Construction and evaluation of liraglutide delivery system based on milk exosomes: a new idea for oral peptide delivery

Background: Increasing the bioavailability of peptide or protein drugs has always been an essential topic in pharmacy. Milk exosomes as a carrier for oral drug delivery systems have begun to attract attention in recent years. The application of oral milk exosomes carriers to peptide drugs such as liraglutide is worth trying. Objective: Milk-derived exosomes are used in this study to encapsulate the GLP-1 receptor agonist liraglutide. It also explored the feasibility of using this drug delivery system for oral biomolecules delivery in the future. Methods: The size and morphology of milk exosomes were characterized. The gastrointestinal stability of milk exosomes was evaluated in a dialysis bag. The cellular uptake of milk exosomes in an intestinal cell was observed. Six drug loading methods have been evaluated and compared preliminarily, and they are the incubation method, sonication method, extrusion method, freeze-thaw cycles method, saponin-assisted method, and electroporation method. Results: As demonstrated in this study, milk exosomes showed significant stability in the gastrointestinal environment and excellent affinity with intestinal cells, indicating their unique benefits used for oral drug delivery. Effective drug loading method for exosomes is challenging. Among the six drug loading methods used in this study, the liraglutide-Exo prepared by the extrusion method obtained the most significant drug load, which was 2.45 times the direct incubation method. The liraglutide-Exo obtained by the freeze-thaw cycles method has the slightest morphological change. Conclusion: The study showed milk exosome-based oral drug delivery systems are promising.

A Review on Lipid Based Oral Drug Delivery Systems

The main problem in oral drug formulations is low and erratic bioavailability, which is mainly due to poor aqueous solubility. This can lead to high inter- and intra-individual variability, lack of dose proportionality, and failure. Improving the bioavailability of drugs with such properties presents one of the greatest challenges in formulations. Oral lipid-based formulations are interesting considerable attention due to their ability to improve solubility, facilitate gastrointestinal absorption, and reduce or eliminate the effect of food on poor water absorption. soluble lipophilic drug and therefore increases bioavailability. This review describes recent findings on Potential Advantages of these Systems, Types of Lipid-Based Drug Delivery Systems, Guidelines for Design of Lipid-Based Formulations, problems solved by LBDDS, Characterization of Lipid-Based Drug Delivery Systems, Applications of lipid-based formulations, including traditional medicine (TM), new trends in LBDDS, Regulatory Aspects has also been examined in the current revision.

DETERMINATION OF THE OPTIMAL CONCENTRATIONS OF PECTIN AND CALCIUM CHLORIDE FOR THE SYNTHESIS OF CHITOSAN-PECTIN MICROPARTICLES

"The oral route of drug inclusion is the most convenient for the patient. In addition to ease of use, this method of drug inclusion has such advantages as non-invasiveness of inclusion, absence of complications during injection; comparative safety for the organism due to the passage of the active substance and auxiliary compounds through the gastrointestinal tract; the possibility of introducing larger doses of the drug at one time. However, despite the obvious advantages, the oral route of inclusion has a number of significant disadvantages that significantly limit its use for a number of drugs. Among them are: relatively slow therapeutic action of the drug with this route of inclusion; the aggressive effect of a number of drugs (for example, antibiotics) on the gastrointestinal tract; low bioavailability of a number of substances (especially high molecular weight hydrophilic compounds), caused by poor permeability of the intestinal epithelium for hydrophilic and large molecules, as well as enzymatic and chemical degradation of the active substance in the gastrointestinal tract. There are various approaches used in the development of oral drug delivery systems. In particular, for the targeted delivery of drugs, it is proposed to use nano- and microcapsules with mucoadhesive properties. Among the polymers used for the synthesis of these microparticles, it is preferable to use pH-dependent, gelable biopolymers that change their structure depending on the acidity of the environment. Microcapsules obtained from compounds with the above properties are capable of protecting the active substance (or from the active substance) in the stomach environment and ensuring its release in the intestine. These properties are possessed by such polysaccharides as alginate, pectin, carrageenan, xylan, etc. The listed biopolymers are non-toxic, biocompatible, and biodegradable, which makes microparticles containing these polysaccharides promising as oral drug delivery systems. To impart mucoadhesive properties to nanoparticles, complexes of the listed polymers with chitosan are used. In this research, pectin, a polysaccharide formed mainly by residues of galacturonic acid, was used as a structural polymer. The concentrations of substances in the initial solutions were selected that were optimal for the synthesis of microcapsules. The main parameters for evaluating the resulting microparticles were the size of the capsules (less than 1 μm for oral inclusion), the zeta-potential, showing the tendency of the microparticles to stick together, and the completeness of the binding of the microparticles to chitosan. It was found that the optimal solutions for the synthesis of microparticles are: 15.7 ml of a solution of pectin 0.093% by weight, 3.3 ml of a solution of chitosan 0.07% by weight and 1.0 ml of a solution of CaCl2 20 mM. The diameter of the microparticles obtained by this method was 700-800 nm, and the value of their zetta-potential, equal to - (34 ± 3) mV, does not cross the particle adhesion threshold. It was also found that the synthesis of microparticles at these concentrations of calcium chloride provides the most complete binding of chitosan to their surface, which increases the mucoadhesive properties of microparticles."

Review on Disease, Dose, Destination and Delivery Aspects of Simvastatin

Statins are the choice of drugs for the treatment and management of hypercholesterolaemia because of their established lipid-lowering efficacy and safety profile. Among the various statins, simvastatin is a very popular antihyperlipidemic drug with pleiotropic effects that have a wide range of applications such as antioxidant, anti-inflammatory, antifibrotic effect as well as angiogenic activity. However, poor biopharmaceutical characteristics like low solubility and high permeability make this drug more challenging for formulation scientists in terms its delivery to different targeted areas. Oral drug delivery systems, lipid nanoparticles, PLGA nanoparticles, sustained-release tablets, matrix-type transdermal, co-encapsulating nanostructured lipid carriers are some of the strategies that have been explored to address this issue. This review provides an update regarding the disease, destination, dose and delivery associated with this wonderful lipid-lowering drug molecule.