Sodium Alginate Concentration Research Articles

The construction of retrograded short-chain amylose beads coated with calcium alginate for increased resistant starch.

A novel strategy was developed to embed retrograded short-chain amylose (RSCA) into calcium alginate (CA) at varying concentrations (0.25 %, 0.5 %, 0.75 %, 1 %, 1.5 %, and 2 %) through ion crosslinking, aimed at enhancing the content of heat-resistant RS. The concentration of sodium alginate (SA) significantly influenced the thickness of the CA shell, thereby affecting the structural characteristics, physicochemical properties, and digestibility of the resulting beads. As the SA concentration increased from 0.5 % to 2 %, the CA shell thickness expanded from 0.612 μm to 1.837 μm, becoming denser and limiting the infiltration of enzymatic liquids during digestion. The initial gelatinization temperature of the beads exceeded 100 °C, and the enthalpy value of the 2 % SA beads was 25.40 ± 0.17 J·g-1, indicating excellent thermal stability. After heat treatment, the crystallinity reached 90.50 %. The RS content of the 2 % SA beads was as high as 72.66 ± 0.15 %, with an estimated glycemic index of 54.72, classifying them as low-glycemic index foods. The heat-resistant RSCA@CA developed in this study shows significant potential for application in functional foods, particularly for individuals with obesity and diabetes.

Development of Wheatgrass (Triticum aestivum) Extract Loaded Solid Lipid Nanoparticles using Central Composite Design and its Characterization- Its In-vitro Anti-cancer Activity

Background: The prevalence of cancer is around the world and is identified as a multifactorial ailment. One of the most common causes of cancer in the world is oxidative stress, and this can be overcome by taking herbal plant wheatgrass in any form. As colloidal carriers with particle sizes of 50-1,000nm, Solid Lipid Nanoparticles (SLNs) combine the benefits of liposomes, emulsions, and other colloidal systems to deliver drugs at their targets. Objective: Aim and objective of the present work is to formulate wheatgrass extract loaded solid lipid nanoparticles using Central Composite design and to investigate the effect of formulation variables. Using hot homoginization method, the present work aimed to formulate wheatgrass loaded chitosan solid lipid nanoparticles using central composite design and to evaluate the extract potential to treat breast cancer on MCF-7 cell line. Methods: This study investigated the effect of three formulation variables on particle size, namely the sodium alginate concentration, the calcium carbonate concentration, and the homogination time. Extraction of wheatgrass was done in soxhlet extractor, using methanolic extract. The hot homogenization technique was used to prepare Triticum aestivum extract loaded solid lipid nanoparticles (SLNs). Result: For CCD, all formulations were analyzed for particle size, which ranged from 362.5 to 933.8 nm, and for polydispersity index, which ranged from 0.137 to 5.799. Batch code SLN-6 was found to be finest suitable because of maximum loading capacity of 67.76 ±0.17 % (w/w), maximum entrapment efficiency of 65.81 ± 0.11 % (w/w) and minimum particle size of 362.5nm by using sodium alginate as surface stabilizer at homogenization time ~ 5 min and having maximum percentage yield of 43.66%. Conclusion: During characterization studies and MCF-6 cell line studies, it was found that batch code SLN-6 was found to be finest suitable and wheatgrass has anti-oxidant potential, and potent against breast cancer.

Timolol Maleate Microspheres: An Ingenious Carrier for Sustained Release Antihypertensive Formulation

