Preparation and characterization of Ganoderma lucidum spores-loaded alginate microspheres by electrospraying (2025)

Production of Ganoderma Lucidum Extract Loaded Gelatin-Sodium Alginate Microspheres, Investigation of Release Kinetics at Different pH Values and Evalution of Kinetic Models

Mugla Journal of Science and Technology

In this study, pH sensitive microsphere polymeric drug carriers were produced by using biodegradable natural gelatin and sodium alginate polymers. Microspheres were loaded with prepared Ganoderma lucidum extract that is a medicinal mushroom and has the potential to be used in several diseases' treatment. Extract release kinetics of the microspheres were examined by spectrophotometric method by using an UV spectrometer. Buffer solutions with different pH values were used as release medium for examination of drug release kinetics of the produced microspheres. The Ganoderma lucidum release of microspheres was presented in terms of percent cumulative release (CR%) defined as the percentage ratio of the instantaneous amount of Ganoderma lucidum released at a certain time of incubation to the initial amount of Ganoderma lucidum loadings. As a result, it was seen that the release of the extract accelerated as pH of the release medium increased and the fastest extract release was observed in the pH 7. The release kinetic models of the microspheres were examined. The release kinetics of microspheres fitted Higuchi model for pH 1.3, pH 5.0 and pH 6.0 and first-order model for pH 3.0 and pH 7.0.

Influence of Sodium Alginate Concentration on Microcapsules Properties Foreseeing the Protection and Controlled Release of Bioactive Substances

Journal of Chemistry, 2021

To understand the abilities of Ca-alginate microcapsules and their specific applications in different fields, it is necessary to determine the physicochemical and structural properties of those formulated microcapsules. In this work, we aimed to study the effect of alginate concentration in the improvement of the encapsulation efficiency (EE) and on the release of phenolic and flavonoid substances. The relationship between the structure of the encapsulated bioactive substance and Ca-alginate network and their effect on the EE and release kinetics have been investigated. The incorporation, structure, morphology, and phase properties of all elaborated materials were characterized by UV-spectroscopy, Fourier transform infrared (ATR-FTIR), scanning electron microscope (SEM), and X-ray diffraction (DRX). The results indicate that increasing the polymer concentration increases the EE and decreases the loading capacity (LC), whereas the effect of alginate polymer concentration on the relea...

Influence of surface morphology and structure of alginate microparticles on the bioactive agents release behavior

Carbohydrate Polymers, 2019

The structure-property relationship in alginate microparticles (microspheres and microcapsules prepared with or without Trichoderma viride spores (Tv) was investigated. Surface morphology, structure and release behavior from alginate microparticles strongly depend on calcium concentration and presence of Tv and chitosan layer. All microparticles exhibited a granular surface structure with substructures consisting of abundant smaller particles. In vitro active agents release study revealed that the increase in calcium cation concentration reduced the release rate of Tv (˜84% for microspheres;˜57% for microcapsules) and calcium cations (˜20% for microspheres;˜23% for microcapsules). The average decrease in k values due to chitosan layer addition is 41% for Tv and 93% for calcium ions, respectively. The underlying Tv release mechanism from microspheres is anomalous transport kinetics, whereas from microcapsules is controlled by Type II transport. The differences in microparticle surface properties did not affect the mechanism controlling calcium ions release detected as diffusion through microparticles.

Preparation and Characteristics of Alginate Microparticles for Food, Pharmaceutical and Cosmetic Applications

Polymers

Alginates are the most widely used natural polymers in the pharmaceutical, food and cosmetic industries. Usually, they are applied as a thickening, gel-forming and stabilizing agent. Moreover, the alginate-based formulations such as matrices, membranes, nanospheres or microcapsules are often used as delivery systems. Alginate microparticles (AMP) are biocompatible, biodegradable and nontoxic carriers, applied to encapsulate hydrophilic active substances, including probiotics. Here, we report the methods most frequently used for AMP production and encapsulation of different actives. The technological parameters important in the process of AMP preparation, such as alginate concentration, the type and concentration of other reagents (cross-linking agents, oils, emulsifiers and pH regulators), agitation speed or cross-linking time, are reviewed. Furthermore, the advantages and disadvantages of alginate microparticles as delivery systems are discussed, and an overview of the active ingre...

