Hydrogels Produced by Photocrosslinking of Dextran Chain: Characterization and Properties

The present study describes the synthesis and characterization of dextran hydrogels produced by photocrosslinking of dextran chains. The hydroxyl groups of native dextran were converted to acrylate groups to make hydrogel precursors with different substitution degrees. The hydrogels were photopolymerizated in the presence of a suitable photoinitiator system (thionine/triethylamine) and characterized by ¹³C,¹H NMR, and infrared spectroscopy. The information about microenvironment formed in hydrogel solutions was obtained by fluorescence spectroscopy using pyrene and nabumetone probes. This technique was used also to study the crosslinking process. The results about the solubility and swelling index data of hydrogels showed that their use as models of drug delivery is technically feasible.     

Influence of hydration and crosslinking in transdermal delivery of nicotine from chitosan-based gels by thermal analysis

Chitosan is a biopolymer that forms hydrogels after swell in acid medium. The environment of the three-dimensional network of the chitosan-based hydrogels can be modified by its degree of swelling and crosslinking. In this way, nicotine was incorporated in the hydrogel formulations, with or without crosslinking with glutaraldehyde (0.01%), in different swollen states. Transdermal delivery of nicotine by chitosan-based hydrogels was studied in order to achieve the prolonged administration of the drug. Thermal analysis indicated a preliminary stability of these formulations, and the mechanism of drug release from hydrogels was dependent of the swelling degree and crosslinking. These formulations were able to control the transdermal flux of nicotine for up to 48 h following zero-order kinetics. The hydrogels with higher amounts of water or the partially dried crosslinked hydrogels reduced the partition of nicotine into the skin, leading to a minor transdermal flux of the drug (<3.4 µg cm⁻² h⁻¹). On the other hand, the partially dried non-crosslinked hydrogels lead to a major transdermal flux of the drug (20.19 µg cm⁻² h⁻¹) due to modifications of the environment into the hydrogel. In this way, these transdermal formulations were promising vehicles for prolonged administration of nicotine.

     

Characterization and Optimization of Injectable In Situ Crosslinked Chitosan-Genipin Hydrogels

In recent years, there has been an increased interest in injectable, in situ crosslinking hydrogels due to their minimally invasive application and ability to conform to their environment. Current in situ crosslinking chitosan hydrogels are either mechanically robust with poor biocompatibility and limited biodegradation due to toxic crosslinking agents or the hydrogels are mechanically weak and undergo biodegradation too rapidly due to insufficient crosslinking. Herein, the authors developed and characterized a thermally-driven, injectable chitosan-genipin hydrogel capable of in situ crosslinking at 37 °C that is mechanically robust, biodegradable, and maintain high biocompatibility. The natural crosslinker genipin is utilized as a thermally-driven, non-toxic crosslinking agent. The chitosan-genipin hydrogel's crosslinking kinetics, injectability, viscoelasticity, swelling and pH response, and biocompatibility against human keratinocyte cells are characterized. The developed chitosan-genipin hydrogels are successfully crosslinked at 37 °C, demonstrating temperature sensitivity. The hydrogels maintained a high percentage of swelling over several weeks before degrading in biologically relevant environments, demonstrating mechanical stability while remaining biodegradable. Long-term cell viability studies demonstrated that chitosan-genipin hydrogels have excellent biocompatibility over 7 days, including during the hydrogel crosslinking phase. Overall, these findings support the development of an injectable, in situ crosslinking chitosan-genipin hydrogel for minimally invasive biomedical applications.     

