{"id":541,"date":"2020-12-23T05:47:15","date_gmt":"2020-12-23T05:47:15","guid":{"rendered":"http:\/\/www.cd-bioparticles.net\/blog\/?p=541"},"modified":"2023-07-24T07:23:58","modified_gmt":"2023-07-24T07:23:58","slug":"oral-nano-drug-delivery-system-1","status":"publish","type":"post","link":"https:\/\/www.cd-bioparticles.net\/blog\/oral-nano-drug-delivery-system-1\/","title":{"rendered":"Oral Nano-drug Delivery System 1"},"content":{"rendered":"

With the development of new drug discovery related technologies such as high-throughput screening technology, a large number of drug candidates have been discovered, but their solubility is often low.\u00a040% to 70% of drug candidates are difficult to obtain therapeutic concentrationdue to low solubility and poor oral absorption.\u00a0In particular, protein and peptide drugs have large molecular weights, are not easy to penetrate biological membranes, are susceptible to the action of enzymes in the organism, and their oral bioavailability is very low.\u00a0According to the solubility and membrane permeability of the drug, drugs can be divided into 4 categories, namely the Biopharmaceutical Classification System (BCS): Class I is high solubility and high permeability drugs;\u00a0Class II is low solubility and high permeability drugs ;\u00a0Class III is a drug with high solubility and low permeability;\u00a0Class IV is a drug with low solubility and low permeability.\u00a0A large number of studies have proved that the nano drug delivery system can effectively improve the dissolution and oral bioavailability of class II, class III, and class IV drugs in BCS.\u00a0Nano drug delivery systems that can be used for oral administration include liposomes, polymer nanospheres\/nanocapsules, solid lipid nanoparticles, microemulsions, nanoemulsions, self-emulsifying microemulsions, polymer micelles, dendrimers, and nanodrug crystals, etc<\/i><\/em>.<\/p>\n

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Figure 1. The challemges of oral nano-drug delivery system.<\/figcaption><\/figure>\n

Liposomes<\/u><\/a>
\nAs a drug carrier, liposomes have a wide range of encapsulation, and water-soluble components, fat-soluble components and amphoteric substances can all be encapsulated.\u00a0Only the substances that are insoluble in both the water phase and the organic phase, or the substances that are highly soluble in both the water phase and the organic phase, are difficult to be wrapped due to easy leakage.\u00a0Liposomes have good targeting and slow-release properties, which can protect drugs from the degradation of enzymes in the intestinal tract and improve drug stability.\u00a0The lipid bilayer structure similar to biomembrane gives liposomes good cell affinity.\u00a0After oral administration, it is easy to fuse, absorb and exchange lipids with intestinal mucosal cells, promote drugs into human cells, and improve drug biology utilization.
\nWhen biological macromolecule drugs such as polypeptides, proteins, and nucleic acids are orally administered, they are easily destroyed by acid and enzymes in the gastrointestinal tract, and their bioavailability is very low.\u00a0Encapsulating these macromolecular drugs in liposomes can protect and promote absorption.\u00a0For example,\u00a0liposomes modified with PEG 2000 are stable in the gastrointestinal pH environment.\u00a0After coating insulin liposomes with chitosan and sodium alginate, oral administration in mice has a better effect on lowering blood sugar.<\/p>\n

One of the biggest obstacles of ordinary liposomes as an oral nano-drug delivery system is that they are extremely unstable under the synergistic effect of intestinal bile salts and intestinal enzymes.\u00a0Scientists hope to find orally stable liposomes.\u00a0The tetraether lipid PLFE was extracted from the archaea Sulfolobus acidocaldarius.\u00a0Compared with ordinary liposomes, the tetraether liposomes prepared by the film dispersion method are very stable in the gastrointestinal environment.\u00a0Tetraether liposomes can be used as oral vaccine carriers and insulin carriers, and the effect of lowering blood sugar is better. Liposomes of dipalmitoylphosphatidylcholine and dipalmitoylphosphatidylethanol will not be catalyzed by phospholipase A and can encapsulate insulin.\u00a0The liposome modified with N-trimethyl chitosan is used as the carrier of salmon calcitonin.\u00a0When N-trimethyl chitosan is about 78% quaternized, it has more mucosal adhesion than chitosan .\u00a0In vivo adhesion experiments show that compared with unmodified liposomes, N-trimethylchitosan modified liposomes stay longer in the body and have better permeability.<\/p>\n

Nanoparticles
\nNanoparticles can improve drug stability, extend the gastrointestinal retention time of drugs, change the distribution of drugs in the body, have the characteristics of slow release and targeted drug delivery, and have extensive research in improving the bioavailability of oral drugs.\u00a0Nanoparticles can be divided into:\u00a01, Natural polymer materials, such as albumin, gelatin, and chitosan according to the preparation materials; 2, Synthetic polymer materials<\/u><\/a>, such as polylactic acid glycolic acid (PLGA), polyalkylbutyl cyanoacrylate (PBCA); 3, Solid lipid materials, including natural or synthetic, steroids, and waxes.<\/p>\n