Background: Timolol maleate is classified as a BCS Class I drug and functions as a non-selective β-adrenergic receptor blocker. Its ability to lower heart rate and cardiac output has led to its widespread use in the treatment of hypertension. Objective: Timolol maleate has a short half-life and is rapidly cleared from the body, which limits its therapeutic effectiveness, requiring frequent dosing and potentially affecting patient adherence. To overcome these challenges, sustained-release microspheres of Timolol maleate were developed using the ion gelation method. Method: The ion gelation technique was employed to create the microspheres due to its various advantages, including ease of use, scalability and gentle processing conditions. Results: All batches exhibited a comparatively lower swelling index in 0.1M HCl (pH 1.2) than in SIF (pH 6.8). It was observed that increasing the concentration of sodium alginate resulted in higher drug content. The microspheres were sized between 400 and 900 μm and demonstrated excellent flow characteristics. An optimized batch achieved an entrapment efficiency of 88.83% and released 92.15% of the drug over 7 hrs. Furthermore, stability studies conducted according to ICH Q1A(R2) for 3 months at 5±3°C and 25±2°C/60±5% RH indicated no significant changes in evaluation parameters. Conclusion: The optimized Timolol maleate-loaded microspheres effectively provided sustained drug release through the membrane over 7 hrs. This study contributes to the development of improved drug delivery systems for better hypertension management, addressing the unmet needs in patient compliance. Keywords: Timolol Maleate, Microspheres, Ion gelation method, Sodium alginate, Calcium chloride, Sustained release, Hypertension

SnO2 Encapsulated in Alginate Matrix: Evaluation and Optimization of Bioinspired Nanoadsorbents for Azo Dye Removal.

Synthesized SnO2 nanoparticles (NPs) demonstrate potential capacity to adsorb toxic azo Congo red dye. The formation of rutile phase SnO2 NPs was confirmed using Powder X-ray diffraction and spherical morphology was corroborated through SEM imaging. TEM analysis confirms average particle size of SnO2 NPs is nearly 3 nm. High azo dye removal efficiency is attributed to large surface area and presence of oxygen vacancies which were substantiated through BET and XPS analysis, respectively. To mitigate the leaching of NPs in treated water, NPs are encapsulated in sodium alginate (SA) matrix, which is proposed as an environmentally friendly, biocompatible, and economic solution. This study specifically focuses on investigating the parameters for the encapsulation of NPs within a sodium alginate matrix using CaCl2 as cross-linker. This work investigates the effect of physical shape of encapsulation, effect of SA and cross-linker (CaCl2) concentration on the feasibility of NP encapsulation and overall adsorption efficiency. Experimental results indicated that the physical form of encapsulation, such as spherical, wire-like, or irregular shape maintained consistent adsorption efficiency, which indicates its versatility. For effective encapsulation of NPs and adsorption, SA and CaCl2 concentration are suggested to be within the range of 0.2-0.3 g and >0.5 M, respectively.

Standardisation of microencapsulation protocol for chilled preservation of Malabari buck spermatozoa

The present study was conducted to standardise the protocol for microencapsulation of buck spermatozoa for its chilled preservation. Semen ejaculates collected from Malabari bucks of age two to three years, weighing 42 to 46 Kg and maintained under uniform managemental conditions were utilised. Sodium alginate of concentrations 0.5, 0.75 and 1.5 per cent with varying gauge sized hypodermic needles of 18G, 20G and 23G were used. The distance between the tip of the needle and the upper meniscus of BaCl2 solution was adjusted to varied distance like ≥ 7 cm, 3.5 to 5 cm, ≤ 2cm. This resulted in capsule sizes of 1 mm, 2 mm, 3 mm, 4 mm, 4.5 mm, 6 mm and 7 mm. Different shape of capsules like globular, plate like, irregular, tear-drop and oval were obtained and the capsule stability varied from 35 to 75 per cent. Capsule parameters were assessed at 0 h, 24 h, 48 h, 72 h and 96 h of chilled preservation in EYC extender at ratio of (1:2). The results of the present study cited that 1.5 per cent sodium alginate concentration, with 23G sized hypodermic needle and distance of 3.5 cm were ideal to acquire uniform spherical shaped stable capsule of size 1.90 ± 0.03 and stability of 75 per cent Keywords: Microencapsulation, chilled preservation, buck spermatozoa, Malabari

Standardization of Protocol for Production of Synthetic Seed of Brahmi (Bacopa monnieri) and Assessment of their Longevity under Differential Storage Condition

