrations appeared ( Figure 4b ). Additionally, a newly formed sharp band at 1630 cm −1 derived from carbonyl group confirmed oxidation of chitosan. The changes in the shape and intensity of the hydroxyl band (3355 cm −1 ) can be explained by the opening of cyclic structure and oxidation of chitosan saccharide units. Moreover, the intensity of absorption bands in DACS, attributed to pyranose rings, decrease significantly. Considerable changes were also observed in the vibration range of the C-O-C groups (1300-1400 cm −1 ), which proves the effective modification of glucoside rings caused by their opening and oxidation in positions C2 and C3. The morphology of unmodified CS and DACS was studied using scanning electron microscopy ( Figure 5 ). The SEM images of native chitosan powder exhibited loosely bound grains with irregular and rough surfaces with the size ranging from 100 to 350 μm [57] . After oxidation, the irregular grains of chitosan disappeared and were transformed into rugged shapes with lots of needle forms. The length of the needle forms was less than 100 μm, and the average size of coarse shapes was between 300-400 μm. The morphology of unmodified CS and DACS was studied using scanning electron microscopy ( Figure 5 ). The SEM images of native chitosan powder exhibited loosely bound grains with irregular and rough surfaces with the size ranging from 100 to 350 µm [57] . After oxidation, the irregular grains of chitosan disappeared and were transformed into rugged shapes with lots of needle forms. The length of the needle forms was less than 100 µm, and the average size of coarse shapes was between 300-400 µm. The results of contact angle measurements obtained for the chitosan and dialdehyde chitosan films are presented in Table 2 . As can be seen, the contact angle for chitosan with the polar liquid (glycerin) is higher than for the non-polar diiodomethane. This means that both samples are less wetted by the polar glycerin. It is confirmed by higher (γ s d ) than the polar component (γ s p ). Therefore, the results confirm the hydrophobic nature of the sample, which are comparable with literature reports [58] . Over two-times higher value of polar component indicate a greater polarity of DACS when compared to the native polysaccharide. This may be because the aldehyde groups in the structure of the oxidized chitosan align towards the surface of the polymer film, and therefore, dialdehyde chitosan is more hydrophilic than unmodified chitosan. Similar conclusions were reported in the literature for oxidized cellulose [59] . This is especially beneficial for biomedical applications of this material and may result in its easier penetration of biological membranes and better solubility in body fluids. Materials 2020, 13, x FOR PEER REVIEW 8 of 28 Figure 5 . Scanning electron microscopy (SEM) pictures of (a,b) chitosan, and (c,d) dialdehyde chitosan powder. The results of contact angle measurements obtained for the chitosan and dialdehyde chitosan films are presented in Table 2 . As can be seen, the contact angle for chitosan with the polar liquid (glycerin) is higher than for the non-polar diiodomethane. This means that both samples are less wetted by the polar glycerin. It is confirmed by higher (γs d ) than the polar component (γs p ). Therefore, the results confirm the hydrophobic nature of the sample, which are comparable with literature reports [58] . Over two-times higher value of polar component indicate a greater polarity of DACS when compared to the native polysaccharide. This may be because the aldehyde groups in the structure of the oxidized chitosan align towards the surface of the polymer film, and therefore, dialdehyde chitosan is more hydrophilic than unmodified chitosan. Similar conclusions were reported in the literature for oxidized cellulose [59] . This is especially beneficial for biomedical applications of this material and may result in its easier penetration of biological membranes and better solubility in body fluids. To determine the thermal properties of dialdehyde chitosan, a TGA-DTG (thermogravimetric analysis-difference thermogravimetry) analysis was performed. Thermograms for chitosan and dialdehyde chitosan are shown in Figure 6 . For unmodified chitosan, the first step of degradation is observed between 20 and 120 • C, with a 7% mass loss assigned to the evaporation of the adsorbed water. The main decomposition stage is observed between 220 and 530 • C and is associated with the 62% mass loss corresponding to the thermal degradation of the chitosan polymer chain. The TG curve of DACS also shows two degradation stages, which are consistent with the literature data [60] . These Materials 2020, 13, 3413 9 of 27 steps can be attributed to the same degradation processes as for pure chitosan. The temperature at the maximum decomposition rate T max = 281 • C in dialdehyde chitosan is slightly lower than for unmodified chitosan (T max = 295 • C. This may be due to the fact that in the structure of chitosan dialdehyde, the pyranose rings have already been opened by the oxidation reaction. To determine the thermal properties of dialdehyde chitosan, a TGA-DTG (thermogravimetric analysis-difference thermogravimetry) analysis was performed. Thermograms for chitosan and dialdehyde chitosan are shown in Figure 6 . For unmodified chitosan, the first step of degradation is observed between 20 and 120 °C, with a 7% mass loss assigned to the evaporation of the adsorbed water. The main decomposition stage is observed between 220 and 530 °C and is associated with the 62% mass loss corresponding to the thermal degradation of the chitosan polymer chain. The TG curve of DACS also shows two degradation stages, which are consistent with the literature data [60] . These steps can be attributed to the same degradation processes as for pure chitosan. The temperature at the maximum decomposition rate Tmax= 281 °C in dialdehyde chitosan is slightly lower than for unmodified chitosan (Tmax =295 °C. This may be due to the fact that in the structure of chitosan dialdehyde, the pyranose rings have already been opened by the oxidation reaction. The XRD patterns of chitosan and dialdehyde chitosan are shown in Figure 7 . Chitosan is a semicrystalline polysaccharide with two main crystalline peaks at 2θ = 10.3 and 20.1°, which corresponds well with the literature reports [61, 62] . In literature, Miller indices (hkl) of diffraction peaks were (0 2 0) and (1 1 0), respectively [63] . Signals in this X-ray diffraction pattern are assigned to crystalline form I and II, respectively. This is as a result of two inter-and intramolecular H-bonding among the functional groups present on the saccharide units. However, the observed signals are very wide, with a high broad halo indicating a relatively low degree of macromolecular ordering, which is typical for natural polysaccharides. The disappearance of the signal at 2θ about 20° in the XRD pattern of DACS proves the complete disappearance of the crystalline phase characteristic for chitosan [44] . Many narrow intensive signals proving the presence of a crystalline product were observed in the DACS diffractogram. It