Mechanical properties of silica hydrogels prepared and aged at physiological conditions: testing in the compression mode

The mechanical properties for silica hydrogel prepared at physiological conditions are reported in this paper. The mechanical testing was performed in the compression mode determining the mechanical characteristics as a function of aging time in TRIS buffer up to 14 days. In addition to a typically used gradient method for Young’s modulus determination from the stress–strain curves, a new phenomenological model was proposed to describe the experimental data. The mechanical properties were stabilized after 2 days of aging, which was concluded from an increase in Young’s modulus between 90 and 400 kPa, an increase in stress at break between 50 and 100 kPa and by a decrease in relative deformation at break from 0.26 to 0.16. The height of samples was constant in the first three days of aging followed by a decrease by ~20%. Dissolving of silica hydrogel characterized through determination of silica content in TRIS buffer employing the molybdenum method was not found to be responsible for this phenomenon. The phenomenological model is proposed to be used for a reliable evaluation of mechanical properties of silica as well as other hydrogels exhibiting low Young’s modulus.     

Studies on radiation synthesis of polyethyleneimine/acrylamide hydrogels

Polyethyleneimine(PEI)/acrylamide(AAM) hydrogels were synthesized by γ-radiation-induced polymerization/crosslinking of aqueous mixtures containing different ratios of PEI and AAM. The gel percentage and equilibrium degree of swelling (EDS) of the synthesized hydrogels were investigated. The compositions of the hydrogels produced were found to be different from the feed composition. Ion-chromatography technique was used to determine the amount of Pb (II) and Cd (II) absorbed by the hydrogel. The maximum binding capacity of the PEI/AAM hydrogels, for Pb and Cd was found to be 19 and 12.6 mg/g, respectively, (at 100 ppm). PEI/AAM hydrogels had better metal uptake efficiency than the pure AAM hydrogel at concentrations less than 50 ppm. Pure PEI was observed to be highly degrading type polymer on exposure to gamma radiation. TGA and FT-IR techniques were used to characterize the prepared hydrogels.     

Gamma radiation synthesis of comb-type graft hydrogels based on poly(acrylic acid) and 4-vinylpyridine

A pH-sensitive comb-type hydrogel was obtained by gamma radiation polymerization and crosslinking of acrylic acid (AAc) in solution. The pH-sensitive 4-vinylpyridine (4VP) was then grafted to the poly acrylic acid (PAAc) hydrogel using gamma radiation from a ⁶⁰Co source. The comb type graft polymers obtained (net-PAAc)-g-4VP has been studied through determination of graft yield and swelling behavior. The critical pH value was found to be 5.6. The apparent mechanical properties appear to be qualitatively better than hydrogels of PAAc upon swelling. The new comb-type system presents faster swelling response (30 h) than the polyacrylic acid hydrogel (50 h). The increase in dose rate from 7.3 to 11.3 kGy h⁻¹, increase the radiation grafting percentage of 4VP in the system. Comb-type polymers were also characterized by DSC, TGA and FTIR-ATR.     

A chemiluminescence and fluorescence spectroscopy study: An investigation of photocrosslinking processes in polymer systems

Chemiluminescence emission is shown to be a valuable method for the analysis and monitoring of the photochemical transformation process in BZMA-co-S copolymers. BZMA-co-S copolymer films are synthesized and irradiated at λ > 400 nm, in order to induce the phototransformation of benzyl (BZ) to benzoyl peroxide (BP) pendant groups, resulting in thermal decomposition and crosslinking. The chemiluminescence emission increases with irradiation time, and is shown to be related to the benzoyl peroxide moieties generated during irradiation. The increase in chemiluminescence intensity is interrupted at longer periods of irradiation, when the concentration of these species tends to a nearly constant value. In this case, others factors are considered to influence the chemiluminescence emission, for example the increasing crosslinking on irradiated samples, which would restrict the mobility of radicals to recombine due to crosslinking of the network.A good correlation between fluorescence, FTIR and CL measurements during photochemical formation and thermal decomposition of peroxides is found. In this work, an intramolecular excimer forming fluorescent probe, DiPyM, is also used to analyse the crosslinking process. The results obtained contribute significantly to the development of chemiluminescence as a highly sensitive methodology for assessing the photocrosslinking of a polymeric material in the early stages of the process and is due to its sensitivity in comparison to that of fluorescence analysis.     