Brahmi [Bacopa monnieri (L) Pennel] is an important medicinal small succulent, medicinal herb belongs to the family ‘Scrophulariaceae’ which is commonly known as Jala Brahmi or Nira-Brahmi. National Medicinal Plants Board (NMPB), estimated an annual demand of Bacopa in 2004-2005 was 6621.8 tonnes, with a 7% annual growth rate. Micropropagation techniques and production of synthetic seeds can be a breakthrough to overcome the low availability of Brahmi propagating materials. So, the present study was conducted to standardize the protocol for preparation of synthetic seeds of Brahmi using nodal segment. The experiment was conducted with five treatments by using combinations of different concentrations of sodium alginate and calcium chloride and preparing two types of synthetic seeds (single layer and double layer). Further the longevity of both single layer and double layered synthetic seeds was studied under two different storage temperatures at 25°C (ambient condition) and 4°C (refrigerator) up to 40 days by inoculating them in two different types of media. The result showed no significant effect of concentrations of gelling agent and complexing agent on the germination percentage of synthetic seeds. The number of shoots per synthetic seed varied from 22.00 to 29.35 with 100% germination and maximum shoots/synthetic seed and shoot length was obtained by using T5 (single layered with MS media, 3% sodium alginate and 2.5% calcium chloride). Maximum number of days of storage can be observed in the single layer synthetic seeds when stored at 4°C along with media followed by double layer synthetic seeds when stored at 4°C along with media. However, seeds stored on vermiculite got dried up in the initial days of storage. Germination was found to be higher in seeds stored at 4°C when compared to seeds stored at 25°C. The study as a whole elucidated the opportunity for the use of synthetic seed as an alternative to traditional propagation system for Brahmi.

Construction of Lactobacillus casei-loaded Water-in-oil High Internal Phase Emulsion and its Study on Anti-breast Cancer Properties

Objective: To prepare an oil-in-water high internal phase emulsion containing Lactobacillus casei, and to optimize and characterize the preparation process. To explore the therapeutic effect of the probiotic-carrying emulsion on in situ breast cancer in mice. Methods: Using corn oil, sodium alginate, polyglycerin ricinoleate and L. casei as raw materials, the high internal phase emulsion containing probiotic oil-in-water was prepared by high-speed homogenization method. The optimal preparation process was obtained through single factor investigation, microstructure characterization, stability investigation and in vitro simulation digestion experiment. Ten female BALB/c mice (SPF grade, 18–20 g) were selected. After the in situ breast cancer model was successfully established, the mice were randomly divided into experimental group and control group, with 5 mice in each group. The mice were administrated with probiotic-loaded emulsion and normal saline respectively, and were administrated with the stomach every other day for 10 days. The change of tumor volume during treatment and tumor mass at the end of treatment were recorded. Results: The optimum process of emulsion was: With the concentration of 5% Polyglycerin ricinolate, 75% aqueous volume, 3000r/min homogenizing speed, 30 s homogenizing time and 2% aqueous sodium alginate concentration, a high internal phase emulsion with a particle size of 9.33 ± 1.74 μm and an appearance of milky paste was prepared. The inclusion rate of probiotics reached 90.97 ± 27.09%. Breast cancer anti-tumor experiment showed that the tumor inhibition rate of the experimental group reached 33.78% compared with the control group. Conclusion: Water-in-oil high internal phase emulsion can effectively protect L. casei and reduce the loss of live probiotic when probiotics pass through the digestive fluid environment. Oral intragastric high internal phase emulsion containing L. casei oil-in-water has a certain therapeutic effect on breast cancer.