should be added that despite careful, repeated washing of the reaction product (DAS), it is not possible to completely remove the excess NaIO4 oxidant and probably its reduced product (NaIO3), which tends to complexation of polysaccharide molecules. A similar situation was noted in the case of dialdehyde starch obtained by the sodium periodate oxidation reaction. It is expected that, when sodium periodate is used as an oxidizer to polysaccharides, a stable iodate The XRD patterns of chitosan and dialdehyde chitosan are shown in Figure 7 . Chitosan is a semi-crystalline polysaccharide with two main crystalline peaks at 2θ = 10.3 and 20.1 • , which corresponds well with the literature reports [61, 62] . In literature, Miller indices (hkl) of diffraction peaks were (0 2 0) and (1 1 0), respectively [63] . Signals in this X-ray diffraction pattern are assigned to crystalline form I and II, respectively. This is as a result of two inter-and intramolecular H-bonding among the functional groups present on the saccharide units. However, the observed signals are very wide, with a high broad halo indicating a relatively low degree of macromolecular ordering, which is typical for natural polysaccharides. The disappearance of the signal at 2θ about 20 • in the XRD pattern of DACS proves the complete disappearance of the crystalline phase characteristic for chitosan [44] . Many narrow intensive signals proving the presence of a crystalline product were observed in the DACS diffractogram. It should be added that despite careful, repeated washing of the reaction product (DAS), it is not possible to completely remove the excess NaIO 4 oxidant and probably its reduced product (NaIO 3 ), which tends to complexation of polysaccharide molecules. A similar situation was noted in the case of dialdehyde starch obtained by the sodium periodate oxidation reaction. It is expected that, when sodium periodate is used as an oxidizer to polysaccharides, a stable iodate complex is formed with the dialdehyde product [48] . Strong interactions between the dialdehyde chitosan and the oxidant (IO 3 − ) result in the formation of the complex and are present as signals in the diffractogram. Materials 2020, 13, x FOR PEER REVIEW 10 of 28 complex is formed with the dialdehyde product [48] . Strong interactions between the dialdehyde chitosan and the oxidant (IO3 − ) result in the formation of the complex and are present as signals in the diffractogram. As previously stated, the main purpose of this work was to obtain new materials based on chitosan cross-linked with a dialdehyde derivative of this polysaccharide. Due to the fact that chitosan materials are widely described and very widely studied, in particular in medical sciences, the obtained films were compared with materials cross-linked with glutaraldehyde and dialdehyde starch. In order to prepare film samples, the cross-linking agent was used in three different amounts based on the weight of chitosan 5, 10, and 15% of the total. Obtained materials were characterized in order to define the structure, morphology, thermal stability, mechanical properties, degree of swell, and toxicity. All of the tested properties affect the utility of the materials in biomedical applications. It is expected that the best material for these functions will have adequate hydrophilicity, strength, and porosity, which will allow free transfer in body fluids, interaction with biological membranes, and free growth of cells on the material surface. Due to their intended use, it is also essential that the materials are not toxic. The analysis of the shape and position of characteristic bands supplied information about molecular structures and conformational changes that follow the cross-linking process. The ATR-FTIR spectra of cross-linked chitosan materials are presented in Figure 8 , and the data are collected in Table 3 . As previously stated, the main purpose of this work was to obtain new materials based on chitosan cross-linked with a dialdehyde derivative of this polysaccharide. Due to the fact that chitosan materials are widely described and very widely studied, in particular in medical sciences, the obtained films were compared with materials cross-linked with glutaraldehyde and dialdehyde starch. In order to prepare film samples, the cross-linking agent was used in three different amounts based on the weight of chitosan 5%, 10%, and 15% of the total. Obtained materials were characterized in order to define the structure, morphology, thermal stability, mechanical properties, degree of swell, and toxicity. All of the tested properties affect the utility of the materials in biomedical applications. It is expected that the best material for these functions will have adequate hydrophilicity, strength, and porosity, which will allow free transfer in body fluids, interaction with biological membranes, and free growth of cells on the material surface. Due to their intended use, it is also essential that the materials are not toxic. The analysis of the shape and position of characteristic bands supplied information about molecular structures and conformational changes that follow the cross-linking process. The ATR-FTIR spectra of cross-linked chitosan materials are presented in Figure 8 , and the data are collected in Table 3 . After chitosan cross-linking with DAS, DACS, or Glu, some changes in the position and shape of the bands were observed in all spectra. Cross-linking of chitosan with dialdehyde compounds, After chitosan cross-linking with DAS, DACS, or Glu, some changes in the position and shape of the bands were observed in all spectra. Cross-linking of chitosan with dialdehyde compounds, regardless of the cross-linking agent's molecular weight, occurs by forming an imine bond (Schiff base formation) between the cross-linker carbonyl group and the amino group of the chitosan. In all samples, the band at 1636 cm −1 , a characteristic absorption peak of imine groups, confirmed this reaction [64] . Moreover, in chitosan films cross-linked with macromolecular cross-linkers, DAS, and DACS, a new band near 770 cm −1 is observed. It may be assigned to the =C-H bond (aldehyde group of cross-linker not linked to chitosan) deformation stretching vibrations. To summarize, in all of the ATR-FTIR spectra of prepared materials, regardless of the cross-linking agent and its ratio, there is explicit confirmation that the chemical cross-linking reaction with the dialdehyde agent was successful. Scanning electron microscopy was applied to determine the surface morphology of prepared samples. Moreover, for better material characteristics of the obtained films, a cross-section was also taken (Figures 9 and 10) . The SEM images of all of the prepared samples are presented in Supplementary Materials ( Figures S1 and S2) . Almost in all cases, regardless of the cross-linking agent and the quantity used, a flat and smooth film surface can be observed. This indicates that prepared chitosan films are homogeneous. Films cross-linked with 10%, and 15% of dialdehyde starch are exceptions ( Figure S1c,d) . The surfaces of these films are significantly more folded and contain