Radiation synthesis and characterization of nanosilver/gelatin/carboxymethyl chitosan hydrogel

A series of antibacterial hydrogels were fabricated from an aqueous solution of AgNO₃, gelatin and carboxymethyl chitosan (CM-chitosan) by radiation-induced reduction and crosslinking at ambient temperature. The nanosilver particles were in situ synthesized accompanying with the formation of gelatin/CM-chitosan hydrogel. Transmission Electron Microscope and UV–vis analysis have verified the formation and homogeneous distribution of nanosilver particles in the hydrogel matrix. The nanosilver/gelatin/CM-chitosan hydrogels possessed interconnected porous structure, had a compressive modulus of 44 to 56 kPa, and could absorb 62 to 108 times of deionized water to its dry weight. Furthermore, the hydrogels were found to have sound antibacterial effect on Escherichia coli (E. coli), and their antibacterial ability could be significantly enhanced by the increasing of AgNO₃ content. The comprehensive results of this study suggest that nanosilver/gelatin/CM-chitosan hydrogels have potential as an antibacterial wound dressing.     

Aggregation-induced emission-active antibacterial hydrogel with self-indicating ability for real-time monitoring of drug release process

Although antibacterial hydrogels are emerging as promising biomaterials for effective inhibition of bacterial infections, monitoring their dynamic release behaviors in a visual manner remains greatly challenging. Herein, non-conjugated luminescent polymers (NCLPs) with aggregation-induced emission (AIE) characteristics are used for the first time to develop a visualization strategy to monitor the release process of the drug-loaded hydrogel. The novel antimicrobial peptide polymers with intrinsic AIE effect, namely nanoengineered peptide-grafted hyperbranched polymers (NPGHPs), are encapsulated in an anionic polyelectrolyte to construct the AIE-active fluorescent polymeric hydrogel (NPGHPs/SA gel). Interestingly, the rigid environment mediated by hydrogen bonding and electrostatic interaction contributes to promoting the unconventional luminescence of fluorescent clusters. Moreover, the successive drug release process of NPGHPs/SA gel can be tracked in real time by using fluorescence microscopy. The hydrogel also has potent antibacterial activities against Gram-negative bacteria (E. coli, P. aeruginosa) and Gram-positive bacteria (S. aureus, B. subtilis). Overall, this work not only provides an advanced biomedical material with broad-spectrum antibacterial ability but also opens a facile avenue up for the investigation of drug release from gel systems.     

A simple route to interpenetrating network hydrogel with high mechanical strength

A simple two-step method was introduced to improve the hydrogel mechanical strength by forming an interpenetrating network (IPN). For this purpose, we synthesized polyacrylate/polyacrylate (PAC/PAC), polyacrylate/polyacrylamide (PAC/PAM), polyacrylamide/polyacrylamide (PAM/PAM) and polyacrylamide/poly(vinyl alcohol) (PAM/PVA) IPN hydrogels. The PAC/PAC IPN and PAC/PAM IPN hydrogels showed compressive strength of 70 and 160 kPa, respectively. For the PAM/PAM IPN and PAM/PVA IPN hydrogels, they exhibited excellent tensile strength of 1.2 and 2.8 MPa, and elongations at break of 1750% and 3300%, respectively. A strain relaxation was also observed in the case of PAM series IPN hydrogels. From FTIR, TGA and SEM measurements, we confirmed that physical entanglement, hydrogen bonds and chemical crosslinking played major roles in improving hydrogel strength and toughening. The two-step technique contributes to the understanding of ideal networks, provides a universal strategy for designing high mechanical strength hydrogels, and opening up the biomedical application of hydrogels.     