Chitosan-Coated Alginate Microcapsules Loaded with Herbal galactagogue Extract: Formulation Optimization and Characterization

2019

Many herbs and spices have been recommended traditionally as galactagogues and several commercial formulations prepared using herbs. Due to the presence of various compounds such as polyphenols, flavonoids, isoflavones, and terpenes, bitter and stringent taste is elicited that make the consumption of these herbal preparations unpleasant. Moreover, these compounds are unstable when exposed to environmental conditions. In this regard, different approaches are used for taste masking such as microencapsulation. In the present study, microcapsules containing herbal galactagogue extract were developed through emulsification/external gelation and Box-Behnken design was used to investigate the effects of independent variables (sodium alginate: 1-1.5%, calcium chloride: 0.2-1% and extract concentrations: 1-5%) on encapsulation efficiency (EE%). Following evaluation of the model, the optimum condition of encapsulation process was selected as 1.49% sodium alginate, 0.84 CaCl2, and 1.58% extrac...

Design, optimization and characterization of glutathione loaded- alginate microspheres for topical antiaging [Diseño, optimización y caracterización de microesferas de glutatión cargado de alginato para el antienvejecimiento tópico]

2019

Context: Glutathione in the reduced form (GSH) is the predominant intracellular form, which acts as a strong antioxidant. However, it has low skin permeability due to the high hydrophilicity. Hence, the objective of this study was to prepare GSH by using microspheres delivery system and adding surfactant to overcome the barrier function of the skin. Aims: To investigate the effect of polymer and surfactant on the characteristics and release profile of GSH-alginate microspheres. Methods: GSH-alginate microspheres were prepared using ionotropic gelation method by aerosolisation. A randomized full factorial design was applied to prepare four different formulations of glutathione loaded alginate microspheres. Design was applied for all formulations to study about effect of independent variables of polymer and crosslinker on the entrapment efficiency (EE), drug loading (DL), particle size, yield, and in vitro drug release profile. For release study, microspheres formulas were also compared to microspheres, which applied into gel base. Results: The GSH-alginate microspheres had a high EE ranging from 34.74 ± 0.07% to 56.63 ± 0.36%, with small particle sizes ranging from 1.89 ± 0.03 µm to 2.42 ± 0.08 µm, and drug loading ranging from 5.72 ± 0.05% to 6.23 ± 0.02%. The kinetic analysis of all release profiles was found to follow Higuchi's diffusion model. EE, DL, particle size, and yield variables had a significant effect on the dependent variables (p<0.05), and flux had no significant effect on the dependent variables (p>0.05). Conclusions: All formulas produced high yield and encapsulation efficiency and small size particles. From the 2 2 randomized full factorial design, there was showed that the combination of the use of surfactant and polymer concentration significantly affected DL and EE.

Alginates and similar exopolysaccharides in biomedical application and pharmacy: Controled delivery of drugs

Advanced technologies, 2016

Due to its biocompatibility, biodegradability, hydrophility, technological properties and vast availability, polysaccharides are widely used as natural non-toxic polymers in different branches of industry (food, cosmetic, textile, construction industries). Exopolysaccharides (as dextran, pullulan) have recently taken up a significant position in pharmaceutical industry. Alginate has an irreplaceable role in biomedicine, since its hydrogel form is successfully applied for immobilization of a wide range of enzymes, therapeutics, biochemical agents and different kinds of microorganisms and cells (herbal, animal or human). Alginate microspheres and microcapsules are used for controlled release of biologically active molecules, as well as cell carriers in tissue engineering. Special benefits are brought by the simplicity of configuration of alginate hydrogel, including the possibility of the controlled production of micro-and nanoparticles. Taking into account a very important role of alginates in the form of hydrogel in biomedicine, in this paper a specific attention is paid on the preparation and application of alginate matrices, microspheres and microcapsules that may have essential and unexchangeable usage/application. This paper therefore displays various possibilities of use of polysaccharide matrices for biomolecules, polysaccharide as excipients of pharmaceutical products for oral or local application, and provides a review of the examples of innovative applications.