numerous nodules compared with the surface of pure chitosan and films with a different cross-linker and DAS in the amount of 5% by mass. The aggregates may be larger to the gel formation caused by the higher cross-linker content, resulting in a more significant surface heterogeneity. The analysis of a cross-section of all of the prepared cross-linked chitosan materials indicated that the films are also homogeneous in bulk. This confirmed that the process occurs in the whole material volume for all cross-linkers. Also, based on the selection of materials, which are cross-linked with 10% and 15% addition of dialdehyde starch, it is known that the heterogeneity applies only to the surface, whereas the material is homogeneous deeper under the surface. base formation) between the cross-linker carbonyl group and the amino group of the chitosan. In all samples, the band at 1636 cm −1 , a characteristic absorption peak of imine groups, confirmed this reaction [64] . Moreover, in chitosan films cross-linked with macromolecular cross-linkers, DAS, and DACS, a new band near 770 cm −1 is observed. It may be assigned to the =C-H bond (aldehyde group of cross-linker not linked to chitosan) deformation stretching vibrations. Table 3 . The position of main bands (cm -1 ) in ATR-FTIR spectra of CS, CS-DACS, CS-DAS, and CS-Glu films. CS 3342 3278 2877 1636 1578 1381 1064 -CS-DACS 3335 3228 2876 1636 1552 1380 1062 776 CS-DAS 3345 3284 2867 1637 1564 1379 1071 772 CS-Glu 3346 3284 2868 1636 1565 1379 1067 - To summarize, in all of the ATR-FTIR spectra of prepared materials, regardless of the crosslinking agent and its ratio, there is explicit confirmation that the chemical cross-linking reaction with the dialdehyde agent was successful. Scanning electron microscopy was applied to determine the surface morphology of prepared samples. Moreover, for better material characteristics of the obtained films, a cross-section was also taken (Figures 9 and 10) . The SEM images of all of the prepared samples are presented in Supplementary Materials (Figures S1 and S2) . Almost in all cases, regardless of the cross-linking agent and the quantity used, a flat and smooth film surface can be observed. This indicates that prepared chitosan films are homogeneous. Films crosslinked with 10%, and 15% of dialdehyde starch are exceptions ( Figure S1c,d) . The surfaces of these films are significantly more folded and contain numerous nodules compared with the surface of pure chitosan and films with a different cross-linker and DAS in the amount of 5% by mass. The aggregates may be larger to the gel formation caused by the higher cross-linker content, resulting in a more significant surface heterogeneity. The analysis of a cross-section of all of the prepared cross-linked chitosan materials indicated that the films are also homogeneous in bulk. This confirmed that the process occurs in the whole material volume for all cross-linkers. Also, based on the selection of materials, which are cross-linked with 10% and 15% addition of dialdehyde starch, it is known that the heterogeneity applies only to the surface, whereas the material is homogeneous deeper under the surface. The surface roughness is of great importance in later material applications. The topography of the surface of the prepared sample was evaluated by atomic force microscopy. One of the primary advantages of rough materials for biomedical applications is the ability to increase the proliferation of connective tissue cells on their surface. Therefore, for applications, such as regenerative medicine The surface roughness is of great importance in later material applications. The topography of the surface of the prepared sample was evaluated by atomic force microscopy. One of the primary advantages of rough materials for biomedical applications is the ability to increase the proliferation of connective tissue cells on their surface. Therefore, for applications, such as regenerative medicine or tissue engineering, material roughness is a particularly desired feature. The images in 3D and 2D scales are presented in Figures 11-13 . As can be seen, the surface morphology of chitosan films without cross-linking is significantly different from cross-linked materials. For pure chitosan, a relatively smooth morphology was observed, which is mainly related to the physical properties of the chitosan such as high intrinsic chain stiffness [65] . The surface of chitosan films cross-linked with dialdehyde polysaccharides is rather rough; however, for CS-Glu, a significant decrease in roughness is observed (Table 4 ). As can be seen from the data in Table 4 , the material with the highest roughness is chitosan cross-linked with 15% addition of dialdehyde starch. The R max value for this sample is more than twice higher than for pure chitosan. A promising material due to surface roughness is also chitosan cross-linked with 5 and 10% addition of dialdehyde chitosan with R max values of 132 and 119, respectively. The roughness results obtained confirmed the observations from SEM. Materials 2020, 13, x FOR PEER REVIEW 14 of 28 or tissue engineering, material roughness is a particularly desired feature. The images in 3D and 2D scales are presented in Figures 11-13 . As can be seen, the surface morphology of chitosan films without cross-linking is significantly different from cross-linked materials. For pure chitosan, a relatively smooth morphology was observed, which is mainly related to the physical properties of the chitosan such as high intrinsic chain stiffness [65] . The surface of chitosan films cross-linked with dialdehyde polysaccharides is rather rough; however, for CS-Glu, a significant decrease in roughness is observed (Table 4 ). As can be seen from the data in Table 4 , the material with the highest roughness is chitosan crosslinked with 15% addition of dialdehyde starch. The Rmax value for this sample is more than twice higher than for pure chitosan. A promising material due to surface roughness is also chitosan crosslinked with 5 and 10% addition of dialdehyde chitosan with Rmax values of 132 and 119, respectively. The roughness results obtained confirmed the observations from SEM. In order to assess the hydrophilic-hydrophobic nature of the obtained materials, measurements of contact angles using glycerin (polar) and diiodomethane (non-polar) were performed. The results of these measurements, as well as the calculated value of surface free energy, the polar and dispersive components, are presented in Table 5 . In order to assess the hydrophilic-hydrophobic nature of the obtained materials, measurements of contact angles using glycerin (polar) and diiodomethane (non-polar) were performed. The results of these measurements, as well as the calculated value of surface free energy, the polar and dispersive components, are presented in Table 5 . All the values of glycerin average contact angle were less than 90°, which proves that the materials are rather hydrophilic. Moreover, it is worth noting that all of the cross-linked material surfaces are characterized by better wettability by glycerol than non cross-linked chitosan (Table 5) . Pure