Formulation and Evaluation of Lungs-Specific Doxorubicin-Loaded Chitosan-PLGA-Alginate Polymeric Nanoparticles

Background: An antibiotic called doxorubicin is produced by the Streptomyces peuce-tius bacterium, which is a member of the anthracycline drug class and is used in chemotherapy. Usually, doxorubicin is employed to cure solid tumors in children and adult patients. The physical and biological stability of the medicine can be increased by encasing it in nanoparticles, which increases the active pharmaceutical ingredient's bioavailability. Objective: This study aimed to create lungs targeting doxorubicin-loaded biodegradable polymer-ic nanoparticulate system by utilizing an appropriate method and conducting its evaluation. Methods: The polymeric nanoparticles using biodegradable polymers were prepared by the emul-sion polymerization method. Franz- diffusion cells were utilized to conduct in-vitro drug diffu-sion investigations. Results: Based on the outcomes of the experiments carried out for the research, polymeric nano-particles of doxorubicin were prepared utilizing different concentrations of chitosan, Sodium al-ginate, and PLGA. The visual appearance of doxorubicin polymeric nanoparticles shows homo-geneous dispersion with no phase separation form. The percentage yield, % entrapment efficien-cy, and drug content obtained for the final formulation were 93.43 ± 1.776, 87.31 ± 1.075, and 91.98 ± 0.493, respectively. A size dimension of 174.51 nm with a PDI of 0.242 and zeta poten-tial value of -36.1 mV of prepared nanoparticles demonstrate the stability of the formulation. The presentation of the PNPs of the optimized formulation having 310mg Tween 80 showed in vitro diffusion of 98.93% ± 0.296 % and an increased flux rate. Based on the determination coeffi-cients, the Higuchi model (K0 = 20.43 and R2= 0.982) was determined to have the best fit for the release data. Conclusion: Based on the trials conducted during the investigation, it was determined that the emulsion polymerization technique was best for the fabrication of the polymeric nanoparticles by utilizing different concentrations of chitosan, Sodium alginate, and PLGA. The formulation F6 containing 310mg Tween 80 suggested improved in vitro diffusion following the Higuchi model throughout all formulations. The findings suggest that a sustained process was responsible for the drug's release from the doxorubicin polymeric nanoparticles.

Chitosan/Sodium Alginate Hydrogel for the Release of Berberine as an Algae Suppressant: RSM Optimization and Analysis of Sustained Release Characteristics.

In this study, we used chitosan/sodium alginate hydrogel as a carrier to prepare berberine sustained-release capsule materials that can inhibit algae for a long time and safely. The preparation conditions of the material were optimized by the response surface method, and the optimized capsule material was characterized and the sustained release characteristics were analyzed to study the change of the algae inhibition effect of the material within 30 days. The results showed that the optimum preparation parameters of the material were 0.54% chitosan content, 2.46% sodium alginate content and 1.09% anhydrous calcium chloride content by response surface optimization design, which was consistent with the parameters set by each factor at the central point. The algae inhibition rate of the material under this preparation condition was 93.75 ± 1.01%, which was similar to the predicted value. The release characteristics analysis showed that the material continuously released up to 90% of berberine within 24 days, and its release characteristics were sustained release after burst release, with good sustained release effect. The results of material characterization showed that chitosan/sodium alginate hydrogel could effectively load berberine and was beneficial to the loading and release of berberine. The results of algae inhibition experiments showed that low concentration materials could control the outbreak of cyanobacterial blooms in a short time, while under high concentration conditions, the materials could inhibit Microcystis aeruginosa efficiently and for a long time.

The Influence of the Structural Architecture on the Swelling Kinetics and the Network Behavior of Sodium-Alginate-Based Hydrogels Cross-Linked with Ionizing Radiation.