Controlling size and stabilization of silver nanoparticles for use in optimized chitosan-dialdehyde xylan wound dressings

The size of silver nanoparticles (AgNPs) is the key factor that governs their antibacterial activity. However, the size of AgNPs is difficult to control because agglomeration and uneven dispersion often occur during the processing of AgNP-based products, which has impeded their applications in different areas. In this work, an efficient strategy was developed to overcome this difficulty and to prepare an antibacterial hydrogel comprising AgNPs and chitosan (CS) with dialdehyde xylan (DAX) as the crosslinking agent. The size of AgNPs was controlled successfully to an extremely fine level (<?9 nm) by reducing AgNO₃ solution in a methanolic suspension of the metal organic framework (MOF) -UiO-66-NH₂, and forming an Ag@UiO-66-NH₂ core–shell structure which avoided the agglomeration of AgNPs. DAX played a dual role by forming a hydrogel structure with CS through crosslinking, but also by stabilizing the even dispersion of Ag@UiO-66-NH₂ in the hydrogel. Accordingly, the as-prepared hydrogels showed excellent antibacterial properties and low cytotoxicity. The survival ratio of NIH/3T3 cells cultured in the hydrogel extract was more than 90%, even when the concentration of the hydrogel extract was as high as 10 mg/mL. In addition, the hydrogel exhibited good abilities of water absorption (swelling ratio was up to 1100%) and self-healing (efficiency was up to 88% after 5 h). The hydrogels with size-well-controlled AgNPs prepared in this work are expected to find broad applications, especially in the area of antibacterial medical auxiliaries.

     

Mussel-inspired chemistry in producing mechanically robust and bioactive hydrogels as skin dressings

The development of hydrogels as skin dressings demonstrates a great potential in real life applications. To achieve this, the hydrogel has to conquer its natural poor mechanical strength, and to prolong its lifetime, antifatigue and self-healing properties originating from dynamic interactions are also required. As skin dressings, the hydrogel needs to maintain its ductility while pursuing the above mentioned properties. In this work, poly(ethylene glycol) diacrylate is used to produce skin dressings by reinforcing poly(ethylene glycol) diacrylate/alginate double network hydrogels with a crosslinker from mussel-inspired chemistry, which is 3,4-dihydroxy-l-phenylalanine. This crosslinking methodology significantly improved mechanical strength of the hydrogel, with 11,200% increase in compressive failure strength; it endowed the hydrogel with outstanding antifatigue and training strengthening properties that makes its mechanical strength increasing in a 50 cycles compressive test; the hydrogel showed excellent self-healing properties that in rheological characterization; it also displayed enhanced storage modulus after withstanding a shear strain up to 1100%; meanwhile, the hydrogel exhibited extreme ductility with an elastic modulus of only 10.90–16.53 kPa. 3,4-dihydroxy-l-phenylalanine also renders the hydrogel its inherent antioxidant activity, conductivity, and bioadhesiveness. Together with the highly transparent appearance, the hydrogels possess a great potential and practibility in the fields of skin dressings.     

Crosslinking Parameter on the Preparation of Cellulose Based Hydrogel with Divynilsulfone

Polymeric hydrogels are crosslinked polymers which display high sorption capacity in water and water solution. In this work, cellulose based hydrogel was prepared with divinylsulfone as crosslinking agent. Cellulose based hydrogel was synthesized as a mixture of sodium salt of carboxymethylcellulose (CMCNa) and hydroxyethylcellulose (HEC). The effect of chemical composition, temperature and reaction time during crosslinking processes was investigated both the value of equilibrium water uptake and swelling ratio. Infrared spectra of the synthesized polymeric networks were studied to investigate the chemical structure of crosslinking reaction qualitatively. The thermal properties and morphology of the obtained cellulose based hydrogels were observed by means of TGA (thermo-gravimetry analysis) and SEM (scanning electron microscopy), respectively. Crosslinking of CMCNa/HEC polymeric network results in a decrease in thermal stability. Hydrogel with weight ratio of CMCNa/HEC 5 to 1 at reaction temperature of 60 °C gave the highest absorption capacity in distilled water.     

Estimation of polarity and fluidity of colloidal interfaces and biosurfaces using rhamnolipid B pyrenacylester as surface-active fluorescent probe

Fluorescent probes are useful to monitor the polarity and fluidity of microenvironments. Therefore, a new amphiphilic fluorescent probe, the pyrenacylester of Rhamnolipid B, was prepared from biosurfactant (Rhamnolipid B) and pyrene. As a result of its surface activity, this probe was expected to be able to penetrate into various kinds of microdomains such as the environments of organic solvents, emulsions, dispersions, surfaces of biomembranes and polymers.     