chitosan has a free surface energy of about 30.70 mJ/m 2 [66] . As shown in Table 5 , the values of polar and dispersive components of surface free energy depend on the type of used cross-linker. Chitosan films cross-linked by DAS and DACS were characterized by slightly lower values of surface free energy than the pure chitosan. However, after comparing the surface energy components, it is seen that the share of the polar component is much higher than in the case of pure chitosan and increases with the addition of a cross-linking agent. A comparison of the value of this component and glycerin contact angle shows that cross-linked chitosan films are more polar than pure chitosan and their hydrophilicity increases with the increasing cross-linking agent ratio. All the values of glycerin average contact angle were less than 90 • , which proves that the materials are rather hydrophilic. Moreover, it is worth noting that all of the cross-linked material surfaces are characterized by better wettability by glycerol than non cross-linked chitosan (Table 5) . Pure chitosan has a free surface energy of about 30.70 mJ/m 2 [66] . As shown in Table 5 , the values of polar and dispersive components of surface free energy depend on the type of used cross-linker. Chitosan films cross-linked by DAS and DACS were characterized by slightly lower values of surface free energy than the pure chitosan. However, after comparing the surface energy components, it is seen that the share of the polar component is much higher than in the case of pure chitosan and increases with the addition of a cross-linking agent. A comparison of the value of this component and glycerin contact angle shows that cross-linked chitosan films are more polar than pure chitosan and their hydrophilicity increases with the increasing cross-linking agent ratio. The results obtained for films cross-linked with 10% and 15% of glutaraldehyde are surprising. Both the value of glycerin contact angle and the polar free surface energy component indicate the highest hydrophilic nature of these materials. This is probably related to the fact that it has a low molecular weight compared to polysaccharide cross-linking agents. For molecules with a lower mass, the proportion of the hydrophobic fragment of the structure is smaller. Also, they can more easily "accumulate" at the surface of the material, resulting in increased interaction of functional groups with the solvent. Based on the results obtained, it can be concluded that all the obtained materials meet the expectations for potential biomedical applications. The values of contact angle and surface free energy polar component allow stating that these materials are promising for such applications. For a better characterization of the materials, thermal analysis of the obtained films was performed. The results of the thermogravimetric analysis of chitosan and chitosan cross-linked films are presented in Figure 14 and Table 6 . As can be seen on the thermogravimetric curves and based on the data collected in Table 6 , pure chitosan film exhibits two thermal degradation stages [67] [68] [69] . The first stage (between 29 • C and 140 • C) is characterized by approximately 8% loss of the initial weight, and is related to the evaporation of water. The intensive decomposition of chitosan takes place in the second stage, in the temperature range of 180-420 • C, with 51% weight loss. This probably results from the detachment of side hydroxyl groups, main chain scission, and pyranose ring-opening reactions. In thermograms of chitosan films cross-linked with DACS and DAS three degradation steps were observed. The exception is the sample CS-5% DACS, where only two stages of decomposition can be found, similar to pure chitosan film. It is probably the result of the similarity of polymer chain structures of chitosan and cross-linker. For materials cross-linked with low molecular weight glutaraldehyde, two decomposition steps were also observed. The first decomposition stage, for all cross-linked films, ranges between 50 and 120 • C and shows about 9-14% loss in weight, due to the loss of bounded and adsorbed water similar to unmodified polysaccharide. The next step of thermal degradation of all cross-linked materials is the intensive destruction, which takes place in the temperature range between 170 and 350 • C and shows about 50% loss in weight due to the degradation of the chitosan chain. As mentioned, for samples cross-linked with glutaraldehyde, only two degradation stages were observed. These stages can be attributed to the same degradation processes as for pure chitosan film. The degradation of the low molecular weight cross-linker occurs in the first stage at a temperature between 20 and 100 • C. The weight loss corresponding to these temperatures is slightly higher than for other materials. As mentioned, in the case of films cross-linked with dialdehyde polysaccharides, there is an additional stage of decomposition in the temperature range between 120 and 180 • C. The weight loss at this stage is small, at the level of 3-5%, which may indicate that this stage consists in breaking the cross-linking of chitosan films. This step does not appear in the case of material cross-linked with 5% addition of dialdehyde starch. The residue at 600 • C is comparable for all materials. The mechanical properties of polymer materials indicate their strength and applicability in conditions where they are subjected to mechanical forces. Parameters describing these properties for the materials are tensile strength, Young's modulus, and elongation at break which are presented in Figures 15-17 for all of the prepared samples. materials cross-linked with low molecular weight glutaraldehyde shows the opposite trend. This fact is in agreement with the literature data, where the increase of the glutaraldehyde corresponds to the decrease of this parameter up to the value almost two times lower than observed for non-cross-linked chitosan films [70] . Based on the comparison of stress at the break of the prepared materials, it can be concluded that the creation of a new cross-linking network between chitosan and dialdehyde polysaccharides leads to the improvement of mechanical properties [41, 71] . Young's modulus value for pure chitosan film is about 75 MPa, and it is almost the same as for films of chitosan cross-linked with 5% addition of DACS and Glu. For the sample cross-linked with 5% of DAS, the Young's modulus value is about 125 MPa. In the case of samples cross-linked with glutaraldehyde, no significant changes in the value of the Young modulus are observed with increasing amounts of cross-linking agent. For samples cross-linked with dialdehyde polysaccharides DACS and DAS, along with the increase in the amount of cross-linking agent, an approximately twofold increase in the Young's modulus is observed. The highest value of the Young's modulus is observed for the material cross-linked with a 15% addition of dialdehyde chitosan (3.5 times higher than for pure chitosan). Elongation at break is an important feature for materials in terms of applications. This parameter is a measure of the tensile