The present work discusses the influence of the structural architecture of sodium alginate-co-acrylic acid-poly(ethylene) oxide hydrogels, crosslinked through electron beam (e-beam) radiation processing. The most important properties of the hydrogels were studied in detail to identify a correlation between the architecture of the hydrogels and their properties. Furthermore, the effect of sodium alginate (NaAlg) concentration, the amounts of the polymer blend, and the size of the samples on hydrogel properties were investigated. The results show that the hydrogels cross-linked (0.5% and 1% NaAlg) with 12.5 kGy exhibit improved physicochemical properties. High gel fraction levels (exceeding 83.5-93.7%) were achieved. Smaller hydrogel diameter (7 mm) contributed to a maximum swelling rate and degree of 20.440%. The hydrogel network was dependent on the hydrogels' diameter and the amount of polymer blend used. The hydrogels best suited the first-order rate constants and exhibited a non-Fickian diffusion character with diffusion exponent values greater than 0.5. This study indicates that the cross-linked hydrogel has good properties, particularly because of its high degree of swelling and extensive stability (more than 180 h) in water. These findings show that hydrogels can be effectively applied to the purification of water contaminated with metals, dyes, or even pharmaceuticals, as well as materials with a gradual release of bioactive chemicals and water retention.

Investigating a siderophore-based approach for the recovery of critical metals from waste streams and leach solutions using microorganisms

As technological advancements progress and unsustainable consumerism of electrical devices rapidly increases, the demand for critical metals continues to rise. The limited supply of these metals, driven by the depletion of non-renewable natural resources, calls for the recycling of waste materials and the development of sustainable and cost-effective extraction methods. Conventional methods of leaching such as pyrometallurgy pose threats to the environment by creating slags and releasing toxic secondary materials. Biohydrometallurgy emerges as an environmentally friendly method to extract metals from low-grade ores and waste material. Siderophores are secondary metabolites secreted by microorganisms that have the ability to selectively chelate certain metals. By immobilizing these siderophores for subsequent bioleaching, target metals can be extracted from multielement solutions. This research focuses on optimizing the immobilization efficiency of the siderophore desferrioxamine B (DFOB) in sodium alginate using physical entrapment for the removal of gallium. Four parameters were varied to find optimal conditions: sodium alginate concentration (1 – 4 % w/v), calcium chloride concentration (1 – 10% w/v), agitation time (0.25 – 10 hours), and DFOB concentration (1 – 4 mM). Using UV-Vis spectroscopy, free siderophore concentration could be determined. After 30 runs, the highest immobilization yield of 80.05% was determined at 2.5% sodium alginate, 10% calcium chloride—the highest concentration tested—after 5.13 hours with a concentration of 2.25 mM DFOB. Design Expert-13 software was used to analyze all experimental results. 2D graphs support that DFOB immobilization depends on responsive parameters, CaCl2 demonstrating the largest impact.

Incorporation of carboxymethyl chitosan (CMCS) for the modulation of physio-chemical characteristics and cell proliferation environment of the composite hydrogel microspheres

Hydrogels have excellent swelling properties and have been widely applied in tissue engineering because of their similarity to the extracellular matrix (ECM). Sodium alginate (SA) and carboxymethyl chitosan (CMCS) were prepared into hydrogel microspheres with Ca2+crosslinking in our study. The morphology, inner structure, mechanical properties, water content, swelling rate and BMP-2 loading and releasing properties were characterized. Our results showed that the composite SA /CMCS hydrogel microspheres were translucent and spherical in shape with uniform particle size. The incorporation of CMCS further increased the diameters of the microspheres, internal pore structure, water content, and mechanical properties of the SA/CMCS hydrogel microspheres. At the same SA concentration, with the increase of CMSC concentration, the diameter of microspheres could be increased by about 0.4 mm, the water content can be increased about 1%-2%. As for the mechanical properties, the compressive strength can be increased by 0.04-0.1 MPa, and the modulus of elasticity can be increased by 0.1-0.15 MPa. BMP-2 was chosen as a model agent and it could be loaded into SA/CMCS microspheres, and the incorporation of CMCS increased BMP-2 loading. The encapsulated BMP-2 was sustainably releasedin vitro. The leaching solutions of the SA/CMCS hydrogel microspheres exhibited good cytocompatibility and could increase ALP activity, ALP expression, and biomineralization on MC3T3-E1 cells. After 7 d of co-culture, ALP activities in S2.5C2 and S2.5C3 groups was increased by 50% and 45% compared with that of the control group. When embedded in the SA/CMCS microspheres, the MC3T3-E1 cells were evenly distributed inside the hydrogel microspheres and remained viable. Transcriptomic studies showed that incorporation of CMCS induced upregulation of 1141 differentially expressed genes (DEGs) and downregulation of 1614 DEGs compared with SA microspheres. The most significantly enriched pathways were the Wnt and MAPK signaling pathways induced by the incorporation of CMCS and BMP-2. In conclusion, our results indicated that the physiochemical characteristics of the SA hydrogel microspheres could be greatly modulated by CMCS to better mimic the ECM microenvironment and induce osteo-inductive activities of MC3T3-E1 cells.