Sodium Alginate—Natural Microencapsulation Material of Polymeric Microparticles

International Journal of Molecular Sciences

From the multitude of materials currently available on the market that can be used in the development of microparticles, sodium alginate has become one of the most studied natural anionic polymers that can be included in controlled-release pharmaceutical systems alongside other polymers due to its low cost, low toxicity, biocompatibility, biodegradability and gelatinous die-forming capacity in the presence of Ca2+ ions. In this review, we have shown that through coacervation, the particulate systems for the dispensing of drugs consisting of natural polymers are nontoxic, allowing the repeated administration of medicinal substances and the protection of better the medicinal substances from degradation, which can increase the capture capacity of the drug and extend its release from the pharmaceutical form.

Alginate microspheres prepared by internal gelation: Development and effect on insulin stability

International Journal of Pharmaceutics, 2006

Recombinant human insulin was encapsulated within alginate microspheres by the emulsification/internal gelation technique with the objective of preserving protein stability during encapsulation procedure. The influence of process and formulation parameters was evaluated on the morphology and encapsulation efficiency of insulin. The in vitro release of insulin from microspheres was studied under simulated gastrointestinal conditions and the in vivo activity of protein after processing was assessed by subcutaneous administration of extracted insulin from microspheres to streptozotocin-induced diabetic rats. Microspheres mean diameter, ranging from 21 to 287 m, decreased with the internal phase ratio, emulsifier concentration, mixer rotational speed and increased with alginate concentration. Insulin encapsulation efficiency, near 75%, was not affected by emulsifier concentration, mixer rotational speed and zinc/insulin hexamer molar ratio but decreased either by increasing internal phase ratio and calcium/alginate mass ratio or by decreasing acid/calcium molar ratio and alginate concentration. A high insulin release, above 75%, was obtained at pH 1.2 and under simulated intestinal pH a complete dissolution of microspheres occurred. Extracted insulin from microspheres decreased hyperglycemia of diabetic rats proving to be bioactive and showing that encapsulation in alginate microspheres using the emulsification/internal gelation is an appropriate method for protein encapsulation.

Synthesis of quercetin-encapsulated alginate beads with their antioxidant and release kinetic studies

Journal of Macromolecular Science, Part A, 2020

In this present study, different forms of quercetin encapsulated beads were synthesized, namely ionic cross-linked gel beads and cryogel beads. Fourier Transform Infrared (FT-IR) spectra of the beads were used to characterize and prove quercetin encapsulation in alginate beads. Swelling and drying profiles were studied. Besides, release kinetics of quercetin molecules from gel beads and cryogels were carefully investigated in two different solvent/media; dimethyl sulfoxide (DMSO) and Roswell Park Memorial Institute Medium (RPMI-1640). Based upon the release kinetic studies, it is found that quercetin release from alginate cryogel beads fits the first-order release model in DMSO and it depends on the concentration of quercetin in the beads. The release of quercetin from alginate gel beads was described by the Higuchi release model, which highlights the release of quercetin molecules through the pores of the matrix. In RPMI-1640, the release of quercetin from both forms of alginate beads fits zero-order release model and it indicates a constant release of quercetin per unit time. Finally, the radical scavenging activity of the quercetin quantities was tested by the 2,2-diphenyl-1-picrylhydrazyl (DPPH) test, and successful results were obtained compared to reference material.