ability of a film before break. The percentage value of elongation at break was calculated from the elongation in length and the original length of the films. For pure CS sample it was about 3.35%. In the case of materials cross-linked with dialdehyde chitosan, the percent elongation increases with increasing amount of cross-linking agent. The elongation at break of samples cross-linked with low molecular weight glutaraldehyde shows the opposite trend. The smallest value of the elongation at break is observed for the material cross-linked with a 15% addition of glutaraldehyde (2 times smaller than for pure chitosan). Young's modulus value for pure chitosan film is about 75 MPa, and it is almost the same as for films of chitosan cross-linked with 5% addition of DACS and Glu. For the sample cross-linked with 5% of DAS, the Young's modulus value is about 125 MPa. In the case of samples cross-linked with glutaraldehyde, no significant changes in the value of the Young modulus are observed with increasing amounts of cross-linking agent. For samples cross-linked with dialdehyde polysaccharides DACS and DAS, along with the increase in the amount of cross-linking agent, an approximately twofold increase in the Young's modulus is observed. The highest value of the Young's modulus is observed for the material cross-linked with a 15% addition of dialdehyde chitosan (3.5 times higher than for pure chitosan). Elongation at break is an important feature for materials in terms of applications. This parameter is a measure of the tensile ability of a film before break. The percentage value of elongation at break was calculated from the elongation in length and the original length of the films. For pure CS sample it was about 3.35%. In the case of materials cross-linked with dialdehyde chitosan, the percent elongation increases with increasing amount of cross-linking agent. The elongation at break of samples cross-linked with low molecular weight glutaraldehyde shows the opposite trend. The smallest value of the elongation at break is observed for the material cross-linked with a 15% addition of glutaraldehyde (2 times smaller than for pure chitosan). The swelling process depends on the structure of the polymer and the type of solvent. Swelling is essential if we consider the suitability of the material for the preparation of e.g., hydrogels, which The value of tensile strength for CS sample was about 3 MPa. After cross-linking with an addition of 5% of different cross-linkers, the tensile strength value is practically the same as for pure chitosan. However, tensile strength increases with rising rates of cross-linking agents for chitosan films cross-linked with dialdehyde polysaccharides. The most significant difference in this parameter was observed for CS-15%DACS sample, where the tensile strength increased to 9.43 MPa, which is 3.5 times more than for pure chitosan. An almost two-fold increase in strength value in comparison to pure chitosan was also observed for CS-10%DAS and 15%DAS films. The tensile strength of materials cross-linked with low molecular weight glutaraldehyde shows the opposite trend. This fact is in agreement with the literature data, where the increase of the glutaraldehyde corresponds to the decrease of this parameter up to the value almost two times lower than observed for non-cross-linked chitosan films [70] . Based on the comparison of stress at the break of the prepared materials, it can be concluded that the creation of a new cross-linking network between chitosan and dialdehyde polysaccharides leads to the improvement of mechanical properties [41, 71] . Young's modulus value for pure chitosan film is about 75 MPa, and it is almost the same as for films of chitosan cross-linked with 5% addition of DACS and Glu. For the sample cross-linked with 5% of DAS, the Young's modulus value is about 125 MPa. In the case of samples cross-linked with glutaraldehyde, no significant changes in the value of the Young modulus are observed with increasing amounts of cross-linking agent. For samples cross-linked with dialdehyde polysaccharides DACS and DAS, along with the increase in the amount of cross-linking agent, an approximately two-fold increase in the Young's modulus is observed. The highest value of the Young's modulus is observed for the material cross-linked with a 15% addition of dialdehyde chitosan (3.5 times higher than for pure chitosan). Elongation at break is an important feature for materials in terms of applications. This parameter is a measure of the tensile ability of a film before break. The percentage value of elongation at break was calculated from the elongation in length and the original length of the films. For pure CS sample it was about 3.35%. In the case of materials cross-linked with dialdehyde chitosan, the percent elongation increases with increasing amount of cross-linking agent. The elongation at break of samples cross-linked with low molecular weight glutaraldehyde shows the opposite trend. The smallest value of the elongation at break is observed for the material cross-linked with a 15% addition of glutaraldehyde (2 times smaller than for pure chitosan). The swelling process depends on the structure of the polymer and the type of solvent. Swelling is essential if we consider the suitability of the material for the preparation of e.g., hydrogels, which is significant for biomedical applications. Cross-linked polymers swell in a limited way because the solvation energy is not large enough to break the newly formed cross-linking (covalent) bonds between the polymer chains, contrary to unmodified linear chitosan. The wettability promotes swelling of the polymer sample because the interactions between macromolecules and solvent molecules facilitate their diffusion into the interior. Chitosan has various functional groups in the structure and is rather easily wetted by polar solvents [72, 73] , which confirms the value of glycerin contact angle. The swelling behavior of chitosan and chitosan films cross-linked by various cross-linkers measured in PBS (phosphate buffer solution) is shown in Figure 18 . As presented, pure chitosan after the first hour of immersion in PBS has a swelling degree value of 153%. However, this swelling ratio is two times lower than for chitosan films cross-linked with dialdehyde polysaccharides after the same period. The lowest degree of swelling after one hour is observed for materials cross-linked with glutaraldehyde. It can also be seen that as the glutaraldehyde content increases, which is associated with a higher degree of cross-linking, the swelling capacity slightly decreases. Also, it can be seen that for these samples, the degree of swelling decreases with the immersion time. This may further indicate that the samples decompose in the PBS starting from the third immersion hour. DACS and DAS cross-linked films show similar swelling, but the most promising are samples cross-linked with 10% and 15% addition of dialdehyde chitosan-even after 25 h, the samples still show a slight increase in swelling, which means that they did not undergo degradation in the buffer. It is very constructive for