The aim of the work was to review the literature data regarding the prospects for the creation and use of multifunctional fluorescent two-dye nanosystems, which enable investigating the distribution of fluorescent components with significant acceleration of the study and introduction of nanomedicines into practice. Special attention is paid to the use of two substances with hydrophobic and hydrophilic properties in one nanoparticle (NP), capable of penetrating a living cell. The method of fluorescence confocal microscopy enables observation of the nanoscale dynamics of distribution and stability of drugs over time. The concomitant use of doxorubicin (DOX) and curcumin (CUR) in single nanoparticle causes synergism in the action of medical drugs, and their own fluorescence makes it possible to use them as multifunctional fluorescent nanosystems. Results. Data from the literature indicate that the use of two or more fluorescent dyes provide an advantage over other, more expensive methods when studying the penetration and distribution of NPs in living samples. The use of nanocarriers is an effective way to significantly increase the bioavailability of those drugs, which are poorly soluble in water. A promising direction of nanomedicine is the creation of complex bio-compatible multifunctional nanomaterials based on several active drugs, with the simultaneous use of their enhancers and the strategy of active targeting. Such recent structures enable targeted and controlled penetration of medicinal compounds into the sites of localization of pathological processes, reducing the toxicity of drugs to normal cells. Conclusions. The use of the fluorescence microscopy method, as exemplified by the two dyes, DOX and CUR, enables to trace the stages of interaction of loaded DOX and CUR nanoparticles with cultured cells, and their release from NPs to determine their amount and localization in organelles cells.
The aim of the work was a generalization of literature data on the prospects for curcumin usage in biotechnology as a component for biologically active nanocomplexes with anti-inflammatory and antioxidant activity creation. It is emphasized that their effectiveness depends on the solubility in aqueous medium and on the metabolism rate decreasing in the body. Current trend is the development of creation methods of hydrophilic curcumin-based nanostructures to increase the time of its biological action. Its nanostructures with silicium, polylysine, copolymers of lactic and glycolic acids and metal ions are the most promising in this respect. For multicomponent hybrid nanoparticles effective usage the substantiation of their component combined use features is necessary. The practical task is to create and to study the functional properties of such combined nanocomplexes. Curcumin complex with metal ions creation contributes to its water solubility and to increase the efficiency of biological action. These complexes have specific characteristics depending on the nature of metal ion. The creation of curcumin-based biocompatible nanocomposites with amplifiers of its action that are known pharmaceuticals is perspective. Such multifunctional nanocomplexes will facilitate the targeted medicines delivery to the places of pathological processes localization and the reduction of their side effects.
The use of multifunctional nanosystems in medicine and research is of contemporary interest. Aim. The purpose of the work was to summarize publications on the prospects of creating and using nanocontainers based on curcumin (Cur). Cur fluorescence in nanoparticles (NP) makes it possible to investigate the distribution of fluorescent and non-fluorescent components, significantly accelerating the study and implementation of drugs in practice. Particular attention is paid to the use of hydrophobic substances in NP, to penetrate into a living cell. Understanding the interaction of NP with living cells is extremely important when these particles are used to transport and deliver water-insoluble drugs to cells. Cur is one of the drugs with various and very promising pharmaceutical effects, it is poorly soluble in aqueous media, and the use of nanocarriers is an effective way to significantly increase its bioavailability. Cur has its own fluorescence, which enables to use it in multifunctional fluorescent nanosystems, for example, with Pluronic® micelles. The use of the fluorescence method makes it possible to trace the stages of interaction of Cur-loaded NP with cultured cells and their localization in cell organelles. With this approach, nanoscale dynamics of drug distribution and stability is observed over time. Conclusions. The main conclusion is that for unstable in the aquatic environment drugs such as Cur, it is necessary to use the most hydrophobic nanostructures without traces of water, which include the nuclei of Pluronic® micelles. This method makes it possible to use other poorly water-soluble drugs. A promising area of nanomedicine is the creation of complex bio-compatible nanomaterials based on several active drugs that reduce the toxicity of preparations to normal cells.
The aim of the work was to review literature data on combined nanochemotherapy using the example of two drugs ̶doxorubicin and curcumin. Special attention was paid to the use of substances with synergistic properties in one nanoparticle, capable to penetrate into living cell. The method of combined chemotherapy of nanopreparations improves processing efficiency. The technique of using nanocontainers with synergistic drugs in combination with ligands reduces the side effects of chemotherapy drugs. Results. Literature data indicate that the use of nanopreparations contributes the rapid creation and use of synergistic combinations that were purposefully delivered to target cells, reducing dosage due to precise targeting. A promising direction of nanomedicine is the creation of multifunctional nanomaterials based on several active drugs having synergistic properties, with the simultaneous use of their enhancers and the strategy of active targeting. These structures enabled targeted and controlled penetration of medicinal compounds into the localization of pathological processes, reducing drugs toxicity for normal cells. Conclusions. Combined chemotherapy using polymers and nanoparticles with ligands, in which synergistic drugs are included, ensures to reduce side effects and doses of chemotherapy drugs, and helps to overcome multiple drug resistance as well.
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