PHOTOPHYSICAL PROBES FOR MONITORING THE ELECTRIC FIELD/MICROPOLARITY WITHIN THE FAUJASITE SUPERCAGE*

The micropolariry of the supercages of zeolites is a reflection of the electric field provided by the cations present within them. The notion of polarity within the cages of X and Y zeolite does not have precisely the same meaning as in solution. In this study, pyrene, pyrenealdehyde, and para-dimethylaminobenzonitrile have been used as photophysical probes to monitor the polarity of the zeolite interior. With pyrenealdehyde and para-dimethylaminobenzonitrile the supercage wherein the probe is expected to reside is more polar or possesses a higher electric field when the cation is Li or Na. The polarity/electric field of the supercage decreases with cation size (Li > Na > K > Rb > Cs) and the supercage is more polar in the case of X zeolites than in Y zeolites. The results with pyrene are generally consistent with those with the other two probes. However, pyrene is unable to sense the difference between Li. Na and other cations.     

Synthesis of guar gum-based hydrogel for sugarcane field solid conditioning

The water crisis is increased everywhere in recent years, which has affected the water demand in different sectors like industries, agriculture, residential, etc. The present research aims to the development of superabsorbent polymer (SAP) using bio-material. The hydrogel is synthesized by grafting Guar gum (GG) with methyl methacrylate (MMA) and crosslinking with polyethylene glycol (PEG). The developed GG-based hydrogelwas characterized by various analytical instruments. The Scanning Electron Microscopy (SEM) demonstrated hydrogels havepores of size 50 ​μm–10 ​μm. The Transmission Electron Microscopy (TEM) analysis has shownthat thematerial consists of spherical shapesand particles of size 141.11nm–182.19 ​nm.The Fourier-Transform Infrared Spectroscopy (FTIR) and Thermogravimetric analysis (TGA) study have confirmedthepresence of functional groups of material, and thermal resistivity. The absorption capacity of developed hydrogelwas found to be 110 ​ml per gram (110% of its dry weight). The hydrogelwasapplied in the field of sugarcane crop and measured soil moisture content after 20 days of application. A better resultwas found of moisture content in the area of hydrogel application (28%) compared to the area without hydrogel application (10%). Moreover, the comparison of different hydrogels is also shown in a study, and the developed hydrogel proves good moisture retention capacity. This technology could be promising in terms of improving perennial crop productivity and combating moisture stress in agriculture. As a soil conditioning material for agricultural applications, the synthesized hydrogel showed tremendous potential.     

Effects of annealing and the addition of PEG on the PVA based hydrogel by gamma ray

Poly(vinyl alcohol) (PVA) is an interesting material with good biocompatibility, high elasticity and hydrophilic characteristics. PVA hydrogels have been formed through chemical crosslinking with aldehyde, photopolymerization and physical crosslinking with freeze-thawing. In this study, crosslinked hydrogels based on PVA, and poly(ethylene glycol) (PEG) were prepared by gamma-ray irradiation, and then annealed at 120 °C. The properties of a hydrogel such as gel fraction, swelling behavior, gel strength as a function of PEG content and annealing time were investigated. Also, the thermal behaviors were examined by thermogravimetric analysis (TGA) and differential scanning calorimetry (DSC). The gel fraction decreases with an increase in PEG content and decrease in annealing time. The tensile strength increases with an increase in annealing time. The thermal behaviors have shown different patterns according to the annealing time. The improved properties suggest that PVA/PEG blend hydrogel can be a good candidate for applications in the articular cartilage.     