medical applications and shows that these materials can be successfully used, for example, for the production of hydrogel bandages. between the polymer chains, contrary to unmodified linear chitosan. The wettability promotes swelling of the polymer sample because the interactions between macromolecules and solvent molecules facilitate their diffusion into the interior. Chitosan has various functional groups in the structure and is rather easily wetted by polar solvents [72, 73] , which confirms the value of glycerin contact angle. The swelling behavior of chitosan and chitosan films cross-linked by various cross-linkers measured in PBS (phosphate buffer solution) is shown in Figure 18 . As presented, pure chitosan after the first hour of immersion in PBS has a swelling degree value of 153%. However, this swelling ratio is two times lower than for chitosan films cross-linked with dialdehyde polysaccharides after the same period. The lowest degree of swelling after one hour is observed for materials cross-linked with glutaraldehyde. It can also be seen that as the glutaraldehyde content increases, which is associated with a higher degree of cross-linking, the swelling capacity slightly decreases. Also, it can be seen that for these samples, the degree of swelling decreases with the immersion time. This may further indicate that the samples decompose in the PBS starting from the third immersion hour. DACS and DAS cross-linked films show similar swelling, but the most promising are samples cross-linked with 10% and 15% addition of dialdehyde chitosan-even after 25 h, the samples still show a slight increase in swelling, which means that they did not undergo degradation in the buffer. It is very constructive for medical applications and shows that these materials can be successfully used, for example, for the production of hydrogel bandages. The Microtox® toxicity test is based on the measurement of the bioluminescence of the Gramnegative A. fischeri bacteria, which is correlated to the bacterial metabolism and cell viability [52] . The The Microtox ® toxicity test is based on the measurement of the bioluminescence of the Gram-negative A. fischeri bacteria, which is correlated to the bacterial metabolism and cell viability [52] . The toxicity of pure chitosan (CS) suspension was also tested. The obtained values of a percentage reduction in the survival of A. fischeri bacteria are shown in Figure 19 . For pure chitosan, the cell viability decrease of A. fischeri cells was equal to 61%. Such high value is most probably caused by the antibacterial activity of this biopolymer [64, 74] , as the material itself is non-toxic [75] . Survival decreases for chitosan films cross-linked by DACS were about 20% lower than for pure chitosan film when DACS was used in 5% or 10% concentration. The decrease of cell viability could be correlated with the increase of the DACS content, as 15% of DACS in the films resulted in 53% cell viability, which was still less toxic than CS. A different relationship was observed for chitosan films cross-linked with DAS. The observed decrease in cell viabilities was not influenced by the concentration of DAS (57%, 58% and 58% cell viability decrease for 5%, 10%, and 15% DAS concentration, respectively). Additionally, it seems that cross-linking with DAS had almost no effect on the toxicity of the chitosan films. However, the use of glutaraldehyde as the cross-linking agent caused a reduction in viability at higher concentrations (24% cell viability for 15% Glu content), which may be related to the toxicity of glutaraldehyde [76] . The Microtox ® 81.9% toxicity test has also recently been used in similar study by Sharma et al. [77] . They researched the cell toxicity of the chitosan-based nanohydrogel nanocomposite, fabricated by facile sol-gel polymerization technique, chitosan-cl-poly(AAc)/ZrPO 4 . The acute toxicity (EC 50 ) values of chitosan-cl-poly(AAc)/ZrPO 4 at 257 and 121 mg/mL towards A. fischeri after 15 and 30 min of incubation indicated that the material obtained is non-toxic and has a biocompatible nature. toxicity of pure chitosan (CS) suspension was also tested. The obtained values of a percentage reduction in the survival of A. fischeri bacteria are shown in Figure 19 . For pure chitosan, the cell viability decrease of A. fischeri cells was equal to 61%. Such high value is most probably caused by the antibacterial activity of this biopolymer [64, 74] , as the material itself is non-toxic [75] . Survival decreases for chitosan films cross-linked by DACS were about 20% lower than for pure chitosan film when DACS was used in 5% or 10% concentration. The decrease of cell viability could be correlated with the increase of the DACS content, as 15% of DACS in the films resulted in 53% cell viability, which was still less toxic than CS. A different relationship was observed for chitosan films cross-linked with DAS. The observed decrease in cell viabilities was not influenced by the concentration of DAS (57%, 58% and 58% cell viability decrease for 5%, 10%, and 15% DAS concentration, respectively). Additionally, it seems that cross-linking with DAS had almost no effect on the toxicity of the chitosan films. However, the use of glutaraldehyde as the cross-linking agent caused a reduction in viability at higher concentrations (24% cell viability for 15% Glu content), which may be related to the toxicity of glutaraldehyde [76] . The Microtox® 81.9% toxicity test has also recently been used in similar study by Sharma et al. [77] . They researched the cell toxicity of the chitosan-based nanohydrogel nanocomposite, fabricated by facile sol-gel polymerization technique, chitosan-cl-poly(AAc)/ZrPO4. The acute toxicity (EC50) values of chitosan-cl-poly(AAc)/ZrPO4 at 257 and 121 mg/mL towards A. fischeri after 15 and 30 min of incubation indicated that the material obtained is non-toxic and has a biocompatible nature. In order to understand the results obtained, it is necessary to analyze them in context of chitosan's antimicrobial activity. The antimicrobial properties of chitosan and its mode of action were broadly reviewed by Kong et al. [78] . Its antimicrobial action is affected by four factors. The first factor is microbial and is related to microorganism and cell age. The second one is intrinsic and is bound to chitosan's positive charge, molecular weight, concentration, and chelating properties, whereas the third one is physical and is related to its water-solubility and solid state. The final factor, the environmental one, involves the ionic strength in medium, pH, temperature, and time of reaction of this biomolecule. Noteworthy, antimicrobial chitosan activities create further possibilities to use this material in various physical forms, e.g., films, fibers, beads, hydrogels in the food, medical and textile industries. Such antimicrobial polymers can be applied as packaging materials, wounddressing materials, edible films and coatings and wrapping materials, as well as in tissue engineering and drug delivery. The antimicrobial activity of chitosan, its derivatives and composites against Gram-positive and Gram-negative bacteria has been