Optimized Eco-Friendly Foam Materials: A Study on the Effects of Sodium Alginate, Cellulose, and Activated Carbon.

This study focuses on optimizing the physical and mechanical properties of foam materials produced with the addition of sodium alginate as the matrix, and cellulose and activated carbon as fillers. Foam materials, valued for their lightweight and insulation properties, are typically produced from synthetic polymers that pose environmental risks. To mitigate these concerns, this study investigates the potential of natural, biodegradable polymers. Various foam formulations were tested to evaluate their density, compression modulus, and thermal conductivity. The results indicated that an increase in activated carbon content enhanced thermal stability, as indicated by higher Ti% and Tmax% values. Additionally, a higher concentration of sodium alginate and activated carbon resulted in higher foam density and compressive modulus, while cellulose exhibited a more intricate role in the material's behavior. In the optimal formula, where the sum of the component percentages totals 7.6%, the percentages (e.g., 0.5% sodium alginate, 5% cellulose, and 2.1% activated carbon) are calculated based on the weight/volume (w/v) ratio of each component in the water used to prepare the foam mixture. These results indicate that natural and biodegradable polymers can be used to develop high-performance, eco-friendly foam materials.

Effect of calcium concentration on metastasis of hepatocellular carcinoma cells cultured in alginate gel beads

Changes in sodium alginate and calcium ion concentrations have a considerable impact on the structural properties of calcium alginate gel (ALG) beads, consequently influencing the biological characteristics of the cells encapsulated within them. This study aimed to examine the effects of calcium on the metastatic potential of hepatocellular carcinoma (HCC) cells encapsulated in ALG beads. The results showed that the invasion ability of HCC cells significantly increased when they were encapsulated in beads prepared with a calcium concentration of 200 mM compared to those prepared with a calcium concentration of 50 mM. Furthermore, the expression levels of genes related to metastasis were significantly elevated in ALG beads prepared with a calcium concentration of 200 mM. Specifically, the expression of activated matrix metalloproteinase 2 (MMP2), matrix metalloproteinase 9 (MMP9), and urokinase-type plasminogen activator system proteins was found to be high. Conversely, the expression of phosphatase and tensin homolog deleted on chromosome 10 was observed to be significantly reduced. These findings indicate that manipulating the calcium ion concentration during the fabrication of ALG beads enables the generation of three-dimensional HCC cells with varying metastatic capacities. This model offers a valuable tool for investigating the mechanisms underlying liver cancer metastasis and screening potential therapeutic drugs.

Alginate functionalized sugarcane cellulose-based beads to improve methylene blue adsorption from aqueous solution

The study was carried out with the goal of synthesizing composite bead of cellulose, chitosan functionalized by sodium alginate using as an efficient and applicable adsorbent for methylene blue removal. Fabricating parameters of the material synthesis process like cellulose mass, sodium hydroxide concentration, immersing time and sodium alginate concentration were assessed in detail. The dye adsorption performance in water under the influence of pH, contact time, dye initial concentration, the material mass, shaking speed, temperature was also thoroughly evaluated. The results of advanced analyses showed that the beads were successfully synthesized with a rough surface and mesoporous structure. The adsorption isotherm and adsorption kinetics of dye adsorption process exhibited that the process was consistent with the Freundlich adsorption isotherm and the pseudo-second-order kinetic model, indicating a favorable physical adsorption process with multilayer of the dye on the adsorbent surface. The intra-particle diffusion model showed the strong dye adsorption by the beads occurred during the first two and half hours. The adsorbent could maintain its adsorption performance of 86 % for three times of regeneration. Finally, this study provided a recyclable and effective adsorbent for dyes separation from water.