Effect of Amino Acid Types on the Mechanical and Antimicrobial Properties of Amino Acid-Based Polyionic Liquid Hydrogels

Polyionic liquid hydrogels attract increasing attention due to their unique properties and potential applications. However, research on amino acid-based polyionic liquid hydrogels is still in its infancy stage. Moreover, the effect of amino acid types on the properties of hydrogels is rarely studied to date. In this work, amino acid-based polyionic liquid hydrogels (D/L-PCAA hydrogels) are synthesized by copolymerizing vinyl choline–amino acid ionic liquids and acrylic acids using Al³⁺ as a crosslinking agent and bacterial cellulose (BC) as a reinforcing agent. The effects of amino acid types on mechanical and antimicrobial properties are systematically investigated. D-arginine-based hydrogel (D-PCArg) shows the highest tensile strength (220.7 KPa), D-phenylalanine-based hydrogel (D-PCPhe) exhibits the highest elongation at break (1346%), and L-aspartic acid-based hydrogel (L-PCAsp) has the highest elastic modulus (206.9 KPa) and toughness (1.74 MJ m⁻³). D/L-PCAsp hydrogels demonstrate stronger antibacterial capacity against Escherichia coli and Staphylococcus aureus, and D/L-PCPhe hydrogels possess higher antifungal activity against Cryptococcus neoformans. Moreover, the resultant hydrogels exhibit prominent hemocompatibility and low toxicity, as well as excellent self-healing capabilities (86%) and conductivity (2.8 S m⁻¹). These results indicate that D/L-PCAA hydrogel provides a promise for applications in wound dressings.     

Methyl methacrylate-co-itaconic acid (MMA-co-IA) hydrogels for controlled drug delivery

In the present work methyl methacrylate-co-itaconic acid (MMA-co-IA) hydrogels were synthesized by free radical copolymerization of methyl methacrylate (MMA) and itaconic acid (IA) using ethylene glycol dimethacrylate (EGDMA) and methylene bisacrylamide (MBAAm) as crosslinkers and benzoyl peroxide as initiator. Selected samples were loaded with model drug lactulose. For the lactulose release, the effect of pH, monomeric compositions, degree of crosslinking were investigated. The release of lactulose was studied for 8 h period in USP phosphate buffer solutions of varying pH 1.2, 5.5, 6.5 and 7.0. The drug release data were fitted into various kinetics models like the zero order, first order, Higuchi and Peppas. The release kinetics of lactulose from MMA/IA hydrogels was found to be best described by the Peppas model. Results showed that drug release increased by increasing IA content in the hydrogels but the effect of changing of crosslinking ratio on drug release was not significant. The surface morphology of MMA/IA drug loaded hydrogel was studied by SEM which revealed uniform distribution of the drug in the hydrogels. In conclusion, it can be said that lactulose can be successfully incorporated into crosslinked MMA/IA hydrogels and its release can be modulated by changing the mole fraction of the acid component in the gels.     

Development of injectable high molecular weight hyaluronic acid hydrogels for cartilage regeneration

The study focuses on developing hyaluronic acid (1200 kilo Dalton) hydrogels for cartilage regeneration. In spite of being highly biocompatible; a large amount of water absorption and easily degrading nature restricts the use of hyaluronic acid in the field of tissue regeneration. This can be rectified by crosslinking hyaluronic acid with a crosslinking agent such as divinyl sulfone; which results in a biocompatible hydrogel with superior rheological properties. Different amounts of divinyl sulfone have been used for crosslinking hyaluronic acid to get three types of hydrogels with differing properties. Swelling studies, rheology analysis, enzymatic degradation and scanning electron microscopic analysis were conducted on all the different types of hydrogels prepared. Viscoelastic properties of the hydrogel were analyzed so that a hydrogel with better elastic property and stability is obtained. Scanning electron microscopy was used to study the morphology of the HA hydrogels. The cytotoxicity testing was conducted to prove the non-toxic nature of the hydrogels and cell culture studies using adipose mesenchymal stem cells showed better adhesion and proliferation properties in all the three hydrogels. Thus hyaluronic acid hydrogel makes a promising material for cartilage regeneration.