demonstrated in many studies [79] [80] [81] [82] . It was Figure 19 . A. fischeri cell viability decreases upon exposition to chitosan-based films. CS-non-crosslinked chitosan, DACS-chitosan films cross-linked with dialdehyde chitosan, DAS-chitosan films cross-linked with diacetyl starch, and Glu-chitosan films cross-linked with glutaraldehyde. The colors represent the content of the cross-linking agent (5%, 10%, 15%) in the film. In order to understand the results obtained, it is necessary to analyze them in context of chitosan's antimicrobial activity. The antimicrobial properties of chitosan and its mode of action were broadly reviewed by Kong et al. [78] . Its antimicrobial action is affected by four factors. The first factor is microbial and is related to microorganism and cell age. The second one is intrinsic and is bound to chitosan's positive charge, molecular weight, concentration, and chelating properties, whereas the third one is physical and is related to its water-solubility and solid state. The final factor, the environmental one, involves the ionic strength in medium, pH, temperature, and time of reaction of this biomolecule. Noteworthy, antimicrobial chitosan activities create further possibilities to use this material in various physical forms, e.g., films, fibers, beads, hydrogels in the food, medical and textile industries. Such antimicrobial polymers can be applied as packaging materials, wound-dressing materials, edible films and coatings and wrapping materials, as well as in tissue engineering and drug delivery. The antimicrobial activity of chitosan, its derivatives and composites against Gram-positive and Gram-negative bacteria has been demonstrated in many studies [79] [80] [81] [82] . It was found that the outer barrier present in Gram-negative bacteria makes these species very susceptible to chitosan [83] [84] [85] . Moreover, it was also noted that chitosan can pass the cell membrane of Gram-negative bacteria, which could further trigger intracellular responses and its interference with DNA and RNA synthesis [86] [87] [88] . The morphology of solid chitosan and its derivatives strongly influence its antimicrobial activity which was presented by Takahashia et al. for the powdered chitosan membranes in their action against Staphylococcus aureus [89] . In addition, differences in antimicrobial action of chitosan hydrogels towards Escherichia coli and S. aureus bacteria were observed depending on the immobilization of this material on the surface of composites [90] . Generally, it was presented in many studies that the chitosan's molecular weight influences biological activity and that chitosan films with higher molecular weights presented no antimicrobial activity [88, 91] . In many studies chitosan as a biopolymer was found to be relatively safe and non-toxic towards mammalian cells. The results obtained are a good introduction for further research of chitosan and its derivatives after the treatment with the natural cross-linking agents, as well as prospective biomedical applications. In summary, dialdehyde chitosan was obtained by one step and a quick reaction with sodium periodate. The content of carbonyl groups was dependent on the amount of oxidant used for the reaction. The oxidation of chitosan to dialdehyde polysaccharide was confirmed with ATR-FTIR, SEM images and XRD analysis. The strong interactions between the dialdehyde chitosan and the residue of oxidant (IO 3 − ) as the complex formation was observed to be similar to starch oxidation by this same method. The ability of the dialdehyde chitosan obtained to chitosan film cross-link was evaluated and compared with chitosan films cross-linked with dialdehyde starch and glutaraldehyde with cross-linker addition of 5%, 10%, and 15 %. All of the prepared chitosan films are homogeneous except materials cross-linked with 10% and 15% of dialdehyde starch. However, all of materials were homogeneous in depth as confirmed on the cross-section. The surface of all materials was rough. The highest roughness was observed for chitosan cross-linked with 15% addition of dialdehyde starch and 5 and 10% addition of dialdehyde chitosan. The R max value for this samples were more than twice higher than for pure chitosan. The values of contact angle and surface free energy polar component for prepared chitosan films allow to state that due to the nature of the surface, chitosan materials cross-linked with dialdehyde chitosan are promising for biomedical applications. Moreover, modification of chitosan films with dialdehyde polysaccharides results in high swelling ability, probably due to the polar nature of DAS and DACS while the samples cross-linked with glutaraldehyde were degraded in the PBS solution. Based on the comparison of stress at the break of the prepared materials, it can be concluded that creation of new cross-linking network between chitosan and dialdehyde chitosan leads to better mechanical properties than for materials cross-linked with glutaraldehyde. Microtox ® toxicity studies of the obtained materials compared to pure chitosan have shown that the lowest toxicity effect is characteristic for materials obtained by cross-linking chitosan with DACS. These results together with good swelling, mechanical and thermal strength results as well as surface morphology make dialdehyde chitosan a very promising material as a cross-linking agent for biomacromolecules in biomedical applications. Natural polysaccharide-based composites for drug delivery and biomedical applications Novel blend for producing porous chitosan-based films suitable for biomedical applications Effect of geometrical structure, drying, and synthetic method on aminated chitosan-coated magnetic nanoparticles utility for HSA effective immobilization Magnetic nanoparticles coated with aminated starch for HSA immobilization-Simple and fast polymer surface functionalization Physicochemical properties and biological activities of novel blend films using oxidized pectin/chitosan Preparation, characterization and feasibility study of dialdehyde carboxymethyl cellulose as a novel cross-linking reagent Functional properties of chitosan films modified by snail mucus extract Antimicrobial chitosan conjugates: Current synthetic strategies and potential applications Borneol-modified chitosan: Antimicrobial adhesion properties and application in skin flora protection Chitin and chitosan: Properties and applications Synthesis, characterization and antimicrobial activity of a novel chitosan schiff bases based on heterocyclic moieties Chitin and chitosan: Properties and applications Preparation, characterization, and potential application of chitosan, chitosan derivatives, and chitosan metal nanoparticles in pharmaceutical drug delivery. Drug Des Effect of cross-linking agents on drug distribution in chitosan hydrogel for targeted drug delivery to treat cancer Preparation and characterization of chitosan physical hydrogels with enhanced mechanical and antibacterial properties Chitosan-based hydrogel wound dressings with electrochemically incorporated silver nanoparticles-In vitro study Chitosan: Application in tissue engineering