Radiation synthesis of sodium alginate/gelatin based ultra-absorbent hydrogel for efficient water and nitrogen management in wheat under drought stress

The main focus of this study was on using radiation to make an ultra-absorbent hydrogel (UAH) from sodium alginate (SA) and gelatin (GL) biopolymers. This UAH can effectively handle water and nitrogen in wheat farming during drought stress. The hydrogel was synthesized by gamma irradiation-induced SA/GL/polyacrylamide crosslinking at 10–40 kGy. Varying SA/GL ratios affected swelling and the gel fraction of SA/GL/PAm hydrogels. The (SA/GL 17/83) hydrogel exhibited a 40.03 g/g swelling degree, while increasing SA content resulted in higher swelling, peaking at 75.5 g/g for (SA/GL 83/17). This indicated a synergistic interaction between SA and GL. The gel fraction also increased from 76.8 to 90.3%, with a higher GL content reflecting increased crosslinking. After multiple hydrolysis cycles, the hydrogel achieved 1293 (g/g) swelling and 36 days of water retention. When applied to wheat (Triticuma estivum) under drought stress, it significantly improved shoot length (18%), root length (43%), shoot fresh weight (49%), and shoot dry weight (51%) under extreme drought. The significant increases in protein and carbohydrate content in both shoots (up to 32% and 19%, respectively) and grains (up to 21% and 24%, respectively), along with the reduction in proline content (up to 38%), demonstrate that ultra-absorbent hydrogel (UAH) effectively enhances nitrogen content, photosynthesis, and overall plant health in wheat under varying drought stress levels. This novel SA/GL-based UAH holds promise for addressing water scarcity and agricultural challenges, offering a sustainable solution for water and nitrogen management under drought stress.

VPreparation of Temperature/pH Dual‐Sensitive Hydrogels and Study of their Properties

AbstractA temperature/pH dual‐sensitive hydrogel was prepared through simple solution radical polymerization. A novel temperature/pH dual‐sensitive terpolymerized semi‐interpenetrating network, P(NIPAAm‐co‐AA‐co‐HEAA)/SA hydrogel, was synthesized using interpenetrating network technology (IPN) with sodium alginate (SA) as the raw material. The temperature‐sensitive monomer N‐isopropylacrylamide (NIPAAm), the pH‐sensitive monomer acrylic acid (AA), and the hydrophilic monomer N‐hydroxyethylacrylamide (HEAA) were incorporated into the structure. The structure and morphology of the hydrogels were investigated using FTIR, TGA and SEM. Additionally, the swelling properties, as well as temperature and pH sensitivity, were examined. The results showed that the content of HEAA and SA influenced the swelling properties of the gels. The gels exhibited distinct swelling behaviors at different temperatures and pH levels, demonstrating remarkable temperature and pH sensitivity. Moreover, it shows rapid response speed and efficient recovery, making them suitable for use as anticancer drug carriers that meet specific requirements.