and skin grafting Chitosan as a potential alternative to collagen for the development of genipin-crosslinked scaffolds Chitosan based scaffolds and their applications in wound healing Glutaraldehyde-crosslinking chitosan scaffolds reinforced with calcium phosphate spray-dried granules for bone tissue applications Mechanism for the inhibition of fat digestion by chitosan and for the synergistic effect of ascorbate Food applications of chitin and chitosans HTCC as a highly effective polymeric inhibitor of SARS-CoV-2 and MERS-CoV Biomedical applications of chitosan and its derivative nanoparticles Chitosanbased hydrogels: From preparation to biomedical applications Synthesis and properties of highly swelling PAAm/ chitosan semi-IPN hydrogels Improving the pervaporation performance of the glutaraldehyde cross-linked chitosan membrane by simultaneously changing its surface and bulk structure The cross-linking of chitosan fibers Effect of cross-linking and blending with poly(vinyl alcohol) on permeability Synthesis and 13 C CP-MAS NMR characterization of a new chitosan-based polymeric network Preparation and characterization of 1,2,4,5-benzenetetra carboxylicchitosan. e-Polymers Novel chitosan-based films cross-linked by genipin with improved physical properties Quinone cross-linked polysaccharide hybrid fiber Chitosan cross-linking with a water-soluble, blocked diisocyanate. 1. solid state Reaction kinetics and gel properties of blocked diisocyinate cross-linked chitosan hydrogels In vitro cytotoxicity and in vivo efficacy of 5-fluorouracilloaded enteric-coated PEG-cross-linked chitosan microspheres in colorectal cancer therapy in rats A novel method for the synthesis of the peg-crosslinked chitosan with a ph-independent swelling behavior Acellular vascular tissues: Natural biomaterials for tissue repair and tissue engineering Biocompatible dialdehyde cellulose/poly(vinyl alcohol) hydrogels with tunable properties 3D printed chitosan dressing cross-linked with genipin for potential healing of chronic wounds Is dialdehyde starch a valuable cross-linking agent for collagen/elastin based materials? N-Succinyl chitosan-dialdehyde starch hybrid hydrogels for biomedical applications Crosslinking effect of dialdehyde starch (DAS) on decellularized porcine aortas for tissue engineering Preparation of dialdehyde chitosan and its application in green synthesis of silver nanoparticles An unexpected reactivity during periodate oxidation of chitosan and the affinity of its 2,3-di-aldehyde toward sulfa drugs Feasibility study of the natural derived chitosan dialdehyde for chemical modification of collagen Design of biostable scaffold based on collagen cross-linked by dialdehyde chitosan with presence of gallic acid Photochemical reactions in dialdehyde starch Preparation and protein immobilization of magnetic dialdehyde starch nanoparticles Estimation of the surface free energy of polymers Collagen/ elastin hydrogels cross-linked by squaric acid Microtox ® acute toxicity test Use of CeO 2 , TiO 2 and Fe 3 O 4 nanoparticles for the removal of lead from water: Toxicity of nanoparticles and derived compounds Bioluminescence of vibrio fischeri: Bacteria respond quickly and sensitively to pulsed microwave electric (but not magnetic) fields pH-responsive chitosan-based film incorporated with alizarin for intelligent packaging applications Novel quaternarized N-halamine chitosan and polyvinyl alcohol nanofibrous membranes as hemostatic materials with excellent antibacterial properties Physiochemical, optical and biological activity of chitosan-chromone derivative for biomedical applications pH responsive N-succinyl chitosan/Poly (acrylamide-coacrylic acid) hydrogels and in vitro release of 5-fluorouracil Introduction of aldehyde groups on surfaces of native cellulose fibers by TEMPO-mediated oxidation Synthesis of chitosan nanoparticles by TPP and their potential mosquito larvicidal application. Front Effect of chitosan membrane surface modification via plasma induced polymerization on the adhesion of osteoblast-like cells Characterization of a dialdehyde chitosan generated by periodate oxidation Synthesis, characterization and antimicrobial activity of maltol functionalized chitosan derivatives Dialdehyde starch-crosslinked chitosan films and their antimicrobial effects X-ray photoelectron spectroscopy and atomic force microscopy studies on cross-linked chitosan thin film The chitosan-Porphyrazine hybrid materials and their photochemical properties Effect of side substituents on thermal stability of the modified chitosan and its nanocomposites with magnetite Volatile compounds formed from the pyrolysis of chitosan Thermal analysis of chitosan and its blends Effect of glutaraldehyde to the mechanical properties of chitosan/nanocellulose Processing and analysis of chitosan nanocomposites reinforced with chitin whiskers and tannic acid as a crosslinker Preparation and characterization of local indonesian chitosan-graft-maleic anhydride as drug carrier Paseiro-Losada, P. Mechanical, structural and physical aspects of chitosan-based films as antimicrobial dressings Chitosan and its antimicrobial potential-A critical literature survey Biodegradation, biodistribution and toxicity of chitosan Effects of glutaraldehyde exposure on human health Facile fabrication of chitosan-clpoly(AA)/ZrPO 4 nanocomposite for remediation of rhodamine B and antimicrobial activity Antimicrobial properties of chitosan and mode of action: A state of the art review Synthesis, characterization, and evaluation of antimicrobial activity of novel chitosan/tigecycline composite Mechanical and antibacterial properties of the chitosan coated cellulose paper for packaging applications: Effects of molecular weight types and concentrations of chitosan Drug-free and non-crosslinked chitosan scaffolds with efficient antibacterial activity against both Gram-negative and Gram-positive bacteria Selective synthesis of N,N,Ntrimethylated chitosan derivatives at different degree of substitution and investigation of structure-activity relationship for activity against P. aeruginosa and MRSA Relationship between antibacterial activity of chitosan and surface characteristics of cell wall Antimicrobial polymers An update on polysaccharide-based nanomaterials for antimicrobial applications Antibacterial action of chitosan and carboxymethylated chitosan Evidence on antimicrobial properties and mode of action of a chitosan obtained from crustacean exoskeletons on Pseudomonas syringae pv. tomato DC3000 V Recent developments in antibacterial and antifungal chitosan and its derivatives Growth inhibitory effect on bacteria of chitosan membranes regulated with deacetylation degree Immobilization of chitosan gel with crosslinking reagent on PNIPAAm gel/PP nonwoven composites surface Antimicrobial activity against foodborne pathogens of chitosan biopolymer films of different molecular weights This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license Acknowledgments: Grateful acknowledgment for the SORIMEX company from Torun for the possibility of mechanical testing of the obtained films. The authors declare no conflict of interest.