Modulating alginate-polyurethane elastomer properties: Influence of NCO/OH ratio with aliphatic diisocyanate

This research addresses the need for enhanced biomaterials by investigating the influence of the NCO/OH ratio on sodium alginate-based polyurethane elastomers(Al-PUEs), offering novel insights into their structural, thermal, mechanical and swelling behavior. Al-PUEs were prepared by blending the chain extenders with key ingredients in a specific molar ratio using aliphatic HMDI and HTPB monomers. The chemical linkages, crystalline behavior, homogeneity, and surface morphology of PUEs were evaluated by FT-IR, XRD, SEM, and EDX analysis. Thermo-mechanical studies were performed using TGA, DSC and tensile testing. Swelling behavior and absorption analysis were analyzed in DMSO and water. The analysis indicated that the hydrophilicity and swelling behavior of the prepared PUEs were affected by the addition of sodium alginate content. The results exhibit the tailor-made network structure of Al-PUEs, resulting in better thermal stability, elasticity of materials via stress-strain behavior and marvelous characteristic features than traditional high-tech yields. Furthermore, the resulting Al-PUEs are potential candidates for biomedical implants.

Development of plant-based egg-white replacer: Improvement of foaming and thermal properties of plant-based proteins

Optimization of protein mixtures and hydrocolloids was carried out for the preparation of sponge cake using egg-white replacer. First, the protein mixtures ranged fixed as followed; soy protein isolate (SPI, 2–8%), wheat protein isolate (WPI, 2–8%), and potato protein isolate (PPI, 2–4%) based on preliminary experiments. The foaming properties of protein mixture was investigated and evaluated using reactive surface methodology (RSM). Then, the effects of guar gum (GG) and sodium alginate (SA) in protein mixture were investigated. According to the results of foam properties, optimized formula of mixture is strongly influenced by the PPI, WPI, and SA concentration. Based on the results of this research, the optimal proportions of egg-white replacers are (2% SPI; 4.6% WPI; 3.4% PPI; 0.24% GG; 0.15% SA). The overall quality characteristics of sponge cakes made with egg white replacer were similar compared to the egg white.

Rederiving kinetics to model biohydrogen production from immobilized microalgae alginate beads at various polymerization degrees of alginate under dark fermentative environment

The performance of immobilized microalgae-alginate beads on biohydrogen production and its stability across several dark fermentation cycles is influenced by the sodium alginate concentrations. Thus, it is vital to determine the optimal condition for immobilization to achieve maximum encapsulation efficiency, stability and biohydrogen production. In this work, different sodium alginate concentrations (2 to 8 w/v%) were used to immobilize microalgae in influencing the dark fermentative biohydrogen productions from municipal wastewater, and its reusability was also investigated. The immobilized microalgae-alginate beads with sodium alginate concentration of 2 % showed the lowest stability and biohydrogen production in all cycles. The highest biohydrogen production was achieved by immobilized microalgal-alginate beads prepared from 8 % sodium alginate, followed by 6 % and 4 % in the first and second cycles. However, 8 % of immobilized microalgae-alginate beads generated the lowest biohydrogen volume during the third cycle. Besides, a model was rederived from the modified Gompertz model and Fick's law of diffusion equation to describe the relationship between polymeric viscosity and biohydrogen production from immobilized microalgae-alginate beads with different sodium alginate concentrations. As the sodium alginate concentrations increased, the viscosity also increased which significantly affected the properties of immobilization matrix formed such as encapsulation efficiency, growth of microalgae, diffusion of substrate and biohydrogen yield. The rederived model managed to fit the experimental data with a coefficient of determination values of >0.95 for all the polymerization degrees of alginate. The kinetic parameters, namely, yield of biohydrogen and specific microalgae growth rate of sodium alginate concentration of 6 % were 129.80 L kg−1 and 4.69 h−1, respectively, which were considered as maximum results as compared with other sodium alginate concentrations. Besides, the difference in biohydrogen productions for all cycles and kinetic data of biohydrogen yields obtained from the rederived model between sodium alginate concentration of 6 % and 8 % only exhibited a slight variance (<3 %). Thus, sodium alginate concentration of 6 % was considered to be an optimal for immobilizing microalgae in performing the dark fermentation. Overall, the results revealed the significance of suitable sodium alginate concentration in maximizing the immobilization of microalgae for performing the dark fermentative biohydrogen production.